NAVAIR Ol-F14AAD-1
NATOPS FLIGHT MANUAL NAVY MODEL
F-l 4D AIRCRAFT THIS PlJBLlCATlON SUPERSEDES NAVAlR DATED 1 FEBRUARY 1992 AND CHANGED THIS PUBLICATION NAVAIR 01-Fl4AAP-1.1 TACTICAL
SOFTWARE
01-Fl4AAD-1 15 MAY 1995
IS INCOMPLETE WITHOUT AND NAVAIR 01-Fl4AAD-IA EFFECTIVITY:
OFP DO1
DISTRIBUTION STATEMENT C Distribution authorfred to U.S. Government agencies and their contractors to protect publications required for official use or for administrative or operational purposes only (1 March 1990). Other requests for this document shall be referred to Commanding Dffrcer, Naval Alr Technical Services Facility, Defense Distribution Depot Susquehanna Pennsylvania, Bldg. 05, !5480 Carlisle Pike, Mechanicsburg, PA 17058-0789. DESTRUCTlON NOTlCE - For unclassified, limited documents, destroy by any method that will prevent disclosure of contents or reconstruction of the document. ISSUED
0801LP0141980
BY AUTHORlTY OF THE CHIEF OF NAVAL OPERATIONS AND UNDERTHE DIRECTION OF THE COMMANDER, NAVAL AIR SYSTEMS COMMAND
’ @merse B1=nk) 1 FEBRUARY 1997 NATEC ELECTRONIC MANUAL
NAVAIR Ol-F14AAD-1
DEPARTMENT OF THE NAVY CHIEF OF NAVAL OPERATIONS 2000NAVY PENTAGON WASHINGTON, D.C. 20350-2000 I February 1997
LETTER OF PROMULGATION 1. The Naval Air Training and OperatingProceduresStandardization(NATOPS) Program is a positive approachtoward improving combat readinessand achieving a substantialreduction in the aircraft mishaprate. Standardization,basedon professionalknowledgeandexperience,providesthe basisfor developmentof an efficient andsoundoperationalprocedure.The standardizationprogram is not plannedto stifle individual initiative, but rather to aid the commanding officer in increasing theunit’s combatpotential without reducingcommandprestigeor responsibility. 2. This manual standardizesground and flight proceduresbut doesnot include tactical doctrine. Compliance with the stipulated manual requirements and proceduresis mandatory except as authorizedherein.In orderto remain effective,NATOPS must be dynamic and stimulateratherthan suppressindividual thinking. Since aviation is a continuing, progressive profession, it is both desirableandnecessarythat new ideasand new techniquesbe expeditiouslyevaluatedand incorporated if proven to be sound. To this end, commanding officers of aviation units are authorizedto modify procedurescontained herein, in accordancewith the waiver provisions establishedby OPNAVINST 3710.7, for the purposeof assessingnew ideasprior to initiating recommendations for permanentchanges.This manual is preparedand kept current by the users in order to achieve maximum readinessand safety in the most efftcient and economicalmanner. Should conflict exist between the training and operating proceduresfound in this manual and those found in other publications,this manual will govern. 3. Checklistsandotherpertinentextractsfrom this publication necessaryto normal operationsand training shouldbe made and carried for use in naval aircraft.
DENNIS V. McGINN RearAdmiral, U.S. Navy Director, Air Warfare
3 (ReverseBlank)
ORIGINAL
NAVAIR 01.F14AAD-1
I
INTERIM CHANGE SUMMARY
I]
The following Interim Changes have been canceled orpreviously incorporated in this manual: INTERIM CHANGE
1 through 8
REMARKS/PURPOSE
Previously incorporated
Xkfollowing
Interim Changes have been incorporated in this Change/Revision:
INTERIM CHANGE NUMBER(S)
REMARKSIPURPOSE
9
Dual CompressorStall Warnings
10
Dual CompressorStall/EngineFlameout Warnings
11
APX-100 AUDIO/TJGHT/OUT Switch
12
ConferenceReview Advance ChangeItems
13
Flap and Slat Asymmetry Procedure
14
Modifies Information andProceduresfor Spoiler Malfunctions
15
ChangesF-14 CurrencyRequirements
16
Modifies Information and Proceduresfor On-Deck EmergencyEgress Interim Changes Outstanding - To be maintained by the custodian of this manual:
INTERIM CHANGE NUMBER
ORIGINATOWDATE (or DATE/TIME GROUP)
PAGES AFFECTED
REMARKS/PURPOSE
ORIGINAL
RAAUZYUW RUENAAA0187 2471749-UUUU--RUENCGU. ZNR UUUUU R 041749Z SEP 01 ZYB FM CNO WASHINGTON DC//N789J3// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// RHMFIUU/NAVOPMEDINST PENSACOLA FL//06// BT UNCLAS SECTION 01 OF 03 MSGID/GENADMIN/N789J// SUBJ/INTERIM CHANGES TO F-14ABD AIRCRAFT NATOPS FLIGHT PUBLICATIONS/ SAFETY OF FLIGHT// REF/A/DOC/NAVAIR 01-F14AAA-1/YMD:19970201// REF/B/DOC/NAVAIR 01-F14AAP-1/YMD:19970201// REF/C/DOC/NAVAIR 01-F14AAD-1/YMD:19970201// REF/D/DOC/NAVAIR 01-F14AAA-1B/YMD:19970201// REF/E/DOC/NAVAIR 01-F14AAP-1B/YMD:19970201// REF/F/DOC/NAVAIR 01-F14AAD-1B/YMD:19970201// REF/G/LTR/VF-101/YMD:20010719// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF C IS NAVAIR 01-F14AAD-1 ((F-14D NATOPS FLIGHT MANUAL (NFM)). REF D IS NAVAIR 01-F14AAA-1B (F-14A NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF E IS NAVAIR 01-F14AAP-1B ((F-14B NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF F IS NAVAIR 01-F14AAD-1B ((F-14D NATOPS POCKET CHECKLIST (PCL)). REF G IS VF-101 LTR 3711 SER 20/1479; SUBJ: F-14 NATOPS REVIEW CONFERENCE REPORT.// RMKS/1. THIS IS INTERIM CHANGE (IC) NUMBER 148 TO REF A (F-14A NFM), IC NUMBER 46 TO REF B (F-14B NFM), IC NUMBER 26 TO REF C (F-14D NFM), IC NUMBER 104 TO REF D (F-14A PCL), IC NUMBER 30 TO REF E (F-14B PCL), AND IC NUMBER 15 TO REF F (F-14D PCL). 2. SUMMARY. THIS IC MSG DIRECTS ENTRY OF THE ADVANCE CHANGE ITEMS FROM THE 19-22JUN01 F-14A/B/D NATOPS REVIEW CONFERENCE WHICH MODIFY EMERGENCY PROCEDURES FOR DOUBLE GENERATOR FAILURE, UNCOMMANDED ROLL AND/OR YAW, AND SPOILER MALFUNCTION/SPOILER STUCK UP IN REFS A THROUGH F. 3. CHANGE REFS A, B, AND C, WITH ALL PREVIOUS IC'S INCORPORATED, AS FOLLOWS: A. LIST OF ACRONYMS AND ABBREVIATIONS. (1) DELETE: NA (2) ADD (INSERT) ABBREVIATION FOR INBOARD ON PAGE 46 OF REF A, AND ON PAGE 44 OF REFS B AND C, RESPECTIVELY, AS FOLLOWS: INBD. INBOARD. (3) ADD (INSERT) ABBREVIATION FOR OUTBOARD ON PAGE 47 OF REF A, AND ON PAGE 46 OF REFS B AND C, RESPECTIVELY, AS FOLLOWS: OUTBD. OUTBOARD. B. DOUBLE GENERATOR FAILURE: (1) DELETE: REF A (F-14A NFM), DFCS SUPPLEMENT, PAGE 14-4X, PARAGRAPH 14.7.2 (DOUBLE GENERATOR FAILURE), REF B (F-14B NFM), DFCS SUPPLEMENT, PAGE 14-4X, _______________________________________________________________________ CNO 041749Z SEP01 Page 1 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
PARAGRAPH 14.7.2 /(DOUBLE GENERATOR FAILURE), AND/OR REF C (F-14D NFM), DFCS SUPPLEMENT, PAGE 14-4X, PARAGRAPH 14.7.2 (DOUBLE GENERATOR FAILURE): (2) ADD (REPLACE WITH) IN EACH NFM: 14.7.2 DOUBLE GENERATOR FAILURE. 1. BOTH GENERATOR SWITCHES -- CYCLE. WHEN OPERATING ON EMERGENCY GENERATOR, THE FOLLOWING IMPORTANT SYSTEMS ARE INOPERATIVE: A. EMERGENCY FLIGHT HYDRAULICS. B. OUTBOARD SPOILER MODULE AND EMERGENCY FLAPS ACTIVATION. C. OBOGS CONCENTRATOR HEATER (F-14D ONLY) (OBOGS MAY STILL FUNCTION AT A REDUCED, BUT ADEQUATE LEVEL). 2. IF TEMPORARY LOSS OF COMBINED SYSTEM PRESSURE CAUSES EMERGENCY GENERATOR TO SHIFT TO 1-KVA MODE: EMERG GENERATOR SWITCH -- CYCLE. CAUTION A SHIFT TO 1-KVA MODE WILL CAUSE LOSS OF ALL DFCS FUNCTIONS AND SPOILERS WITHOUT ILLUMINATION OF CAUTION LIGHTS. IF THE 5-KVA MODE IS REGAINED, A MASTER RESET WILL BE REQUIRED TO REGAIN SAS, SPOILER, AUTHORITY STOP, AND ARI FUNCTIONS. NOTE DFCS SYNCHRONIZATION CAN TAKE UP TO 2 SECONDS FOLLOWING A POWER INTERRUPT. IF THE MASTER RESET PUSHBUTTON IS DEPRESSED DURING THE SYNCHRONIZATION TIME, AN ADDITIONAL DEPRESSION OF THE MASTER RESET PUSHBUTTON WILL BE REQUIRED TO RESTORE SPOILER FUNCTIONALITY. 3. LAND AS SOON AS PRACTICABLE. C. UNCOMMANDED ROLL AND/OR YAW: (1) DELETE: REF A (F-14A NFM), CHAPTER 14, PAGE 14-31, PARAGRAPH 14.12.1 (UNCOMMANDED ROLL AND/OR YAW), REF B (F-14B NFM), CHAPTER 14, PAGES 14-33 AND 14-34, PARAGRAPH 14.12.1 (UNCOMMANDED ROLL AND/OR YAW), AND/OR REF C (F-14D NFM), CHAPTER 14, PAGE 14-37, PARAGRAPH 14.12.1 (UNCOMMANDED ROLL AND/OR YAW): (2) ADD (REPLACE WITH) IN EACH NFM: 14.12.1 UNCOMMANDED ROLL AND/OR YAW. NOTE IF UNCOMMANDED ROLL AND/OR YAW OCCURS DURING HIGH-AOA MANEUVERING (ABOVE 15 UNITS), ASSUME DEPARTURE FROM CONTROLLED FLIGHT AND APPLY APPROPRIATE DEPARTURE AND/OR SPIN RECOVERY PROCEDURES. NOTE FAILURES THAT MAY CAUSE UNCOMMANDED ROLL AND/OR YAW INCLUDE, BUT ARE NOT LIMITED TO: A. ENGINE FAILURE. B. STUCK UP SPOILER. C. ASYMMETRIC FLAPS AND/OR SLATS. _______________________________________________________________________ CNO 041749Z SEP01 Page 2 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
D. UNCOMMANDED DIFFERENTIAL STABILIZER AND/OR RUDDER AUTOMATIC FLIGHT CONTROL SYSTEM INPUTS CAUSED BY ABNORMAL POWER TRANSIENTS. E. HARDOVER RUDDER. 1. IF FLAP TRANSITION: FLAP HANDLE -- PREVIOUS POSITION. 2. RUDDER AND STICK -- OPPOSITE ROLL/YAW. NOTE FOR SPOILER MALFUNCTION, USE LATERAL STICK AS PRIMARY LATERAL CONTROL AND RUDDER ONLY AS NEEDED TO MAINTAIN BALANCED FLIGHT. 3. AOA -- BELOW 12 UNITS. 4. DOWNWING ENGINE -- MAX THRUST (IF REQUIRED). 5. MASTER RESET PUSHBUTTON -- DEPRESS. NOTE DFCS SYNCHRONIZATION CAN TAKE UP TO 2 SECONDS FOLLOWING A POWER INTERRUPT. IF THE MASTER RESET PUSHBUTTON IS DEPRESSED DURING THE SYNCHRONIZATION TIME, AN ADDITIONAL DEPRESSION OF THE MASTER RESET PUSHBUTTON WILL BE REQUIRED TO RESTORE SPOILER FUNCTIONALITY. 6. ROLL SAS -- ON. 7. ROLL TRIM -- OPPOSITE STICK (IF REQUIRED). 8. OUT OF CONTROL BELOW 10,000 FEET AGL -- EJECT. 9. CONTROL REGAINED -- CLIMB AND INVESTIGATE FOR THE FOLLOWING: A. FLAP AND SLAT ASYMMETRY. B. SAS MALFUNCTION. NOTE SAS FAILURE MAY CAUSE UNCOMMANDED ROLL AND/OR YAW, EVEN WITHOUT ILLUMINATION OF THE ASSOCIATED LIGHTS. C. SPOILER MALFUNCTION. D. HARDOVER RUDDER. E. STRUCTURAL DAMAGE. 10. SLOW-FLY AIRCRAFT TO DETERMINE CONTROLLABILITY AT 10,000 FEET AGL MINIMUM. D. SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP: (1) DELETE: REF A (F-14A NFM), DFCS SUPPLEMENT, PAGE 14-15X AND 14-16X, PARAGRAPH 14.12.11.3 (SPOILERS CAUTION LIGHT/ SPOILER MALFUNCTION/SPOILER STUCK UP), REF B (F-14B NFM), DFCS SUPPLEMENT, PAGES 14-15X AND 14-16X, PARAGRAPH 14.12.9.3 (SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP), AND/OR REF C (F-14D NFM), DFCS SUPPLEMENT, PAGES 14-17X AND 14-18X, PARAGRAPH 14.12.7.3 (SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP): (2) ADD (REPLACE WITH) AS PARAGRAPH 14.12.11.3 IN F-14A NFM, AS PARAGRAPH 14.12.9.3 IN F-14B NFM, AND/OR AS PARAGRAPH 14.12.7.3 IN F-14D NFM): 14.12.11.3 SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/ SPOILER STUCK UP. _______________________________________________________________________ CNO 041749Z SEP01 Page 3 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
CAUTION IF THE CURRENT CONFIGURATION IS ACCEPTABLE FOR LANDING, CAREFUL CONSIDERATION SHOULD BE GIVEN BEFORE DEPRESSING MASTER RESET WHEN A SPOILER ACTUATOR MECHANICAL MALFUNCTION IS SUSPECTED. A DEPLOYED SPOILER THAT RESULTED FROM DFCS COMPUTERS DROPPING OFF LINE IS NOT CONSIDERED A MECHANICAL FAILURE. NOTE USE LATERAL STICK AS PRIMARY CONTROL AND RUDDER ONLY AS NEEDED TO MAINTAIN BALANCED FLIGHT. NOTE SUBSEQUENT DEPRESSION OF THE MASTER RESET PUSHBUTTON MAY CLEAR FAILURE UNTIL SPOILER IS COMMANDED TO MOVE AGAIN. 1. MASTER RESET PUSHBUTTON -- DEPRESS. NOTE DFCS SYNCHRONIZATION CAN TAKE UP TO 2 SECONDS FOLLOWING A POWER INTERRUPT. IF THE MASTER RESET PUSHBUTTON IS DEPRESSED DURING THE SYNCHRONIZATION TIME, AN ADDITIONAL DEPRESSION OF THE MASTER RESET PUSHBUTTON WILL BE REQUIRED TO RESTORE SPOILER FUNCTIONALITY. IF FAILURE REMAINS/REOCCURS: 2. AVOID ABRUPT LATERAL CONTROL MOVEMENTS AND HIGH ROLL RATES. CAUTION WITH WINGS FORWARD OF 62 DEGREES, EXCESSIVE HORIZONTAL TAIL DIFFERENTIAL MAY CAUSE SEVERE STRUCTURAL DAMAGE. IF SPOILER(S) FAIL DOWN: 3. PERFORM CONTROLLABILITY CHECK PROCEDURE, PARAGRAPH 14.11.7. IF SPOILER(S) REMAIN UP OR FLOATING, OR IF CONTROL UNSATISFACTORY WITH FLAPS DOWN: NOTE ANY SINGLE, FULLY-DEFLECTED, FAILED-UP SPOILER IS CONTROLLABLE EVEN WITH FLAPS DOWN IF THE REMAINING SPOILERS ARE OPERATING. WITH MULTIPLE FAILURES, AIRCRAFT CONFIGURATION IS THE CRITICAL FACTOR. WITH FLAPS DOWN, ROLL CONTROL USING LATERAL STICK ALONE MAY BE IMPOSSIBLE. HOWEVER, WITH FLAPS UP, ADEQUATE ROLL CONTROL TO REGAIN WINGS LEVEL FLIGHT IS AVAILABLE WITH USE OF LATERAL STICK ALONE. CHOICE OF FLAP POSITION FOR LANDING AND CV RECOVERY/DIVERT DECISION SHOULD BE MADE FOLLOWING A CONTROLLABILITY CHECK. 4. PERFORM CONTROLLABILITY CHECK PROCEDURE, PARAGRAPH 14.11.7, USING MANEUVERING FLAP/SLAT (PREFERRED) OR NO-FLAP CONFIGURATION ONLY. NOTE IF CONTROLLABILITY IS UNSUITABLE FOR LANDING APPROACH DUE TO COMPLETE LOSS OF SPOILERS, _______________________________________________________________________ CNO 041749Z SEP01 Page 4 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
CONSIDERATION MAY BE GIVEN TO ATTEMPTING A POWER ON RESET IN AN ATTEMPT TO REGAIN AT LEAST ONE SPOILER SET. SEE DFCS FOR PROCEDURES (F-14A PARAGRAPH 14.12.11.4, F-14B PARAGRAPH 14.12.9.4, AND F-14D PARAGRAPH 14.12.7.4). IF CONTROLLABILITY SATISFACTORY: 5. PERFORM MANEUVER FLAP/SLAT OR NO-FLAP STRAIGHT-IN APPROACH AT OR ABOVE MINIMUM CONTROL AIRSPEED. IF CONTROLLABILITY STILL UNSATISFACTORY: WARNING WITH BOTH INBD AND OUTBD SPOILER CONTROL CB'S PULLED, ALL OPPOSING SPOILER CONTROL WILL BE LOST. CAUTION MARGINAL CONTROL OR LOSS OF CONTROL MAY BE EXPERIENCED DUE TO REMOVAL OF A SPOILER SET WITH MULTIPLE FAILURES PRESENT. NOTE IT MULTIPLE FAILED-UP SPOILER PANELS RESULT IN UNSATISFACTORY HANDLING QUALITIES REGARDLESS OF FLAP POSITION, AN ATTEMPT MAY BE MADE TO FAIL THE PANELS DOWN BY REMOVING POWER VIA THE CORRESPONDING SPOILER CONTROL CB'S. THIS MAY TAKE AS LONG AS 60 SECONDS, AND RESULT IN A MARGINAL CONTROL SITUATION OR A LOSS OF CONTROL SITUATION BECAUSE POWER TO THE OTHER SPOILERS HAS BEEN REMOVED. THEREFORE, IT SHOULD BE CONSIDERED ONLY AS A LAST RESORT. 5. SPOILER CONTR CB FOR AFFECTED PAIR -- PULL (7G9 FOR INBD, 8C5 FOR OUTBD IN F-14A/B), (8G9 FOR INBD, 9C5 FOR OUTBD IN F-14D). IF UNCONTROLLABLE ROLL, OR NO IMPROVEMENT IN CONTROLLABILITY: 6. SPOILER CONTR CB (AFFECTED SPOILER) -- RESET. 7. MASTER RESET PUSHBUTTON -- DEPRESS. FUNCTIONALITY LOST FROM CYCLING SPOILER CONTROL CB WILL NOT BE REGAINED UNTIL THE MASTER RESET PUSHBUTTON IS DEPRESSED. 8. IF UNSUITABLE FOR LANDING,PERFORM CONTROLLED EJECTION. IF CONTROLLABILITY IMPROVES: 9. PERFORM STRAIGHT-IN APPROACH IN BEST CONFIGURATION WITH CB(S) OUT. NOTE OUTBOARD SPOILER POSITION INDICATORS WILL INDICATE DOWN WITH CB 8C5 (F-14A/B) OR 9C5 (F-14D) PULLED. NOTE WITH CB'S 7G9 AND 8C5 (F-14A/B) OR 8G9 AND 9C5 (F-14D) PULLED, GROUND ROLL BRAKING IS NOT AVAILABLE. RESET ON LANDING ROLLOUT IF DESIRED. 4. CHANGE REFS D, E, AND F, WITH ALL PREVIOUS IC'S INCORPORATED, AS FOLLOWS: A. DOUBLE GENERATOR FAILURE: _______________________________________________________________________ CNO 041749Z SEP01 Page 5 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
(1) DELETE: REF D (F-14A PCL), PAGE 24, DOUBLE GENERATOR FAILURE PROCEDURE, REF E (F-14B PCL), PAGE 26, DOUBLE GENERATOR FAILURE PROCEDURE, AND/OR REF F (F-14D PCL), PAGE 38, DOUBLE GENERATOR FAILURE PROCEDURE: (2) ADD (REPLACE WITH) IN EACH PCL AS CONTAINED IN PARAGRAPH 3.B(2) ABOVE, EXCEPT OMIT PROCEDURE PARAGRAPH NUMBER. B. UNCOMMANDED ROLL AND/OR YAW: (1) DELETE: REF D (F-14A PCL), PAGE 47, UNCOMMANDED ROLL AND/OR YAW PROCEDURE, REF E (F-14B PCL), PAGE 57, UNCOMMANDED ROLL AND/OR YAW PROCEDURE, AND/OR REF F (F-14D PCL), PAGE 71, UNCOMMANDED ROLL AND/OR YAW PROCEDURE: (2) ADD (REPLACE WITH) IN EACH PCL AS CONTAINED IN PARAGRAPH 3.C(2) ABOVE, EXCEPT: (A) OMIT PROCEDURE PARAGRAPH NUMBER, AND (B) OMIT NOTES THAT PRECEDE STEP 1. C. SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP: (1) DELETE: REF D (F-14A PCL), PAGES 48 AND 49, SPOILERS CAUTION LIGHT/ SPOILER MALFUNCTION/SPOILER STUCK UP, REF E (F-14B PCL), PAGES 58, 58A, AND 59, SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP), AND/OR REF F (F-14D PCL), PAGES 72, 72A, AND 73, SPOILERS CAUTION LIGHT/SPOILER MALFUNCTION/SPOILER STUCK UP: (2) ADD (REPLACE WITH) IN EACH PCL AS IN PARAGRAPH 3.D(2) ABOVE, EXCEPT: (A) OMIT PROCEDURE PARAGRAPH NUMBER, (B) REPLACE PARAGRAPH 14.11.7 (CONTROLLABILITY CHECK) REFERENCES IN STEPS 3 AND 4 WITH "PAGE 46" IN F-14A PCL, "PAGE 56" IN F-14B PCL, AND "PAGE 70" IN F-14D PCL, AND (C) REPLACE PARAGRAPH 14.12.7 (DFCS POR) REFERENCE IN STEP 4 NOTE WITH "PAGES 46A THROUGH 46C" IN F-14A PCL, "PAGES 56A THROUGH 56C" IN F-14B PCL AND "PAGES 70A THROUGH 70C" IN F-14D PCL. 5. CONTACT VF-101 F-14A/B/D NATOPS PROGRAM MANAGER, LT GREG KNEPPER, AT DSN 433-5147 OR COMM (757)433-5147, FAX DSN 433-4368 OR (757)4334368, OR E-MAIL
[email protected] IF REF G OR REPLACEMENT PAGES ARE REQUIRED. NAVAIR 4.1.1.1 POC IS LCDR SCOTT PORTER, AT DSN 757-7017 OR COMM (301)757-7017, OR EMAIL
[email protected]. 6. THIS MESSAGE AND ALL OTHER NATOPS INTERIM CHANGES WILL BE POSTED ON THE NATEC WEBSITE, WWW.NATEC.NAVY.MIL, WITHIN 15 DAYS OF THE RELEASE OF THIS MESSAGE. IF UNABLE TO VIEW THIS MESSAGE AT THE NATEC WEBSITE, PLEASE INFORM THE CNO NATOPS OFFICE AT DSN 288-5797 OR COMM (202)433-5797.// BT
_______________________________________________________________________ CNO 041749Z SEP01 Page 6 of 6 NA 01-F14AAA-1 IC 148 NA 01-F14AAP-1 IC 46 NA 01-F14AAD-1 IC 26 NA 01-F14AAA-1B IC 104 NA 01-F14AAP-1B IC 30 NA 01-F14AAD-1B IC 15
RAAUZYUW RUENAAA0915 0951755-UUUU--RUEASUU. ZNR UUUUU R 051758Z APR 01 ZYB ZYW FM CNO WASHINGTON DC//N789J// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO NAVOPMEDINST PENSACOLA FL BT UNCLAS //N04790// MSGID/GENADMIN/N789// SUBJ/INTERIM CHANGES TO F-14 AIRCRAFT NATOPS FLIGHT PUBLICATIONS /SAFETY OF FLIGHT// REF/A/DOC/NAVAIR/YMD:19970201// REF/B/DOC/NAVAIR/YMD:19970201// REF/C/DOC/NAVAIR/YMD:19970201// REF/D/DOC/NAVAIR/YMD:19970201// REF/E/DOC/NAVAIR/YMD:19970201// REF/F/DOC/NAVAIR/YMD:19970201// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAA-1B (F-14A NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF C IS NAVAIR 01-F14AAP-1 ((F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF D IS NAVAIR 01-F14AAP-1B ((F-14B NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF E IS NAVAIR 01F14AAD-1 ((F-14D NATOPS FLIGHT MANUAL (NFM)). REF F IS NAVAIR 01F14AAD-1B ((F-14D NATOPS POCKET CHECKLIST (PCL)).// RMKS/RMKS/1. THIS IS INTERIM CHANGE (IC) NUMBER 147 TO REF A (F-14A NFM), IC NUMBER 103 TO REF B (F-14A PCL), IC NUMBER 45 TO REF C (F-14B NFM), IC NUMBER 29 TO REF D (F-14B PCL), IC NUMBER 25 TO REF E (F-14D NFM), AND IC NUMBER 14 TO REF F (F-14D PCL). 2. SUMMARY. ADDS RUDDER HARDOVER PROCEDURE, REVISES CONTROLLABILITY CHECK PROCEDURE, AND MODIFIES UNCOMMANDED ROLL AND/OR YAW PROCEDURE IN REFS A THROUGH F. 3. CHANGE REF A (F-14A NFM), REF B (F-14B NFM), AND REF C (F-14D NFM) AS FOLLOWS: A. CHAPTER 14, F-14A PAGES 14-29 AND 14-30/F-14B PAGES 14-32 AND 14-33/F-14D PAGES 14-35 AND 14-36, PARAGRAPH 14.11.7 CONTROLLABILITY CHECK: (1) DELETE EXISTING PARAGRAPH. (2) ADD (INSERT) REPLACEMENT PARAGRAPH: 14.11.7 CONTROLLABILITY CHECK. THERE ARE SEVERAL MALFUNCTIONS THAT MAY SIGNIFICANTLY AFFECT THE HANDLING CHARACTERISTICS IN THE CRUISE AND LANDING CONFIGURATIONS. THESE MALFUNCTIONS INCLUDE, BUT ARE NOT LIMITED TO: A. SPOILER MALFUNCTION* B. FLAP/SLAT ASYMMETRY* C. STRUCTURAL DAMAGE D. UNCOMMANDED SAS INPUTS* E. RUDDER MALFUNCTION (HARDOVER)* F. WING SWEEP ASYMMETRY* G. JAMMED FLIGHT CONTROLS H. (DFCS ONLY) ARI FAILURE* * THESE MALFUNCTIONS, WHICH HAVE UNIQUE NATOPS PROCEDURES SPECIFIC _______________________________________________________________________ CNO 051758Z APR01 Page 1 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
TO A PARTICULAR FAILURE MODE, SHOULD BE PERFORMED BEFORE BEGINNING A CONTROLLABILITY CHECK. NATOPS PROCEDURES CANNOT ACCOUNT FOR EVERY POTENTIAL MALFUNCTION. IT IS ABSOLUTELY IMPERATIVE THAT THE AIRCREW THOROUGHLY AND SAFELY EVALUATE THE DEGRADED HANDLING CHARACTERISTICS OF THE DAMAGED OR MALFUNCTIONING AIRCRAFT PRIOR TO CONTINUED FLIGHT AND LANDING. THIS CHECK DOES NOT TAKE PRIORITY OVER EXISTING EMERGENCY PROCEDURES. UPON ENCOUNTERING A PROBLEM THAT ALTERS THE HANDLING QUALITIES OF THE AIRCRAFT, THE AIRCREW SHOULD REALIZE THAT THE AIRCRAFT MAY NO LONGER BE A STABLE AIRFRAME, ESPECIALLY IN THE LANDING CONFIGURATION. IN ADDITION, THE FLIGHT CHARACTERISTICS MAY RAPIDLY DEGRADE OR EVEN BECOME UNCONTROLLABLE WHEN NORMAL CONFIGURATION CHANGES ARE INTRODUCED OR DURING AIRSPEED CHANGES. INCREASED AWARENESS OF FLIGHT PARAMETERS SHOULD PREVAIL FOLLOWING A MALFUNCTION UNTIL THE AIRCRAFT IS SAFELY ON DECK. EVEN THOUGH THE AIRCRAFT MAY POSSESS SIGNIFICANTLY DIFFERENT OR EVEN HAZARDOUS FLYING QUALITIES, THE PILOT AND RIO HAVE NUMEROUS CUES AVAILABLE TO THEM TO WARN OF POTENTIAL PROBLEMS. SOME OF THESE CUES INCLUDE: A. TURN NEEDLE AND BALL POSITION B. AOA C. BUFFET D. YAW STRING POSITION E. FLIGHT CONTROL POSITIONS F. TRIM SETTINGS G. ROLL-OFF H. RATE OF DESCENT ALL CUES SHOULD BE VERY CLOSELY MONITORED SINCE THEY TELL THE PILOT WHAT THE AIRCRAFT IS DOING OR IS ABOUT TO DO. STALL/DEPARTURE RECOVERY PROCEDURES AND EJECTION SHOULD BE DISCUSSED PRIOR TO ANY CONTROLLABILITY CHECK. IN THE EVENT OF A STALL/DEPARTURE, NATOPS PROCEDURES SHOULD BE APPLIED IMMEDIATELY. IF DURING FLAP/SLAT TRANSITION, FOLLOW UNCOMMANDED ROLL/YAW PROCEDURES. A RAPID INCREASE IN AIRSPEED CAN BE ATTAINED THROUGH JUDICIOUS USE OF FORWARD STICK AND MILITARY POWER. AFTER A THOROUGH CONTROLLABILITY CHECK (TO INCLUDE APPROACH AND WAVEOFF/BOLTER PERFORMANCE AND FLIGHT CHARACTERISTICS), THE AIRCREW MUST MAKE THE DECISION AS TO WHETHER THE AIRCRAFT CAN BE SAFELY LANDED ABOARD THE CARRIER OR SHOULD BE DIVERTED. WARNING IF AIRCRAFT STALLS OR DEPARTS IN DIRTY CONFIGURATION, IMMEDIATELY UNLOAD AND PLACE THROTTLES AT MILITARY. DO NOT RAISE FLAPS UNTIL RECOVERED. (IF DURING FLAP/SLAT TRANSITION, FOLLOW UNCOMMANDED ROLL/YAW PROCEDURES.) WARNING A CONTROLLABILITY CHECK REQUIRES THE TOTAL ATTENTION AND AWARENESS OF THE AIRCREW. THE AIRCREW MUST BE PREPARED TO ENCOUNTER UNUSUAL HANDLING CHARACTERISTICS, SINCE THE AERODYNAMIC PROPERTIES OF THE AIRCRAFT MAY BE SIGNIFICANTLY CHANGED. STALL SPEED AS WELL AS FLIGHT AND GROUND HANDLING CHARACTERISTICS MAY BE DRASTICALLY DIFFERENT FROM NORMAL. NOTE _______________________________________________________________________ CNO 051758Z APR01 Page 2 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
IF FLIGHT CONTROL MALFUNCTION IS DUE TO UNCOMMANDED STAB AUG TRANSIENTS, SPOILER MALFUNCTION, FLAP/SLAT ASYMMETRY, RUDDER MALFUNCTION (HARDOVER), AND/OR WINGSWEEP MALFUNCTIONS; PERFORM APPLICABLE EMERGENCY PROCEDURE(S) AS NECESSARY BEFORE BEGINNING A CONTROLLABILITY CHECK. 1. CLIMB TO 10,000 FEET AGL MINIMUM. 2. OBTAIN VISUAL CHECK IF POSSIBLE. 3. DECELERATE GRADUALLY TO 200 KNOTS IF FEASIBLE. 4. DIRTY AIRCRAFT, ONE CONFIGURATION CHANGE AT A TIME, WHILE FLYING STRAIGHT AND LEVEL. NOTE LANDING GEAR SHOULD BE LOWERED BEFORE FLAPS. DO NOT LOWER ARRESTING HOOK UNTIL LANDING GEAR IS CONFIRMED DOWN AND LOCKED. 5. IF FLAPS ARE LOWERED, DO SO INCREMENTALLY AND BE ALERT FOR A FLAP/SLAT ASYMMETRY. 6. IF MANEUVER FLAPS ARE USED FOR LANDING APPROACH: WING SWEEP DRIVE NO. 1 AND WG SWP DR NO. 2 / MANUV FLAP CB'S -- PULL (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D). NOTE FAILURE TO PULL WING SWEEP DRIVE CIRCUIT BREAKERS (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D) COULD RESULT IN INADVERTENT MANEUVER DEVICE RETRACTION OR WING SWEEP DURING APPROACH. NOTE WINGSWEEP WARNING, WINGSWEEP ADVISORY, AND FLAP CAUTION LIGHTS WILL ILLUMINATE WITH BOTH WING SWEEP DRIVE CIRCUIT BREAKERS PULLED (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D). 7. USE DIFFERENTIAL THRUST, IF REQUIRED, TO ACHIEVE ACCEPTABLE FLIGHT CHARACTERISTICS. 8. SLOW-FLY AIRCRAFT TO DETERMINE APPROACH HANDLING CHARACTERISTICS, INCLUDING TURNS. 9. FLY SIMULATED APPROACH TO EVALUATE LINEUP CORRECTIONS, POWER CHANGES, AND WAVEOFF/BOLTER PERFORMANCE AND FLIGHT CHARACTERISTICS. 10. FOR LANDING, USE MINIMUM SAFE CONTROL SPEED, BUT NO SLOWER THAN OPTIMUM AOA. 11. IF PERFORMANCE AND FLIGHT CHARACTERISTICS DICTATE THAT A CV LANDING IS NOT POSSIBLE -- DIVERT. 12. IF DIVERTING WITH A FLIGHT CONTROL MALFUNCTION -- MAKE AN ARRESTED LANDING, IF POSSIBLE. NOTE IF NORMAL LANDING ROLLOUT IS ATTEMPTED, FLAP HANDLE SHOULD BE CHECKED DOWN ON DECK WITH SPOILER BRAKE SELECTED TO ENABLE FULL GROUND ROLL BRAKING AUTHORITY. 13. IF DIRECTIONAL CONTROLLABILITY IS IN QUESTION: A. SHOREBASED ARRESTED LANDING SHOULD BE FLOWN TO TOUCHDOWN AT OR JUST PRIOR TO ARRESTING GEAR. B. USE A LANDING SIGNAL OFFICER IF POSSIBLE. C. IF ARRESTING GEAR NOT ENGAGED AND PERFORMANCE AND FLIGHT CHARACTERISTICS PERMIT, EXECUTE WAVEOFF/TOUCH-AND-GO, IF POSSIBLE. D. EXPECT DIRECTIONAL EXCURSIONS DURING WAVEOFF/BOLTER, ARRESTED LANDING, OR LANDING ROLLOUT. E. NOSEWHEEL STEERING SHOULD NOT BE ENGAGED IF RUDDER PEDAL _______________________________________________________________________ CNO 051758Z APR01 Page 3 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
AUTHORITY IS RESTRICTED. F. USE RUDDER, LATERAL STICK, AND/OR DIFFERENTIAL BRAKING TO OPPOSE ANY DIRECTIONAL EXCURSIONS DURING NORMAL LANDING ROLLOUT. G. BRIEF RUNWAY DEPARTURE PRIOR TO LANDING AND IDENTIFY ANY OBSTRUCTIONS IN CLOSE PROXIMITY TO RUNWAY. B. CHAPTER 14, PARAGRAPH 14.12.1 UNCOMMANDED ROLL AND/OR YAW, F-14A NFM PAGE 14-31/F-14B NFM PAGE 14-33/F-14D NFM PAGE 14-37, F-14B FAILURE D AND F-14A/D FAILURE E: (1) DELETE "FROM YAW SAS (19 DEG)", SO PARAGRAPH READS: "D. RUDDER HARDOVER." (FOR F-14B), OR "E. RUDDER HARDOVER." (FOR F-14A/D). (2) ADD: NA C. CHAPTER 14, F-14A NFM PAGE 14-33/F-14B NFM PAGE 14-35/F-14D NFM PAGE 14-38, AFTER RUDDER AUTH LIGHT PARAGRAPH: (1) DELETE: NA (2) ADD (INSERT) RUDDER HARDOVER PROCEDURE AS PARA 14.12.8A IN F-14A NFM, AS PARA 14.12.7A IN F-14B NFM, AND AS PARA 14.12.5A IN F-14D NFM: 14.12.8A/7A/5A (NUMBER AS APPROPRIATE) RUDDER HARDOVER. A RUDDER HARDOVER WILL RESULT IN A SINGLE FULLY DEFLECTED (OVER 30 DEGREES, PEGGED ON COCKPIT INDICATOR) INBOARD OR OUTBOARD RUDDER WITH POSSIBLE RESTRICTED OPPOSING "GOOD" RUDDER AUTHORITY AND A FLIGHT HYDRAULIC FAILURE. RUDDER TRIM AND RUDDER PEDAL AUTHORITY MAY ALSO BE RESTRICTED. THIS PROCEDURE ONLY APPLIES TO A TRUE RUDDER HARDOVER FAILURE, NOT A YAW SAS HARDOVER FAILURE WHICH WILL BE MANIFESTED BY BOTH RUDDERS BEING DEFLECTED UP TO 9.5 DEGREES WITH MECHANICAL RUDDER AUTHORITY STILL AVAILABLE. A YAW SAS HARDOVER SHOULD BE EASILY CONTROLLED WITH RUDDER TRIM AND THE AVAILABLE MECHANICAL RUDDER. IN CRUISE CONFIGURATION ABOVE 15 UNITS ANGLE OF ATTACK, A DEPARTURE FROM CONTROLLED FLIGHT MAY OCCUR WITH A RUDDER HARDOVER. UPRIGHT DEPARTURE/SPIN RECOVERY PROCEDURES MAY NOT FULLY RECOVER THE AIRPLANE, AND IT MAY BE NECESSARY TO PERFORM UNCOMMANDED ROLL/YAW PROCEDURES. WARNING WITH ZERO FLIGHT HYDRAULIC PRESSURE, ENSURE HYDRAULIC TRANSFER PUMP IS SECURED AS SOON AS POSSIBLE. IN THE EVENT OF HYDRAULIC MALFUNCTION, REFER TO APPROPRIATE HYDRAULIC EMERGENCY PROCEDURE AND EXECUTE APPROPRIATE STEPS IN PARALLEL AS REQUIRED. AFTER COMPLETION OF UNCOMMANDED ROLL/YAW PROCEDURES: 1. CONFIRM RUDDER HARDOVER VIA COCKPIT INDICATOR AND/OR RIO/WINGMAN VISUAL INSPECTION. NOTE RESTRICTION OF AUTHORITY, IF ANY, OF OPPOSING "GOOD" RUDDER MAY BE DETERMINED BY REFERENCE TO THE COCKPIT INDICATOR. 2. IF CARRIER BASED, DIVERT TO AN AIRFIELD WITH SHORT FIELD ARRESTING GEAR. 3. PERFORM CONTROLLABILITY CHECK PROCEDURE. NOTE EXPECT ROLL AND YAW OSCILLATIONS DURING THROTTLE AND CONTROL MOVEMENTS. UNDESIRABLE AIRSPEED INCREASE MAY OCCUR DUE TO DIFFERENTIAL THRUST. AIRSPEED CONTROL MAY ALSO BE INFLUENCED BY FLAP POSITION AND PILOT WORKLOAD. SPECIFICALLY, EVALUATE _______________________________________________________________________ CNO 051758Z APR01 Page 4 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
THE EFFECTS OF ANY REQUIRED DIFFERENTIAL THRUST ON LINEUP CORRECTIONS, WAVEOFF/BOLTER PERFORMANCE, AND FLIGHT CHARACTERISTICS. NOTE SIMULATION HAS INDICATED THAT FULL FLAP SETTING COMBINED WITH SEVERELY RESTRICTED OPPOSING RUDDER RESULTS IN MORE PRONOUNCED ROLL AND YAW OSCILLATIONS. 4. DURING CRUISE, USE DIFFERENTIAL THRUST, RUDDER, LATERAL STICK, AND RUDDER TRIM TO RELIEVE PILOT WORKLOAD AND CONTROL FORCES. USE LATERAL TRIM AS NECESSARY. WARNING IF JETTISON IS REQUIRED, CONSIDERATION SHOULD BE GIVEN TO KEEPING THE WING STATIONS SYMMETRIC AND AVOIDING AFT C.G. CONDITIONS. NOTE IT IS UNKNOWN WHAT THE FUEL CONSUMPTION WILL BE IN THIS CONFIGURATION. THEREFORE, FUEL QUANTITY MUST BE CLOSELY MONITORED. RECOMMEND USING GEAR UP, FLAPS DOWN, SINGLE ENGINE BINGO CHARTS. FUEL IMBALANCE MAY OCCUR DURING PROLONGED FLIGHT WITH HIGHER DEMANDS ON ONE ENGINE. USE FEED SWITCH TO MINIMIZE FUEL SPLIT. 5. IF NO SUITABLE DIVERT AVAILABLE AND AIRCRAFT SUFFICIENTLY CONTROLLABLE FOR CV APPROACH, ATTEMPT CV ARRESTED LANDING. NOTE RECOMMEND PRACTICE APPROACH TO CV, FUEL PERMITTING. 6. IF NO SUITABLE DIVERT AVAILABLE AND CONTROLLED CV APPROACH IS IN QUESTION, PERFORM A CONTROLLED EJECTION. PRIOR TO LANDING: WARNING CONTROLLABILITY OF A RUDDER HARDOVER AIRBORNE IS NO INDICATION OF THE ABILITY TO MAINTAIN DIRECTIONAL CONTROL ON DECK. UPON TOUCHDOWN,EXPECT THE AIRCRAFT TO EXPERIENCE UNCONTROLLABLE DIRECTIONAL EXCURSIONS POTENTIALLY DEPARTING THE LANDING AREA/RUNWAY. NOTE ENSURE FAMILIARITY WITH LANDING CONSIDERATIONS OF CONTROLLABILITY CHECK PROCEDURES. NOTE SIMULATION INDICATED THAT BANK ANGLE CONTROL WAS ENHANCED BY LEADING LATERAL STICK INPUTS WITH DIFFERENTIAL THRUST. 7. LATERAL TRIM - NEUTRALIZE NOTE THE USE OF LATERAL TRIM TO REDUCE STICK FORCES DURING ACTUAL APPROACH AND LANDING SHOULD BE AVOIDED AS THIS REDUCES THE SPOILER DEFLECTION AVAILABLE FOR ROLL CONTROL. 8.(F-14B/D ONLY) ASYM THRUST LIMITER SW -- OFF (IF REQUIRED) WARNING ASYMMETRIC THRUST LIMITER SHOULD ONLY BE DISABLED IF REQUIRED TO ASSIST/MAINTAIN CONTROL. (F-14B/D ONLY) 9./8. PERFORM ARRESTED LANDING. WARNING USE ONLY OPPOSING THROTTLE FOR WAVEOFF/BOLTER. CAUTION _______________________________________________________________________ CNO 051758Z APR01 Page 5 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
IF RUDDER PEDAL AUTHORITY IS RESTRICTED, NOSEWHEEL STEERING SHOULD NOT BE ENGAGED UPON LANDING ROLLOUT. (3) RENUMBER RUNAWAY STABILIZER TRIM PROCEDURE, PARA 14.12.7.2 IN F-14B NFM AS NEW PARA 14.12.7B, AND PARA 14.12.5.2 IN F-14D NFM AS NEW PARA 14.12.5B. (NO RENUMBERING OF RUNAWAY STABILIZER TRIM PROCEDURE IN F-14A NFM IS NECESSARY). (4) NOTE THAT PARAGRAPHS NUMBERED AS, FOR EXAMPLE, 14.12.7A AND 14.12.7B ARE NOT SUBORDINATE TO 14.12.7, BUT FALL BETWEEN 14.12.7 AND 14.12.8 AT THE SAME LEVEL. THIS IS DONE TO AVOID RENUMBERING PARAGRAPHS 14.12.8 AND SUBSEQUENT AT THIS TIME. RENUMBERING OF THE SUBSEQUENT PARAGRAPHS WILL OCCUR DURING PRODUCTION OF THE NEXT REVISION OR CHANGE TO EACH PUBLICATION. 4. CHANGE REFS D (F-14A PCL), REF E (F-14B PCL), AND REF F (F-14D PCL) AS FOLLOWS: A. F-14A PAGE 46 / F-14B PAGE-56 / F-14D PAGE 70, CONTROLLABILITY CHECK PROCEDURE: (1) DELETE EXISTING PROCEDURE. (2) ADD (INSERT) REPLACEMENT PROCEDURE: CONTROLLABILITY CHECK. IT IS ABSOLUTELY IMPERATIVE THAT THE AIRCREW THOROUGHLY AND SAFELY EVALUATE THE DEGRADED HANDLING CHARACTERISTICS OF DAMAGED OR MALFUNCTIONING AIRCRAFT PRIOR TO CONTINUED FLIGHT AND LANDING. THIS CHECK DOES NOT TAKE PRIORITY OVER EXISTING EMERGENCY PROCEDURES. WARNING IF AIRCRAFT STALLS OR DEPARTS IN DIRTY CONFIGURATION, IMMEDIATELY UNLOAD AND PLACE THROTTLES AT MILITARY. DO NOT RAISE FLAPS UNTIL RECOVERED. (IF DURING FLAP/SLAT TRANSITION, FOLLOW UNCOMMANDED ROLL/YAW PROCEDURES.) WARNING A CONTROLLABILITY CHECK REQUIRES THE TOTAL ATTENTION AND AWARENESS OF THE AIRCREW. THE AIRCREW MUST BE PREPARED TO ENCOUNTER UNUSUAL HANDLING CHARACTERISTICS SINCE THE AERODYNAMIC PROPERTIES OF THE AIRCRAFT MAY BE SIGNIFICANTLY CHANGED. STALL SPEED AS WELL AS FLIGHT AND GROUND HANDLING CHARACTERISTICS MAY BE DRASTICALLY DIFFERENT FROM NORMAL. NOTE IF FLIGHT CONTROL MALFUNCTION IS DUE TO UNCOMMANDED STAB AUG TRANSIENTS, SPOILER MALFUNCTION, FLAP/SLAT ASYMMETRY, RUDDER MALFUNCTION (HARDOVER), AND/OR WINGSWEEP MALFUNCTIONS; PERFORM APPLICABLE EMERGENCY PROCEDURE(S) AS NECESSARY BEFORE BEGINNING A CONTROLLABILITY CHECK. 1. CLIMB TO 10,000 FEET AGL MINIMUM. 2. OBTAIN VISUAL CHECK IF POSSIBLE. 3. DECELERATE GRADUALLY TO 200 KNOTS IF FEASIBLE. 4. DIRTY AIRCRAFT, ONE CONFIGURATION CHANGE AT A TIME, WHILE FLYING STRAIGHT AND LEVEL. NOTE LANDING GEAR SHOULD BE LOWERED BEFORE FLAPS. DO NOT LOWER ARRESTING HOOK UNTIL LANDING GEAR IS CONFIRMED DOWN AND LOCKED. 5. IF FLAPS ARE LOWERED, DO SO INCREMENTALLY AND BE ALERT FOR A FLAP/SLAP ASYMMETRY. 6. IF MANEUVER FLAPS ARE USED FOR LANDING APPROACH: WING SWEEP _______________________________________________________________________ CNO 051758Z APR01 Page 6 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
DRIVE NO. 1 AND WG SWP DR NO. 2 / MANUV FLAP CB'S -- PULL (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D). NOTE FAILURE TO PULL WING SWEEP DRIVE CIRCUIT BREAKERS (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D) COULD RESULT IN INADVERTENT MANEUVER DEVICE RETRACTION OR WING SWEEP DURING APPROACH. NOTE WINGSWEEP WARNING, WINGSWEEP ADVISORY, AND FLAP CAUTION LIGHTS WILL ILLUMINATE WITH BOTH WING SWEEP DRIVE CIRCUIT BREAKERS PULLED (LE1 AND LE2 FOR F-14A/B; LD1 AND LE1 FOR F-14D). 7. USE DIFFERENTIAL THRUST, IF REQUIRED, TO ACHIEVE ACCEPTABLE FLIGHT CHARACTERISTICS. 8. SLOW-FLY AIRCRAFT TO DETERMINE APPROACH HANDLING CHARACTERISTICS, INCLUDING TURNS. 9. FLY SIMULATED APPROACH TO EVALUATE LINEUP CORRECTIONS, POWER CHANGES, AND WAVEOFF/BOLTER PERFORMANCE, AND FLIGHT CHARACTERISTICS. 10. FOR LANDING, USE MINIMUM SAFE CONTROL SPEED, BUT NO SLOWER THAN OPTIMUM AOA. 11. IF PERFORMANCE AND FLIGHT CHARACTERISTICS DICTATE THAT A CV LANDING IS NOT POSSIBLE -- DIVERT. 12. IF DIVERTING WITH A FLIGHT CONTROL MALFUNCTION -- MAKE ARRESTED LANDING, IF POSSIBLE. NOTE IF NORMAL LANDING ROLLOUT IS ATTEMPTED, FLAP HANDLE SHOULD BE CHECKED DOWN ON DECK WITH SPOILER BRAKE SELECTED TO ENABLE FULL GROUND ROLL BRAKING AUTHORITY. 13. IF DIRECTIONAL CONTROLLABILITY IS IN QUESTION: A. A SHOREBASED ARRESTED LANDING SHOULD BE FLOWN TO TOUCHDOWN AT OR JUST PRIOR TO THE ARRESTING GEAR. B. USE LSO IF POSSIBLE. C. IF ARRESTING GEAR NOT ENGAGED AND PERFORMANCE AND FLIGHT CHARACTERISTICS PERMIT, EXECUTE WAVEOFF/TOUCH-AND-GO, IF POSSIBLE. D. EXPECT DIRECTIONAL EXCURSIONS DURING WAVEOFF/BOLTER, ARRESTED LANDING, OR LANDING ROLLOUT. E. NOSEWHEEL STEERING SHOULD NOT BE ENGAGED IF RUDDER PEDAL AUTHORITY IS RESTRICTED. F. USE RUDDER, LATERAL STICK, AND/OR DIFFERENTIAL BRAKING TO OPPOSE ANY DIRECTIONAL EXCURSIONS DURING NORMAL LANDING ROLLOUT. G. BRIEF RUNWAY DEPARTURE PRIOR TO LANDING AND IDENTIFY ANY OBSTRUCTIONS IN CLOSE PROXIMITY TO THE RUNWAY. B. F-14A PAGE 56 /F-14B PAGE 66 /F-14D PAGE 80, AFTER RUDDER AUTH LIGHT PROCEDURE: (1) DELETE: NA (2) ADD (INSERT) NEW PROCEDURE: RUDDER HARDOVER. A RUDDER HARDOVER WILL RESULT IN A SINGLE FULLY DEFLECTED (OVER 30 DEGREES, PEGGED ON COCKPIT INDICATOR) INBOARD OR OUTBOARD RUDDER WITH POSSIBLE RESTRICTED OPPOSING "GOOD" RUDDER AUTHORITY AND A FLIGHT HYDRAULIC FAILURE. RUDDER TRIM AND RUDDER PEDAL AUTHORITY MAY ALSO BE RESTRICTED. _______________________________________________________________________ CNO 051758Z APR01 Page 7 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
WARNING WITH ZERO FLIGHT HYDRAULIC PRESSURE, ENSURE HYDRAULIC TRANSFER PUMP SWITCH IS SECURED AS SOON AS POSSIBLE. IN THE EVENT OF HYDRAULIC MALFUNCTION, REFER TO APPROPRIATE HYDRAULIC EMERGENCY PROCEDURE AND EXECUTE APPROPRIATE STEPS IN PARALLEL AS REQUIRED. AFTER COMPLETION OF UNCOMMANDED ROLL/YAW PROCEDURES: 1. CONFIRM RUDDER HARDOVER VIA COCKPIT INDICATOR AND/OR RIO/WINGMAN VISUAL INSPECTION. NOTE RESTRICTION OF AUTHORITY, IF ANY, OF OPPOSING "GOOD" RUDDER MAY BE DETERMINED BY REFERENCE TO THE COCKPIT INDICATOR. 2. IF CARRIER BASED, DIVERT TO AN AIRFIELD WITH SHORT FIELD ARRESTING GEAR. 3. PERFORM CONTROLLABILITY CHECK PROCEDURE. NOTE EXPECT ROLL AND YAW OSCILLATIONS DURING THROTTLE AND CONTROL MOVEMENTS. UNDESIRABLE AIRSPEED INCREASE MAY OCCUR DUE TO DIFFERENTIAL THRUST. AIRSPEED CONTROL MAY ALSO BE INFLUENCED BY FLAP POSITION AND PILOT WORKLOAD. SPECIFICALLY, EVALUATE THE EFFECTS OF ANY REQUIRED DIFFERENTIAL THRUST ON LINEUP CORRECTIONS, WAVEOFF/BOLTER PERFORMANCE, AND FLIGHT CHARACTERISTICS. NOTE SIMULATION HAS INDICATED THAT FULL FLAP SETTING COMBINED WITH SEVERELY RESTRICTED OPPOSING RUDDER RESULTS IN MORE PRONOUNCED ROLL AND YAW OSCILLATIONS. 4. DURING CRUISE, USE DIFFERENTIAL THRUST, RUDDER, LATERAL STICK, AND RUDDER TRIM TO RELIEVE PILOT WORKLOAD AND CONTROL FORCES. USE LATERAL TRIM AS NECESSARY. WARNING IF JETTISON IS REQUIRED, CONSIDERATION SHOULD BE GIVEN TO KEEPING THE WING STATIONS SYMMETRIC AND AVOIDING AFT C.G. CONDITIONS. NOTE IT IS UNKNOWN WHAT THE FUEL CONSUMPTION WILL BE IN THIS CONFIGURATION. THEREFORE, FUEL QUANTITY MUST BE CLOSELY MONITORED. RECOMMEND USING GEAR UP, FLAPS DOWN, SINGLE ENGINE BINGO CHARTS. FUEL IMBALANCE MAY OCCUR DURING PROLONGED FLIGHT WITH HIGHER DEMANDS ON ONE ENGINE. USE FEED SWITCH TO MINIMIZE FUEL SPLIT. 5. IF NO SUITABLE DIVERT AVAILABLE AND AIRCRAFT SUFFICIENTLY CONTROLLABLE FOR A CV APPROACH, ATTEMPT CV ARRESTED LANDING. NOTE RECOMMEND PRACTICE APPROACH TO CV, FUEL PERMITTING. 6. IF NO SUITABLE DIVERT AVAILABLE AND CONTROLLED CV APPROACH IN QUESTION, PERFORM A CONTROLLED EJECTION. PRIOR TO LANDING: WARNING CONTROLLABILITY OF A RUDDER HARDOVER AIRBORNE IS NO INDICATION OF THE ABILITY TO MAINTAIN DIRECTIONAL CONTROL ON DECK. UPON TOUCHDOWN, EXPECT THE AIRCRAFT TO EXPERIENCE UNCONTROLLABLE DIRECTIONAL EXCURSIONS POTENTIALLY DEPARTING THE LANDING AREA/ _______________________________________________________________________ CNO 051758Z APR01 Page 8 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
RUNWAY. NOTE ENSURE FAMILIARITY WITH LANDING CONSIDERATIONS OF CONTROLLABILITY CHECK PROCEDURES. NOTE SIMULATION INDICATED THAT BANK ANGLE CONTROL WAS ENHANCED BY LEADING LATERAL STICK INPUTS WITH DIFFERENTIAL THRUST. 7. LATERAL TRIM -- NEUTRALIZE NOTE THE USE OF LATERAL TRIM TO REDUCE STICK FORCES DURING ACTUAL APPROACH AND LANDING SHOULD BE AVOIDED AS THIS REDUCES THE SPOILER DEFLECTION AVAILABLE FOR ROLL CONTROL. 8. (F-14B/D ONLY) ASYM THRUST LIMITER SW -- OFF (IF REQUIRED) WARNING (F-14B/D ONLY) ASYMMETRIC THRUST LIMITER SHOULD ONLY BE DISABLED IF REQUIRED TO ASSIST/MAINTAIN CONTROL. 9./8. PERFORM ARRESTED LANDING. WARNING USE ONLY OPPOSING THROTTLE FOR WAVEOFF/BOLTER. CAUTION IF RUDDER PEDAL AUTHORITY IS RESTRICTED, NOSEWHEEL STEERING SHOULD NOT BE ENGAGED UPON LANDING ROLLOUT. 5. VF-101 POC IS F-14A/B/D NATOPS PROGRAM MANAGER, LT GREG KNEPPER, AT DSN 433-4322 OR COMM (757)433-4322, FAX DSN 433-4368 OR (757)4334368, OR E-MAIL
[email protected]. NAVAIR 4.1.1.1 POC IS LCDR JOE MCKEE, AT DSN 757-7011 OR COMM (301)757-7011, OR EMAIL
[email protected].// BT
_______________________________________________________________________ CNO 051758Z APR01 Page 9 of 9 NA 01-F14AAA-1 IC 147 NA 01-F14AAA-1B IC 103 NA 01-F14AAP-1 IC 45 NA 01-F14AAP-1B IC 29 NA 01-F14AAD-1 IC 25 NA 01-F14AAD-1B IC 14
PAAUZYUW RUENAAA4544 1612054-UUUU--RUENNSN. ZNR UUUUU P R 091944Z JUN 00 ZYB FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO RUDJABF/NAVWARCOL NEWPORT RI//213// RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// BT UNCLAS //N03711// MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES (IC'S) TO F-14B AND F-14D AIRCRAFT NATOPS FLIGHT /PUBLICATIONS// REF/A/DOC/NAVAIR/01FEB97// REF/B/DOC/NAVAIR/01FEB97// REF/C/DOC/NAVAIR/01FEB97// REF/D/DOC/NAVAIR/01FEB97// REF/E/MSG/CNO/311705ZMAY00// NARR/REF A IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAP-1F (F-14B NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)). REF C IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)). REF D IS NAVAIR 01-F14AAD-1F (F-14D NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)). REF E ISSUED DFCS IC'S AS F-14B NFM IC 42, F-14B FCFCL IC 9, F-14D NFM IC 22, AND F-14D FCFCL IC 2.// RMKS/1. THIS IS IC NUMBER 44 TO REF A (F-14B NFM), IC NUMBER 10 TO REF B (F-14B FCFCL), IC NUMBER 24 TO REF C (F-14D NFM), AND IC NUMBER 3 TO REF D (F-14D FCFCL). 2. SUMMARY. EXPANDS FUNCTIONAL CHECKFLIGHT ENGINE RUNUP CHECK PROCEDURES IN REFS A THROUGH D (F-14B AND F-14D NFM'S AND FCFCL'S). THESE CHANGES HAVE ALREADY BEEN INCORPORATED INTO PMCF CARDS FOR DFCS AIRCRAFT AS PART OF REF E. THEREFORE, CHANGES CONTAINED IN THIS MSG NEED BE MADE ONLY TO F-14B AND F-14D AIRCRAFT PUBS WITH AFCS, AND SHALL NOT BE INCORPORATED INTO F-14B AND F-14D NATOPS PUBS WITH DFCS. IF NATOPS PUBS HAVE REF E INCORPORATED, RETAIN THIS IC MSG, BUT HOLD ENTRY OF IC'S IN THIS MSG IN ABEYANCE AND MAKE ENTRY ON EACH PUB INTERIM CHANGE SUMMARY PAGE AS "ALREADY INCORPORATED BY CNO 311705Z MAY00". 3. CHANGE REF A (F-14B NFM), CHAPTER 10, PAGES 10-11 AND 10-12, PARAGRAPH 10.3.5 ENGINE RUNUP, STEP 48 AS FOLLOWS: A. DELETE STEP 48. B. ADD (INSERT) REPLACEMENT STEP: AB 48. ENGINE RUNUP -- CHECK. WARNING ENGINE CHECKS SHALL NOT BE PERFORMED IN TENSION AND SHALL BE PERFORMED WITH THE SHUTTLE FORWARD OF THE LAUNCH BAR. CAUTION SHIPBOARD USE OF MRT AND MINIMUM AB IS RESTRICTED TO A MAXIMUM OF 30 SECONDS TO PREVENT DAMAGE TO THE JBD. JBD COOL DOWN REQUIRES BOTH THROTTLES AT IDLE FOR 30 SECONDS, AND MAY BE NECESSARY DURING THESE CHECKS. CAUTION ABOARD SHIP, EXCESSIVE ASYMMETRIC THRUST MAY DAMAGE THE HOLDBACK BAR. _______________________________________________________________________ CNO 091944Z JUN00 Page 1 of 2 NA 01-F14AAP-1 IC 44 NA 01-F14AAP-1F IC 10 NA 01-F14AAD-1 IC 24 NA 01-F14AAD-1F IC 3
A. VERIFY HOOK STOWED AND RATS LIGHT OUT. B. BOTH ENGINE MODES -- SEC. C. BOTH THROTTLES -- MIL. NOTE ACCELERATION TIME (LESS THAN 10 SECONDS). NOTE ASHORE, CHECKS MUST BE PERFORMED WITH THE OPPOSING ENGINE AT IDLE FOR THE BRAKES TO HOLD. D. BOTH ENGINE MODES -- PRIMARY. RECORD ENGINE PARAMETERS (READ IN FOUR COLUMNS). ENGINE LEFT RIGHT PARAMETER ENGINE ENGINE LIMITS --------------- ------ ------ ----------------NOZ POSITION . . . . . . 3 TO 10 - NOMINAL (PERCENT) (CLOSED) (AT MIL) OIL (PSI) . . . . . . 25 TO 65 RPM (PERCENT) . . . . . . 95 TO 104 NOMINAL (107.7 MAXIMUM) EGT (DEGREES C) . . . . . . 935 FF (PPH) . . . . . . 9,000 TO 12,000 E. HOOK -- DOWN. VERIFY RATS LIGHT AND 3 TO 6 PERCENT RPM DECAY. F. RIGHT THROTTLE -- MIN AB. VERIFY RPM INCREASES 3 TO 6 PERCENT. G. RIGHT THROTTLE -- MIL. H. LEFT THROTTLE -- MIN AB. VERIFY RPM INCREASES 3 TO 6 PERCENT. I. LEFT THROTTLE -- MIL. J. THROTTLE MODE SWITCH -- MAN. K. BOTH THROTTLES -- IDLE. L. THROTTLE MODE SWITCH -- BOOST. M. HOOK -- UP. VERIFY STOWED AND RATS LIGHT OUT. N. PERFORM AICS PROGRAMMER RESET. O. BOTH THROTTLES -- MIL. P. FLIGHT CONTROL WIPEOUT -- PERFORM. 4. CHANGE REF B (F-14B FCFCL), PAGES 1-10 AND 1-11, ENGINE RUNUP, STEP 48 AS IN PARAGRAPHS 3.A AND 3.B ABOVE. 5. CHANGE REF C (F-14D NFM), CHAPTER 10, PAGES 10-11 AND 10-12, PARAGRAPH 10.3.5 ENGINE RUNUP, STEP 51, AS FOLLOWS: A. DELETE STEP 51. B. ADD (INSERT) STEP 51 TO READ THE SAME AS IN STEP 48 IN PARAGRAPH 3.B ABOVE. 6. CHANGE REF D (F-14D FCFCL), PAGES 1-11 AND 1-12, ENGINE RUNUP, STEP 51, AS FOLLOWS: A. DELETE STEP 51. B. ADD (INSERT) STEP 51 TO READ THE SAME AS IN STEP 48 IN PARAGRAPH 3.B ABOVE. 7. REFS A THROUGH E ARE AVAILABLE FOR REFERENCE ON THE NATEC WEB SITE, WWW.NATEC.NAVY.MIL. IF REQUIRED, THE NSATS DFCS PACKAGES ARE AVAILABLE FROM THE VF-101 F-14A/B/D AIRCRAFT NATOPS PROGRAM MANAGER, LT DOUG THIEN, AT DSN 433-4322 OR COMM (757) 433-4322, FAX DSN 4335667 OR (757) 433-5667, OR E-MAIL
[email protected].// BT _______________________________________________________________________ CNO 091944Z JUN00 Page 2 of 2 NA 01-F14AAP-1 IC 44 NA 01-F14AAP-1F IC 10 NA 01-F14AAD-1 IC 24 NA 01-F14AAD-1F IC 3
PAAUZYUW RUENAAA4384 1522109-UUUU--RUENNSN. ZNR UUUUU P R 311944Z MAY 00 ZYB FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES// INFO RUDJABF/NAVWARCOL NEWPORT RI//213// RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// BT UNCLAS //N03711// SECTION 01 OF 02 MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES (IC'S) TO F-14 AIRCRAFT NATOPS FLIGHT PUBLICATIONS// REF/A/DOC/NAVAIR/01FEB97// REF/B/DOC/NAVAIR/01FEB97// REF/C/DOC/NAVAIR/01FEB97// REF/D/DOC/NAVAIR/01FEB97// REF/E/DOC/NAVAIR/01FEB97// REF/F/DOC/NAVAIR/01FEB97// REF/G/DOC/VF-101/16MAR99// REF/H/MSG/CNO/122040ZSEP97// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAA-1B (F-14A NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF C IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF D IS NAVAIR 01-F14AAP-1B (F-14B NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF E IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)). REF F IS NAVAIR 01-F14AAD-1B (F-14D NATOPS POCKET CHECKLIST (PCL)). REF G IS VF-101 LTR 3711 SER 0326; SUBJ: F-14 NATOPS CONFERENCE REPORT. REF H ISSUED IC 32 TO REF C (F-14B NFM) AND IC 23 TO REF D (F-14B PCL).// RMKS/1. THIS IS IC NUMBER 146 TO REF A (F-14A NFM), IC NUMBER 102 TO REF B (F-14A PCL), IC NUMBER 43 TO REF C (F-14B NFM), IC NUMBER 28 TO REF D (F-14B PCL), IC NUMBER 23 TO REF E (F-14D NFM), AND IC NUMBER 13 TO REF F (F-14D PCL). 2. SUMMARY. ISSUES REF G ADVANCE CHANGE ITEMS FROM THE F-14A/B/D AIRCRAFT NATOPS REVIEW CONFERENCE HELD IN NOV98 INTO REFS A THROUGH F. ALL CHANGES CONTAINED IN THIS MSG AFFECT ONLY AIRCRAFT WITH AFCS INSTALLED, AND DO NOT APPLY TO AIRCRAFT WITH DFCS. THESE CHANGES SHOULD NOT BE INCORPORATED IF AIRCRAFT FLOWN DO NOT HAVE DFCS INCORPORATED SINCE THE DFCS CHANGES WILL DELETE ANALOG FLIGHT CONTROL SYSTEM (AFCS) INFORMATION IN SUBJECT PUBS. IF UNIT'S AIRCRAFT HAVE DFCS INCORPORATED, RETAIN THIS IC MSG, BUT HOLD ENTRY OF THESE IC'S IN ABEYANCE, AND MAKE ENTRY ON EACH PUB INTERIM CHANGE SUMMARY PAGE AS "AFCS - NOT APPLICABLE TO DFCS AIRCRAFT". 3. CHANGE REF A (F-14A NFM), CHAPTER 14, AS FOLLOWS: A. PAGE 14-32, PARAGRAPH 14.12.5.2 BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PARAGRAPH TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT): WARNING CONDITIONS PERMITTING, TROUBLESHOOTING SHOULD NOT BE CONDUCTED BELOW 5,000 FEET AGL. _______________________________________________________________________ CNO 311944Z MAY00 Page 1 of 5 NA 01-F14AAA-1 IC 146 NA 01-F14AAA-1B IC 102 NA 01-F14AAP-1 IC 43 NA 01-F14AAP-1B IC 28 NA 01-F14AAD-1 IC 23 NA 01-F14AAD-1B IC 13
B.
C.
4. A.
(2) AFTER STEP 5 (PITCH CMPTR AC CB (LB1) OR ROLL CMPTR AC CB (LA1)) -- CYCLE): (A) DELETE: NA (B) ADD (INSERT): WARNING CYCLING BOTH PITCH AND ROLL AC COMPUTER CB'S SIMULTANEOUSLY MAY RENDER BOTH THE INBOARD AND OUTBOARD SPOILERS INOPERATIVE. PAGE 14-35, PARAGRAPH 14.12.11.1 SPOILER MALFUNCTION/SPOILER STUCK UP: (1) BETWEEN PARAGRAPH TITLE AND STEP 1: (A) DELETE FIRST NOTE: NOTE SPOILERS CAUTION LIGHT WILL NOT ILLUMINATE WITH SPOILER FLR ORIDE SWITCHES IN THE ORIDE POSITION. (B) ADD (REPLACEMENT) FIRST NOTE: NOTE SPOILERS CAUTION LIGHT WILL ILLUMINATE ONLY IF ANY SET OF SPOILERS HAVE FAILED DOWN TO THE MINUS 4-1/2 DEGREES POSITION. (2) STEP 3: (A) DELETE STEP 3: 3. COUNTER ROLL WITH AT LEAST 1 INCH OF LATERAL STICK. (B) ADD (REPLACE WITH): 3. IF UNCOMMANDED ROLL IS ENCOUNTERED: COUNTER ROLL WITH AT LEAST 1 INCH OF LATERAL STICK. (C) RETAIN NOTE WHICH FOLLOWS STEP 3. PAGE 14-38, PARAGRAPH 14.12.16.1 AUTOPILOT LIGHT: (1) DELETE AUTOPILOT LIGHT PROCEDURE. (2) ADD (REPLACE) WITH: 14.12.16.1 AUTOPILOT LIGHT WARNING CONDITIONS PERMITTING, TROUBLESHOOTING SHOULD NOT BE CONDUCTED BELOW 5,000 FEET AGL. 1. MASTER RESET -- DEPRESS. IF LIGHT REMAINS ILLUMINATED: 2. PITCH AND ROLL CMPTR AC CIRCUIT BREAKERS -- CYCLE (LB1, LA1). WARNING CYCLING BOTH PITCH AND ROLL AC COMPUTER CB'S SIMULTANEOUSLY MAY RENDER BOTH THE INBOARD AND OUTBOARD SPOILERS INOPERATIVE. CHANGE REF B (F-14A PCL), AS FOLLOWS: PAGE 48, SPOILER MALFUNCTION/SPOILER STUCK UP: (1) BETWEEN PROCEDURE TITLE AND STEP 1: (A) DELETE FIRST NOTE: NOTE SPOILERS CAUTION LIGHT WILL NOT ILLUMINATE WITH SPOILER FLR ORIDE SWITCHES IN THE ORIDE POSITION. (B) ADD (INSERT) REPLACEMENT FIRST NOTE: NOTE SPOILERS CAUTION LIGHT WILL ILLUMINATE ONLY IF ANY SET OF SPOILERS HAVE FAILED DOWN TO THE MINUS 4-1/2 DEGREES
_______________________________________________________________________ CNO 311944Z MAY00 Page 2 of 5 NA 01-F14AAA-1 IC 146 NA 01-F14AAA-1B IC 102 NA 01-F14AAP-1 IC 43 NA 01-F14AAP-1B IC 28 NA 01-F14AAD-1 IC 23 NA 01-F14AAD-1B IC 13
B.
C.
5. A.
B.
C.
6. A.
POSITION. (2) STEP 3: (A) DELETE STEP 3: 3. COUNTER ROLL WITH AT LEAST 1 INCH OF LATERAL STICK. (B) ADD (REPLACE WITH): 3. IF UNCOMMANDED ROLL IS ENCOUNTERED: COUNTER ROLL WITH AT LEAST 1 INCH OF LATERAL STICK. (C) RETAIN NOTE WHICH FOLLOWS STEP 3. PAGE 54, PITCH OR ROLL STAB AUG -- BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PROCEDURE TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT): WARNING CONDITIONS PERMITTING, TROUBLESHOOTING SHOULD NOT BE CONDUCTED BELOW 5,000 FEET AGL. (2) AFTER STEP 5: (A) DELETE: NA (B) ADD (INSERT) WARNING: WARNING CYCLING BOTH PITCH AND ROLL AC COMPUTER CIRCUIT BREAKERS SIMULTANEOUSLY MAY RENDER BOTH THE INBOARD AND OUTBOARD SPOILERS INOPERATIVE. CHANGE PAGE 70, FOLLOWING CADC LIGHT NOTE AND GLOVE VANE LIGHT PROCEDURES: (1) DELETE: NA (2) ADD (INSERT) AUTOPILOT LIGHT PROCEDURE AS PROVIDED IN PARAGRAPH 3.C(2) ABOVE, EXCEPT OMIT PARAGRAPH NUMBER. CHANGE REF C (F-14B NFM), CHAPTER 14, AS FOLLOWS: PAGE 14-34, PARAGRAPH 14.12.5.2 BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PARAGRAPH TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS PROVIDED IN PARAGRAPH 3.A(1)(B) ABOVE. (2) BETWEEN STEPS 5 AND 6: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS IN PARAGRAPH 3.A(2)(B) ABOVE. PAGE 14-37, PARAGRAPH 14.12.9.1 SPOILER MALFUNCTION/SPOILER STUCK UP (CURRENT TEXT WAS INCORPORATED BY IC 32 (REF H PARAGRAPH 5.F(1) AND 5.F(2) ABOVE)): (1) BETWEEN PARAGRAPH TITLE AND STEP 1, REPLACE FIRST NOTE AS IN PARAGRAPHS 3.B(1)(A) AND 3.B(1)(B) ABOVE. (2) IN STEP 3, REPLACE STEP 3 AS IN PARAGRAPHS 3.B(2)(A) THROUGH 3.B(2)(C) ABOVE. PAGE 14-40, PARAGRAPH 14.12.14.1 AUTOPILOT LIGHT: (1) DELETE AUTOPILOT LIGHT PROCEDURE. (2) ADD (INSERT) REPLACEMENT PROCEDURE AS IN PARAGRAPH 3.C(2) ABOVE. CHANGE REF D (F-14B PCL), AS FOLLOWS: PAGES 58 AND 59, SPOILER MALFUNCTION/SPOILER STUCK UP (CURRENT TEXT WAS INCORPORATED BY IC 23 (REF H PARAGRAPHS 6.B(1) AND 6.B(2)
_______________________________________________________________________ CNO 311944Z MAY00 Page 3 of 5 NA 01-F14AAA-1 IC 146 NA 01-F14AAA-1B IC 102 NA 01-F14AAP-1 IC 43 NA 01-F14AAP-1B IC 28 NA 01-F14AAD-1 IC 23 NA 01-F14AAD-1B IC 13
B.
C.
7. A.
B.
C.
8. A.
B.
ABOVE: (1) BETWEEN PROCEDURE TITLE AND STEP 1, REPLACE FIRST NOTE AS IN PARAGRAPHS 4.A(1)(A) AND 4.A(1)(B) ABOVE. (2) IN STEP 3, REPLACE STEP 3 AS IN PARAGRAPHS 4.A(2)(A) THROUGH 4.A(2)(C) ABOVE. PAGES 64 AND 65, PITCH OR ROLL STAB AUG -- BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PROCEDURE TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS PROVIDED IN PARAGRAPH 4.B(1)(B) ABOVE. (2) BETWEEN STEPS 5 AND 6: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS IN PARAGRAPH 4.B(2)(B) ABOVE. PAGE 80, AFTER CADC LIGHT PROCEDURE: (1) DELETE: NA (2) ADD (INSERT) AUTOPILOT LIGHT PROCEDURE AS PROVIDED IN PARAGRAPH 3.C(2) ABOVE, EXCEPT OMIT PARAGRAPH NUMBER. CHANGE REF E (F-14D NFM), CHAPTER 14, AS FOLLOWS: PAGE 14-38, PARAGRAPH 14.12.3.2 BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PARAGRAPH TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS PROVIDED IN PARAGRAPH 3.A(1)(B) ABOVE. (2) BETWEEN STEPS 5 AND 6: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS IN PARAGRAPH 3.A(2)(B) ABOVE. PAGE 14-40, PARAGRAPH 14.12.7.1 SPOILER MALFUNCTION/SPOILER STUCK UP: (1) BETWEEN PARAGRAPH TITLE AND STEP 1, REPLACE FIRST NOTE AS IN PARAGRAPHS 3.B(1)(A) AND 3.B(1)(B) ABOVE. (2) IN STEP 3, REPLACE STEP 3 AS IN PARAGRAPHS 3.B(2)(A) THROUGH 3.B(2)(C) ABOVE. PAGE 14-44, PARAGRAPH 14.12.13 AUTOPILOT LIGHT (1) DELETE AUTOPILOT LIGHT PROCEDURE. (2) ADD (INSERT) REPLACEMENT PROCEDURE AS IN PARAGRAPH 3.C(2) ABOVE. CHANGE REF F (F-14D PCL), AS FOLLOWS: PAGE 72, SPOILER MALFUNCTION/SPOILER STUCK UP: (1) BETWEEN PROCEDURE TITLE AND STEP 1, REPLACE FIRST NOTE AS IN PARAGRAPHS 4.A(1)(A) AND 4.A(1)(B) ABOVE. (2) IN STEP 3, REPLACE STEP 3 AS IN PARAGRAPHS 4.A(2)(A) THROUGH 4.A(2)(C) ABOVE. PAGES 78 AND 79, PITCH OR ROLL STAB AUG -- BOTH PITCH OR BOTH ROLL STAB LIGHTS: (1) BETWEEN PROCEDURE TITLE AND CAUTION WHICH PRECEDES STEP 1: (A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS PROVIDED IN PARAGRAPH 4.B(1)(B) ABOVE. (2) BETWEEN STEPS 5 AND 6:
_______________________________________________________________________ CNO 311944Z MAY00 Page 4 of 5 NA 01-F14AAA-1 IC 146 NA 01-F14AAA-1B IC 102 NA 01-F14AAP-1 IC 43 NA 01-F14AAP-1B IC 28 NA 01-F14AAD-1 IC 23 NA 01-F14AAD-1B IC 13
(A) DELETE: NA (B) ADD (INSERT) WARNING WITH TEXT AS IN PARAGRAPH 4.B(2)(B) ABOVE. C. PAGE 93, AUTOPILOT LIGHT PROCEDURE: (1) DELETE: NA (2) ADD (INSERT) AUTOPILOT LIGHT PROCEDURE AS PROVIDED IN PARAGRAPH 3.C(2) ABOVE, EXCEPT OMIT PARAGRAPH NUMBER. 9. REF G DISTRIBUTED TO CONCERNED NATOPS ADVISORY GROUP MEMBERS, F-14 SQUADRONS, AND REVIEW CONFERENCE ATTENDEES. NATOPS PROGRAM MANAGER IS ALSO PREPARING REPLACEMENT PAGES FOR DISTRIBUTION TO FLEET UNITS. IF REF C OR REPLACEMENT PAGES REQUIRED, CONTACT VF-101 F-14A/B/D NATOPS PROGRAM MANAGER, LT DOUG THIEN, AT DSN 433-4322 OR COMM (757)433-4322, FAX DSN 433-5667 OR (757)433-5667, OR E-MAIL
[email protected].// BT
_______________________________________________________________________ CNO 311944Z MAY00 Page 5 of 5 NA 01-F14AAA-1 IC 146 NA 01-F14AAA-1B IC 102 NA 01-F14AAP-1 IC 43 NA 01-F14AAP-1B IC 28 NA 01-F14AAD-1 IC 23 NA 01-F14AAD-1B IC 13
PAAUZYUW RUENAAA4373 1521826-UUUU--RUENNSN. ZNR UUUUU P R 311705Z MAY 00 ZYB FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO RUDJABF/NAVWARCOL NEWPORT RI//213// RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// BT UNCLAS //N03711// MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES (IC'S) TO F-14 AIRCRAFT NATOPS FLIGHT PUBLICATIONS// REF/A/DOC/NAVAIR/01FEB97// REF/B/DOC/NAVAIR/01FEB97// REF/C/DOC/NAVAIR/01FEB97// REF/D/DOC/NAVAIR/01FEB97// REF/E/DOC/NAVAIR/01FEB97// REF/F/DOC/NAVAIR/01FEB97// REF/G/DOC/NAVAIR/01FEB97// REF/H/DOC/NAVAIR/01FEB97// REF/I/DOC/NAVAIR/01FEB97// REF/J/DOC/NSATS/UNDATED// REF/K/DOC/NSATS/UNDATED// REF/L/DOC/NSATS/UNDATED// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAA-1B (F-14A NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF C IS NAVAIR 01-F14AAA-1F (F-14A NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)). REF D IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 W/CHG-1 01FEB97. REF E IS NAVAIR 01-F14AAP-1B (F-14B NATOPS POCKET CHECKLIST (PCL)) DTD 15MAY95 W/CHG-1 01FEB97. REF F IS NAVAIR 01-F14AAB-1F (F-14B NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)). REF G IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)). REF H IS NAVAIR 01-F14AAD-1B (F-14D NATOPS POCKET CHECKLIST (PCL)). REF I IS NAVAIR 01-F14AAD-1F (F-14D NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)). REF J IS NSATS DFCS CHANGE 1 TO F-14A NATOPS PUBS. REF K IS NSATS DFCS CHANGE 1 TO F-14B NATOPS PUBS. REF L IS NSATS DFCS CHANGE 1 TO F-14D NATOPS PUBS.// RMKS/1. THIS IS IC NUMBER 145 TO REF A (F-14A NFM), IC NUMBER 100 TO REF B (F-14A PCL), IC NUMBER 8 TO REF C (F-14A FCFCL), IC NUMBER 42 TO REF D (F-14B NFM), IC NUMBER 27 TO REF E (F-14B PCL), IC NUMBER 9 TO REF F (F-14B FCFCL), IC NUMBER 22 TO REF G (F-14D NFM), IC NUMBER 12 TO REF H (F-14D PCL), AND IC NUMBER 2 TO REF I (F-14D FCFCL). 2. SUMMARY. ISSUES NSATS DIGITAL FLIGHT CONTROL SYSTEM (DFCS) CHANGES FOR INCORPORATION INTO F-14A, F-14B AND F-14D NATOPS PUBS. THESE CHANGES SHOULD NOT BE INCORPORATED IF AIRCRAFT FLOWN DO NOT HAVE DFCS INCORPORATED SINCE THE DFCS CHANGES WILL DELETE ANALOG FLIGHT CONTROL SYSTEM (AFCS) INFORMATION IN SUBJECT PUBS. IF UNIT'S AIRCRAFT DO NOT HAVE DFCS INCORPORATED, RETAIN THIS IC MSG, BUT HOLD ENTRY OF THESE IC'S IN ABEYANCE UNTIL UNIT AIRCRAFT HAVE DFCS _______________________________________________________________________ CNO 311705Z MAY00 Page 1 of 2 NA 01-F14AAA-1 IC 145 NA 01-F14AAA-1B IC 100 NA 01-F14AAA-1F IC 8 NA 01-F14AAP-1 IC 42 NA 01-F14AAP-1B IC 27 NA 01-F14AAP-1F IC 9 NA 01-F14AAD-1 IC 22 NA 01-F14AAD-1B IC 12 NA 01-F14AAD-1F IC 2
INCORPORATED AND MAKE ENTRY ON EACH PUB INTERIM CHANGE SUMMARY PAGE AS "DFCS - ENTRY HELD IN ABEYANCE UNTIL INCORPORATION OF DFCS INTO UNIT'S AIRCRAFT". 3. CHANGE REF A (F-14A NFM) BY ENTERING REF J NSATS DFCS F-14A CHANGE 1 NFM CHANGES AS IC 145 IF UNIT AIRCRAFT INCORPORATE DFCS. 4. CHANGE REF B (F-14A PCL) BY ENTERING REF J NSATS F-14A DFCS CHANGE 1 PCL CHANGES AS IC 100 IF UNIT AIRCRAFT INCORPORATE DFCS. 5. REF C (F-14A FCFCL) IS SUPERSEDED BY REF J NSATS DFCS F-14A CHANGE 1 FCFCL AS IC 8 IF UNIT AIRCRAFT INCORPORATE DFCS. REF J NSATS AIRCREW ACCEPTANCE AND FLEET AIRCREW ACCEPTANCE FCFCLS ARE ALSO APPROVED FOR USE DURING DFCS ACCEPTANCE CHECKS AS APPROPRIATE. 6. CHANGE REF D (F-14B NFM) BY ENTERING REF K NSATS DFCS F-14B CHANGE 1 NFM CHANGES AS IC 42 IF UNIT AIRCRAFT INCORPORATE DFCS. 7. CHANGE REF E (F-14B PCL) BY ENTERING REF K NSATS F-14B DFCS CHANGE 1 PCL CHANGES AS IC 27 IF UNIT AIRCRAFT INCORPORATE DFCS. 8. REF F (F-14B FCFCL) IS SUPERSEDED BY REF K NSATS DFCS F-14B CHANGE 1 FCFCL AS IC 9 IF UNIT AIRCRAFT INCORPORATE DFCS. REF K NSATS AIRCREW ACCEPTANCE AND FLEET AIRCREW ACCEPTANCE FCFCLS ARE ALSO APPROVED FOR USE DURING DFCS ACCEPTANCE CHECKS AS APPROPRIATE. 9. CHANGE REF G (F-14D NFM) BY ENTERING REF L NSATS DFCS F-14D CHANGE 1 NFM CHANGES AS IC 22 IF UNIT AIRCRAFT INCORPORATE DFCS. 10. CHANGE REF H (F-14D PCL) BY ENTERING REF L NSATS F-14D DFCS CHANGE 1 PCL CHANGES AS IC 12 IF UNIT AIRCRAFT INCORPORATE DFCS. 11. REF I (F-14D FCFCL) IS SUPERSEDED BY REF L NSATS DFCS F-14D CHANGE 1 FCFCL AS IC 2 IF UNIT AIRCRAFT INCORPORATE DFCS. REF L NSATS AIRCREW ACCEPTANCE AND FLEET AIRCREW ACCEPTANCE FCFCLS ARE ALSO APPROVED FOR USE DURING DFCS ACCEPTANCE CHECKS AS APPROPRIATE. 12. REFS J, K AND L DISTRIBUTED TO CONCERNED NATOPS ADVISORY GROUP MEMBERS AND UNITS BY SEPCOR. NATOPS PROGRAM MANAGER HAS ALSO PREPARED AND IS DISTRIBUTING REPLACEMENT PAGES TO FLEET UNITS. IF REFS J, K, AND/OR L REQUIRED, CONTACT VF-101 F-14A/B/D NATOPS PROGRAM MANAGER, LT DOUG THIEN, AT DSN 433-4322 OR COMM (757)433-4322, FAX DSN 433-5667 OR (757)433-5667, OR E-MAIL
[email protected].// BT
_______________________________________________________________________ CNO 311705Z MAY00 Page 2 of 2 NA 01-F14AAA-1 IC 145 NA 01-F14AAA-1B IC 100 NA 01-F14AAA-1F IC 8 NA 01-F14AAP-1 IC 42 NA 01-F14AAP-1B IC 27 NA 01-F14AAP-1F IC 9 NA 01-F14AAD-1 IC 22 NA 01-F14AAD-1B IC 12 NA 01-F14AAD-1F IC 2
PAAUZYUW RUENAAA3385 0902359-UUUU--RUENNSN. ZNR UUUUU P R 300001Z MAR 00 ZYB FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// RUDJABF/NAVWARCOL NEWPORT RI//213// BT UNCLAS //N03711// SECTION 01 OF 02 MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES TO F-14 AIRCRAFT NATOPS PUBLICATIONS// REF/A/DOC/NAVAIR/01FEB97// REF/B/DOC/NAVAIR/01FEB97// REF/C/DOC/NAVAIR/01FEB97// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 CHG-1 01FEB97. REF B IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY97 CHG-1 01FEB97. REF C IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)) DTD 01FEB97.// RMKS/1. THIS IS INTERIM CHANGE NUMBER 143 TO REF A (F-14A NFM), INTERIM CHANGE NUMBER 41 TO REF B (F-14B NFM), AND INTERIM CHANGE NUMBER 21 TO REF C (F-14D NFM). 2. SUMMARY. PROVIDES ADDITIONAL DISCUSSION OF CATAPULT TAKEOFF PROCEDURES, FLIGHT CHARACTERISTICS AND RIO RESPONSIBILITIES DURING NIGHT/IFR CATAPULT LAUNCHES. 3. CHANGE REF A (F-14A NFM), CHAPTER 8, PAGE 8-3, PARA 8.4.2 CATAPULT LAUNCH, AS FOLLOWS: A. IN FIRST PARAGRAPH, AFTER FOURTH SENTENCE, "WHEN A TURNUP SIGNAL IS RECEIVED....AND THE RIO IS READY.": (1) DELETE: NA (2) ADD: THE RIO MAY SELECT THE AVIA DISPLAY PRIOR TO LAUNCH TO PROVIDE ADDITIONAL INFORMATION DURING INITIAL FLYAWAY. HOWEVER, THE VSI AND AOA INFORMATION DISPLAYED ON THE AVIA IS PARTICULARLY SUSCEPTIBLE TO LAG AND INACCURACIES, AND SHOULD BE USED ONLY AS A SECONDARY SOURCE OF INFORMATION. THE RIO'S PRIMARY SCAN SHOULD BE AIRSPEED, ALTITUDE AND ATTITUDE FROM THE CONVENTIONAL INSTRUMENTS. B. AFTER FIRST PARAGRAPH: (1) DELETE CAUTION. (2) ADD: WARNING FAILURE TO ALLOW THE CONTROL STICK TO MOVE AFT DURING THE CATAPULT STROKE WILL RESULT IN DEGRADED PITCH RATE AND EXCESSIVE SINK OFF THE BOW. CAUTION CATAPULT LAUNCH WITH A PARTIALLY FILLED EXTERNAL TANK IS NOT AUTHORIZED. C. SECOND PARAGRAPH: (1) DELETE SECOND PARAGRAPH, INCLUDING THE THREE SIGNALS SUBPARAGRAPHS. (2) ADD: THE F-14 MUST BE FLOWN OFF THE CATAPULT BY THE PILOT. AT SHUTTLE RELEASE, THE ENERGY STORED IN THE NOSE STRUT IS RELEASED, ROTATING THE AIRCRAFT TO THE INITIAL FLYAWAY ATTITIDE OF APPROXIMATELY 12-15 DEGREES NOSE-UP ON THE VDI AND HUD. THE AIRCREW SHOULD PLAN AND TRIM FOR THE STANDARD _____________________________________________________________________________ CNO 300001Z MAR00 Page 1 of 4 NA 01-F14AAA-1 IC 143 NA 01-F14AAP-1 IC 41 NA 01-F14AAD-1 IC 21
EXCESS ENDSPEED OF 15 KNOTS UNLESS NOTIFIED OTHERWISE. LOWER EXCESS ENDSPEED THAN ANTICIPATED AND/OR A LOWER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO USE AFT STICK AT THE END OF THE CATAPULT STROKE TO ESTABLISH AND MAINTAIN THE DESIRED CLIMBOUT PITCH ATTITUDE OF 10 DEGREES. HIGHER ENDSPEED THAN EXPECTED AND/OR A HIGHER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO STOP THE ROTATION AT 10 DEGREES WITH SLIGHT FORWARD STICK. WHILE ROTATING TO THE FLYAWAY ATTITUDE, THE FLIGHTCREW WILL FEEL THE AIRCRAFT SETTLE APPROXIMATELY 5 FEET BEFORE COMMENCING A CLIMB. FOR CATAPULT LAUNCHES WITH EXCESS ENDSPEED LESS THAN 15 KNOTS, THE AOA WILL RISE ABRUPTLY TO 17 UNITS AND THEN GRADUALLY DECREASE AS AIRSPEED INCREASES DURING THE FLYAWAY. AIRCREW COORDINATION IS PARTICULARLY CRITICAL IN THIS REGIME, SINCE THE AIRCREW MUST ENSURE THAT INITIAL FLYAWAY PARAMETERS ARE MAINTAINED WHILE REMAINING ALERT FOR ANY ABNORMAL LAUNCH CHARACTERISTICS AND ENGINE MALFUNCTIONS. HIGH ENDSPEED AND/OR SINGLE-ENGINE FLYAWAY WITH TRIM SETTINGS ABOVE 2 DEGREES MAY REQUIRE SIGNIFICANT FORWARD STICK PRESSURE. IN ALL CONFIGURATIONS, THE USE OF AFTERBURNER AND/ OR LEVEL RAPID ACCELERATION WILL REQUIRE REDUCED NOSE TRIM SETTINGS. THE RIO SHALL SCAN AIRSPEED, ALTITUDE AND ATTITUDE TO CONFIRM A POSITIVE RATE OF CLIMB. THE AVIA DISPLAY MAY BE USED TO PROVIDE ADDITIONAL INFORMATION (AOA AND POSITIVE RATE OF CLIMB) DURING THE INITIAL FLYAWAY, THOUGH, THE VSI AND AOA INFORMATION DISPLAYED ON THE AVIA IS PARTICULARLY SUSCEPTIBLE TO LAG AND INACCURACIES, AND SHOULD BE USED ONLY AS A SECONDARY SOURCE OF INFORMATION. WHEN AN AIRCRAFT IS LAUNCHED IN AFTERBURNER, THE FOLLOWING DAY SIGNALS AND RESPONSES ARE USED: 1. CATAPULT OFFICER GIVES TWO-FINGER TURNUP SIGNAL; PILOT ADVANCES POWER TO MIL. 2. WHEN AIRCRAFT IS AT MIL POWER, CATAPULT OFFICER RESPONDS WITH FIVE FINGERS (OPEN HAND HELD TOWARD PILOT); PILOT SELECTS MAX POWER. 3. PILOT CHECKS INSTRUMENTS, POSITIONS HIMSELF, THEN SALUTES THE CATAPULT OFFICER. 4. WHEN AIRCRAFT IS AT MAX POWER AND PILOT HAS SALUTED, CATAPULT OFFICER TOUCHES AND THEN RAISES HAND FROM FLIGHT DECK TO SIGNAL FOR CATAPULT TO BE FIRED. ADDITIONAL CONSIDERATIONS EXIST FOR NIGHT/IFR CATAPULT LAUNCHES. AIRCRAFT ACCELERATION AND THE LACK OF EXTERNAL VISUAL CUES WILL CAUSE THE AIRCREW TO SENSE THAT THE NOSE IS HIGHER THAN ACTUAL AND CAN RESULT IN SPATIAL DISORIENTATION. UNDER THESE CONDITIONS, A VIGILANT INSTRUMENT SCAN IS REQUIRED TO ENSURE THAT THE PROPER ATTITUDE IS MAINTAINED THROUGHOUT THE LAUNCH AND SUBSEQUENT CLIMBOUT. THE AIRCREW SHOULD ALSO BE ALERT FOR POWER TRANSIENTS, WHICH CAN TEMPORARILY DISABLE THE PILOT'S PRIMARY ATTITUDE DISPLAY (VDI) DURING AND AFTER THE CATAPULT STROKE, AND REQUIRE TRANSITION TO THE STANDBY GYRO FOR ATTITUDE INFORMATION. 4. CHANGE REF B (F-14B NFM), CHAPTER 8, PAGE 8-3, PARA 8.4.2, CATAPULT LAUNCH: A. CAUTION AFTER FIRST PARAGRAPH: (1) DELETE TEXT "BECAUSE OF SURGE LOAD CONSIDERATIONS" AT END OF _____________________________________________________________________________ CNO 300001Z MAR00 Page 2 of 4 NA 01-F14AAA-1 IC 143 NA 01-F14AAP-1 IC 41 NA 01-F14AAD-1 IC 21
CAUTION. (2) ADD: NA B. THIRD (LAST) PARAGRAPH: (1) DELETE THIRD PARAGRAPH. (2) ADD: THE F-14 MUST BE FLOWN OFF THE CATAPULT BY THE PILOT. AT SHUTTLE RELEASE, THE ENERGY STORED IN THE NOSE STRUT IS RELEASED, ROTATING THE AIRCRAFT TO THE INITIAL FLYAWAY ATTITIDE OF APPROXIMATELY 12-15 DEGREES NOSE-UP ON THE VDI AND HUD. THE AIRCREW SHOULD PLAN FOR THE STANDARD EXCESS ENDSPEED OF 15 KNOTS, UNLESS NOTIFIED OTHERWISE. LOWER EXCESS ENDSPEED THAN ANTICIPATED OR A LOWER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO USE BACKSTICK AT THE END OF THE CATAPULT STROKE TO CAPTURE AND MAINTAIN THE DESIRED CLIMBOUT PITCH ATTITUDE OF 10 DEGREES. HIGHER ENDSPEED THAN EXPECTED OR A HIGHER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO STOP THE ROTATION AT 10 DEGREES WITH SLIGHT FORWARD STICK. WHILE ROTATING TO THE FLYAWAY ATTITUDE, THE FLIGHTCREW WILL FEEL THE AIRCRAFT SETTLE APPROXIMATELY 5 FEET BEFORE COMMENCING A CLIMB. FOR CATAPULT LAUNCHES WITH EXCESS ENDSPEED LESS THAN 15 KNOTS, THE AOA WILL RISE ABRUPTLY TO 17 UNITS AND THEN GRADUALLY DECREASE AS AIRSPEED INCREASES DURING THE FLYAWAY. AIRCREW COORDINATION IS PARTICULARLY CRITICAL IN THIS REGIME, SINCE THE AIRCREW MUST ENSURE THAT INITIAL FLYAWAY PARAMETERS ARE MAINTAINED WHILE REMAINING ALERT FOR ANY ABNORMAL LAUNCH CHARACTERISTICS AND ENGINE MALFUNCTIONS. HIGH ENDSPEED AND/OR SINGLE-ENGINE FLYAWAY WITH TRIM SETTINGS ABOVE 2 DEGREES MAY REQUIRE SIGNIFICANT FORWARD STICK PRESSURE. IN ALL CONFIGURATIONS, THE USE OF AFTERBURNER AND/OR LEVEL RAPID ACCELERATION WILL REQUIRE REDUCED NOSE TRIM SETTINGS. THE RIO SHALL SCAN AIRSPEED, ALTITUDE AND ATTITUDE TO CONFIRM A POSITIVE RATE OF CLIMB. THE AVIA DISPLAY MAY BE USED TO PROVIDE ADDITIONAL INFORMATION (AOA AND POSITIVE RATE OF CLIMB) DURING THE INITIAL FLYAWAY, THOUGH, THE VSI AND AOA INFORMATION DISPLAYED ON THE AVIA IS PARTICULARLY SUSCEPTIBLE TO LAG AND INACCURACIES, AND SHOULD BE USED ONLY AS A SECONDARY SOURCE OF INFORMATION. THE RIO'S PRIMARY SCAN SHOULD BE AIRSPEED, ALTITUDE AND ATTITUDE FROM THE CONVENTIONAL INSTRUMENTS. ADDITIONAL CONSIDERATIONS EXIST FOR NIGHT/IFR CATAPULT LAUNCHES. AIRCRAFT ACCELERATION AND THE LACK OF EXTERNAL VISUAL CUES WILL CAUSE THE AIRCREW TO SENSE THAT THE NOSE IS HIGHER THAN ACTUAL AND CAN RESULT IN SPATIAL DISORIENTATION. UNDER THESE CONDITIONS A VIGILANT INSTRUMENT SCAN IS REQUIRED TO ENSURE THAT THE PROPER ATTITUDE IS MAINTAINED THROUGHOUT THE LAUNCH AND SUBSEQUENT CLIMBOUT. THE AIRCREW SHOULD ALSO BE ALERT FOR POWER TRANSIENTS, WHICH CAN TEMPORARILY DISABLE THE PILOT'S PRIMARY ATTITUDE DISPLAY (VDI) DURING AND AFTER THE CATAPULT STROKE, AND REQUIRE TRANSITION TO THE STANDBY GYRO FOR ATTITUDE INFORMATION. 5. CHANGE REF C (F-14D NFM), CHAPTER 8, PAGE 8-4, PARA 8.4.2, CATAPULT LAUNCH: A. DELETE THIRD (LAST) PARAGRAPH. B. ADD: THE F-14 MUST BE FLOWN OFF THE CATAPULT BY THE PILOT. AT _____________________________________________________________________________ CNO 300001Z MAR00 Page 3 of 4 NA 01-F14AAA-1 IC 143 NA 01-F14AAP-1 IC 41 NA 01-F14AAD-1 IC 21
SHUTTLE RELEASE, THE ENERGY STORED IN THE NOSE STRUT IS RELEASED, ROTATING THE AIRCRAFT TO THE INITIAL FLYAWAY ATTITIDE OF APPROXIMATELY 12-15 DEGREES NOSE-UP ON THE VDI AND HUD. THE AIRCREW SHOULD PLAN FOR THE STANDARD EXCESS ENDSPEED OF 15 KNOTS, UNLESS NOTIFIED OTHERWISE. LOWER EXCESS ENDSPEED THAN ANTICIPATED OR A LOWER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO USE BACKSTICK AT THE END OF THE CATAPULT STROKE TO CAPTURE AND MAINTAIN THE DESIRED CLIMBOUT PITCH ATTITUDE OF 10 DEGREES. HIGHER ENDSPEED THAN EXPECTED OR A HIGHER PITCH TRIM SETTING THAN RECOMMENDED WILL REQUIRE THE PILOT TO STOP THE ROTATION AT 10 DEGREES WITH SLIGHT FORWARD STICK. WHILE ROTATING TO THE FLYAWAY ATTITUDE, THE FLIGHTCREW WILL FEEL THE AIRCRAFT SETTLE APPROXIMATELY 5 FEET BEFORE COMMENCING A CLIMB. FOR CATAPULT LAUNCHES WITH EXCESS ENDSPEED LESS THAN 15 KNOTS, THE AOA WILL RISE ABRUPTLY TO 17 UNITS AND THEN GRADUALLY DECREASE AS AIRSPEED INCREASES DURING THE FLYAWAY. AIRCREW COORDINATION IS PARTICULARLY CRITICAL IN THIS REGIME, SINCE THE AIRCREW MUST ENSURE THAT INITIAL FLYAWAY PARAMETERS ARE MAINTAINED WHILE REMAINING ALERT FOR ANY ABNORMAL LAUNCH CHARACTERISTICS AND ENGINE MALFUNCTIONS. HIGH ENDSPEED AND/OR SINGLE-ENGINE FLYAWAY WITH TRIM SETTINGS ABOVE 2 DEGREES MAY REQUIRE SIGNIFICANT FORWARD STICK PRESSURE. IN ALL CONFIGURATIONS, THE USE OF AFTERBURNER AND/OR LEVEL RAPID ACCELERATION WILL REQUIRE REDUCED NOSE TRIM SETTINGS. THE RIO SHALL SCAN A REPEAT OF THE PILOT'S HEADS UP DISPLAY AND ASSOCIATED STANDBY FLIGHT INSTRUMENTS TO ENSURE THE CORRECT FLYAWAY CONDITIONS ARE MET (AIRSPEED, ALTITUDE AND ATTITUDE). ADDITIONAL CONSIDERATIONS EXIST FOR NIGHT/IFR CATAPULT LAUNCHES. AIRCRAFT ACCELERATION AND THE LACK OF EXTERNAL VISUAL CUES WILL CAUSE THE AIRCREW TO SENSE THAT THE NOSE IS HIGHER THAN ACTUAL AND CAN RESULT IN SPATIAL DISORIENTATION. UNDER THESE CONDITIONS, A VIGILANT INSTRUMENT SCAN IS REQUIRED TO ENSURE THAT THE PROPER ATTITUDE IS MAINTAINED THROUGHOUT THE LAUNCH AND SUBSEQUENT CLIMBOUT. // BT
_____________________________________________________________________________ CNO 300001Z MAR00 Page 4 of 4 NA 01-F14AAA-1 IC 143 NA 01-F14AAP-1 IC 41 NA 01-F14AAD-1 IC 21
PTAUZYUW RUENAAA7311 3221825-UUUU--RULSTGP. ZNR UUUUU P R 181806Z NOV 98 ZYB PSN 667712M29 FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES// INFO RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// RULSTGP/COMNAVWARDEVCOM DIV WASHINGTON DC//NATOPS// BT UNCLAS //N03711// MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGE TO F-14D AIRCRAFT NATOPS FLIGHT MANUAL// REF/A/DOC/NAVAIR/01FEB97// REF/B/MSG/CNO WASH DC/231304ZOCT98// NARR/REF A IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)), AND REF B IS INTERIM CHANGE NUMBER 19 (EJECTION SEAT AIRCREW WEIGHTS) TO REF A.// RMKS/1. THIS IS INTERIM CHANGE NUMBER 20 TO REF C (F-14D NFM). 2. SUMMARY. CORRECTS ERROR IN IC 19 (REF B) TO F-14D NFM (REF A). REF B INCORRECTLY REPLACED THE FIRST THREE SENTENCES OF FIRST PARAGRAPH OF PARA 2.38.1. THIS MESSAGE RESTORES ORIGINAL WORDING OF THE FIRST PARAGRAPH AND CHANGES THE SECOND PARAGRAPH. 3. CHANGE REF A (F-14D NFM), CHAPTER 2, PAGE 2-243, PARAGRAPH 2.38.1 EJECTION SEAT, AS FOLLOWS: A. FIRST PARAGRAPH OF PARAGRAPH 2.38.1. IF IC 19 NOT YET INCORPORATED INTO FIRST PARAGRAPH, PROCEED TO PARAGRAPH 3.B BELOW. IF IC 19 ALREADY INCORPORATED INTO FIRST PARAGRAPH, PROCEED AS FOLLOWS: (1) DELETE FIRST THREE SENTENCES, AS FOLLOWS: AFTER EJECTION HAS BEEN INITIATED, TWO PITOT HEADS MOUNTED NEXT TO THE PARACHUTE CONTAINER ARE DEPLOYED. AIRSPEED AND ALTITUDE ARE PROVIDED TO THE BATTERY-OPERATED ELECTRONIC SEQUENCER MOUNTED UNDER THE PARACHUTE CONTAINER. THE SEQUENCER USES THE INFORMATION TO DETERMINE THE RELEASE TIME FOR THE DROGUE BRIDLES, THE DEPLOYMENT TIME FOR THE PARACHUTE, AND RELEASE TIME FOR THE HARNESS LOCKS. (2) ADD (INSERT): THE NACES SEAT (FIGURE 2-126) IS PROVIDED WITH A ROCKETDEPLOYED 6.5 METER (20-FOOT), AEROCONICAL, STEERABLE PARACHUTE THAT IS PACKED WITH A RIBBON EXTRACTION DROGUE IN A CONTAINER BEHIND THE SEAT OCCUPANT'S HEAD. THE SEAT BUCKET HOLDS THE SURVIVAL KIT AND ALSO HAS THE SEAT FIRING HANDLE AND OTHER OPERATING CONTROLS. THE PARACHUTE RISERS ATTACH TO THE CREWMWMBER'S TORSO HARNESS BY MEANS OF SEAWATER-ACTIVATED RELEASE SWITCHES. B. SECOND PARAGRAPH: (1) DELETE THIRD SENTENCE: THE SEQUENCER, WHICH ALSO RECEIVES STATIC PRESSURE, USES THE INFORMATION TO DETERMINE THE PROPER SEQUENCING OF DEPLOYMENT OF THE SEAT DROGUE AND PARACHUTE AND RELEASE OF THE HARNESS LOCKS. (2) ADD (INSERT) REPLACEMENT THIRD SENTENCE: THE SEQUENCER USES THE INFORMATION TO DETERMINE THE RELEASE TIME FOR THE DROGUE BRIDLES, THE DEPLOYMENT TIME FOR THE PARACHUTE, AND RELEASE TIME FOR THE HARNESS LOCKS.// BT
________________________________________________________________________ CNO 181806Z NOV98 Page 1 of 1 NA 01-F14AAD-1 IC 20
PTAUZYUW RUENAAA6845 2961414-UUUU--RULSTGP. ZNR UUUUU P R 231304Z OCT 98 ZYB PSN 532084M22 FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES INFO RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// RULSTGP/COMNAVWARDEVCOM DIV WASHINGTON DC//NATOPS// BT UNCLAS //N03711// MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES TO F-14 AIRCRAFT NATOPS FLIGHT MANUALS// REF/A/DOC/NAVAIR/01FEB97// REF/B/DOC/NAVAIR/01FEB97// REF/C/DOC/NAVAIR/01FEB97// NARR/REF A IS NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 WITH CHG-1 01FEB97, REF B IS NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 WITH CHG-1 01FEB97, AND REF C IS NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)).// RMKS/1. THIS IS INTERIM CHANGE NUMBER 142 TO REF A (F-14A NFM), INTERIM CHANGE NUMBER 40 TO REF B (F-14B NFM), AND INTERIM CHANGE NUMBER 19 TO REF C (F-14D NFM). 2. SUMMARY. ADDS WARNINGS ABOUT EJECTION SEAT INJURY RISKS TO PAGE 02 RUENAAA6845 UNCLAS EACH NFM. 3. CHANGE REF A (F-14A NFM), AS FOLLOWS: A. CHAPTER 2, PAGE 2-159, PARAGRAPH 2.35 EJECTION SYSTEM, WARNING AFTER SECOND PARAGRAPH: (1) DELETE: NA (2) ADD (INSERT) NEW FIRST BULLET INTO WARNING: WARNING REGARDLESS OF THE GRU-7A EJECTION SEAT LIMITATIONS, ANY PERSON WHOSE NUDE BODY WEIGHT IS BELOW 136 POUNDS OR ABOVE 213 POUNDS IS SUBJECT TO INCREASED RISK OF INJURY FROM EJECTION. B. CHAPTER 16, PAGES 16-1 AND 16-3, PARAGRAPH 16.1.1 EJECTION ENVELOPE, SECOND PARAGRAPH AND ITEMS: (1) DELETE SECOND PARAGRAPH AND ITEMS 1 THROUGH 3. (2) ADD (INSERT) WARNING WITH TEXT: THE ESCAPE SYSTEM WILL FUNCTION UP TO 0.9 IMN OR 600 KIAS, WHICHEVER IS GREATER. HOWEVER, HUMAN LIMITATIONS ARE MORE RESTRICTIVE, AS INDICATED BELOW: WARNING REGARDLESS OF THE GRU-7A EJECTION SEAT LIMITATIONS, ANY PERSON WHOSE NUDE BODY WEIGHT IS BELOW 136 POUNDS OR ABOVE 213 POUNDS IS SUBJECT TO INCREASED RISK OF INJURY FROM EJECTION. 1. ZERO TO 250 KIAS - SAFE EJECTION (INJURY IMPROBABLE) 2. 250-600 KIAS - HAZARDOUS EJECTION (APPRECIABLE FORCES ARE EXERTED UPON THE BODY, MAKING INJURY PROBABLE) 3. ABOVE 600 KIAS - EXTREMELY HAZARDOUS EJECTION (EXCESSIVE FORCES ARE EXERTED UPON THE BODY, MAKING SERIOUS INJURY OR DEATH HIGHLY PROBABLE) C. CHAPTER 16, PAGE 16-2, FIGURE 16-1 EJECTION SEAT LIMITATIONS: (1) DELETE: NA (2) AT TOP OF PAGE BETWEEN FIGURE TITLE "COMMAND DUAL EJECTION" AND NOTE, ADD: GRU-7A EJECTION SEAT(S) _______________________________________________________________________ CNO 231304Z OCT98 Page 1 of 5 NA 01-F14AAA-1 IC 142 NA 01-F14AAP-1 IC 40 NA 01-F14AAD-1 IC 19
D.
4. A.
B.
C.
(3) BELOW "EJECTION SEAT - HUMAN FACTORS LIMITATIONS" GRAPH, ADD: (BULLET) THIS INFORMATION WAS EXTRAPOLATED USING THE GRU-7A QUALIFICATION WEIGHTS. (BULLET) THE GRU-7A WAS QUALIFIED FOR USE BY MALE AVIATORS WITH NUDE WEIGHTS FROM 136 LB TO 213 LB. (BULLET) THE HUMAN FACTOR LIMITATIONS ARE FOR HIGH SPEED AERODYNAMIC LOADS ONLY. CHAPTER 16, PAGE 16-3, PARAGRAPH 16.1.1.1 EJECTION AT GROUND LEVEL/ON DECK: (1) DELETE FIRST THREE PARAGRAPHS. (2) ADD (INSERT): 16.1.1.1 EJECTION AT GROUND LEVEL/ON DECK. THE GRU-7A EJECTION SEAT IS DESIGNED FOR ZERO-ZERO EJECTION CAPABILITY FOR A MAXIMUM NUDE CREWMEMBER WEIGHT OF 213 POUNDS. AIRCREW ABOVE 213 POUNDS NUDE WEIGHT HAVE AN INCREASED RISK OF INJURY DUE TO AN INADEQUATE PARACHUTE RECOVERY ALTITUDE. AT THE MAXIMUM NUDE WEIGHT OF 213 POUNDS, THE MARGIN OF SAFETY IS VERY NARROW BELOW 50 KTAS. TAILWIND AND AIRCRAFT DECELERATION ALSO CONTRIBUTE TO INCREASED INJURY RISK. FOR AIRCREW BELOW 136 POUNDS, THE ZERO-ZERO EJECTION PARACHUTE RECOVERY ALTITUDE IS INCREASED. HOWEVER, LIGHTWEIGHT AIRCREW OCCUPANTS BELOW 136 POUNDS NUDE WEIGHT ARE SUBJECTED TO HIGHER LOADS AS AIRSPEED INCREASES, ESPECIALLY AT AIRSPEEDS GREATER THAN 450 KIAS. THE EJECTION SEAT BECOMES LESS STABLE AND DECELERATION FORCES DURING DROGUE CHUTE DEPLOYMENT BECOME MORE SEVERE. ANALYSIS HAS SHOWN THAT LOWERING THE SEAT PRIOR TO EJECTING INCREASES SEAT STABILITY DURING A HIGH SPEED EJECTION. (3) RETAIN OLD LAST PARAGRAPH. CHANGE REF B (F-14B NFM), AS FOLLOWS: CHAPTER 2, PAGE 2-152, PARAGRAPH 2.35 EJECTION SYSTEM, WARNING AT TOP OF PAGE: (1) DELETE: NA (2) ADD (INSERT) NEW FIRST BULLET INTO WARNING: WARNING REGARDLESS OF THE GRU-7A EJECTION SEAT LIMITATIONS, ANY PERSON WHOSE NUDE BODY WEIGHT IS BELOW 136 POUNDS OR ABOVE 213 POUNDS IS SUBJECT TO INCREASED RISK OF INJURY FROM EJECTION. CHAPTER 16, PAGE 16-1, PARAGRAPH 16.1.1 EJECTION ENVELOPE, SECOND PARAGRAPH AND ITEMS: (1) DELETE SECOND PARAGRAPH AND ITEMS 1 THROUGH 3. (2) ADD (INSERT) WARNING WITH TEXT: THE ESCAPE SYSTEM WILL FUNCTION UP TO 0.9 IMN OR 600 KIAS, WHICHEVER IS GREATER. HOWEVER, HUMAN LIMITATIONS ARE MORE RESTRICTIVE, AS INDICATED BELOW: 1. ZERO TO 250 KIAS - SAFE EJECTION (INJURY IMPROBABLE 2. 250-600 KIAS - HAZARDOUS EJECTION (APPRECIABLE FORCES ARE EXERTED UPON THE BODY, MAKING INJURY PROBABLE) 3. ABOVE 600 KIAS - EXTREMELY HAZARDOUS EJECTION (EXCESSIVE FORCES ARE EXERTED UPON THE BODY, MAKING SERIOUS INJURY OR DEATH HIGHLY PROBABLE) CHAPTER 16, PAGE 16-2, FIGURE 16-1 EJECTION SEAT LIMITATIONS: (1) DELETE: NA (2) AT TOP OF PAGE BETWEEN FIGURE TITLE "COMMAND DUAL EJECTION" AND NOTE, ADD: GRU-7A EJECTION SEAT(S)
_______________________________________________________________________ CNO 231304Z OCT98 Page 2 of 5 NA 01-F14AAA-1 IC 142 NA 01-F14AAP-1 IC 40 NA 01-F14AAD-1 IC 19
D.
5. A.
B.
C.
(3) BELOW "EJECTION SEAT - HUMAN FACTORS LIMITATIONS" GRAPH, ADD: (BULLET) THIS INFORMATION WAS EXTRAPOLATED USING THE GRU-7A QUALIFICATION WEIGHTS. (BULLET) THE GRU-7A WAS QUALIFIED FOR USE BY MALE AVIATORS WITH NUDE WEIGHTS FROM 136 LB TO 213 LB. (BULLET) THE HUMAN FACTOR LIMITATIONS ARE FOR HIGH SPEED AERODYNAMIC LOADS ONLY. CHAPTER 16, PAGE 16-3, PARAGRAPH 16.1.1.1 EJECTION AT GROUND LEVEL/ON DECK: (1) DELETE FIRST THREE PARAGRAPHS. (2) ADD (INSERT): 16.1.1.1 EJECTION AT GROUND LEVEL/ON DECK. THE GRU-7A EJECTION SEAT IS DESIGNED FOR ZERO-ZERO EJECTION CAPABILITY FOR A MAXIMUM NUDE CREWMEMBER WEIGHT OF 213 POUNDS. AIRCREW ABOVE 213 POUNDS NUDE WEIGHT HAVE AN INCREASED RISK OF INJURY DUE TO AN INADEQUATE PARACHUTE RECOVERY ALTITUDE. AT THE MAXIMUM NUDE WEIGHT OF 213 POUNDS, THE MARGIN OF SAFETY IS VERY NARROW BELOW 50 KTAS. TAILWIND AND AIRCRAFT DECELERATION ALSO CONTRIBUTE TO INCREASED INJURY RISK. FOR AIRCREW BELOW 136 POUNDS, THE ZERO-ZERO EJECTION PARACHUTE RECOVERY ALTITUDE IS INCREASED. HOWEVER, LIGHTWEIGHT AIRCREW OCCUPANTS BELOW 136 POUNDS NUDE WEIGHT ARE SUBJECTED TO HIGHER LOADS AS AIRSPEED INCREASES, ESPECIALLY AT AIRSPEEDS GREATER THAN 450 KIAS. THE EJECTION SEAT BECOMES LESS STABLE AND DECELERATION FORCES DURING DROGUE CHUTE DEPLOYMENT BECOME MORE SEVERE. ANALYSIS HAS SHOWN THAT LOWERING THE SEAT PRIOR TO EJECTING INCREASES SEAT STABILITY DURING A HIGH SPEED EJECTION. (3) RETAIN OLD LAST PARAGRAPH. CHANGE REF C (F-14D NFM), AS FOLLOWS: CHAPTER 2, PAGE 2-243, PARAGRAPH 2.38 EJECTION SYSTEM, WARNING AFTER SECOND PARAGRAPH: (1) DELETE: NA (2) ADD (INSERT) NEW FIRST BULLET INTO WARNING: WARNING REGARDLESS OF THE SJU-17 EJECTION SEAT LIMITATIONS, ANY PERSON WHOSE NUDE BODY WEIGHT IS BELOW 136 POUNDS OR ABOVE 213 POUNDS IS SUBJECT TO INCREASED RISK OF INJURY FROM EJECTION. CHAPTER 2, PAGE 2-243, PARAGRAPH 2.38.1 EJECTION SEAT, FIRST PARAGRAPH: (1) DELETE FIRST THREE SENTENCES. (2) ADD (INSERT): AFTER EJECTION HAS BEEN INITIATED, TWO PITOT HEADS MOUNTED NEXT TO THE PARACHUTE CONTAINER ARE DEPLOYED. AIRSPEED AND ALTITUDE ARE PROVIDED TO THE BATTERY-OPERATED ELECTRONIC SEQUENCER MOUNTED UNDER THE PARACHUTE CONTAINER. THE SEQUENCER USES THE INFORMATION TO DETERMINE THE RELEASE TIME FOR THE DROGUE BRIDLES, THE DEPLOYMENT TIME FOR THE PARACHUTE, AND RELEASE TIME FOR THE HARNESS LOCKS. CHAPTER 2, PAGE 2-243, PARAGRAPH 2.38.1.1 SEAT FIRING HANDLE: (1) DELETE PARAGRAPH. (2) ADD: 2.38.1.1 SEAT FIRING HANDLE. EJECTION IS INITIATED BY PULLING UP ON THE SEAT FIRING HANDLE ON THE FRONT OF THE SEAT BUCKET BETWEEN THE CREWMEMBERS THIGHS. A PULL FORCE OF 25 TO 40 POUNDS IS REQUIRED TO REMOVE THE FIRING HANDLE FROM ITS
_______________________________________________________________________ CNO 231304Z OCT98 Page 3 of 5 NA 01-F14AAA-1 IC 142 NA 01-F14AAP-1 IC 40 NA 01-F14AAD-1 IC 19
HOUSING. A CONTINUED PULL FORCE OF 30 TO 60 POUNDS IS REQUIRED TO INITIATE EJECTION. THIS ACTION OPERATES LINKAGE THAT WITHDRAWS THE SEARS FROM THE TWO SEAT INITIATOR CARTRIDGES, COMMENCING THE EJECTION SEQUENCE. D. CHAPTER 2, PAGE 2-248, PARAGRAPH 2.38.1.9 SURVIVAL KIT, THIRD PARAGRAPH: (1) DELETE FIRST SENTENCE. (2) ADD (INSERT): A URT-33C RADIO LOCATOR BEACON IS IN A CUTOUT IN THE LEFT THIGH SUPPORT AND IS CONNECTED TO THE COCKPIT FLOOR BY A STATIC OPERATING CABLE SO THAT IT CAN BE AUTOMATICALLY ACTUATED DURING EJECTION. E. CHAPTER 2, PAGE 2-250, PARAGRAPH 2.38.4.1 ELECTRONIC SEQUENCING: (1) DELETE SUBPARAGRAPHS 1 THROUGH 3. (2) ADD (INSERT): 1. MODE 1 -- THIS IS THE LOW-ALTITUDE, LOW-AIRSPEED MODE. THE BRIDLES ARE RELEASED 0.32 SECONDS AFTER SEAT FIRST MOTION. THE PARACHUTE DEPLOYMENT ROCKET FIRES TO DEPLOY THE PARACHUTE AND THE HARNESS RELEASE SYSTEM OPERATES TO FREE THE OCCUPANT FROM THE SEAT. 2. MODES 2, 3, AND 4 -- THESE MODES ARE FOR LOW TO MEDIUM ALTITUDES. THE SEAT IS DECELERATED BY THE DROGUE AND AFTER A TIME DELAY DETERMINED BY THE ELECTRONIC SEQUENCER THE PARACHUTE DEPLOYMENT ROCKET FIRES TO DEPLOY THE PARACHUTE BEFORE THE DROGUE BRIDLES ARE RELEASED. THE HARNESS RELEASE SYSTEM OPERATES TO FREE THE OCCUPANT FROM THE SEAT. 3. MODE 5 -- THIS MODE IS SELECTED AT HIGH ALTITUDE. THE SEAT (WITH DROGUE BRIDLES CONNECTED) DESCENDS TO 18,000 FEET, WHERE THE BRIDLES ARE RELEASED. THE PARACHUTE DEPLOYMENT ROCKET FIRES TO DEPLOY THE PARACHUTE AND THE HARNESS RELEASE SYSTEM OPERATES TO FREE THE OCCUPANT FROM THE SEAT. F. CHAPTER 16, PAGES 16-1 AND 16-5, PARAGRAPH 16.1.1 EJECTION ENVELOPE: (1) DELETE SECOND PARAGRAPH AND ITEMS 1 THROUGH 3. (2) ADD (INSERT): WARNING DURING EJECTION SEAT DEVELOPMENT AND TESTING, THE SJU-17(V)3/A AND SJU-17(V)4/A WERE QUALIFIED FOR USE BY MALE AVIATORS WITH NUDE WEIGHTS FROM 136 POUNDS TO 213 POUNDS. OPERATION OF THE SEAT BY PERSONNEL NOT WITHIN THESE PARAMETERS SUBJECTS THE OCCUPANT TO INCREASED RISK OF INJURY. 1. GENERAL INJURY RISKS: A. EJECTION SEAT STABILITY IS DIRECTLY RELATED TO OCCUPANT RESTRAINT. ALL OCCUPANTS SHOULD BE PROPERLY RESTRAINED IN THE SEAT BY THEIR TORSO HARNESS FOR OPTIMUM PERFORMANCE AND MINIMUM INJURY RISK. B. INERTIA REEL PERFORMANCE MAY BE DEGRADED FOR OCCUPANTS OUTSIDE OF THE QUALIFIED WEIGHT RANGE. LIGHTER OCCUPANTS MAY BE INJURED DURING THE HAULBACK, AND BOTH LIGHT AND HEAVY OCCUPANTS MAY EXPERIENCE POOR EJECTION POSITIONS, RESULTING IN AN INCREASED RISK OF INJURY DURING EJECTION. 2. INJURY RISKS FOR AVIATORS WITH NUDE WEIGHTS LESS THAN 136 POUNDS: _______________________________________________________________________ CNO 231304Z OCT98 Page 4 of 5 NA 01-F14AAA-1 IC 142 NA 01-F14AAP-1 IC 40 NA 01-F14AAD-1 IC 19
A. THE CATAPULT WAS DESIGNED FOR THE EJECTION SEAT QUALIFIED WEIGHT RANGE. LIGHTER WEIGHT OCCUPANTS ARE SUBJECT TO A HIGHER RISK OF INJURY FROM THE CATAPULT DUE TO GREATER ACCELERATION. B. LIGHTER WEIGHT OCCUPANTS ARE AT A GREATER RISK OF INJURY DURING EJECTIONS ABOVE 300 KIAS DUE TO INSTABILITY DURING DROGUE DEPLOYMENT. C. LIGHTER WEIGHT OCCUPANTS ARE AT A GREATER RISK OF INJURY DURING EJECTIONS NEAR THE UPPER END OF MODE 1 (APPROACHING 300 KIAS) DUE TO HIGH PARACHUTE OPENING SHOCK. 3. INJURY RISKS FOR AVIATORS WITH NUDE WEIGHTS GREATER THAN 213 POUNDS: A. LARGER OCCUPANTS MAY NOT ATTAIN SUFFICIENT ALTITUDE FOR PARACHUTE FULL INFLATION IN ZERO-ZERO CASES OR AT EXTREMELY LOW ALTITUDES AND VELOCITIES. B. LARGER OCCUPANTS MAY NOT ATTAIN SUFFICIENT ALTITUDE TO CLEAR THE AIRCRAFT TAIL STRUCTURE. THE ESCAPE SYSTEM WILL FUNCTION UP TO 0.9 IMN OR 600 KIAS, WHICHEVER IS GREATER. HOWEVER, HUMAN LIMITATIONS ARE MORE RESTRICTIVE AS INDICATED BELOW: 1. ZERO TO 250 KIAS -- SAFE EJECTION (INJURY IMPROBABLE) 2. 250 TO 600 KIAS -- HAZARDOUS EJECTION (APPRECIABLE FORCES ARE EXERTED UPON THE BODY, MAKING INJURY PROBABLE) 3. ABOVE 600 KIAS -- EXTREMELY HAZARDOUS EJECTION (EXCESSIVE FORCES ARE EXERTED UPON THE BODY, MAKING SERIOUS INJURY OR DEATH HIGHLY PROBABLE). (3) RETAIN OLD LAST PARAGRAPH. // BT
_______________________________________________________________________ CNO 231304Z OCT98 Page 5 of 5 NA 01-F14AAA-1 IC 142 NA 01-F14AAP-1 IC 40 NA 01-F14AAD-1 IC 19
DEPARTMENT OF NAVAL AIR SYSTEMS 47123 8”SE ROAD. PATUXENT RIVER. MD
THE NAVY COMMAND “Nrr “IPT 20670-I 547
IN“CCL.IIPEmIO 3711
Ser AIR-t.3P/7.0098 17 Jul98
From: To:
Commander, Naval Air Systems Command Distribution
Subj:
INTERIM
P.&
(a) (b) c-3
01-F-14AAA-I. 01-F-14AAP-1. 01-F-14AAD-1.
Encl:
(1) (2) (3)
F-14A Interim NATOPS Change Number 141 F-14B Interim NATOPS Change Number 39. F-14D Interim NATOPS Change Number 18.
CHANGE TO F-14A/B/D NATOPS PUBLICATIONS F-14A NATOPS Flight Manual dtd 15 May 95 with Change 1.01 Feb 97. F-14B NATOPS Flight Manual dtd 15 May 95, with Change 1.01 Feb 97. F-14D NATOPS Flight Manual dtd 01 Feb 97.
1. The following F-14 Aircrall Interim NATOPS Changes are hereby issued: a. F-14A Interim NATOPS Change Number 141 to reference (a). b. F-14B Interim NATOPS Change Number 39 IO reference (b). c. F-14D Interim NATOPS Change Number 18 to reference (c). 2. Make the following moditications to the F-14A, F-14B. and F-14D NATOPS Manuals: a. Cross through NATOPS Manual page 4-14 with a pen and write “superseded” b. Insert (1) (2) (3)
change F-14A: F-14B: F-14D:
pages 4-14a and 4-14b into the NATOPS Manual from the following enclosures: enclosure (1) enclosure (2) enclosure (3)
c. At the bottom of page J-15, cross through “figure 2 of 2” with a pen, and write “figure 3 of 3” in its place. d.
Enter the following on page 5, in the front of the appropriate NATOPS Manual,:
F-14A F-14B F-14D
Interim Chance @gn& 141 39 18
Oricinator/Date
Pages Affected
CNASUl7 Jol98 CNASCIl7 Jul98 CNASCI17 Jul98
4-14akl 4-14a/b 4-14&l
w HARRY LEHMAN By direction
Remar!&Pwwse Rolling Maneuvering Limits Rolling Maneuvering Limits Rolling Maneuvering Limits
Subj:
DFFER~M CHANGE TO F-14tVB/D
NATOPS PUBLICATIONS
Distribution: AIR-4.1.1 AIR-I.4.1 COMNAVAIRLANT, NORFOLK VA (N422C24) COMNAVAJBJ’AC. SAN DIEGO. CA (N422CTPL) NAVAIRPRA, ATSUGI, JA VF-2 (QAXTPL) VP-I 1 (CTPL UNIT 25504. QATPL) VF-14 (QAXTPL) VF-3 I (QA/CTPL) VF-32 (QAAXF’L) V-F-41 (QA/CTPL) VP-IO1 DET KEY WEST (QiXTPL) VF-10 1 (QA/CTPL) VF-102 (QA/CTPL) VF-103 (QAAX-PL) V-F-143 (QAAX-PL) VF-154 (QA/CTPL) VF-201 (QAXTPL) VF-211 (QA/CTPL) W-2 13 (QA/CTF’L) VK-9 DET PT MUGU. CA SWATSLANT, OCEANA, VA NAMTRAGRUDET, OCEANA, VA (TECH LIB) NAESU DE-C OCEANA, VA GRUMMAN, ST AUGUSTINE (TECH LB) MCDONNELL DOUGLAS, ST LOUIS, MO XEROX G.E. CO @l/D-T58) DCMC PACIFIC JAPAN (NIPPI TECH LIB) NSAWC FALLON, NV (50 QAICTPL) NAVTACSUPPACT, WASH NAVY YARD NAVAL WAR COLLEGE, NEWPORT RI NAWCAD, PATUKENT RIVER, MD (AJR4.4.7. AMDI BLDG; 5.1.1.1, DATA CNTR) NAWCWD. CHINA LAKE, CA NAVY AVIATION SUP OFF, PHILADELPHIA, PA (05 134 I) NAVWEPTESTRON F-I- MUGU, CA (562E4OE) NAVAVDEPOT, JACKSONVILLE, FL (3.3.3) NAVSTRIKE AC TEST SQDN. NAS PATUXENT RIVER MD NATESTPlLSCH. SYSZSYS ENGTEST DIR NAWCAD PATUKENT RIVER, MD NAWCAD SETD PATUXENT RIVER, MD (SYO4OC) HUGHES, INDIANAFOLIS IN (LIB C64N) NAWCAD LAKEHURST NJ (4872B696/1PIGA, 725281492) NAWCWD PT MUGU, CA (333OOOEv’DCC) COMFITWINGLANT, OCEANA, VA NAVAB~TBCHSERVFAC. PHILADELPHIA. PA (2,3 133) HQ NAICIGTO, WRIGHT PAlTERSON Al?3
F-14D INTERIM NATOPS CHANGE #18 (includesF- 14D Natopspages4-14a and4-14b)
Enclosure(3)
NAVAIR
Ol-F14AAD-1
F-14D ROLL SAS ON MANEUVERING ENVELOPE WITHOUT EXTERNAL FUEL TANKS SEPTEMBER ESTIMATED
DATE: OATA BASIS:
0.2
ROLLING
0.4
0.8
RESTRICTED
1.0
1.2
TRUE
MACH
1.4
1.6
1.8
2.0
2.2
NUMBER
TO:
REGION
1 - 360’ MAXIMUM BANK ANGLE CHANGE AT IG. 160. MAXIMUM BANK ANGLE CHANGE AT OTHER THAN IG. 4.OG: ALL CONFIGURATIONS WITH WING-MOUNTED AIM-54. 5.20: ALL OTHER CONFIGURATIONS (See next sheet for external tanks).
REGION
2 - 360’ 160’
REGION
NOTE:
1994 FLIGHTTEST
0.6
MANEUVERS
I
ANGLE ANGLE
CHANGE CHANGE
AT AT
1G. OTHER
3 - NO ABRUPT STICK INPUTS. 360’ MAXIMUM BANK ANGLE
CHANGE
AT
1G ONLY.
DO NOT EXCEED CONFIGURATION.
Figure
4-9.
MAXIMUM BANK MAXIMUM BANK (4G MAXIMUM).
MAXIMUM NATOPS
Maneuvering
ALLOWABLE UMITS OF
AIRSPEED FOR STORE FIGURE 4-4 APPLY.
Limits
Rolling
4-14a
-
(Sheet
THAN
1G
1 of 3) INTERIM
I CHANGE
19
NAVAIR Ol-F14AAD-1
F-14D ROLL SAS ON MANEUVERING ENVELOPE WITH EXTERNAL FUEL TANKS
MAY lss6 ESTlMATEO
DATE: DATA BASIS:
0.2
ROLLING
0.1
MANEUVERS
REGION
REGION
NOTE:
DO NOT EXCEED CONFIGURATION.
FUGHTTEST
0.6
0.6
RESTRICTED
1 - 360’ 180’ 4.OG
1.0
1.2
TRUE
MACH
1.4
1.6
1.6
2.0
2.2
NUMBER
TO:
MAXIMUM BANK ANGLE CHANGE AT MAXIMUM BANK ANGLE CHANGE AT LIMIT: FULL LATERAL STICK ROLLS.
IG. OTHER
THAN
IG.
2 - 360’ MAXIMUM BANK ANGLE CHANGE AT IG. NO ABRUPT STICK INPUTS. ROLLING MANEUVERS LIMITED TO COORDINATED TURNS USING MAXIMUM OF 0.5 INCH’ LATERAL STICK INPUTS. l.OG DURING ROLLS.
MAXIMUM NATOPS
ALLOWABLE AIRSPEED LIMITS OF FIGURE U
Figure 4-9. Maneuvering Limits -
Roiling
FOR STORE APPLY.
(Sheet 2 of 3) INTERIM CHANGE 18
PTAUZYUW RUENAAA3280 0781546-UUUU--RULSTGP. ZNR UUUUU P R 191427Z MAR 98 ZYB PSN 203824M19 FM CNO WASHINGTON DC//N889// TO ALL TOMCAT AIRCRAFT ACTIVITIES// INFO RUCTPOH/NAVOPMEDINST PENSACOLA FL//06// RULSTGP/NAVTACSUPPACT WASHINGTON DC//60// BT UNCLAS //N03711// MSGID/GENADMIN/N889// SUBJ/INTERIM CHANGES TO F-14 AIRCRAFT NATOPS PUBLICATIONS// REF/A/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAA-1 (F-14A NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY95 CHG-1 01FEB97// REF/B/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAA-1F (F-14A NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL))// REF/C/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAP-1 (F-14B NATOPS FLIGHT MANUAL (NFM)) DTD 15MAY97 CHG-1 01FEB97// REF/D/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAP-1F (F-14B NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL))// REF/E/DOC/NAVAIR/15MAY95// AMPN/NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM)) DTD 01FEB92 CHG-3 15MAY95// REF/F/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAD-1 (F-14D NATOPS FLIGHT MANUAL (NFM))// REF/G/DOC/NAVAIR/15MAY95// AMPN/NAVAIR 01-F14AAD-1F (F-14D NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL)) DTD 01FEB92 CHG-3 15MAY95// REF/H/DOC/NAVAIR/01FEB97// AMPN/NAVAIR 01-F14AAD-1F (F-14D NATOPS FUNCTIONAL CHECKFLIGHT CHECKLIST (FCFCL))// RMKS/1. THIS IS INTERIM CHANGE NUMBER 139 TO REF A (F-14A NFM), INTERIM CHANGE NUMBER 7 TO REF B (F-14 FCFCL), INTERIM CHANGE NUMBER 37 TO REF C (F-14B NFM), INTERIM CHANGE NUMBER 8 TO REF D (F-14B FCFCL), INTERIM CHANGE NUMBER 17 TO REFS D AND G (F-14D NFM'S), AND INTERIM CHANGE NUMBER 1 TO REFS G AND H (F-14D FCFCL'S). REFS F AND H ARE CURRENTLY AT PRINTER AND, WHEN DISTRIBUTED, WILL SUPERSEDE REFS E AND G, RESPECTIVELY. 2. SUMMARY. MODIFIES FUNCTIONAL CHECKFLIGHT PROCEDURES IN REFS A THROUGH I. ALPHABETICAL SUFFIXES ARE USED BELOW WITH STEP NUMBERS WHEN INSERTING ADDITIONAL STEPS TO AVOID RENUMBERING SUBSEQUENT STEPS (E.G., STEP 11A INDICATES AN INSERTED STEP WHICH FOLLOWS CURRENT STEP 11 AND WILL BE NUMBERED AS STEP 12 IN NEXT UPDATE OF THE PUBLICATION, WHILE STEP 11.A INDICATES SUBSTEP A OF STEP 11.) 3. CHANGE REF A (F-14A NFM), CHAPTER 10, AS FOLLOWS: A. PAGE 10-1, PARAGRAPH 10.2: (1) DELETE EXISTING PARAGRAPH. (2) ADD: 10.2 CHECKFLIGHT PROCEDURES. A FLIGHT PROFILE HAS BEEN ESTABLISHED FOR EACH CHECKFLIGHT CONDITION AND IS IDENTIFIED BY THE LETTER CORRESPONDING TO THE PURPOSE FOR WHICH THE CHECKFLIGHT IS BEING FLOWN (A, B, C, AS SHOWN IN _______________________________________________________________________ CNO 191427Z MAR98 Page 1 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
FIGURE 10-1). THE APPLICABLE LETTER IDENTIFYING THE PROFILE PRECEDES EACH ITEM IN THE FUNCTIONAL CHECKFLIGHT CHECKLIST (NAVAIR 01-F14AAA-1F). POSTMAINTENANCE CHECKFLIGHT PROCEDURES ARE SPECIFIC AND ARE TO BE PERFORMED IN CONJUNCTION WITH NORMAL NATOPS OPERATING PROCEDURES (PART III). CHECKFLIGHT PERSONNEL SHALL FAMILIARIZE THEMSELVES WITH THE PROFILE REQUIREMENTS BEFORE EACH FLIGHT. A DAILY INSPECTION IS REQUIRED BEFORE EACH CHECKFLIGHT. AN AIRCRAFT IS CONSIDERED HIGH GROSS WEIGHT FOR PROFILE PURPOSES IF OVER 56,000 POUNDS TOTAL WEIGHT. AIRCREW SHALL BE COGNIZANT OF THE AIRCRAFT'S CONFIGURATION AND THE CUMULATIVE NEGATIVE EFFECTS OF WEAPONS RAILS AND EXTERNAL STORES ON AIRCRAFT STABILITY. NOTE SHIPBOARD CONSTRAINTS CAN PRECLUDE COMPLETION OF SOME ITEMS ON THE APPLICABLE FLIGHT PROFILE CHECKLIST. 10.2.1 GENERAL CONDUCT. THOROUGH, PROFESSIONAL CHECKFLIGHTS ARE A VITAL PART OF THE SQUADRON MAINTENANCE EFFORT. CHECK CREWS PERFORM A VALUABLE SERVICE TO THE MAINTENANCE DEPARTMENT BY CARRYING OUT THIS FUNCTION. THE QUALITY OF SERVICE PROVIDED BY CHECK CREWS REFLECTS DIRECTLY IN THE QUALITY OF MAINTENANCE AND SUBSEQUENTLY ENHANCES FLIGHT OPERATIONS. THE COMMANDING OFFICER SHALL ENSURE THAT THOROUGHNESS, PROFESSIONALISM, AND SAFETY ARE OBSERVED THROUGHOUT THE CHECKFLIGHT EVOLUTION AND THAT CHECK CREWS STRICTLY ADHERE TO THE PROFILE CHECKLIST. SAFETY IS A PRIMARY CONSIDERATION DURING ALL CHECKFLIGHTS. B. PAGE 10-19, PARA 10.3.12, STEP 70 (NEGATIVE ALPHA MCB/FOD CHECK): (1) DELETE STEP 70. (2) ADD: 70. DELETED C. PAGE 10-21, PARA 10.3.12, AFTER STEP 72.M: (1) DELETE: NA (2) ADD: ABC 72A. NEGATIVE ALPHA/MCB/FOD CHECK (20,000 FEET, 300 KIAS). WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF ENGINE STALLS AND/OR AIRCRAFT DEPARTURES. NOTE THIS CHECK VERIFIES THE PROPER OPERATION OF EACH MCB WITH APPROXIMATELY 4 DEGREES NEGATIVE ALPHA AS SENSED BY THE AICS SENSOR PROBES, AND IS RELATIVELY INDEPENDENT ON THE AMOUNT OF NEGATIVE G APPLIED. A. THROTTLES -- MIL B. RAISE NOSE TO 10 DEGREES ABOVE HORIZON, ROLL INVERTED (ENSURE WINGS LEVEL). _______________________________________________________________________ CNO 191427Z MAR98 Page 2 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
D.
E.
F.
G.
H.
C. SMOOTHLY APPLY FORWARD STICK PRESSURE (NOT TO EXCEED -1.0 G). MCB TEST LIGHTS SHOULD ILLUMINATE (COORDINATE WITH RIO). D. CHECK FOR NORMAL ENGINE OPERATION AND FOD OR LOOSE GEAR. E. RELEASE FORWARD STICK AND PERFORM COORDINATED ROLL TO UPRIGHT WINGS LEVEL ATTITUDE. CHECK MCB TEST LIGHTS OUT AT +1.0 G. PAGE 10-24, PARA 10.4.4, STEP 19 (MCB TEST LIGHTS): (1) DELETE STEP 19. (2) ADD: AB 19. REFUEL PROBE CHECK: A. MCB TEST LIGHTS -- ILLUMINATED WITH PROBE EXTENDED/OFF WHEN RETRACTED (COORDINATE WITH PILOT). PAGE 10-24, PARA 10.4.5 FIFTEEN THOUSAND-FOOT CHECKS: (1) DELETE STEPS 23 THROUGH 25. (2) ADD: AB 23. ECS CHECK A. SET WCS SWITCH TO STBY BEFORE PILOT ECS CHECK. ABC 24. HIGH AOA MACH LEVER/AUTO MAN DEVICES/MCB CHECKS A. ALPHA COMP CB (7C8) -- IN. B. CONFIRM ROLL SAS OFF AND THROTTLES IDLE. C. OBSERVE MANEUVER DEVICES EXTENDED AT 10.5 UNITS AOA. D. MCB TEST LIGHTS ILLUMINATED AFTER 16 UNITS AOA (COORDINATE WITH PILOT). E. CONFIRM RPM INCREASE AT 18+/-1 UNITS AOA (GREATER THAN 80 PERCENT). F. OBSERVE MANEUVER DEVICES RETRACT AT 8 UNITS AOA. G. ALPHA COMP CB -- OUT. AB 25. AICS/MCB CHECK A. AICS CB'S (7E1 AND 7E2) -- PULL. B. MCB TEST LIGHTS -- ILLUMINATED. C. AICS CB'S -- RESET. D. MCB TEST LIGHTS -- OFF. ABC 25A. STRUCTURAL INTEGRITY CHECK A. ANTI-G VALVE OPERATION PAGE 10-24, PARA 10.4.6, AFTER STEP 27 (WCS SWITCH -- STBY): (1) DELETE: NA (2) ADD: AB 27A. AT 0.85 IMN WITH THROTTLES LESS THAN MIL, MCB TEST LIGHTS -- CHECK OFF (COORDINATE WITH PILOT). PAGE 10-25, PARA 10.4.7, AFTER STEP 28 (ENGINE INSTRUMENTS) TABLE: (1) DELETE: NA (2) ADD: AB 28A. MACH LEVER AND MCB CHECK A. MCB TEST LIGHTS -- ILLUMINATED AT IDLE (COORDINATE WITH PILOT). PAGE 10-25, PARA 10.4.7: STEP 32 (MCB TEST LIGHTS):
_______________________________________________________________________ CNO 191427Z MAR98 Page 3 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
(1) DELETE STEP 32. (2) ADD: 32. DELETED I. RENAME PAGE 10-25, PARA 10.4.8 DESCENT AS: 10.4.8 DESCENT/20,000-FOOT CHECKS J. PAGE 10-27, PARA 10.4.8, STEP 34 (MCB CHECK): (1) DELETE ALL. (2) ADD: ABC 34. MCB CHECK A. GUN ARMED POWER CB (8C3) -- PULL (RIO). B. CONFIRM WEAPONS SELECT -- GUN. C. CONFIRM MASTER ARM SWITCH -- ON. D. CONFIRM THROTTLES -- STABILIZED ZONE 2 (APPROXIMATELY 2.4 NOZZLE POSITION). E. CONFIRM TRIGGER -- SQUEEZE. F. VERIFY NOZZLE POSITION INCREASE. G. MCB TEST LIGHTS -- ILLUMINATED. (COORDINATE WITH PILOT) H. VERIFY NOZZLES RETURN TO THE ORIGINAL POSITION. I. CONFIRM MASTER ARM SWITCH -- OFF. J. CONFIRM GUN -- DESELECTED K. GUN ARMED POWER CB (8C3) -- RESET. ABC 34A. NEGATIVE ALPHA/MCB/FOD CHECK (20,000 FEET, 300 KIAS) WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF ENGINE STALLS AND/OR AIRCRAFT DEPARTURES. NOTE THIS CHECK VERIFIES THE PROPER OPERATION OF EACH MCB WITH APPROXIMATELY 4 DEGREES NEGATIVE ALPHA AS SENSED BY THE AICS SENSOR PROBES, AND IS RELATIVELY INDEPENDENT ON THE AMOUNT OF NEGATIVE G APPLIED. A. CONFIRM THROTTLES -- MIL. B. AFTER PILOT RAISES NOSE TO 10 DEGREES ABOVE HORIZON AND ROLLS INVERTED WINGS LEVEL (NOT TO EXCEED -1.0 G), CONFIRM MCB TEST LIGHTS ILLUMINATED. C. CHECK FOR FOD OR LOOSE GEAR. D. AS AIRCRAFT ROLLS UPRIGHT TO WINGS LEVEL ATTITUDE, CHECK MCB TEST LIGHTS OUT AT +1.0 G. 4. CHANGE REF B (F-14A FCFCL) AS FOLLOWS: A. PART 1, PILOT CHECKLIST: (1) PAGE 1-19, STEP 70 (NEGATIVE ALPHA MCB/FOD CHECK): (A) DELETE STEP 70. (B) ADD: 70. DELETED _______________________________________________________________________ CNO 191427Z MAR98 Page 4 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
(2) PAGE 1-21 AFTER STEP 72.M: (A) DELETE: NA (B) ADD STEP 72A (NEGATIVE ALPHA/MCB/FOD CHECK) AS IN PARAGRAPH 3.C(2) ABOVE. B. PART 2, RIO CHECKLIST: (1) CHANGE PAGE 2-4, STEP 19 (MCB TEST LIGHTS) AS IN PARAGRAPHS 3.D(1) AND 3.D(2) ABOVE. (2) CHANGE PAGE 2-5, STEPS 23 THROUGH 25A, AS IN PARAGRAPHS 3.E(1) AND 3.E(2) ABOVE. (3) PAGE 2-5, AFTER STEP 27 (WCS SWITCH -- STBY): (A) DELETE: NA (B) ADD STEP 27A (AT 0.85 IMN WITH THROTTLES....) AS IN PARAGRAPH 3.F(2) ABOVE. (4) PAGE 2-5, AFTER STEP 28 (ENGINE INSTRUMENTS) TABLE: (A) DELETE: NA (B) ADD STEP 28A (MACH LEVER AND MCB CHECK) AS IN PARAGRAPH 3.G(2) ABOVE. (5) PAGE 2-6, STEP 32 (MCB TEST LIGHTS): (A) DELETE STEP 32. (B) ADD: 32. DELETED (6) PAGE 2-6, DESCENT HEADING (AFTER STEP 32): (A) DELETE: DESCENT (B) ADD: DESCENT/20,000-FOOT CHECKS (7) CHANGE PAGE 2-8, STEP 34 (MCB CHECK), AS IN PARAS 3.J(1) AND 3.J(2) ABOVE. 5. CHANGE REF C (F-14B NFM), CHAPTER 10, AS FOLLOWS: A. CHANGE PAGE 10-1, PARA 10.2 AS IN PARAS 3.A(1) AND 3.A(2) ABOVE, EXCEPT REPLACE REFERENCE TO 01-F14AAA-1F WITH 01-F14AAP-1F. B. PAGE 10-20, PARA 10.3.8, STEP 73 (NEGATIVE ALPHA/FOD CHECK): (1) DELETE STEP 73. (2) ADD: 73. DELETED C. PAGE 10-21, PARA 10.3.12, AFTER SUBSTEP 74.F(3): (1) DELETE: NA (2) ADD: ABC 74A. NEGATIVE ALPHA/FOD CHECK (20,000 FEET, 300 KIAS) WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF AIRCRAFT DEPARTURES. A. THROTTLES -- MIL. B. RAISE NOSE TO 10 DEGREES ABOVE HORIZON, ROLL INVERTED (ENSURE WINGS LEVEL). C. SMOOTHLY APPLY FORWARD STICK PRESSURE (NOT TO EXCEED -1.0 G). D. CHECK FOR NORMAL ENGINE OPERATION AND FOD OR LOOSE GEAR. E. RELEASE FORWARD STICK AND PERFORM COORDINATED ROLL TO UPRIGHT WINGS LEVEL _______________________________________________________________________ CNO 191427Z MAR98 Page 5 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
ATTITUDE. D. RENAME PAGE 10-25, PARA 10.4.8 DESCENT AS: 10.4.8 DESCENT/20,000-FOOT CHECKS E. PAGE 10-27, AFTER SUBSTEP 26.F: (1) DELETE: NA (2) ADD: ABC 26A. NEGATIVE ALPHA/FOD CHECK (20,000 FEET, 300 KIAS) WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF AIRCRAFT DEPARTURES. A. CONFIRM THROTTLES -- MIL. B. AFTER PILOT RAISES NOSE TO 10 DEGREES ABOVE HORIZON AND ROLLS INVERTED WINGS LEVEL (NOT TO EXCEED -1.0 G), CHECK FOR FOD OR LOOSE GEAR. 6. CHANGE REF D (F-14B FCFCL) AS FOLLOWS: A. PART 1, PILOT CHECKLIST: (1) PAGE 1-21, STEP 73 (NEGATIVE ALPHA/FOD CHECK): (A) DELETE STEP 73. (B) ADD: 73. DELETED (2) PAGE 1-23 AFTER SUBSTEP 74.F(3): (A) DELETE: NA (B) ADD STEP 74A, (NEGATIVE ALPHA/FOD CHECK) AS IN PARAGRAPH 5.C(2) ABOVE. B. PART 2, RIO CHECKLIST: (1) PAGE 2-6, DESCENT HEADING (AFTER STEP 25.C): (A) DELETE: DESCENT (B) ADD: DESCENT/20,000-FOOT CHECKS (2) PAGE 2-7, AFTER SUBSTEP 26.F: (A) DELETE: NA (B) ADD STEP 26A (NEGATIVE ALPHA/FOD CHECK) AS IN PARAGRAPH 5.E(2) ABOVE. 7. CHANGE REF E (F-14D NFM DTD 15MAY95), CHAPTER 10, AS FOLLOWS: A. CHANGE PAGE III-10-1, PARA 10.2 AS IN PARAS 3.A(1) AND 3.A(2) ABOVE, EXCEPT REPLACE REFERENCE TO 01-F14AAA-1F WITH 01-F14AAD-1F. B. PAGE III-10-11, STEP 68 (NEGATIVE ALPHA/FOD CHECK): (1) DELETE STEP 68. (2) ADD: 68. DELETED C. PAGE III-10-14, AFTER SUBSTEP 77.G(2): (1) DELETE: NA (2) ADD: ABC 77A. NEGATIVE ALPHA/FOD CHECK (20,000 FEET, 300 KIAS) WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS _______________________________________________________________________ CNO 191427Z MAR98 Page 6 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF AIRCRAFT DEPARTURES. A. THROTTLES -- MIL. B. RAISE NOSE TO 10 DEGREES ABOVE HORIZON, ROLL INVERTED (ENSURE WINGS LEVEL). C. SMOOTHLY APPLY FORWARD STICK PRESSURE (NOT TO EXCEED -1.0 G). D. CHECK FOR NORMAL ENGINE OPERATION AND FOD OR LOOSE GEAR. E. RELEASE FORWARD STICK AND PERFORM COORDINATED ROLL TO UPRIGHT WINGS LEVEL ATTITUDE. D. RENAME PAGE III-10-16, PARA 10.4.9 DESCENT AS: 10.4.9 DESCENT/20,000-FOOT CHECKS E. PAGE III-10-17, AFTER SUBSTEP 23.E: (1) DELETE: NA (2) ADD: ABC 23A. NEGATIVE ALPHA/FOD CHECK (20,000 FEET, 300 KIAS) WARNING IT IS IMPERATIVE THAT THE PROCEDURES IN THIS CHECK BE FOLLOWED EXACTLY AND NEGATIVE-G MANEUVERING AT HIGH GROSS WEIGHT (OVER 56,000 POUNDS) SHOULD BE AVOIDED BECAUSE OF THE HIGH PROBABILITY OF AIRCRAFT DEPARTURES. A. CONFIRM THROTTLES -- MIL. B. AS PILOT RAISES NOSE TO 10 DEGREES ABOVE HORIZON AND ROLLS INVERTED TO WINGS LEVEL (NOT TO EXCEED -1.0 G), CHECK FOR FOD AND LOOSE GEAR. 8. WHEN RECEIVED, CHANGE REF F (F-14D NFM DTD 01FEB97), CHAPTER 10, AS FOLLOWS: A. CHANGE PAGE III-10-1, PARA 10.2 AS IN PARAS 3.A(1) AND 3.A(2) ABOVE, EXCEPT CHANGE REFERENCE TO 01-F14AAA-1F TO 01-F14AAD-1F. B. PAGE III-10-21, STEP 76 (NEGATIVE ALPHA/FOD CHECK): (1) DELETE STEP 76. (2) ADD: 76. DELETED C. PAGE III-10-22, AFTER SUBSTEP 77.G(2): (1) DELETE: NA (2) ADD STEP 77A (NEGATIVE ALPHA/FOD CHECK) AS IN PARA 7.C(2) ABOVE. D. RENAME PAGE III-10-25, PARA 10.4.9 DESCENT AS: 10.4.9 DESCENT/20,000-FOOT CHECKS E. PAGE III-10-26, AFTER SUBSTEP 23.E: (1) DELETE: NA (2) ADD STEP 23A (NEGATIVE ALPHA/FOD CHECK) AS IN PARA 7.E(2) ABOVE. 9. CHANGE REF G (F-14D FCFCL DTD 15MAY95) AS FOLLOWS: A. PART 1, PILOT CHECKLIST: (1) PAGE 1-19, STEP 68 (NEGATIVE ALPHA/FOD CHECK): (A) DELETE STEP 68. (B) ADD: _______________________________________________________________________ CNO 191427Z MAR98 Page 7 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
68. DELETED (2) PAGE 1-24, AFTER SUBSTEP 77.G(2): (A) DELETE: NA (B) ADD STEP 77A (NEGATIVE ALPHA/FOD CHECK) AS IN PARA 7.C(2) ABOVE. B. PART 2, RIO CHECKLIST: (1) PAGE 2-5, AFTER STEP 22 (ENGINE INSTRUMENTS) TABLE: (A) DELETE: DESCENT (B) ADD: DESCENT/20,000-FOOT CHECKS (2) PAGE 2-6, AFTER SUBSTEP 23.E: (A) DELETE: NA (B) ADD STEP 23A (NEGATIVE ALPHA/FOD CHECK) AS IN PARAGRAPH 7.E(2) ABOVE. 10. WHEN RECEIVED, CHANGE REF H (F-14D FCFCL DTD 01FEB97) AS FOLLOWS: A. PART 1, PILOT CHECKLIST: (1) PAGES 1-22 AND 1-23, STEP 76 (NEGATIVE ALPHA/FOD CHECK): (A) DELETE STEP 76. (B) ADD: 76. DELETED (2) PAGE 1-23, AFTER SUBSTEP 77.G(2): (A) DELETE: NA (B) ADD STEP 77A (NEGATIVE ALPHA/FOD CHECK) AS IN PARA 7.C(2) ABOVE. B. PART 2, RIO CHECKLIST: (1) PAGE 2-5, AFTER STEP 22 (ENGINE INSTRUMENTS) TABLE: (A) DELETE: DESCENT (B) ADD: DESCENT/20,000-FOOT CHECKS (2) PAGE 2-6, AFTER SUBSTEP 23.E: (A) DELETE: NA (B) ADD STEP 23A (NEGATIVE ALPHA/FOD CHECK) AS IN PARAGRAPH 7.E(2) ABOVE. // BT
_______________________________________________________________________ CNO 191427Z MAR98 Page 8 of 8 NA 01-F14AAA-1 IC 139 NA 01-F14AAA-1F IC 7 NA 01-F14AAP-1 IC 37 NA 01-F14AAP-1F IC 8 NA 01-F14AAD-1 IC 17 NA 01-F14AAD-1F IC 1
NAVAIR OI-Fl4AAD-I
SUMMARY Information
OF APPLICABLE
relating to thefollowing
CHANGE
TECHNICAL
DIRECTIVES
recent technical directives has been incorporated in this manual.
DESCRIPTION
DATE INC. IN MANUAL
AFC 793
StandardCentral Air Data Computer
30 sep 94
None
AFC 795
RadarWarning ReceiverModification
30 sep 94
None
AYC 832
Incorporationof Unmodified OBOGS Monitor
15 May95
Panel size increasedon pilot’s right console
AFC 843
BOL Chaff Incorporation
1 Feb 97
5A BOL PWR circuit breakers at 219,211O
NUMBER
Information relating to thefollowing
I
CHANGE NUMBER
VlSUAL IDENTlFlCATlON
applicable technical directives will be incorporated in ofuhwe change. DESCRIPTION
I
7 (ReverseBlank)
VISUAL IDENTIFICATION
ORIGINAL
NAVAIR 01.F14AAD-1
RECORD OF CHANGES Change No. and Date of Change
Date of Entry
Page Count Verified by (Signature)
I
9 (ReverseBlank)
ORIGINAL
NAVAIR Ol-F14AAD-1
F-14D NATOPS FliQht Manual CONTENTS
PART I -THE
AIRCRAFT
CHAPTER 1 -AIRCRAFT 1.1 1.1.1 1.1.2 1.1.3 1.1.4 1.1.5
AND ENGINE
AIRCRAFT . . . . . . . Aircraft Weight. . . . . . Cockpit . . . . . . . . . ElectronicNomenclature TecbnicalDirectivea . . . Block Numbers . . . . .
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: ::::
l-l : :1-2 : :::;
CHAPTER 2 -SYSTEMS 2.1 2.1.1 2.1.2 2.1.3 2.1.4
AIR INLET CONTROL SYSTEM .......... Normal AICS Operations ............... AICS Test ....................... AICS Failure Modes of Operation. .......... AICS Anti-Ice .....................
. . . . .
. . . . .
....... ....... ....... .......
2-1 2-1 2-1 2-4 2-9
2.2 2.2.1 2.2.2
ENGINE.. ...................... Engine Control ..................... Variable ExhaustNozzle ...............
. . . . . . . . . . . .
. . . . . . . . . . . . .
....... ...... ......
2-9 2-11 2-16
2.3 2.3.1 2.3.2 2.3.3
FATIGUE ENGINE MONITORING SYSTEM ... FEMS Functional Description ............. FEMS Operation .................... FEMS and OBC ....................
. . . .
. . . .
. . . .
. . . .
. . . .
...... ...... ...... ......
2-16 2-16 2-21 2-21
2.4 2.4.1 2.4.2 2.4.3 2.4.4 2.4.5 2.4.6
ENGINE FUEL SYSTEM .............. Motive Flow Fuel Pump ................ Engine Fuel Boost Pump. ............... Main Fuel Pump .................... Main Engine Control ................. Afterburner Fuel Pump ................ Ahburner Fuel Control ...............
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2-21 2-21 2-21 2-21 2-21 2-23 2-23
2.5 2.5.1
THROTTLES ..................... Throttle Control Modes ................
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2-23 2-23
2.6 2.6.1 2.6.2
ENGINE BLEED AR. ................ Engine Anti-ice .................... Environmental Control System Leak Detection. . , .
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2-27 2-21 2-29
2.1 2.7.1 2.7.2
ENGINE COMPARTMENTVBNTIL.ATION Engine In-Flight Ventilation .............. Engine GroundVentilation ..............
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2-30 2-30 2-30
ORIGINAL
NAVAIR Ol-F14AAD-1
Page NO. 2.8 2.8.1 2.8.2 2.8.3
ENGINE IGNITION SYSTEM Main High-Energy Ignition . . . . Afterburner Ignition . . . . . . . Backup Ignition . . . . . . .
2.9 2.9.1 2.9.2 2.9.3 2.9.4
ENGINE STARTING SYSTEM External Airstart . . . . . . . . . Engine Crank . . . . . . . . . . CrossbleedStart . . . . . . . . Aitarts . . . . . . . .. . . . .
2.10 2.10.1 2.10.2 2.10.3
ENGINEOILSYSTEM. . . . . oil cooliig . . . . . . . . Oil PressureIndicators . . . . . . OIL HOT Caution Lights . . .
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ENGINEINSTRUMENTS ...... Engine RPM Indicator ......... ExhaustGas TemperatureIndicator . 2.11.3 Fuel Flow Indicator .......... Engine Instrument GroupBIT ..... 2.11.4 Engine InstrumentGroup Self-Test . . 2.11.5 Engine Oil PressureIndicator ..... 2.11.6 2.11.7 ExhaustNozzle Position Indicator. .. 2.11.8 Engine Monitor Display Format ... 2.11.9 MFD Engine Caution Legends .... 2.11.10 Engine Stall/OvertemperatureWarning
2.11 2.11.1 2.11.2
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FIREDETECTIONSYSTEM Fire Detection Test. ..........
2.13 2.13.1 2.13.2 2.13.3
. . . . . FIRE EXTINGUISHING SYSTEM 1’ . . Fire ExtinguisherPushbuttons.... Fire Extinguisher Advisory Lights . . . . . . . Fire Extinguisher Test ......... . . . .
2.14 2.14.1 2.14.2 2.14.3 2.14.4 2.14.5 2.14.6 2.14.7 2.14.8 2.14.9 2.14.10
2.14.11 2.14.12
AIRCR4FT FUEL SYSTEM .............. Fuel Tankage. ...................... Fuel Quantity System .................. Engine Feed ....................... Fuel Transfer. ...................... Fuel Quantity Balancing ................. Fuel Transfer/FeedDuring Single-EngineOperation . . Fuel Dump ........................ Internal Tank PressurizationandVent ......... Fueling and Defueling .................. In-Flight Refueling. ................... Hot Refueling ...................... Automatic Fuel Electrical Controls ...........
2.15 2.15.1
ELECTRICAL POWER SUPPLY SYSTEM. . Normal Electrical Operation . . . . , .
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2-32 2-32 2-32 2-34 2-34
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2-35 2-35 2-35 2-37 2-31 2-31 2-31 2-37 2-37 2-38 2-38
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2.12 2.12.1
ORIGINAL
. 2-30 . . . 2-32 . . . 2-32 2-32 .
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2-40
2-43 2-50 2-54 2-54 2-55 2-56 2-56 2-57 2-59 2-59
2-59 2-59
NAVAIR 0%Fl4AAD1
Page No. 2.15.2 2.15.3
Electrical Power Distribution .......... DegradedElectrical Operation .........
2.16 2.16.1 2.16.2 2.16.3 2.16.4
HYDRAULIC POWER SUPPLY SYSTEMS . Flight and Combined Systems .......... Hydraulic Power Distribution .......... OutboardSpoiler System ............ Backup Flight Control System. .........
2.17 2.17.1 2.17.2 2.17.3
PNEUMATIC POWER SUPPLY SYSTEMS . Normal Canopy Control ............. Auxiliary Canopy Open Control ......... EmergencyGear Extension ...........
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2.18. 2.18.1 2.18.2 2.18.3
2-61 . . . 2-62
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. . 2-76 . . . 2-76 . . . 2-76 . . . 2-76
MISSION COMPUTER SYSTEM ....... Aircrew Interface ................ OperationalStates ................ Aircrafl Master Modes ..............
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2.19 2.19.1
STANDARD CENTRAL AIR DATA COMPUTER Central Air Data Computer Tests ..........
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. . 2-78 . . . 2-78
2.20 2.20.1 2.20.2 2.20.3 2.20.4
WING-SWEEP SYSTEM .............. Wing-Sweep Performance .............. Wing-Sweep Modes ................. Wing-Sweep Interlocks ............... Wing-Sweep System Test ..............
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. . . 2-81 . . . 2-81 . . . 2-82 . . 2-86 . . . 2-86
2.21 2.21.1 2.21.2
FLAPS AND SLATS ................ Flap and Slat Controls ................ Flap and Slat Operation ...............
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2.22 2.22.1
SPEEDBRAKES .................. SpeedbrakeOperation ................
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: : : 2-94
2.23 2.23.1 2.23.2 2.23.3 2.23.4 2.23.5 2.23.6
FLIGHT CONTROL SYSTEMS . Longitudinal Control ......... IntegratedTrim System ....... Lateral Control ............ Spoiler Control ............ Yaw Control ............. Direct Lift Control ..........
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2.24 2.24.1 2.24.2 2.24.3 2.24.4 2.24.5
AUTOMATIC FLIGHT CONTROL SYSTEM Stability Augmentation System ......... Voltage Monitor Control Unit .......... Autopilot ..................... Pilot Relief and GuidanceModes ........ AFCSTest ....................
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2.25 2.25.1 2.25.2
LANDING GEAR SYSTEMS ........... Landing Gear Handle. ................ MainLandingGear. ..................
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. 2-68 2-68 . 2-71 . 2-72 . 2-72
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2-76 2-76 2-78 2-78
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: : 2-101 2-106 . . 2-109
: : ;::;: . * 2-116 : : 2-116 . . 2-l 16 ORIGINAL
NAVAIR 01-Fl4AAD-1
2.25.3 2.25.4 2.25.5
Nose Landing Gear . . . . . . . . . . Landing GearNomd Operation . , . Emergency GearExtension . . . . . .
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2.118 2-l 19 2-120
2.26 2.26.1 2.26.2 2.26.3 2.26.4 2.26.5 2.26.6 2.26.7
WHEELBRAKE SYSTEM ...... Brake Characteristics ......... Normal Braking ............ Antiskid ................ Auxiliary Brake ............ BRAKES Warning Light ....... Parking Brake ............. Wheel Antirotation. ..........
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2-120 2-122 2-122 2-122 2-124 2-124 2-124 2-125
2.21 2.27.1 2.21.2 2.27.3
NOSEWHEEL STEERING SYSTEM Nosewheel SteeringControl ...... NosewheelCentering ......... Shimmy Damping ...........
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2-125 2-125 2-127 2-127
2.28 2.28.1 2.28.2 2.28.3
NOSEGEAR CATAPULT SYSTEM Nose Strut Kneel ............ Launch Bar. .............. Holdback Fitting ............
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2-127 2-127 2-129 2-129
2.29 2.29.1
... ARRESTINGHOOKSYSTEM Arresting Hook Operation .......
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2-129 2-129
2.30 2.30.1 2.30.2 2.30.3 2.30.4 2.30.5 2.30.6 2.30.7
ENVIRONMENTAL CONTROL SYSTEM ECS Air Sources.................. Cockpit Air-Conditioning ............. Electronic Equipment Cooling .......... Pressurization ................... Windshield Air andAnti-Ice ............ Gun-GasPurging ................. DegradedECS Operation .............
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2-132 2-132 2-135 2-136 2-136 2-138 2-138 2-138
2.31 2.31.1 2.31.2 2.31.3 2.31.4
OXYGEN SYSTEM. ......... On-Board Oxygen GeneratingSystem Backup Oxygen System ........ BOS PressuroIndicator ........ EmergencyOxygen Supply ......
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...... 2-141 2-141 ...... 2-143 ...... . * * * . . 2-144 2-144 ......
2.32 2.32.1
PITOT-STATIC SYSTEM ...... Pitot-Static Heat ............
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2-144 2-144
2.33 2.33.1 2.33.2 2.33.3 2.33.4 2.33.5 2.33.6 2.33.7
CONTROL AND DISPLAY SYSTEM Display Types ............. Display Processors........... System Operation ........... Heads-Up Display ........... Multistatus Indicator .......... Multifunction Displays ........ Cursor Controls ............
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2-145 2-145 2-153 2-153 2-153 2-154 2-158 2-158
ORIGINAL
14
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NAVAIR 01.FMAAD-1
2.33.8 2.33.9
Displays, Formats, andSymbology MFD Formats . . . . . . . . . . .
2.34 2.34.1 2.34.2
DATA ENTRY UNIT . . . . . . . Data Entry Unit Operating Modes . DEU Menu Pages . . . . . . . . .
2.35 2.35.1. 2.35.2 2.35.3 2.35.4
FLIGHT INSTRUMENTS . . . StandbyAttitude Indicator . . . . StandbyAirspeed Indicator . . . StandbyAltimeter , . . . . . . . AN/APN-194(V) Radar Altimeter
2.36 2.36.1 2.36.2 2.36.3 2.36.4
ANGLE-OF-ATTACK SYSTEM . AOA Test ............. AOA Indicator ........... AOA Indexer. ........... Approach Lights ..........
2.31 2.37.1
CANOPY SYSTEM . . . . . . . . Canopy Operation . . . . . . . . .
2.38 2.38.1 2.38.2 2.38.3 2.38.4
EJECTION SYSTEM . . Ejection Seat . . . . . . . . CommandEjection Lever . . Ejection Initiation . . . . . . SeatOperationAfter Ejection
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2.39 2.39.1 2.39.2 2.39.3
LIGHTING SYSTEM . . . Exterior Lights . . . . . . . . Interior Lights . . . . . . . . Warning and Indicator Lights
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2.40 2.40.1 2.40.2 2.40.3 2.41 2.41.1 2.41.2 2.41.3 2.41.4
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2-160 2-181
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2-225 2-225 2-227
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2-234 2-234 2-234 2-234 2-234
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2-236 2-239 2-239 2-239 2-239
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2-240 2-240
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2-243 2-243 2-248 2-248 2-250
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STORES MANAGEMENT SYSTEM/ JETTISON SMS WeaponsRephccable Assemblies . . . . . , Multistatus Indicator . . . . . . . . . . . . . . . . . StoresJettisonModes . . . . . . . . . . . . . . , ,
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MISCELLANEOUS EQUIPMENT . . . . . . Boarding Ladder . . . . . . . . . , . . . . . . Nose Radome . . , . . . . . , . . , . . . . . , SystemsTest and SystemPower GroundPanel , ExtcrnalBaggageContainer (CNU-188/A) . . .
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2-268 2-268 2-268 2-269 2-269
CHAPTER 3 - SERVICING AND HANDLING 3.1 3.1.1 3.1.2 3.1.3 3.1.4 3.1.5 3.1.6
SERVICING DATA . , . . . . GroundRefueling . . . , . . . Engine Oil . . . . . , , . . . . IntegratedDrive GeneratorOil Hydraulic Systems . . . . . . . Pneumatic Systems . . . . . . BackupOxygen Supply . . . .
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. .2 . *E 3-a . . . 3-a
ORIGINAL
NAVAIR 01.FI4AAD-I
3.2 3.2.1 3.2.2 3.2.3 3.2.4
GROUNDHANDLING......................................3DangerAreas .......................................... RadarRadiationAreas ..................................... Towing Turn Radii and Ground Clearances .......................... Tiedown Points .........................................
CHAPTER 4 -OPERATING
8 .3-S .3-S 3-15 3-15
LIMITATIONS
4.1 4.1.1 4.1.2 4.1.3 4.1.4 4.1.5 4.1.6 4.1.7
LIMITATIONS ........................................ Engine Limits .......................................... StarterLimits............................................4Aimtart Envelope ........................................ ........................................ CrosswindLiits Ground OperationsLimits .................................... Ejection SeatOperationLimits ................................. Autopilot Liits .........................................
..4- 1 .4-l 1 .4-l .4-l .4-l .4-l .4-l
4.2 4.2.1
.................................. AIRSPEED LlMITATIONS MaximumAirspeeds........................................4-
.4-l
4.3 4.3.1 4.3.2
ACCELERATION LIMITS ................................... Cruise Configuration. ...................................... Approach Configuration .....................................
.4-S .4-S .4-S
4.4 4.4.1 4.4.2
ANGLE-GF-ATTACK LIMITS ................................ Cruise Configuration. ...................................... Approach Configuration .....................................
.4-5 .4-S 4-10
:::.1 4.5.2 4.5.3 4.5.4 4.5.5
MANEUVERING LIMITS ................................... Approach Configuration ..................................... Cruise Configuration. ...................................... .......................................... Rolling Liita Sideslip Limits .......................................... Prohibited Maneuvers ......................................
4-10 4-10 4-10 4-10 4-10 4-10
4.6 4.6.1 4.6.2
SASLIMITS...........................................4-13 Cruise Contiguration ....................................... Approach Configuration .....................................
4-13 4-13
4.7 4.7.1 4.7.2
TAKEOFF AND LANDING FLAP AND SLAT TRANSITION LIMITS Clean and Symmetric StoresLoading .............................. External StoresLoading With up to 66,000Inch-Pounds (5,500 Foot-Pounds)Asymmetry ................................ External StoresLoading With GreaterThan 66,000Inch-Pounds (5,500Foot-Pounds)Asymmetry ................................
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4.8
GROSS WEIGHT LIMITS -TAKEOFF,
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4.9
BARRICADE ENGAGEMENT LIMITS ............................
4-17
4.10
CENTER OF GRAVITY POSITION LIMITS .........................
4-18
4.7.3
ORIGINAL
I6
LAUNCH, AND LANDING.
5
4-13 4-13 4-17 4-17 4-17
NAVAIR Ol-F14AAD.1
4.11 4.11.1 4.11.2 4.11.3 4.11.4 4.11.5
EXTERNALSTORESANDGUNLIMITS 28O-GallonExternal Fuel Tank Liits .......... External BaggageContainer(CNU-188/A). GunBurstLimits. ..................... Launch Limits ....................... JettisonLiits ...................
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4.12
BANNER TOWING RESTRICTIONS .......................
4.13 4.13.1 4.13.2
TACTICAL AIR RECONNAISSANCE POD SYSTEM LIMITATIONS Authorized StoresLoading ............................ Iuterim AIM-7 as Ballast .............................
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4-18 4-18 4-18 4-18 4-18 4-19 4-19
. . . 4-20 . . . 4-20 . . . 4-20
PART II - INDOCTRINATION CHAPTER 5 - INDOCTRINATION GROUND TRAINING SYLLABUS . . . . . . . . . Minimum Ground Training Syllabus . . . . . .. Waiving of Minimum Ground Training Requirements
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51212
FLIGHT-G SYLLABUS . . . . . Flightcrew Flight Training Syllabus . . . . Flightcrew FlightTraining Phases. . . . . .
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5.3 5.3.1 5.3.2 5.3.3 5.3.4 5.3.5
OPERATINGCRITERIA. . .. . . . . . . . . . . Ceiling/Visibility Requirements . . . . . . . . . . . . NATOPS Qualification and Cunency Requirements . Requirementsfor Various Flight Phases . . . . . . , Mission Commander. . . . . . . . . . . . . . . . . , Minimum Flightcrew Requirements. . . . . . .
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5.4
FLIGHT CREWMEMBERFLIGHT
:::.1 5.1.2 :.221
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5-1 . . . . . 5-1 . . . . . 5-l
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EQUIPMENT REQUIREMENTS . . . .
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. 5-2 . 5-2 . 5-3 . . :: . 54
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PART Ill - NORMAL PROCEDURES CHAPTER 6 - FLIGHT PREPARATION 6.1 6.1.1 6.1.2
PREFLIGHT BRIEFING . . . . . . . . . . Admin . . . . . . . . . . . . . . . . . . . . Missions . . . . . . . . . . . . . . . . . . .
CHAPTER 7 -SHORE-BASED
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PROCEDURES
7.1 7.1.1
CHECKLISTS . . . . . . . . . . . . . . . . Tactical Air ReconnaissancePod System .
z.1 712.2 7.2.3 7.2.4 7.2.5
EXTERIOR INSPECTION . . . . . . . . . ArcaAroundAircrafi . . . . . . . . . . . . Foreign Object Damageand Leak Inspection GroundSafety DevicesandCovers . . . . . SurfaceCondition . . . . . . . . . . . . . . Security of Panels . . . . . . . . . . . . . . 17
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7-l 7-1
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;:: 7-l 7-l 7-2 l-2
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ORIGINAL
l-2 7-2 7-2
7.2.6 7.2.1 1.2.8
Leaks ......................
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Movable Sties ............... InspeotionAreas ................
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7.3
EJECTION SEAT INSPECTION ................................
1.4 7.4.1 7.4.2 7.4.3 7.44 1.45 7.4.6 7.4.7 7.4.8 7.4.9 7.4.10 7.4.11 7.4.12 7.4.13 7.4.14 7.4.15 7.4.16 7.4.17 7.4.18
PILOT PROCEDURES ........ Interior Inspection -Pilot ...... Prestart-Pilot ............ Engine Start- Pilot ......... Poststati - Pilot ............ Taxiing ................. Taxi-Pilot .............. Takeoff ................ Flaps-Up Takeoff ........... Formation Takeoff. .......... Takeoff Aborted ............ Takeoff Checklist ........... Ascent Checkliit ............ In-Flight OBC ............. Prelandand Descent .......... PatternEntry ............. Landing ................ Landing Checklist ........... Postlandiog- Pilot ..........
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7.5 7.5.1 7.5.3 1.5.4 7.5.5 7.5.6 7.5.7 7.5.8
. . , . RIO PROCEDURES .......... InteriorInspection-RIO. ....... . . . Prestart-RIO . . . . ErmineStart - IhO’ : : : : : : : : : : . . . . PO&art-RIO .................... Taxi -R IO ...................... In-Flight ReconnaissanceSystem Chock - RIO TARPSDepradedModeProcedmes ......... Postlandh&Y-RIO..................
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1.6
HOT REFUELING PROCEDURES ...................
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. 7-35
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. 136
z.1 7.7.2
DECK-LAUNCHED INTERCEPT PROCEDURES ........... Pilot procedures .............................. RIoProcednms ..............................
7.8
HOT SWITCH PROCEDURES .......
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. l-36
% 71912 1.9.3 7.9.4 7.9.5
FIELD CARRIER LANDING PRACTICE Preflight Inspection .............. Takeoff ..................... RadioProceduresandPatternEntry ..... Pattern ..................... Night FCLP ..................
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ORIGINAL
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. 7-8 7-10 7-11 7-13 I-11 7-19 7-20 7-21 7-21 7-22 7-22 7-23 l-23 l-23 7-24 ;:z
7-27
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: : : l-28 7-29 : : : 7-30 . . . 7-33 : : : 7-33 . . . l-35
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I-31 I-31 I-31 7-31
: 7-31 7-38
NAVAIR WF14AAD.I
Page NO.
CHAPTER 8 -CARRIER-BASED
t:1 8:1:2
PROCEDURES
8.1.3
CARRIER PREFLIGHT .................................... Launch.. ............................ Briefing.. ........................... Preflight.. ..........................................
El 8:2:2
START AND POSTSTART .................................. Carrier Alignment SAHRSStandaloneCarrierAligomeot.. ....................................
8.3 8.3.1 8.3.2
TAXIING ........................................... ..8- 3 NosewheelSteering. 8-3 TaxiSpeed. ..... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . :::8- 3
8.4 8.4.1 8.4.2 8.4.3
CATAPULT HOOKUP (DAY) ................................. Catapult Trim Requirements CatapultLaunch.......::::::::::::::::::::::::::::::::::: Catapult Abort Procedures(Day) ................................
El 8:5:2 8.5.3 8.5.4 8.5.5 8.5.6 8.5.7 8.5.8 8.5.9 8.5.10 8.5.11 8.5.12 8.5.13
LANDING ................................................ 8-5 CarrierLamimgPattem(VFR). :::::::::::::::8-5 Manual Approach Technique . ............................................ Approach Power CompensatorTechnique : : : : : : : : .8”:; Waveoff Technique ....................................... .8-8 Bolter Technique. . ................................................... 8-8 BingoFuel ..I :::: :::::::: 1: 18-8 ArrestedLamlingandExitFromtheLandiigArea .8% ...................... Carrier-ControlledApproaches ................ 8-9 HoldPhase...........................::::::::::::::::::89 Platform ............................................ ..8- 9 Ten-Mile DME Fix 8-9 Six-MileDMEFix.::::::::::::::::::::::::::::::::::::::::8-9 Meatball Contact ........................................ .8-9
8.6
WAVEOFF AND BOLTER.
8.7 8.7.1 8.7.2 8.7.3 8.7.4 8.7.5 8.7.6 8.7.7 8.7.8
NIGHT FLYING ....................... Briefb Prefli$t :::::::::::::::::::::::::::: Poststart ....................... : .... Taxi .............................. CatapultHookup (Night) ................... CatapultLaunch ........................ CatapultAbort Procedures(Night) .............. ArrestedLanding and Exit From Landing Area (Night) ...
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.8-l 8-l . . . . . . . . . . . . . . . ..8-1 ..8- 1 .8-l 8-l :::::::::::::::::8-3
.8-3 i: .8-4
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. 8-11
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8-11 8-11 8-11 8-11 8-11 8-11 8-11 8-11 8-12
CHAPTER 9 - SPECIAL PROCEDURES El 9.1.2 9.1.3
IN-FLIGHT REFUELING PROCEDURES ......... In-Flight Refueling Controls ................. In-Flight Refueling Checklist ........................ In-Flight Refueling Techniques ....................... 19
: : : : : : :
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9-l 9-l 9-1 9-l ORIGINAL
NAVAIR 01.FMAAD-1
El 91212 9.2.3 9.2.4 9.2.5
FORMATION FLIGHT . . . . . . . . . . . . . . . .. . . . .. . . ParadeFormation BreakFormation.::... . . DiamondFour-Plane Forrna~o~ . : : : : : : : Cruise Formation . . . . . . . . . . . . . . . . Airaft Lighting During Night Formation Flight
.. ..
9.3 9.3.1 9.3.2 9.3.3
BANNER TOWING. , Ground Procedures . . shipboard Procedures . Flight Procedures . .
9.4
FUEL MANAGEMENT SYSTEM OPERATIONAL CHECK . .
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9-2 9-2 9-3 9-3
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9-4 9-4 9-4 94
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CHAPTER 10 - FUNCTIONAL CHECKFLIGHT PROCEDURES 10.1
FUNCTIONAL CHECKFLIGHTS ...................
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10.2
CHECKFLIGHT PROCEDURES ...................
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. . . 10-l
10.3 FUNCTIONAL CHECKFLIGHT PROCEDURES (PILOT) .... 10.3.1 Prestart ................................. 10.3.2 start .................................. 10.3.3 Poststart ................................ 10.3.4 Taxi .................................. 10.3.5 Engine Rump ............................. 10.3.6 Takeoff and Climb ........................... 10.3.7 lO,OOO-Foot Check. .......................... 10.3.8 15,000-FootChecks .......................... 10.3.9 Airstarts (20,000Feet) ......................... 10.3.10 Climb to 35,000Feet ......................... 10.3.11 High-SpeedDash (35,000Feet) .................... 10.3.12 Zoom (40,000Feet) .......................... 10.3.13 20,000-FootChecks .......................... 10.3.14 Approach ................................ 10.3.15 Touchdown ... ; .......................... 10.4 10.4.1 10.4.2 10.4.3 10.4.4 10.4.5 10.4.6 10.4.7 10.4.8 10.4.9 10.4.10 10.4.11 10.4.12 10.4.13
ORIGINAL
FUNCTIONAL CHECKFLIGHT PROCEDURES (RIO) Prestart ........................... Poststart .......................... Taxi Takeo&ndtix%::::::::::::::::::::: 15,000-FootChecks .................... 20,000-FootChecks .................... Climb to 35,000Feet ................... High SpeedDash (35,000Feet) .............. Descent ........................... Approach .......................... Landing .......................... In Chocks ......................... Postflight ..........................
20
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10-l
10-2 10-2 10-3 10-6 lo-11 lo-11 10-13 10-13 10-15 lo-18 10-18 lo-19 lo-20 lo-20 lo-22 lo-23
. . lo-23 . . lo-23 lo-23 : : lo-23 lo-24 : : 10-24 . . 10-25 . . 10-25 . . lo-25
::.. :z: lo-28 lo-28 . * lo-28
. .
NAVAIR 01.FlUAD-I
PART N - FLIGHT CHARACTERISTICS CHAPTER 11 - FLIGHT CHARACTERISTICS 11.1 11.1.1 11.1.2 11.1.3 11.1.4
PRIMARY FLIGHT CONTROLS ........................ Pitch Control .................................... Roll Control .................................... Directional (Yaw) Control ............................ Stability Augmentation ..............................
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11-l 11-l 11-l 11-t 11-l
11.2 11.2.1 11.2.2 11.2.3
SECONDARY FLIGHT CONTROLS ...................... Maneuver Flaps and Slats ............................. Landing Flaps, Slats,and DLC .......................... Speedbrakes ....................................
...... ...... ...... ......
11-l 11-2 11-2 11-2
11.3 11.3.1 11.3.2 11.3.3 11.3.4 11.3.5 11.3.6 11.3.7
GENERAL FLIGHT CHARACTERISTICS ................... Static Longitudinal Stability ........................... Dynamic Longitudinal ResponseCharacteristics ................. Maneuvering Stick Force ............................. Roll Performance RollResponse.. ...................................................... Dutch Roll .............................. TrimCharacteristics.. .......................
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11-2 11-2 11-2 11-2 11-2 11-3 11-3 11-3
11.4 11.4.1
ASYMMETRIC THRUST FLIGHT CHARACTERISTICS IN COMBAT AND CRUISE CONFIGURATION . . . . . .. .. . . . . . . . . . . General .............................. . . . . . .
......
11-3 11-3
11.5 11.5.1 11s.2
ENGINE STALLS AND FLAMEOUT. ............ Medium andHigh-Subsonic Airspeed ............. Low SubsonicAirspeed .....................
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11-4 I14 11-4
11.6 11.6.1 11.6.2 11.6.3 11.6.4 11.6.5 11.6.6 11.6.7 11.6.8 11.6.9
HIGH ANGLE OF ATTACK FLIGHT CHARACTERISTICS Directional Stability ....................... Dihedral Effect stores . .... : :: : : : : : : :: : : : : : : : : : : : : : : Stability Augmentation System ........... i ..... ManeuveringFlaps and Slats ............ : ..... Lateral Control Reversal ..................... Miscellaneous .......................... Stall characteristics .......................................... VerticalStalls .:I 1
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11-5 11-5 11-5 11-5 11-5 11-5 11-6 11-6 11-6 11-9
11.7 11.7.1 11.7.2 11.7.3 11.7.4 11.7.5 11.7.6 11.7.7 11.7.8 11.7.9
DEPARTURE FROM CONTROLLED FLIGHT General.. ................. ::::::: . .... Lateral-Stick-InducedDepartures ................ Rudder-InducedDepartures ................... Cross-Control-InducedDepartures ............... Asymmetric-Thrust-InducedDepartures AcceleratedDepartures .. ....................................... Coupling.. .................................... DepartureRecovery ................................ Upright DepartureRecovery. ...........................
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11-9 . 11-9 . 11-9 11-12 11-12 11-12 11-13 11-13 11-13 11-13
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ORIGINAL
NAVAIR 01.Fl4AAD-1
Page No. 11-16 , . . . 11-19 . . . 11-19 . . . . 11-19
11.7.10 11.7.11 11.7.12 11.7.13
Flat Spin ............................... Negative AOA Departures ..................... Inverted Stall/Departore ....................... Inverted Spin .............................
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11.8 11.8.1 11.8.2 11.8.3 11.8.4 11.8.5 11.8.6 11.8.7
TAKEOFF AND LANDING CONFIGURATION FLIGHT cI-L4RAcTERIsTIcs ......................... Normal Stalls ............................. Stall Recovery ............................. Asymmetric Thrust Flight Characteristics .............. DegradedApproach Con&ration .................. OutboardSpoiler Module Failure .................... SASOff.. .............................. AR Wing-Sweep Landings ......................
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11.9 11.9.1 11.9.2
ASYMMETRIC WING SWEEP ................... Wing-Sweep Design Limitations. ................... Asymmetric Wing-Sweep Flight Characteristics. ..........
11.10 11.10.1 11.10.2 11.10.3 11.10.4 11.10.5 11.10.6
DUAL HYDRAULIC FAILURES BACKUP FLIGHT CHARACTERISTICS . . . . . . . . . General. . . . . . . . . . . . . . . Low Mode Cruise andFormation. . High Mode Cruise and Formation. . . . In-Flight Refueling. . . . . . . . . . . . . . Lanclmg. . . . . . . . . . . . . . . BFCMThermalDurability. . . , . . . .
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11.11 11.11.1 11.11.2 11.11.3 11.11.4
FLIGHT CHARACTERISTICS WITH AFT CG LOCATIONS StoreEffectaonCgLocation. . . . . . . . . . . . . . . . . . . : : : : Wing-Sweep Effects on Stability. , . . . . . . . . . . . . . . . . . . . . Cruise and Combat Flight CharacteristicsWith Aft CG. . . . . . . . . . Takeoff endLanding Configuration Flight Characteristicswith Aft Cg.
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FLIGHT CONTROL MODULE . . . . . . . . . . . . . . .. . . . . . .
11-20 . 1l-20 1l-20 . 11-20 . 11-25 . 11-25 . 1l-25 . 11-25
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11-29 11-29 11-31 11-32 11-32 11-33 11-33
. 11-33 . 11-33 11-34 : 11-34 . 11-34
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PART V - EMERGENCY PROCEDURES CHAPTER 12 -GROUND 12.1 12.1.1 12.1.2 12.1.3 12.1.4 12.1.5 12.1.6 12.1.7 12.1.8 12.1.9
ON-DECK EMERGENCIES . . . . . . . . . . . . EngineFiiontheDeck . , , ,. . . . . . . .. . . Abnormal Start. . . . . . . . , , . . . . . . . . . . START VALVE Light After Engine Start . . . . . UncommandedEngine Accelerationon Deck. . . . Ground EgressWithout Parachuteand Survival Kit EmergencyEntrance. . . . . . . . . . . . . . . . . Weight-On-Off Wheels Switch Maltimction. . . . . Binding/Jammed Flight Controls On Deck . . . . . BrakeFailureatTaxiSpecd.. . . .. . . . . . . .
CHAPTER 13 -TAKEOFF 13.1 13.1.1 ORIGINAL
EMERGENCIES . , . . . . , , . , . . I . . . .. ;.
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12-1 12-1 12-l 12-1 12-l 12-2 12-2 12-2 12-4 12-4
EMERGENCIES
ABORTED TAKEOFF . . . . . . . . . . . . . . . , . . . . . . . Aborted Takeoff Checklist. . . . , . . . . . . . . . . , . , , . . , 22
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13-1 : : 13-1
NAVAIR 01.Fl4AAD-1
Page NO.
13.2 13.2.1 13.2.2 ,13.2.3 13.2.4 13.25 13.3 13.3.1 13.3.2
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13-2 13-2 13-2 13-2 13-2 13-3
SINGLE-ENGINE FAILURE FIELD/CATAPULT LAUNCHWAVEOFF Angle-of-AttacloEndspeedConsideration. . . . . . : . . . . . . . Rate of Climb Consideration. . . . . . . . . . . . . . . . . . . StoresJettisonConsiderations. . . . . . . . . . . . . . . . . . . Aircrew Coordination. Single-EngineFailure Fieiaidatap;l;La~c~a~e~~f : : : : : : : : : : ::
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BLOWN TIRE DURING TAKEOFF . . . . . . . . . . . . . . . . Blown Tim During Takeoff; Takeoff Aborted or At&r Landing Touchdown . Blown Tie During Takeoff; Takeoff Continuedor After Landing Go-Around
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. 13-3 . 13-3 . 13-3
. 14-1 . 14-1 . 14-1
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CHAPTER 14 - IN-FLIGHT EMERGENCIES 14.1 14.1.1 14.1.2
... COMMUNICATIONSFAILURE Flightcrew Attention Signals. ...... COMM-NAV Emergency Procedures
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14.2
PITOT-STATIC SYSTEM FAILURES
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14.3
EMERGENCYJETTISON
14.4
FIRELlGHTAND/ORFIRBlNFLIGHT
14.5 14.51 145.2 14.5.3 14.5.4 14.5.5 14.5.6 14.5.7 14.5.8 14.5.9 14.5.10 14.5.11 14.5.12 14.5.13 14.5.14
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. 14-2
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. 14-4
ENGINE EMERGENCIES .......................... CompressorStall. ............................... Airs tarts. .................................... Single-EngineFlight Characteristics. ..................... Engine Overspeed(Nl or N2 OSP Legend) ................. Engine START VALVE Light ........................ Engine Transferto SEC Mode ......................... UncommandedSEC Mode Rpm Decay .................... UncommandedEngine Acceleration Airborne (No Throttle Movement). .. ExhaustNozzle Failed (No Nozzle Responseto Throttle Movement). ... Stnck/JammedThrottle(s). .......................... AICS Malfunctions .............................. INLET ICE Light ............................... Oil SystemMaltimction. ........................... RATS OperationIn Flight ...........................
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14-5 14-5 14-7 ‘14-11 14-12 14-12 14-12 14-13 14-15 14-15 14-15 14-16 14-17 14-17 14-17
14.6 14.6.1 14.6.2 14.6.3 14.6.4 14.6.5
FUEL SYSTEM MALFUNCTIONS Fuel PressureCautionLights. ..... LorRFUELLOWLight ....... Fuel TransferFailures ......... UncommandedDump ......... Fuel Leak. ...............
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14-18 14-18 14-18 14-18 14-19 14-19
14.7 14.7.1 14.7.2 14.7.3 14.7.4 14.7.5 14.7.6
ELECTRICAL FAILURE ........ GeneratorFailure. ............ Double GeneratorFailure ........ Double Transformer-RectifierFailure. . TRANS/RECT Light. .......... Electrical Fire. .............. Total Electrical Failure .........
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ORIGINAL
NAVAlR O-l-l=MAAD-1
14.8 14.8.1 14.8.2 14.8.3 14.8.4
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14.8.5 14.8.6 14.8.7 14.8.8
ECS MALFUNCTIONS/FAlLURES .................... ECS Leak/Elimination of Smoke andFumes. ................ COOLINGAIRLight ............................ TARPS ECS Lights Illuminate ....................... SENSOR COND Light Illuminated and/orPUMP PhaseCircuit Breakers Poppedor APG-71 PM Acronym ...................... Cockpit TemperatureControl Malfunction ................. Cockpit Overpressurizationon Deck. .................... CABIN PRESS Light ............................ WSHLDHOTLight .............................
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14-28 14-28 14-28 14-28 14-28
14.9 14.9.1 14.9.2 14.9.3 14.9.4
OXYGEN SYSTEM FAILURE ...................... OBOGS Light ................................ B/U OXY LOW Light (Both Cockpits) ................... BNOXYLOWLight(PilotOnly) ..................... BNOXYLOWLight(RIOOnly) .....................
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14-29 14-29 14-29 14-30 14-30
14.10 LAD/CANOPY LIGHT AND/OR LOSS OF CANOPY . . . . 14.10.1 LAD/CANOPY Light With RIO CANOPY Light/Canopy Loss 14.10.2 LAD/CANOPY Light Without RIO CANOPY Light .. ..
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. . 14-30 . 14-30 . 14-31
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14.11 14.11.1 14.11.2 14.11.3 14.11.4 14.11.5 14.11.6 14.11.7 14.11.8 14.11.9
HYDRAULIC SYSTEM MALFUNCTIONS ....... Combined PressureApproximately 2,400to 2,600 Psi ... FlightPressureApproximately2,400 to2,6OOPsi ..... Combined PressureZero. .................. Flight PressureZero ..................... Both Combined and Flight PressureZero .......... Backup Flight Module Maltimction ............. Controllability Check .................... OutboardSpoiler Module Malfunction ........... Low Brake Accumulator Pressure..............
14.12 14.12.1 14.12.2 14.12.3 14.12.4 14.12.5 14.12.6 14.12.7 14.12.8 14.12.9 14.12.10 14.12.11 14.12.12 14.12.13 14.12.14
FLIGHT CONTROL FAILURES OR MALFUNCTIONS UncommandedRoll and/orYaw ............. Yaw Channel Failure Pitchor Roll ChannelFail& : : : : : : : : : : : : : : : STAB AUG Transients .................. RudderAuthority Failure ................. Horizontal Tail Authority Failure ............. Spoiler Malfunction .................... FLAP Light ........................ Flap and Slat Asymmetry ................. WING SWEEP Advisory Light andW/S Caution Legend UnscheduledWing Sweep ................. CADC Light ........................ AUTOPILOT Light .................... Weight On-Off Wheels Switch Malfunction .......
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14.13 14.13.1 14.13.2 14.13.3
DEPARTURE&PIN .................... Vertical Recovery ..................... Upright DeparhueiFlat Spin ................ Inverted Departure/Spin ..................
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ORIGINAL
24
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. 14-37 . . 14-37 . . 14-37 . 14-37 . . 14-38 . 14-38 . . 14-39 . . 14-39 . . 14-41 . 14-41 . . 14-42 . . 14-43 . . 14-43 . . 14-44 . . 14-44
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14-31 . 14-31 14-31 . 14-32 . 14-33 . 14-33 . 14-35 . 14-35 . 14-36 . . 14-36
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14-25 . 14-25 . 14-27 . . 14-27
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NAVAIR Ql-F14AAD-l
Pa e ht. CHAPTER 15 - LANDING EMERGENCIES 15.1
DUAL-ENGINE LANDING, ONE OR BOTH ENGINES INSECONDARYMODE...................
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15.2
SINGLE-BNGINELANDINGPRIMARY
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15.3 153.1
SINGLE-ENGINE LANDING SECONDARY MODE . . . SingleEngine LandingSEC Mode . . . . . . . . , . . .
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. 15-3 . . 15-4
15.4 154.1 15.4.2
LANDING GEAR EMERGENCIES . . . . . . . . . . . . Landing Gear Emergency Lowering. . . . . . . . . . . . Landing Gear Malfimctions . . . . . . . . . . . . . . . . . .
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. . 15-6 . . 15-6 . . 15-6
15.5
BLOWN-TIRE
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. 15-10
15.6 15.6.1 15.6.2
FLAP AND SLAT LANDING EMERGENCIES No-Flaps and No-Slats Landing ......... Auxilii Flap Failure ...............
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. 15-10 . 15-10 . 15-10
15.7 15.7.1 15.7.2
........ WING-SWEEP EMERGENCIES. Aft Wing-Sweep Landings ............ Asymmetric Wing Sweep .............
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. 15-11
15.8 15.8.1
AFT HUNG ORDNANCE LANDINGS ........... LandingwithABHungOrdnance. ..............
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. 15-16 . 15-17
15.9 159.1 15.9.2 15.9.3 15.9.4
FIELD ARRESTMENTS ................... Field Arresting Gear ...................... Short-Field Arrestment .................... Long-Field Arrestment .................... Engaging Speeds. .......................
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. 15-17 . 15-17 15-18 . 15-18 . 15-18
15.10
BARRICADE
ARRESTMENT
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. 15-18
15.11
ARRESTlNG
HOOK EMERGENCY
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. 15-21
15.12
FORCED
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. 15-21
LANDING
LANDING
MODE
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................ DOWN
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: 15-11
CHAPTER 16 - EJECTION 16.1 16.1.1 16.1.2 16.1.3
EJECTION .................... Ejection Envelope ................ Ejection Preparation ............... Ejection Initiation ................
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16.2
MANUAL
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16.3 16.3.1 16.3.2 16.3.3 16.3.4 16.3.5
SURVlVAl/l’OSTEJECTION PROCEDURES Manual Man/Seat Separation .......... Survival Kit Deployment ............ Pamchute steering ............... Parachute Landing Preparation ......... RaftBoarding ..................
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BAILOUT
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25
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ORIGINAL
NAVAIR 01.Fl4AAD-1
Pa e ht. PART VI -ALL-WEATHER
OPERATIONS
CHAPTER 17 -INSTRUMENT
PROCEDURES
17.1 17.1.1 17.12 17.1.3 17.1.4
AUTOMATIC CARRIER LANDING SYSTEM Mode I. ModeII.::::::::::::::::::::: ModeIII..................... Flight Director . . . . . . . . . . . . . . . . . .
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17.2 17.2.1 17.2.2 17.2.3 17.2.4 17.2.5 17.2.6 17.2.7
AIRCRAFT SUBSYSTEMS . . . . . . . Data Link. . . . . . . , , , . . . , . . . . Automatic Flight Control System . . . . . . . . . . . Radar Beacon (AIWAPN-154) ACLS Beacon Augmentor (R-1623) . , . Approach Power Compensator Performance ACLSlILS Displays (MFD and HUD) . . Instrument Landing System (AIWARA-63)
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17.3 17.3.1 17.3.2
SURFACE SUBSYSTEMS . . . . . . . . . ‘. . . Automatic Landing System QQUSPN-42) Instrument Landing System (ANk9PN-41). . .
17.4 17.4.1 17.4.2 17.4.3 17.4.4
ACLS PROCEDURES Preflight . . . . . . Poststart Checks . . Approach Phase . . Landing Phase . . .
CHAPTER 18 -EXTREME
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17-1 17-1 17-1 17-1 17-1
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17-2 17-2 17-2 17-2 17-3 17-3 17-5
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17-8 : 17-8 . 17-8 17-10 17-10 17-10 17-10 17-12
* . . . .
WEATHER
18.1 18.1.1 18.1.2
ICEANDR4IN . . . . . . . . . . . . . . . . Icing . . . . . . . . . . . . . . . . . . . . . . Rain . . . . . . . . . . . . . . . . . . . . . .
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18.2 18.2.1 18.2.2 18.2.3 18.2.4 18.2.5
HYDROPLANING . . . . . . Dynamic Hydroplaning . . . . Viscous Hydroplaning . . , , . Combined Dynamic and Viscous Reverted Rubber Skids
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18.3 18.3.1
TURBULENCE AND THUNDERSTORMS IntheStorm .................
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18.4 18.4.1 18.4.2 18.4.3 18.4.4 18.4.5 18.4.6 18.4.7
COLD-WEATHER OPERATIONS Prefligbt ...... ......... Engine Start ................ Taxiing ................... Takeoff ................... Landing .................. After Landing ............... Before Leaving Aircmft ..........
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ORIGINAL
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1: 1
26
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18-2 18-2 18-2 18-3 183 184
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18-4 18-5 18-5 18-5 18-5 18-5 18-6 18-6
NAVAIR 0%FMAAD-1
Pa e ht. 18.5 18.5.1 18.5.2 18.5.3
HOT-WEATHER AND DESERT OPERATIONS . . . . . . . . . . . . . . . . . . . . . . ” E%::::::::::::::::::::::::::::::::::::::::::::: Landing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PART VII - COMMUNICATIONS-NAVIGATION
18-6 18-6 18-6 18-6
EQUIPMENT AND PROCEDURES
CHAPTER 19 - COMMUNlCAllONS 19.1 19.1.1 19.1.2 19.1.3
COMMUNICATIONS AND ASSOCIATED EQUIPMENT canmunications An-. ................................... Cannumications Antenna Selection .............................. Mutual Interference .......................................
19.2 19.2.1 19.2.2
INTERCOMMUNICATIONS ................................. Audio Warning Signals ..................................... Pilot Tone Volme&can Command Panel ...........................
19.3 19.3.1 19.3.2 19.3.3 19.3.4 19.3.5
V/UHF RADIO (AN/ARC-182) ................................ Preset Channel(s) Load ..................................... Built-In Test. ........................................... Have Quick (Antijam) Mode.. .................................. ................................ Have Quick Load Instructions. Radio Frequency Control/Indicators. .............................
19.4
V/UHF
AUTOMATIC
UHF VOICE
SECURITY
DIRECTION
FINDER
EQUIPMENT
.................
19-1 19-5 19-7 19-7 19-7 19-7 19-7 19-12 19-18 .................
(OA-8697)
(TSEC/KY-58)
19.5 19.5.1 19.5.2 19.5.3 19.5.4
prelaunch.......................? Postlaunch. ........................................... AhLanding .........................................
19.6 19.6.1 19.6.2 19.6.3 19.6.4
JOINT TACTIC AL. INFORMATION DISTRIBUTION JTIDSTeminal......................................... JTIDSControls ......................................... DataStolageSet. ........................................ JTJDS System operation. ...................................
19.1
IN-FLIGHT
19.8
GROUND
.................. ....................
HANDLING
SIGNALS
SYSTEM
19-18 19-18 19-U) 19-U) 19-U) 19-U)
KY-58 Operation .......................................
VISU AL. COMMUNICATIONS
19-1 19-1 19-1 19-1
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19-21 19-21 19-22 19-22 19-25 19-26
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19-26
..............................
CHAPTER 20 - NAVlGAllON 20.1 20.1.1 20.1.2 20.1.3 20.1.4 ;C$.; 20:1:7
NAVIGATION AN/ASN-139
SYSTEM ................... Inertial Navigation Set. .............. AN/USN-2(V) Standard Attitude Heading Reference System. . Mission Computer System. ................... ................. Navigation Data Initialization. Disp!ays Subsyse ...................... Tactwd Infommtton Display. .................. .................... Convcrtcr Interface Unit.
27
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............... ...............
............... ............... ............... ............... ...............
20-l 20-l
20-3 204 z 20-S 20-S ORIGINAL
NAVAIR OI-Fl4AAD-1
20.1.8 20.1.9 20.1.10 20.1.11 20.1.12 20.1.13 20.2 20.2.1.
NAVIGATION SYSTEM DATA DISTRIBUTION . . . . . . . Navigation Data Display. . . . . . . . . . . . . . . . . . . . .
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20.3 20.3.1 20.3.2 20.3.3. 20.3.4 20.3.5 20.3.6
NAVIGATION SYSTEM OPERATION . INS and SAHRS ConcurrentAlignment. . ConcurrentCarrier Alignment. . . . . . , StandaloneAligmnent . . . . . . . . . . , Initially EnteredNavigation Parameters. . In-Flight Operation. . . . . . . . . . . . , Tactical Navigation. . . . . . . . . . . . ,
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20-5
Central Air Data Computer. . . . . . . . . . . . . . . . . . . . AN/ARN-118 Tactical Air Navigation Systemor AN/URC-107 Joint Tactical Information Distribution System. ANIASW-27C Data Lii. . .. . . .. . . . . .. . . . . . . UHF Automatic Direction Finder. . . . . . . . . . . . . . Bearing DistanceHeading Indicator. . . . . . . . . . . . . . . ANKJRC-107 Joint Tactical Information Distribution System.
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. 20-5 20-10 20-10 20-10 20-10
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20-14 20-14 20-25 20-28 20-31 20-35 20-43
CHAPTER 21 - IDENTIFICATION 21.1 21.1.1 21.1.2
IDENTIFICATION TRANSPONDER (AN/APX-100) IFF Transponder. .................... Altitude Computations. .................
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. 21-1 . . 21-l . . . 21-6
21.2 21.2.1
IFF INTERROGATOR (AN/APX-76) ......... IFF Self-Test. ......................
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. . . 21-6 . . . 21-6
22.1 22.1.1 22.1.2 22.1.3 22.1.4 22.1.5 22.1.6 22.1.7 22.1.8
RECONNAISSANCE SYSTEM . . . . . TARPS Pod. . . . . . . . . . . . . . . Serial Frame Camera. . . . . . . . . , . , Panoramic Camera. . . . . . , . . . , , , Mared Line ScannerSet. . . . . . . . . . Data Display System. . . . . . . . . . . . TARPS Environmental Control System. . Control Indicator Power Distribution Unit. Controller ProcessorSignal Unit. . . . . .
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. 22-1 . 22-2 . . . 22-2 , . . 22-2 : : : 22-2
PART VIII -WEAPON
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SYSTEMS
CHAPTER 22 -TARPS
SUBSYSTEM
22.2
DISPLAY SYSTEM. ..................
22.3
TARPS EQUIPMENT CIRCUIT BREAKERS
22.4 22.4.1 22.4.2 22.4.3 22.4.4
RECONNAISSANCE DISPLAYS AND FORMATS . MFD RECON DATA StatusFormat. .......... ReconnaissanceFault/Problem Reporting. ....... ReconnaissanceSteeringSelection. ........... HuDMx Symbology. .................
ORIGINAL
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28
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: : 22-10 . 22-10 . . 22-14
NAVAIR Ol-F14AAD-I
Page NO. . . . . . . . . . . . . . . .
. 22-14 . 22-14 . 22-22
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22.5 22.5.1 22.5.2 22.5.3 22.5.4 22.5.5
RECONNAISSANCE SYSTEM OPERATION ..... RIXOM~~S~TUPX ParameterEntry. ............. In-Flight Entry of ReconnaissanceWaypoint Parameters. One-Fix Update. ...................... Plotting Command Course/MapTargetLeg. ....... Cycling sensors. ......................
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22.6 22.6.1 22.6.2 22.6.3 22.6.4
PILOT RECONNAISSANCE OPERATION ....... Navigation Visual SurfaceWaypoint Update. ...... Pilot TARPS Steering. ................... Identification of TargetsUsing Television CameraSet. . Altitode (AGL) Mechanization. ..............
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22.7 22.7.1 22.7.2 22.7.3 22.7.4 22.7.5 22.7.6 22.7.7
SENSOR CAPAEIILITJES AND LIMITATIONS .................. Lineal Coverage..................................... Serial Frame Camera. ................................. PanoramicCamera. .................................. Long-RangeOblique PhotographyCamera(KS-153A With 610~Mm Lens). .... PhotographicFilm. ................................... Intied ReconnaissanceSet. ............................. Digital Data System. ..................................
CHAPTER 23 -NAVIGATION 23.1 23.1.1 23.1.2
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: 22-22 . 22-22 22-22 22-22 22-22 22-23 22-23
. 22-23 . 22-23 . 22-23 22-24 . 22-25 . 22-26 . 22-26 . 22-28
COMMAND AND CONTROL GRID
NAVIGATION COMMAND AND CONTROLGRID . . . NAVGRIDDataEntry. . . . . . . . . . . . . . . . . . . . . NAV GRID Displays. . . . . . . . . . . . . . . . . . . . .
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23-1 : : 23-1 . . 23-3
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37-1
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37-1 37-1 37-1 37-1 37-1 37-1
CHAPTER 24 - LANTIRN TARGETING SYSTEM - RESERVED CHAPTERS 25 TO 36 - (REFER TO NAVAIR 0%Fl4AAD-IA) PART IX - FLIGHTCREW COORDINATION CHAPTER 37 - FLIGHTCREW COORDINATION 37.1
INTRODUCTION ............
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37.2 37.2.1 37.2.2 37.2.3 37.2.4 37.2.5
PILOT AND RIO RESPONSIBILITIES Aircrew Coordination .......... Pilot Responsibilities .......... RadarInterceptOffker Responsibilities Mission Commander. .......... Specific Responsibilities .........
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37.3 37.3.1 37.3.2 37.3.3 37.3.4
.... SPECIALCONSIDERATIONS Functional Checktlighta ......... Formation Flights ............ ., ........ Training ........ SAFC ...................
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. 37-3 . . 37-3 . . 374 . 37-4 . 37-4
ORIGINAL
NAVAIR 0%F14AAD-1
37.4 37.4.1 37.4.2 37.4.3
PROCEDURES, TECHNIQUES, AND CHECKLISTS . . . . . . . General................................... Pilot RIO.:::::::::::::::::::::::::::::’:::::::
CHAPTER 38 -AIRCRAFT
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SELF-TEST
38.1
AIRCRAFT SELF-TEST OVERVIEW
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38.2 38.2.1
MASTER TEST PANEL CHECKS ................ MASTER TEST Switch Operation .................
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38.3 38.3.1 38.3.2 38.3.3 38.3.4
ON-BOARD CHECKOUT ........................ Built-in-Teat Description ......................... Test F're.requisites/Restrictions ....................... Avionic BIT Operation .......................... Joint Tactical Information Distribution SystemOn-Board Check ....
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38.4 38.4.1
COOPERATIVE SUPPORT SOFTWARE. CSS Operation . . . . . . . . . . . . .
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38-32 . 38-32
38.5 38.5.1 38.5.2 38.53
RADARSYSTEMBUILT-INTEST . BIT Modes . . . . . . . . . . . . . . . RadarBIT Operation . . . . . . . . . Flycatcher . . . . . . . . . . . . . . .
............ ............ ............ ............
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: : 39-l 39-l : : 39-1 39-1
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38-1
: : 38-l 38-3 : : 38-3 38-7 : ‘38-10 38-9 38-28
38-39 3840 38-43 38-62
PART X - NATOPS EVALUATION CHAPTER 39 -
NATOPS EVALUATION AND QUESTION BANK
39.1 39.1.1 39.1.2 39.1.3
NATOPS EVALUATION PROGRAM Concept ................ .:I Implementation ............... Definitions ..................
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39.2 39.2.1 39.2.2 39.2.3 39.2.4 39.2.5 39.2.6 39.2.1
GROUND EVALUATION ......... Open-Book Examination .......... Closed-Book Examination OralExamination.. ... . . . . . . . . . Emergency ................. Malfunction ................. MFT and WSTProcedures Evaluation ... Grading Instructions .............
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39.3 39.3.1
FLIGHT EVALUATION ........... Instrument Flight Evaluation. .........
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39.4 39.5
ORIGINAL
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. 39-l . . . 39-2 . . . 39-2 : 39-2 : : 39-2 . . . 39-2 . . . 39-2 . 39-2
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: : 39-2 39-2
OPERATIONAL DEPLOYABLE SQUADRONS . . . .
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TRATNING AND EVALUATION SQUADRONS . . .
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NAVAIR
39.6.1 39.6.2 39.6.3 39.6.4 39.6.5 39.6.6 39.6.1 39.6.8
FLIGHT EVALUATIONS ................. Mission Planniog and Brieting ............... Preflight and Line Operations ........... ; .... TaxiandRunup ....................... Climb andCruise Communications. 1: 1: 1: 1: 1: 1: 1: 1: 1: 1: 1: Emergency and Malfunction Procedures .......... Postflight Procedures MissionEvaluation .:::::::::: ::::::::::
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39.1 39.7.1
RECORD AND REPORTS .................. critique. ............................
39.8 39.8.1 39.8.2
FLIGHTEVALUATIONGRADlNGCRITERIA Flight Evaluation GradeDetermination ............ Fiil GradeDetermination ..................
39.9
APPLICABLE PUBLICATIONS ...............
39.10
NATOPS EVALUATION QUESTION BANK
39.6
PART XI -
PERFORMANCE
DATA
(REFER
TO NAVAIR
......
.......
Of-Fl4AAD-1
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39-3 : 39-3
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. 39-20
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39-3 39-3 39-3 39-3 39-3 39-3 39-3 39-3 39-3
39-l ‘39-19 . 39-20
. 39-20
0%Fl4AAP-1.1)
31 (ReverseBlank)
ORIGINAL
NAVAIR Ol-Fl4AAD1
List of Illustrations WAPTER
1 -AIRCRAFT
Figure l-l. Figure 1-2. Figure.1-3.
AND ENGINE
Aircraft Dimensions . . . . . . . . .. . . . . . . Characteristicsand Limitations . . . . . . . . . . . . . Electronic Nomenclature . . . . . . , . . . . . . . . . . . .
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1-2 1-3 1-5
CHAPTER 2 -SYSTEMS Figure 2-1. Figure 2-2. Figure 2-3. Figure 2-4. Figure 2-5. Figure 2-6. Figure 2-7. Figure 2-8. Figure 2-9. Figure 2-10. Figure2-11. Figure 2-12. Figure 2-13. Figure 2-14. Figure 2-15. Figure.2-16. Figure 2-17. Figure 2-18. Figure 2-19. Figure 2-20. Figure 2-21. Figure 2-22. Figure 2-23. Figure 2-24. Figure 2-25. Figure 2-26. Figure 2-27. Figure 2-28. Figure 2-29. Figure 2-30. Figure 2-3 1. Figure 2-32. Figure 2-33. Figure 2-34. Figure 2-35. Figure 2-36. Figure 2-37. Figure 2-38. Figure 2-39. Figure 2-40. Figure 2-41.
Air Inlet Control System ................... AICS Control and Indicators ................. Variable-GeometryInlet Configuration ............ AICS Normal OperatingMode ................ Fail-OperationalMode -No INLET Light ......... Fail-Safe Mode-INLET Light Ilhnninatcd ... : ..... Ramp Monitor Logic ...................... AICS Anti-Ice System ..................... Fl lo-GE-400 Engine ..................... ENG MODE SELECT Panel andENG SEC Lights ..... AFTC Functiional Relationships ............... Rich Stability Cutback- Fl lo-GE400 Engine ....... Variable Area ExhaustNozzle. ................ FEMS Multifunction Display Configuration ......... Fatigue Engine Monitoring SystemDiagram ......... Flight MaintenanceIndicator ................. Engine Fuel System ...................... Afterburner Fuel Sequencing ................. Throttle Interlocks ....................... Throttle Control ........................ Autothrottle Controls and Indicators ............. Engine Bleed Air/Compartment Ventilation ......... Anti-Ice Control ........................ Engine Start System ...................... Engine Instnnnents(Fl lo-GE-400) .............. MFD Engine Monitor Display ................. Fire Detection System ..................... FireExtinguishing Switches and Advisory Lights ...... Fuel Tanks ........................... Fuel Controls andIndicators ................. Engine Fuel Feed ....................... Aft FuselageFuel Transfer .................. Forward FuselageFuel Transfer ................ Wing and External Tank Fuel Transfer ............ Fuel Vent andDump ...................... Refueling System ....................... GeneratorPanel ........................ Circuit Breaker Alphanumeric Index ............. Hydraulic System Controls and Indicators .......... OutboardSpoiler System ................... Backup Flight Control System .................
33
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2-2 2-3 2-5 2-6 2-6 2-7 2-8 2-10 2-10 2-12 2-13 2-15 2-17 2-18 2-19 2-20 2-22 2-24 2-25 2-26 2-28 2-30 2-31 2-33 2-36 2-38 2-39 2-41 2-41 2-44 2-47 2-49 2-50 2-52 2-56 2-57 2-60 2-63 2-69 2-73 2-74
ORIGINAL
NAVAIR 01.FWAAD-I
Page No. Figure 2-42. Figure 2-43. Figure.2-44. Figure 2-45. Figure 246. Figure 2-47. Figure 2-48. Figure 2-49. Figure 2-50. Figure 2-51. Figure 2-52. Figure 2-53. Figure 2-54. Figure 2-55. Figure 2-56. Figure 2-57. Figure 2-58. Figure 2-59. Figure 2-60. Figure 2-61. Figure 2-62. Figure 2-63. Figure 2-64. Figure 2-65. Figure 2-66 Figure 2-67. Figure 2-68. Figure 2-69. Figure 2-70. Figure 2-71. Figute.2-72. Figure 2-73. Figure 2-74. Figure 2-15. Figure 2-76. Figure 2-77. Figure 2-78. Figure 2-79. Figum 2-80. Figure 2-81. Figure 2-82. Figure 2-83. Figure 2-84. Figure 2-85. Figure 2-86. Figure 2-87. Figure 2-88. Figure 2-89. Figure 2-90. Figure 2-91. Figure 2-92. Figure 2-93. Figure 2-94. ORIGINAL
Mission Computer SystemArchitecture. .............. CADC Functional Relationships .................. CADC Processor. .......................... CADC ProcessorIndicators ..................... Wing-Sweep Controls and Indicators ................ Wing-Sweep Modes ......................... Wing-Sweep Interlocks ....................... Flap and Slat Controls and Indicators ................ Wing Control Surfaces. ....................... Maneuver Flap Envelope ...................... Maneuver Slat/Flap Automatic Schedulefor CADC ........ Speedbrakes ............................. SpeedbrakeControl and Indicator .................. Control SurfaceIndicators ...................... Longitudinal Control System .................... Longitudinal SystemAuthority ................... Control Stick andTrim ....................... IntegratedTrim Schedules...................... Lateral Control System ....................... Lateral SystemAuthority ...................... Spoiler Control System ....................... Spoiler Gearing Schedule ...................... Spoiler Failure OverridePanel ................... Yaw Control System ......................... Yaw System Authority. ....................... AFCS Ratesand Authorities ..................... AFCS Controls and Indicators. ................... LandingGearCoatrolsandIndicatots. ............... WheelbrakeControls and Indicators ................ Antiskid BIT Box .......................... NosewheelSteeringControls .................... Launch Bar Coatrols ......................... LaunchBar(Catapult) ........................ Arresting Hook Controls ....................... Air-Conditioaing and PreasurimtionControls and Indicators ... Avionic Equipment Liquid Cooling Controls and Lights ..... Cabin PressureSchedule....................... Canopy Defog Controls and Windshield Air ............ Oxygen System Controls and Indicators .............. Oxygen Duration Chart ....................... AirsWam Sensors .......................... Display SystemsControls and Indicators .............. Display Format Groups ....................... Heads-UpDisplay .......................... Pilot DISPLAYS Control Panel ................... Multistates Indicator Symbols/Meanings .............. Muhitimction Display ........................ Cursor Controls ........................... Warning, Caution, Advisory Functions ............... Test Patterns ............................. HUDTLNBasicFormat. ...................... HUD Declutter Levels ........................ HUD Added Symbology ....................... 34
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2-77 2-79 2-79 2-80 2-83 2-85 2-87
;:;; 2-93 2-93 2-94 2-95 2-97 2-99 2-99 : 2-100 .2-102 .2-102 .2-103 .2-104 .2-105 .2-107 .2-108 .2-108 .2-l 10 .2-111. .2-117 .2-121 .2-123 .2-126 .2-128 .2-130 .2-131 .2-133 .2-137 .2-139 .2-140 .2-142 .2-145 .2-146 .2-147 .2-151 .2-154 .2-155 .2-158 .2-159 .2-161 .2-163 .2-166 .2-167 .2-171 .2-173
NAVAIR 0%Fl4AAD-1
Page NO. Figure 2-95. Figure 2-96. Figure 2-97. Figure 2-98. Figure.2-99. Figure 2-100. Figure 2-101. Figure 2-102. Figure 2-103. Figure 2-104. Figure 2-105. Figure 2-106. Figure 2-107. Figure 2-108. Figure 2-109. Figure 2-110. Figure 2-111. Figure 2-l 12. Figure 2-113. Figure 2-l 14. Figure 2-115. Figure 2-l 16. Figure 2-117. Figure 2-l 18. Figure 2-119. Figure 2-120. Figure 2-121. Figure 2-122. Figure 2-123. Figure 2-124. Figure 2-125. Figure 2-126. Figure 2-127. Figure 2-128. Figure 2-129. Figure 2-130. Figure 2-131. Figure 2-132. Figure 2-133. Figure 2-134. Figure 2-135. Figure 2-136.
CHAPTER 3 -SERVICING Figure 3-l. Figure 3-2. Figure 3-3. Figure 3-4. Figure 3-5. Figure 3-6. Figure 3-7. Figure 3-8. Figure 3-9.
.2-175 .2-177 .2-179 .2-182 .2-183 .2-185 .2-186 .2-187 .2-188 .2-190 .2-191 .2-193 .2-197 .2-208 .2-208 .2-210 .2-215 .2-217 .2-218 .2-219 Z-221 .2-224 .2-226 .2-228 .2-229 .2-23 1 .2-233 .2-235 .2-237 .2-239 .2-241 .2-244 .2-247 .2-249 .2-252 .2-255 .2-260 .2-264 .2-266 .2-267 .2-269 .2-269
HUD Symbology Available on TLN Formats. .................... HUDAfASearchFormats. .............................. HUD Symbology Available on MA Formats ..................... I-IUDA/GBasicFormat ................................ HUD Symbology Available on A/G Formats ..................... HUD Overlay Formats ................................. HUD Manual Reticle Format ............................. SlavedDEU PageControl ............................... MFD MENU Displays. ................................ MFD Spin Indicator Display. ............................. MFD Warning/Caution/Advisory andMessageOverlays .............. Computer andOBC Messages............................. Typical MFD Alpbauumeric Format ......................... MFD VDI Formats-Takeoff, Landing, Navigation ................ MFD MI Symbology Available on TLN Formats .................. MFDVDIAir-to-AirandAir-to-GroundFormats .................. MFD VDI Symbology Available on Air-to-Air and Air-to-Ground Formats) .... MFD VDI Air-to-Air (A/G) Format .......................... MFD VDI Recon Overlay Format ........................... MFDVDIRadarandIRSTSGverlayFormats .................... MFD HSD Format .................................... Plot Line and CourseLine Displays .......................... MFD HSD Tacan Displays .............................. HSD TacanCD1 Format ................................ MFD SMS Format - CAP/Attack, Fighter Wingforms ............... MFD Engine Monitor Format ............................. Data Entry Unit/Main Menu Page .......................... Data Entry Parameters................................. Angle of Attack Conversion .............................. Augle+f-Attack Displays ............................... Cockpit Canopy Control Handle and Indicator Lights ................ Ejection Seat ...................................... Survival Kit ...................................... Command Ejection Lever ............................... Cockpit Light Controls ................................ Pilot Indicator Lights ................................. RIO Indicator Lights .................................. Multistates Indicator .................................. JettisonControls .................................... ACM JettisonSelection andDisplay ......................... SystemsTest and System Power Ground Pane .................... CNU-188/A External BaggageContainer ....................... AND HANDLING
Aircraft Servicing Locations. ...................... Aircraft Servicing Data ......................... Ah&Servicing.. .......................... Runup DangerAreas -Exhaust Jet Wake Velocity and Temperature RadarRadiationHazardAreas ..................... Noise DangerAreas ........................... Towing Turn Radii, ........................... Towing .................................. Tiedown Arrangement .......................... 35
3-l . 3-2 . 3-5 . 3-9 3-10 3-14 3-16 3-17 3-18
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ORIGINAL
NAVAIR OI-Fl4AAD-3
CHAPTER 4 -OPERATING Figure.4-1. Figure 4-2. Figure 4-3. Figure 44. Figure 4-5. Figure 4-6. Figure 4-7. Figure 4-8. Figure 4-9. Figure 4- IO. Figum4-11.
LIMITATIONS
Store Station Configuration .......................... instrument Markings .............................. Engine OperatingLimits ............................ Maximum Allowable Airspeeds ........................ Variation of Maximum Allowable Normal Load Factor With CrossWeight Maximum Allowable Angleof-Attack RudderDeflections ......... Angle-of-Attack Limits ............................ Maneuvering Limits - CruiseConfiguration. ................ Maneuvering Limits-Rolling ........................ Flap Limitations ................................ Tactical Air ReconnaissancePod SystemLimitations ............
CHAPTER 7 -SHORE-BASED Figure 7-1. Figure 7-2. Figure 7-3. Figure 7-4.
Figure 8-1. Figure 8-2. Figure 8-3. Figure 84. CHAPTER 10 Figure 10-l.
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. 4-2 . 4-3 . 4-4 . 4-6 . 4-9 4-11 4-12 4-13 4-14 4-16 4-21
PROCEDURES
Exterior Inspection . . . . . . . . . . . . . . . . . . . Ejection Seat Safe-and-Arm Module . . . . . . . . . Taxi Turn Radii (Maximmu NosewheelSteering70”). Field Carrier Landing Practice. . . . . . . . . . . . .
CHAPTER 8 -CARRIER-BASED
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7-2 . . . 7-7 . . 7-18 . . 7-39
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PROCEDURES
Catapult Launch Trim Requirements . . . . . . Center-ofGravity Variation With Fuel Loading Carrier Landing Pattern . . . . . . . . . . . . . Carrier-ControlledApproach (Typical) . . . . .
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FUNCTIONAL CHECKFLIGHT PROCEDURES Flight Profile . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . , .
. . 10-l
CHAPTER 11 - FLIGHT CHARACTERISTICS Figure 11-l. Figure 11-2. Figure 11-3. Figure 1l-4. Figure 1l-5. Figure 1l-6. Figure 11-7. Figure 11-8. Figure 11-9. Figure 1l-10. Figure 11-11. CHAPTER 12 Figure 12-l.
ORIGINAL
Lateral-Control-InducedDepartureAreas .............. Rudder-InducedDepartoreAreas .................. Cross-Control-InducedDepartureAreas .............. F-14 DepartureRecoveryDiagram ................. Spin Arrow Displays ......................... MFD-l/TID Right Spin Display (INS and SAHRS Failed) ..... StallSpeedsforWingRockat25UnitsAOA ........... Minimum Control Speed,Ground(VMCG) ............ Rudder Effectiveness ........................ Landing Approach Airspeed (15 Units AOA) ............ Asymmetric Wing-Sweep LandingApproach ...........
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11-7 . 11-10 . 11-11 . 11-15 11-17 . 11-18 . 11-21 . 11-22 11-23 . 11-26 . 1l-30
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GROUND EMERGENCIES EmergencyEntrance . , . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12-3
36
NAVAIR Ol-F14AAD.1
Pa e r$,. CHAPTER 14 - IN-FLIGHT EMERGENCIES Figure 14-I. Figure 14-2. Figure 14-3. Figure 14-4. Figure 14-5. Figure 14-6.
Airspeed Indicator Failure . . . . . . . , . . . . . . . . . . . . . . External StoresJettison . . . . . . , . . . . . . . . . . . . . . . . Airstart Envelope . . . . . . . . . . . . . . . . . . . . . . . . . , SecondaryMode Thrust Levels . . . . . . . . . . . . . . . . . . . EmergencyGeneratorDistribution . . . . . . . . . . . . . . . . . Failure of Both Transformer-RectifiersEquipment InoperativeList
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. 14-2 . 14-3 . 14-9 .14-14 .14-21 .14-23
CHAPTER 15 - LANDING EMERGENCIES Figure 15-1. Figure 15-2. Figure 15-3.
Landing GearMalfunction EmergencyLanding Guide .......... Asymmetric Wing-SweepLanding Approach Airspeed ......... EmergencyField Arrestment Guide ...................
CHAPTER 16 -EXTREME Figure 16-1. Figure 16-2. Figure 16-3. Figure 164.
Figure 17-I. Figure 17-2. Figure 17-3. Figure 17-4.
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RadarBeaconPanel . . . . . . . . ACLS/JLS Steering . . . . . . . . ANlARA-63 DecoderPanel . . . . ACLS Mode I and II Approaches .
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CHAPTER 18 -EXTREME Figure 18-1. Figure 18-2.
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WEATHER
Minimum Ejection Altitude . . . ProperEjection Position . . . . Ejection Initiation . . . . . . . . Life PreserverAssembly Inflation
CHAPTER 17 -INSTRUMENT
15-7 15-12 15-19
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16-2 16-6 16-6 16-7
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PROCEDURES . . . .
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17-4 17-6 17-9 17-11
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WEATHER
Icing DangerZone . . . . . . . . . . . . . . . . . . . Combined Viscous and Dynamic Tire Hydroplaning .
18-2 . . . . . . 18-3
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CHAPTER 19 -COMMUNICATIONS Figure 19-1. Figure 19-2. Figure 19-3. Figure 19-4. Figure 19-5. Figure 19-6. Figure 19-7. Figure 19-8. Figure 19-9. Figure 19-10. Figure 19-11. Figure 19-12. Figure.19-13. Figure 19-14. Figure 19-15.
Communicationsand AssociatedEquipment ...... Antcnna SelectPanel ................... IntercommunicationControls .............. Glossaryof Tones .................... Pilot TONE VOLUMWTACAN CMD Panel. ..... AN/ARC-l82 V/UHF Control Panel .......... Radio Frequency/ChannelIndicator ........... Pilot VOLUME Control Panel .............. Common BIT Indications ................ Example of an ARC- 182Have Quick JJMWOD Fill . . Have QuickJJ Error Codes ............... KY-58 Controls ..................... JTIDS Control Panels .................. In-Flight Communications ................ Deck&round Handling Signals .............
37
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19-2 19-3 19-4 19-6 19-8 19-9 19-11 . 19-13 . 19-14 . 19-14 , 19-18 . 19-19 19-23 . 19-27 . 19-31 . . . . .
ORIGINAL
NAVAIR 01.Fl4AAD-l
p;y CHA?TER 20 - NAVIGATION Figure.20-l. Figure 20-2. Figure 20-3. Figure.20-4. Figure 20-5. Figure 20-6. Figure.20-7. Figure 20-8. Figure 20-9. Figure 20-10. Figure 20-11. Figure 20-12. Figure 20-13. Figure 20-14. Figure 20-15. Figure 20-16. Figure 20-17. Figure 20-18. Figure 20-19. Figure 20-20. Figure 20-21. Figure 20-22. Figure.20-23. Figure 20-24. Figure 20-25. Figure 20-26. Figure 20-27. Figure 20-28. Figure 20-29. Figure 20-30. Figure 20-31. Figure 20-32. Figure 20-33. Figure 20-34. Figure 20-35. Figure 20-36. Figure 20-37. Figure 20-38. Figure 20-39. Figure 20-40. CHAPTER 21Figure 21-I. Figure 21-2. Figure 21-3.
Navigation System .................................... NAV MODE Select/ComputerResetPanel ....................... DEU Navigation Formats ................................ TacauControls and Indicators .............................. Navigation SystemData Distribution ......................... HUD Navigation Outputs(TLN Basic) ........................ MFD MI (TLN Basic) Navigation Outputs ..................... Own-Aircrafi Basic Data Format ........................... MFD HSD Format -Navigation Outputs ...................... Navigation Data Display Summary .......................... MFD MENU1 and MENU2 Displays ......................... DEU Owu-Aircraft Data Entry (Typical) ....................... DD/TID Own-Aircraft Data Enhy ........................... MFD Ground Alignment Formats ........................... CV Alignment Formats- SINS ........................... .......................... CV Alignment Formats -Mar& DD Align Data Entry ................................. SAHRS StandaloneAlign MFD Format ....................... Data Entry Unit Waypoiut Pages(Typical) ...................... MFD Waypoiut Data Format ............................. DD Waypoint Data Entry ............................... Magnetic Variation SourceSelectionand DD Entry ................. INS In-Flight Align Formats .............................. SecondaryNavigation Mode Manually Selected ................... SAHRS Velocity ReferenceSelection ........................ IMU Backup Navigation Mode Selection ....................... ........................ SAHRSBackupSLVaudDGModes. Display of Waypoint and TacanData ......................... INS UPDATE MFD Formats ............................. HSD Basic MFD Format ............................... DDControlPauelWithGNDMAPSelected ..................... MFD TSD Format ................................... HUD/DesignatePosition Update ........................... Navigation SystemContinuousUpdate MFD Format ................ SurfaceWaypoint Position MFD Formats ...................... Cursor Controls .................................... Manual SteeringMode Formats ............................ Data-Lii SteeringMode Formats .......................... Destination SteeringMode Formats .......................... Tacao SteeringMode Formats .............................
20-2 20-3 20-S 20-S .20-12 .20-13 .20-15 .20-16 .20-17 .20-18 .20-20 .20-21 .20-22 .20-23 .20-26 .20-28 .20-30 .20-30 .20-33 .20-34 .20-35 .20-36 .20-38 .20-39 .2040 .20-41 .20-42 .20-44 .20-46 .20-49 .20-51 .20-51 .20-53 .20-54 .20-55 .20-58 .20-61 .20-63 .20-65 .20-67
IDENTIFICATION IFF Control Panels . . . . . . . . . . . . , Mode 4 Caution and Reply Light Logic . . IFF Display Formats . . . . . . . . . . . .
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CHAPTER 22 - TARPS SUBSYSTEM Figure 22-l. Figure 22-2. ORIGINAL
Tactical Air ReconnaissancePod System . TARPS ComponentLocations . . . . . 38
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NAVAlR 0%FI4AAD-I
Figure 22-3. Figure 224. Figure 22-5. Figure 22-6. Figure 22-7. Figure 22-8. Figure 22-9. Figure 22-10. Figure 22-11. Figure 22-12. Figure 22-13. Figure 22-14. Figure 22-15. Figure 22-16.
Controller ProcessorSignal Unit .............. MFDMENU2Format. ................... MFDRECONDATAStatusFotmat ............ TARPS Advisories. ..................... MFD OBCiMaintenance Failure Formats .......... HUDMX ReconnaissanceSymbology ........... BUD ReconnaissanceDisplay (Command CourseSteering) Dynamic SteeringPoint Display ............... ........... MFDRECONWPTDATA1Format MFDRECONWPTDATA2Format ........... DEU ReconnaissanceSelection ............... KS-87D Serial Frame CameraCharacteristics ....... KA-99A PanoramicCameraCharacteristics ........ KS-153A Still Picture CameraCharacteristics (610~Mm Standoff Configuration) ..............
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224 22-l 1 22-11 22-12 22-13 22-15 22-17 22.19 22-20 22-20 22-21 22-24 22.25
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CHAPTER 23 - - NAVIGATION COMMAND AND CONTROL GRID Figure 23-l. Figure 23-2. Figure 23-3. Figure 23-4.
DEUNAVGRIDDataEntq-Typical ......... ................ TlD NAV GRID Displays ................. TSD NAV GRID Display .................
DDNAVGRIDDataEnky
CHAPTER 38 -AIRCRAFT Figure 38-l. Figure 38-2. Figure.38-3. Figure.38-4. Figure 38-5. Figure 38-6. Figure 38-7. Figure 38-8. Figure 38-9. Figure 38-10. Figure 38-11. Figure 38-12. Figure 38-13. Figure 38-14. Figure 38-15. Figure 38-16. Figure 38-17. Figure 38-18. Figure 38-19. Figure 38-20. Figure 38-21. Figure 38-22. Figure.38-23. Figure 38-24. Figure 38-25. Figure 38-26. Figure 38-27. Figure 38-28.
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
. . . .
23-2 23-3 234 23-5
SELF TEST
On-Board Checkout .................... Test Types ......................... Master Test Panel ..................... SubsystemBIT Mode Test Times ............. Deftition of StatusTypes ................. StatusTypes ........................ Interlock Test Restrictions ................. OBC Display Format Types ................ OBC Failure Acronyms .................. OBC Basic Format. .................... Format Examples ..................... OBC Computer Messages ................. OBCICSS Messages .................... OBC-RelatedWarning/Caution/Advisory Messages ... DEU CSS Page ...................... DEUPages for OperatorCodeandDataType ...... DEU Flycatcher Pages ................... MFD CSS Display Format ................. Flycatcher Error Messages. ................ DEU Block AddressPages ................ DEU Trap Pages ...................... Block Address/TrapError Messages ........... DD RadarWarning Maltese Cross ............ MFD/TtD ORT Abort Displays .............. Test-in-ProgressDisplay .................. WRA Common Names and Designators ......... BIT Menu Display Format. ................ DegradedMode AssessmentFormat ........... 39
........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ........... ...........
38-2 38-3 384 38-6 38-8 38-9 38-11 38-13 38-14 38-25 38-26 38-29 38-30 3831 38-33 38-33 38-34 38-35 3836 38-37 38-38 38-39 38-40 3842 3844 38-45 38-46 3846 ORIGINAL
NAVAIR Ol-Fl4AAD-1
Figure 38-29. Figure 38-30. Figure 38-31. Figure 38-32. Figure 38-33. Figure 38-34. Figure 38-35. Figure 38-36. Figure 38-37. Figure 38-38. Figure 38-39. Figure 38-40. Figure 38-41. Figure 38-42. Figure 38-43. Figure 38-44. Figurc38-45. Figure 38-46. Figure 38-46. Figure 38-47. Figure 38-48. Figure 38-49. Figure 38-50.
ORIGINAL
MaintenanceDisplay Format (Test Complete) ........ MaintenanceDisplay (Test Complete) ............ Test Target Menu ....................... ContinuousMonitor Display ................. Radar ContinuousMonitor Acronyms ............. OBC ContinuousMonitor Acronyms ............. TlDMenuforTCSIBIT,InProgress ............. TCS BIT Prompts and RIO Responses ............ Initial C/D TEST Display ................... C/D TEST 1 Display(At?erAging Is Completed) ...... C/D TEST 2 Display ...................... C/D TEST 3 Display ...................... DD Responsesfor SCU/SSP/DD SelectTests ........ DD Responsesfor SHC SelectTests ............. DD Responsesfor TID SelectTests .............. BIT Static DD Display (ATTK Selected) ........... BIT Static TID Display (ATTK Selected)........... BIT Static DD Display (GND STAB or TV Selected) .... BIT Static DD Display (GND STAB or TV Selected) .... BIT Static TlD Display (Non-Am Selection) ....... BIT DD Dynamic Display ................... BIT Dynamic TID Display (ATTK Selected)......... Special Test 80-InstrumentationTest .............
40
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . , .
. . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . .
. . . . 38-47
. * . . 38-47 . . . . 38-48 . . . . 3849 . . . . 38-50 . . . . 38-51 . . * . 38-53 . . . . 38-53 . . . . 38-54 . . . . 38-54 . . . . 38-55 . . . . 38-55 . . . . 38-56 * . . . 38-56 . . . . 38-56 . . . . 38-57 . . 38-58 . . . . 38-59 . . . . 38-60 . . . 38-61 . . . . 38-62 . . . . 38-63 . . . . 38-63
NAVAIR 01-FUAAD-I
LIST OF ABBREVIATIONS
AND ACRONYMS AGR. Air-to-ground ranging.
A A/A. Air-to-air
AC. Air inlet control; air interceptcontrol.
AAC. Aviation armamentchange.
AICS. Air inlet control system.
AAI. Au-to-air interrogator.
AIM-54 Phoenix missile.
AAW. Antiair warfare.
AM. Amplitude modulation.
AB. Afterburner.
A/N. Alphanumeric.
ac. Alternating current.
AOA. Angle of attack.
ACC. Aircrew systemchange.
AOB. Angle of bank.
ACL. Automatic carrierlanding.
APC. Approach power compensator.
ACLS. Automatic carrier landing system.
APCS. Approachpower compensatorsystem.
ACM. Air combat maneuver.
ARDP. Advance radardataprocessor.
ACQ. Acquisition (TCS).
ARI. Aileron rudder interconnect.
ACS. Automatic channelselect.
ARSP. Advance radarsignal processor.
AID. Analog-to-digital.
ASC. Advancedsignal converter
ADAC. Airborne dataacquisition computer.
ASE. Allowable steeringerror.
ADF. Automatic direction finder.
ASH. Automatic storedheading.
ADI. Attitude director indicator.
ASPJ. Airborne self-protectionjammer.
ADL. Armament datum line.
ASR. Air surveillanceradar.
AEC. Automatic exposurecontrol.
ATDC. Airborne tactical data control.
AFB. Airframe bulletin.
ATDS. Airborne tactical datasystem.
AFC. Airframe change.
ATLS. Asymmetric thrust limiting system.
AFCS. Automatic flight control system.
AVB. Avionic bulletin.
AFTC. Augmenter fan temperaturecontrol.
AVC. Avionic change.
AIG. Air-to-ground.
AVIA. TID AOA, W, ILS, and ACLS.
AGI. Armament gasingestion.
AVTR. Airborne videotaperecorder.
AGL. Above ground level.
AWCS. Airborne weaponscontrol system. 41
ORIGINAL
NAVAIR 0%F14AAD-1
AWL. All-weather landing.
CARQUAL. Carrier qualifications.
AYC. Accessorieschange.
CAS. Calibrated airspeed. CAT. Catapult.
B BARO. Barometric.
CATCC. Carrier air t&tie control center.
BATR. Bullet at targetrange.
CAW. Caution, advisory, warning.
BCD. Bii
cb. Circuit breaker.
code decimal.
BDA. Bomb damageassessment.
CC. Cubic centimeter.
BDHI. Bearing distanceheadingindicator.
CCA. Carrier controlled approach.
BER. BIT evaluationreport.
CCIP. Continuously computedimpact point.
BFCM. Backup flight control module.
CCRS. Command course.
BIDI. Bidirectional hydraulic pump.
CDI. Coursedeviation indicator.
Bingo. Return me1state.
CDIR. Camouflagedetectioninfrared.
BIST. Built-m self test.
cg. Centerof gravity.
BIT. Built-m test.
CGTL. Command ground track line.
BLS. Basic landing display.
Charlle time. Expectedtime over ramp.
BMT. BIT moving target.
CICU. Computerintegratedconverterunit. CIPDU. Control indicator power distriiution tit.
1 BOL. BOFORS launcher. Bolter. Hook down, unintentional touch and go.
CIU. Converterinterfaceunit.
BOS. Backup oxygen system.
CM. Continuousmonitor.
BPS. Beam power supply.
CMB. Code matrix box.
BRU. Bomb rack unit.
CMM. Continuousmonitor mode.
BSF. Band suppressionfilter.
CMPTR. Computer.
BTOF. Bullet time of flight.
CNI. Communication-navigation-identification. COT. Crew operationtrainer.
c CA. Cartridgeactuateddevice.
CP. Central processor.
CADC. Central air datacomputer.
CPS. Controller processorsignal unit; cycles per second.
CAINS. Car&r aircraft inertial navigation system.
CRT. Cathoderay tube.
CAP. Combat air patrol; computer addresspanel.
ORIGINAL
CSD. Constantspeeddrive. 42
NAVAIR Ol-F14AAD-1
CSS. Control stick steering.
DSPT. Dyoamic steeriugpoint.
CTVS. Cockpit television sensor.
DSS. Data storageset.
cv. Aircraft carrier.
DSU. Data storageunit. E
CVA. Aircraft carrier approach. CVS. course vectoring symbols.
EAC. Expectedapproachclearancetime.
CWI. Continuous-waveihminator.
EAS. Equivalent airspeed.
D
ECA. Expandedchaff adaptor.
D/A. Digital-to-analog.
ECM. Electronic countermeasures.
dB. Decibel.
ECS. Environmental control system.
dc. Direct current.
ECU. Electronic control unit.
DD. Digital display.
EED. Electroexplosivedevices.
DDP. Digital data processor.
EGT. Exhaustgastemperature.
DDPG. Digital dataprocessorgroup.
EIF. Exposureinterval factor.
DDS. Data display system;digital datasystem.
EIG. Engine instrumentgroup.
DECM. Defensive electroniccountermeasures.
EMCON. Electronic radiation control.
DEW. Destination.
EMSP. Engine monitoring systemprocessor. ETA. Estimated time of arrival.
1 DEU. Data entry unit. DF. Diction
F
finder.
DFM. Dogfight mode.
FCF. Functional checkflight.
DG. Directional gyro.
FMA. Familiarization.
D/L. Data link.
FCLP. Field carrier landing practice.
DLC. Direct lift control.
FD. Fault direction.
DLS. Data-Iii transceiver.
FEMS. Fatigue enginemonitoring system.
DMA. Degradedmode assessment.
FF. Fuel flow.
DME. Distance measuringequipment.
F/F. Fighter to fighter.
DPGS. Data processingground statiofi.
FFIDL. Fighter-to-fighter datalink.
DRO. Destructive readout.
FHF. Failure history file.
DROT. Degradedrangeon target.
FL Fault isolation.
43
ORIGINAL
NAVAIR 0%F14AAD-1
FL. Flight level.
HEFOE. Hydraulic electric fuel oil engine.
FLC. Film motion compensation.
HERO. Hazards of electromagnetic radiation to ordnance.
FLOLS. Fresnellens optical landing system. FLRP. Fighter link referencepoint. FMC. Fighter mode command,fihn motion compensation; forward motion correction. I
hot start. A start that exceeds normal starting temperatures. HSD. Horizontal situation display. HSI. Horizontal situation indicator.
FMI. Flight maintenanceindicator.
HUD. Heads-updisplay.
FMLP. Field mirror landing practice.
hung start. A start that results in a stagnatedrpm and temperature.
FOD. Foreign object damage.
I
FOV. Field of view. IAS. Indicated airspeed.
1 fpm. feet per minute. FRL. Fuselagereferenceline.
IBIT. Initiated BIT.
FRS. Fleet replacementsquadron.
ICAO. International Civil Aviation Organization.
FTCM. Flight test continuousmonitoring.
ICS. Intercommunications.
FTJU. Fuel tank jettison unit.
IDG. Integrated-drivegenerator.
FWD. Foiward.
IFB. Interferenceblanker. IFF. Identification, friend or foe.
G G. Guard channel.
IFOV. Instantaneousfield of view.
g. Gravity.
IFR. Instrument flight rules.
G/A. Ground to air.
IFT. In-flight training.
GACH. Gimble angle crosshair.
IFX. IFF transponder.
GCA. Ground-controlledapproach.
IGV. Inlet guide vane.
GCI. Ground-controlledintercept.
ILCOS. Instantaneouslead computedoptical sight.
GCU. Generatorcontrol unit; gun control unit.
ILS. Instrumentlandmg system.
GHz. Gigahertz.
IMC. Instrument meteorologicalconditions.
GSS. Gun scoring system.
IMN. Indicated Mach number.
GT. Ground track.
IMU. Inertial measurementunit. InHg. Inih of Mercury.
H
INS. Inertial navigation system.
HDG. Heading. ORIGINAL
44
I
NAVAIR 0%FI4AAD-1
IP. Initial point.
LCOS. Lead computing optical sight.
IPF. Interferenceprotection featore.
LE. Leading edge.
IR. Infrared.
LOROP. Long-rangeoblique photography. LOS. Lie of sight.
1 IRCM. Infraredcountermeasures. IRLS. I&ad
LOX. Liquid oxygen.
line scannet
IRNR. Jnfiarednot ready.
LPA. Life preserverassembly.
IRRS. Idared reconnaissanceset
LS. Line scanner.
IRST. Infrared searchand track
LSO. Landing signal officer (Paddles).
IRW. Infrared wide.
LTE. Launch to eject. M
ITER. Improved triple ejectorrack ITS. Integratedtrim system.
M. Mach.
IU. Interfaceunit.
MAC. Mean aerodynamicchord. MAD. Magnetic azimuth detector.
J JAT. Jam angletrack
MAO VAR. Magnetic variation.
JTIDS. Joint tactical information distribution system.
MAN. Manual. MAS. Missile auxiliary subsystem.
K KCAS. Knots calibratedaimpeed.
MATS. Missile auxiliary test set.
KCP. Keyer control panel.
MAX. Maximum.
KEAS. Knots estimatedairspeed.
MCB. Midcompressionbypass.
kHr. Kilohertz.
MCF. Motion compensation&&or.
KIAS. Knots indicated airsped
MCM. Monitor control message.
KTS. Knots.
MCS. Mission computersystem. MCT. Memory confidencetest.
L LAOT. Low-PRF an&ma on tar@.
meatball. Glideslopeimage of mirror lan&mg system.
LAR. Launchacceptability region.
MEC. Main enginecontxol.
LARI. Lateral automatic rudderinterconnect.
MER. Multiple ejector rack
LEA. Limits of basic airma%
MFD. Multifunction display.
LCD. Liquid crystal display.
MHz. Megahertz.
45
ORIGINAL
NAVAIR Ol-F14AAD.1
P
PSU. Power switching unit.
Paddles. Landing signal ofEcer.
PT. Engine power trim.
PA. Power approach.
Pt. Total pressure.
PAL. Pilot automatic lock-on.
PTO. Pilot takeover.
PAN. Panoramic.
PTP. Point to point.
PAP. Precision approachpoint.
Pn. Turbine exhaustpressure. a
PAR. Precision approachradar. Q. Dynamic pressure.
PC. Pulse compression.
R
PCD. Precisioncoursedirection. PD. PulseDoppler.
RACH. Radarangle crosshair.
PDCP. Pilot display control panel.
RARI. Rudderautomatic rudder interconnect.
PDS. PulseDoppler search.
RDO. Recoveryduty otlicer.
PDSTT. PulseDoppler single-targettrack.
RDR. Radar.
PFPM. Potential flightpath marker.
RDSCU. Radarsensorcontrol unit.
PGU. Improved round for the M-61 gun (new bullet).
RECON. Reconnaissance.
PH. Phoenixmissile.
RF. Radio frequency.
PIO. Pilot-induced oscillation.
RFCI. Radio frequency/controlindicators.
PLM. Pilot lock-on mode.
RFI. Radio frequencyindicator.
PP. Peakpower.
RHA. Recordingheadassembly.
PPC. Powerplantcharge.
RIO. Radarinterceptofficer.
pph. Poundsper hour.
RNAV. Relative navigation.
PPI. Plan position indicator.
ROE. Rules of engagement.
PPLI. Preciseparticipantlocation and identification.
ROM. Read-onlymemory.
PRI. Primary.
ROT. Rangeon target.
PS. Pulsesearch.
rpm. High-pressurecompressorrotor speed(Nz).
Ps. Static pressure.
RRC. Roundsremaining counter.
psi. Poundsper squareinch.
RTGS. Real time gunsight.
PSTT. Pulsesingle-targettrack.
RlT-I. Round trip timing interrogation.
47
I
ORIGINAL
NAVAIR 01.FlrlAAD-1
RWR. Radarwarning receiver.
STN. Sourcetrack number.
RWS. Rangewhile search.
STT. Single-targettrack.
S SA. Semiautomaticacquisition mode.
SSI. Standardserial interface. SW. Sidewiudermissile. T
SAHRS. Standardattitude headingreferencesystem. SAM. Surf&e-to-air missile.
tacan. Tactical air navigation.
SAR. Searchand rescue.
TAC DRO. Tactical destmctive readout.
SAS. Stability augmentationsystem.
TADIL. Tactical digital information link.
SAT. Simultaneousalignment and test.
TARPS. Tactical air reconnaissancepod system.
SC. Sensorcontrol.
TAS. True ahpeed.
SCADC. Standardceutral air datacomputer.
TBT. Turbine blade temperature.
SCP. Sensorcontrol panel.
TCA. Turbine compressorassembly.
SDIS. Sensordisplay indicator set.
TCR. Tie code readout.
SEAM. Sidewinder expandedacquisition mode.
TCS. Television cameraset.
SEAWARS. Seawater-activatedreleasesystem.
TDRS. Tactical datarecordingsystem. TDMA. Time-division multiple access.
1 SEC. Single-enginesecondary. SHDG. Storedbeadingground align.
TDS. Tactical datasystem.
SIF. Selective identification feature.
TED. Trailing edgedown.
SINS. Ship’s inertial navigation system.
TER. Triple ejectorrack.
SMAL. Single-mode alignment.
TEU. Trailing edgeup.
SMDC. Shieldedmild detonatorcord.
TID. Tactical information display.
SMP. Storemanagementprocessor.
TIMS. Terminal input messages. TIT. Turbine inlet tempemtum.
I SMS. Storesmanagementsystem. SP. Sparrow missile.
TLN. Takeoff, landing, navigation.
SPAM. Special aid to maintenance.
TMA. Target undermissile attack
SPS. Solenoid power supply.
TOF. Tie
STAB AUG. Stability augmentation.
TOM.
STBY. Standby.
T/R. Transformer-rectifier.
ORIGINAL
48
of fall.
Terminal output messages.
I
NAVAIR WF~4AAD.1
1s. Static temperature.
VLA. Vertical lever arm.
la. Free air temperature.
vM, Manual MAG VAR.
TSEC. Transmissionsecurity.
Vmcg. Minimum control groundspeed.
Tn. Compressorinlet temperature.
VMCU. Voltage monitor control unit.
T14.
Compressordischargetemperatom.
VR. Rotation speed.
TV. Television.
VSL. Vertical scanlock-on.
TVS. Television search.
VSV. Variable statorvane.
NT. Television track
VSWR. Voltagestandardwave ratio.
TWS. Track while scan.
VTR. Videotaperecorder. U
UHF. Ultrahigh frequency.
W. Vertical velocity. Vi. Critical enginefailure speed. W
UHT. Unit horizontal tail. lJTM. Universal test message. V
WCS. Weaponcontrol system. WDIR. Wind direction.
Vc. Closing veIocity rate.
WFOV. Wide field of view.
vC. ComputedMAG VAR.
WOD. Wind over the deck; word of the day.
VDI. Vertical display indicator.
WOW. Weight on wheels or weight off wheels.
VDIG. Vertical display indicator group.
WPM. Weaponsprogram memory.
VEC. Vector.
WRA. Weaponsreplaceableassembly.
VERT. Vertical.
WSPD. Windspeed.
VFR. Visual flight rules.
WST. Weaponssystemtrainer. Y
VgIH. Velocityibeight. V/H. Velocity altitude factor (vg/H).
YY. Geographicreferencepoint for NAV GRID.
VID. Visual identification.
49 (ReverseBlank)
NAVAIR Of-F14AAD-g
PREFACE. SCOPE
TECHSERVFAC), Philadelphia, PA. If there is a continuing needfor this publication, eachactivity’s Central Technical Publication Librarian must send a revised ADRL report on floppy disk to NAVAIRTECHSERVFAC. If an activity does not have a library, then send a letter to the Commanding Officer, NAVAIRTECHSERVFAC, ATTNz Code 251, 700 Robbins Avenue, Philadelphia, PA 19111,requesting assignmentof a distriiution accountnumber (if necessary)and automaticmailing of Wtre issuesof the publications needed
This NATOPS flight manual is issuedby the authority of the Chief of Naval Operationsand under the direction of Commander,Naval Air Systems Command in conjunction with the naval air training and operating proceduresstandardization(NATOPS) program. This manual, togetherwith the supplementalmanualslisted below, containsinformation on all aircraft systems,performance data, and operatingproceduresrequited for safeand effective operations.However, it is not a substitute for sound judgment. Compound emergencies, available facilities, adverseweather or terrain, or considerationsaffecting the lives and property of others may require modification of the procednrescontained herein.Readthis manual t?om cover to cover. It is your responsibility to have a completeknowledge of its contents.
Note The ADRL floppy disk canbe usedonly to place an activity on the mailing list for automatic distribution offumre issuesof thepublications.It cannotbe usedto makeone-time ordersofpublicationrfrom currentstock To get publications from stock, see One-Time Ordersabove.
APPLICABLE PUBLlCATlONS The following applicable publications complement this manual:
Onceestablishedon automaticdistribution for this or any other NAVAIR technical publication, an activity must submit anADRLreportonfloppydiskat leastonce every 12 months to update or contii their automatic distribution requirements.
NAVAIR 01-F14AAP-1.1 (PerformanceCharts) NAVAIR OI-F14AAD-IA (Supplemental)
Note Activities not submitting an ADRL reporton floppy disk for more than 12monthsmay be dropped from distriiution of all NAVAIR technical publications.
NAVAIR Ol-F14AAD-1B (PocketChecklist) NAVAIR 01-F14AAD-IF (Functional Checktlight Checklist) HOW TO GET COPIES
UPDATING THE MANUAL One-Time Orders To ensurethat the manual contains the latest procedures and information, NATOPS review conferences areheld in accordancewith the current OPNAVINST 3710.7series.
If this publication is needed on a one-time basis (without future updates),orderit from stockby sending an electronic DD 1348 requisition in accordancewith NAVSUP Publication 2002 found on NAVSUP PubliI cation 600 (Naval Logistics Library) CD-ROM disc. Automatic Distribution
CHANGE RECOMMENDATIONS Recommendedchangesto this manual or otherNATOPS publicationsmay be submittedby anyonein accordancewith the current OPNAVINST 3710.7series.
(With Updates)
This publication and changesto it are automatically sentto activities that are establishedon the Automatic Distribution RequirementsList (ADRL) maintainedby Naval Air Technical Services Facility (NAVAIR-
Routine changerecommendationsare submitted directly to the model manageron OPNAV 3710/6shown
51
ORIGINAL
NAVAIR Ql-F14AAD-1
on the next page.The addressof the model managerof this aircraft is: Commandmg Officer Fighter Squadron101 DET MIRAMAR NAS Miramar, Hangar 3 SanDiego, CA 92145
WARNINGS, CAUTIONS, AND NOTES The following definitions apply to “WARNINGS,” “CAUTIONS,” and “Notes” found throughout this manual.
Attn: F-14D Model Manager
An operatingprocedure,practice, or condition, etc., that may result in injury or deathif not carefully observedor followed.
Change recommendations of an URGENT nature (safety of flight, etc.,) should be submitted directly to the NATOPS advisory group member in the chain of command by priority message. YOUR RESPONSIBILITY NATOPS flight manualsarekept currentthrough an active manual changeprogram. Any corrections,additions, or constructivesuggestionsfor improvementof its contentshouldbe submittedby routineor urgentchange recommendation,as appropriate.
An operatingprocedure,practice, or condition, etc.,that may result in damageto equipment if not carefully observedor followed. Note An operatingprocedure,practice, or condition, etc., that is essentialto emphasize.
NATOPS FLIGHT MANUAL INTERIM CHANGES Flight manual interim changesarechangesor corrections to the NATOPS flight manuals. They are issued by CNO or NAVAIRSYSCOM either asprimed pages or as a naval message.The Interim ChangeSummary pageis provided asa recordof all interim changes.Each manual custodian should check the Interim Change Summary pageto seethat all interim changeshavebeen incorporated.
WORDING The concept of word usage and intended meaning that hasbeenadheredto in preparing this manual is as follows: “Shall” has been used only when application of a procedureis mandatory.
CHANGE SYMBOLS
“Should” has beenused only when application of a procedureis recommended.
Revisedmaterial is indicated by a black vertical line in either margin of the pagelike the one printed next to this paragraph.The changesymbol showswhere there hasbeena change.The changemight be material added or information restated.A changesymbol in the margin by the chapternumber andtitle indicates a new or completely revisedchapter.
ORIGINAL
“‘May” and “need not” have been used only when application of a procedureis optional. “Will” has beenused only to indicate fittmity, never to indicateany degreeof requirementfor application of a procedure.
52
NAVAIR
N4TOPS/TACTlcAL CHANQE RECOMMENDATION oPNAv37lo16 (4-90) SN olo7-l.F-aem
Ql-F14AAD1
DATE
To BE FILLED IN BY ORIQINATOR AND FORWAROELl TO MODEL MANAGER FROM Kwnam)
Udl
10-w
Unit
c+amplebemof-
~RevMonDate~QlgnDeDate~~~
PaQe
q
parasraph
CHECK IFCONTINUED ON RACK
JusUlloaUon
amm
Rank
line
-OfUnitOfTO EE FILLED IN By MODEL MANAQER @Hum to Oti@nator) FROM
DATE I
TO
ISI
MoDELblw4AQEN
53
AIRCRAFT
ORIGINAL
NAVAIR 07+14AAD-I
ORIGINAL
NAVAIR 0%FUAAP1
PART I
The Aircraft Chapter1-Aircraft andEngine Chapter2 -Systems Chapter3 - ServicingandHandling Chapter4 -Operating Limitations
55 (ReverseBlanR)
ORIGINAL
NAVAIR
CHAPTER
Aircraft
01.Fl4AAD-1
1
and Engine
1.1 AIRCRAFT
The F-14D aircraft is a supersonic,two-place, twinengine, swing-wing, air-superiority tighter designed and manufactured by Grumman Aerospace Corporation. In addition to its primaty tighter role, carrying missiles (Sparrow and/or Sidewinder) and an internal ZO-mm gun,the aircraft is designedfor fleet air defense (Phoenixmissiles) andgroundattack(conventionalordnance) missions. Armament and peculiar auxiliaries used only during secondarymissions are installed in low-drag, external configurations. Mission versatility and tactical flexibility are enhanced through independentoperationalcapability or integrationunder existing tactical datasystems. The forward fuselage,containing the flightcrew and electronic equipment,projects forward from midfuselage and wing glove. Outboard pivots in the highly swept wing glove support the movable wing panels, whichincotporateintegralfuelcells andfull-spanleadingedgeslats and trailing-edge flaps for supplementallift control. In flight, the wings may be varied in sweep, area, camber, and aspect ratio by selection of any leading-edgesweepangle between20” and 68”. Wing sweepcan be automatically or manually controlled to optimize performanceandtherebyenhanceaircraft versatility. Separatevariable-geometry air inlets, offset from the fuselagein the glove, direct primary airflow to two Fl lo-GE-400 dual-axial compressor,turbofan engines equippedwith afterburnersfor thrust augmentation. The displacedenginenacellesextendrearwardto the tail section, supportingthe twin vertical tails, horizontal tails, and ventral fins. The middle and aft fuselage, which contains the main fuel cells, tapersoff in depthto the rearwhereit accommodatesthe speedbrake surfacesand arresting hook. All control surfacesare positionedby irreversiblehydraulic actuatorsto provide desiredcontrol effectivenessthroughoutthe flight envelope.Stability augmentationfeaturesin the flight control system enhanceflight characteristicsand thereby provide a more stableandmaneuverableweaponsdelivery platform. The tricycle-type, forward-retractinglanding gearis designedfor nosegearcatapultlaunch andcarrier landings.Missiles and external storesare carried from eight hardpointstationson the centerfuselagebetween l-l
the nacellesand under the nacellesand wing glove; no storesare carried on the movable portion of the wing. The fuel system incorporatesboth in-flight and singlepoint groundrefueling capabilities.Aircraft generaldimensions are shown in Figure l-l. FO-1 shows the generalplacementof componentswithin the aircraft. A summary of aircraft limitations and characteristicsare shown in Figure 1-2. Refer to Chapter 4 for detailed information. 1.1.1 Aircraft Weight. The basic weight of the aircraft is approximately 43,735 pounds, which includes trappedfuel, oil gun, andpylons. Consult the applicable Handbookof Weight andBalance(NAVAIR Ol-lB-40) for the exactweight of any seriesaircraft. Cockpit. The aircraft accommodatesa twomain crew that consistsof a pilot and RIO in a tandem seating arrangement.To maximize external field of view, stationswithin thetandemcockpit areprominently located atop the forward fuselage and enclosedby a single clamshellcanopy.Integral boardingprovisionsto the cockpit and aircraft top deck are on the left side of the fuselage.Each crew station incorporatesa rocket ejectionseatthatis vertically adjustablefor crew accommodation A single environmental control system provides conditionedair to the cockpit and electronicbays for pressurization and air-conditioning. Oxygen for breathingis suppliedto the crew underpressurefrom an on-boardoxygengeneratingsystemwith storedgaseous oxygen as backup. The cockpit arrangementprovides minimum duplication of control capability, which, of necessity,requirestwo crewmen for flight. 1.1.2
1.1.2.1 Pilot Cockpit. The forward station of the cockpit is arrangedandequippedfor the pilot (FO-3).In additionto threeelec,tronicdisplays for viewing tactical, flight, navigational,andECM data,thepilot instrument panelalsocontainsarmamentcontrols,flight andengine instmments. Engine controls, fuel management,auxiliary devices,autopilot, andcommunicationcontrol panels areon the left console.Display, power,lighting, and environmentalcontrolsare on the right console. RIO Cockpit. The aft station of the cockpit is equippedfor the RIO (FO-4). This instrument panel
1.1.2.2
ORIGINAL
NAVAIR 0%F14AAD-1
Figure 1-I. Aircraft Dimensions AVB AVC AYC
contains controls and three electronic displays for the radar,tactical, and navigational flight instruments.Armament controls, sensorcontrols, and communication panelsareon the let?console.The right consolecontains a navigational display, data entry unit, ECM controls, data-link controls and lighting, andthe IFF panel.
1.1.5 Block Numbers. The following production block numbers correspondto aircrag serial numbers @No). Selectedblocks85and 110areupdatedto F-14D/ block 170configuration.
1.1.3 Electronic Nomenclature. Figure 1-3 is an alphabeticallisting ofthe tactical, communication,navigation, flight control, and instrumentsin the aircraft.
BlockNo.
1.1.4 Technical Directives. As technical changes aremade to the aircraft, thosethat affect aircraft operation or pilot and RIO need-to-know operationwill be incorporatedin the appropriatesectionsandlisted in the Summary of Applicable Technical Directives in the front of this manual. In some instances,technicaldirectives may be incorporatedon the aircrag while it is still on the production line beforedelivery. Check the Technical Directives Section of the Aircraft Log Book for applicable modifications. The following are types of technicaldirectives used in this manual: ACC ACC AFC
ORIGINAL
Avionics Bulletin Avionics Change AccessoriesChange.
Aviation Armament Change Aircrew System Change Airhame Change
1-2
Serial No. (BuNo)
160
163412
-
163416
165
163693
-
163904
170
164340 164599
- 164351and - 164604
85
159610,159613.159600, 159629,159628.159619, 159592,159595,159603, 159635,159633,159018, 159630,159608,159631
110
161159,161158,161166. 161163,161154.
NAVAIR
Length Height (Tail) Wingspan @ 20’ wingsweep Wingspan @ 68’ wingsweep Wingspan in oversweep Wing Area
62 16
8.5” Cross bleed 2 min continuous 5 min continuous 0” I Start Cari
AOB < 45” Roll SAS on
15kt.S
165 MS 190kts 20 MS 6Okts
20% 30% 30%
HYD PRESS = 3000 psi
EGT = 780 - 935°C
NO2 POS INFLIGHT
HUNG START
m/n speed for antiskid operation mex wheel braking (51 .O k A/C) max tire speed
RPM EGT
= =
AOA
= =
FUEL = LIGHTS:
max 90” crosswind component max canopy open
then 10 min off then 10 min off
FF = 950 - 1400 PPH
HOT START:
Min 200’ AGL for flaps/slats up on takeoff Min 800’ AGL for dirty-up Min 180 MS for retraction of flaps 12 units AOA for all transitions
Ol-Fl4AAD-1
890°C (will normally peak @ 30 - 40% RPM) Hung RPM below63% with rising EG No lightoff within 20 set of throttle to IDLE
96% 950 f 10°C (initiates engine overtemp alarm) 10,500 pph 18i05UNlTS 2,000 i 200# (all tapes and windows) Land R FUEL LOW
Mln RPM with throttle at idle
Max RPM with pneumatic starter
RPM must fall below for generator auto-reset 50% Engine crank switch automatically shuts off 60% Generator comes on line 50% Generator light illuminates (if RPM falling) 60% Ensure engine crank off (ovsplvalve) 62 - 78% Normal idle 75 - 90% Auto throttle range 95 - 104% MIL & above 107.7% Overspeed (chevrons flash) 110.0% Engine secures (fuel shutoff)
M/n auxiliary canopy (3000 psi) M/n normal canopy (3000 psi) CHS accumulator FHS accumulator M/n emergency gear preflight M/o emergency gear extension Wheel brake accumulator (2 gages) Arresting hook dashpot
Figure 1-2. Characteristicsand Limitations (Sheet1 of 2) l-3
800 psi 1200 psi 1800 psi 1800 psi 3000 psi 1800 psi 1900 f 50 psi 800~10 psi NZl97
ORIGINAL
NAVAIR 01.Fl4AAD-1
Aft-Left Tank Group Capacity Fwd-Right Tank Group Capacity Max split between cockpit totals Fuel dump rate Fuel dump auto shutoff with Ground refuel rate @ 50 psi In-flight refuel rate @ 57 psi
Normal Hyd. system operating press BIDI activates when one system is BIDI output w/3000 psi on good side BIDI shuts off when failed system is Emer. Fit. Hyd. on if both systems Outb’d Spoiler Module electrically inhibited @ Outb’d Spoiler Module depressurized @
450 300 250 400 400/0.9 TMN 400 300 300/0.6 TMN 350/l .5 TMN >0.7 TMN >0.5 TMN 2.4 TMN
5900 6300 300 1500 4000 450 475
170-200 200 - 300/0.8 TMN 400/0.6 TMN
- 6200 Ibs - 6600 Ibs Ibs Ibs/min Ibs remaining gal/min gallmin
3000 f 100 psi c2100 psi 2400 - 2600 psi 400 psi for IOsec <2100 psi 62” W/S
Pitch SAS off YawSASoff Roll SAS off
APPROACH:
Pitch SAS off Yaw SAS off Roll SAS off
Sear Down Symmetric Limit Sear Down Rolling [coordinated turns only 225 Flaps/Slats Down Rolling Limit w/ maneuvering sxtended (50,000 lb aircraft) 56,000 lb aircraft symmetric 38,000 lb aircraft symmetric 53,000 lb aircraft symmetric 50,000 lb aircraft symmetric
below 12,000 ft 12 - 25,000 ft 25 - 34,000 ft above 34,000 ft with roll SAS off
Figure 1-2. Characteristicsand Limitations (Sheet2 of 2) ORIGINAL
None l.OTMN 1 .O TMN (wing mounted AIM-54) 1.52 TMN (EX tank, fuselage AIM-54, A/G stores) 1.6 TMN (all other configurations) . None None not permitted during T/O & Land flap transitions
1. Intentional Spins 2. During AB operations; sustained 0 to -0.5 g flight: flight from -0.5 g to -2.4 g’s for more than IO seconds. 3. At MIL power or less; zero or negative g flight for more than 20 seconds. 4. AIM-9 launch with flaps/slats extended. 5. Fuel dump while in A/B or with S/Bs extended. 6. Dual eng AB takeoff, waveoffs, bolters or cal launches 7. Single eng MAX AB takeoff, waveoff, or cat launches 3. ACLS mode l/IA approaches 9. Rolling maneuvers with bank angle changes in excess of 360
Windmill airstart airspeed required Spooldown airstart airspeed required Rudder authority limits inputs to
Max Max Max Max Max
CRUISE:
65” W/S
<350 Ejection Safe 350 - 450 Ejection Hazardous >450/0.9 TMN Ejection Extremely Hazardous
650 700 650 1.75 TMN 1.52 TMN
Approach configuration Cruise configuration Max IFR probe speed
l-4
- 280 KTS)
0 - 2.0 0 - 2.0
flaps/slats limit limit limit limit
5.2 4.6 5.5 6.0 6.5
TACTICAL STANDARD CENTRAL AIR DATA COMPUTER (AIRCRAFT INCORPORATING AFC 793) ................................ CPU-175/A CENTRAL AIR DATA COMPUTER .................................... CP-11666/A CHAFF DISPENSING SET. ........................................... AN/ALE-39 JOINT TACTICAL INFORMATION DISTRIBUTION SYSTEM. ............... ANIARQ-107 DIGITAL DATA LINK ............................................. ANIASW-27BlC ELECTRONIC COUNTERMEASURES SET ............................. AN/AL@165 FUSE FUNCTION CONTROL SET ..................................... ANlAWW-4 GUN CONTROL UNIT .......................................... C-11414/AYQ-15 IFF INTERROGATOR SET. .......................................... ANIAPX-76C IFF TRANSPONDER SET ......................................... AN/APX-100(V) lRSTS......................................................~AN/AAS-429XN1 MISSILE LAUNCHEWBOL CHAFF DISPENSER ......................... LAU-138AIA INTERFERENCE BLANKER ......................................... MX-10666/A MISSILE POWER SUPPLY ............................................ PP-8043/A ................................................. PANORAMICCAMERA KA-99A RADAR WARNING SET. ........................................... ANIALR-67(V) SERIAL FRAME CAMERA. .............................................. KS-876 STORES MANAGEMENT SET ........................................ ANIAYQ-15 MISSION COMPUTERS. ANIAYK-14 9XN-60 PMM .................................. TARPS POD .......................................................... LA-610 TELEVISION CAMERA SET ........................................... AN/AX%1 RADAR SYSTEM ............................................. ANIAPG-71 (XN-1) COMMUNICATION CRYPTOGRAPHIC SYSTEM ......................................... INTERCOMMUNICATIONS SYSTEM .................................. VHF/UHF COMMUNICATIONS SET ...................................
TSECIKY-58 LS460BIAIC AN/ARC-l82
NAVIGATION AUTOMATIC DIRECTION FINDER ................................... STANDARD ATTITUDE HEADING REFERENCE SYSTEM ................ INERTIAL NAVIGATION SYSTEM. .................................... RADAR ALTIMETER. ............................. ............... RADAR BEACON AND AUGMENTOR SET ............ ANIAPN-154(V) RECEIVER DECODER GROUP ....................................... TACTICAL NAVIGATION SET ..................................... MAGNETIC AZIMUTH DETECTOR SET. .................................
OA-8697/ARD AN/USN-2(V) AN/ASN-139 AN/APN-194(V) and R-16231APN AN/ARA-63 AN/ARN-118(V) DSU-4AlA
FLIGHT CONTROL AND INSTRUMENTS AIR INLET CONTROL APPROACH POWER AUTOMATIC FLIGHT BEARING DISTANCE VERTICAL VELOCITY STANDBY AIRSPEED STANDBY COCKPIT STANDBY COMPASS
PROGRAMMER. ................................. COMPENSATOR SET ............................ CONTROL SET .................................. HEADING INDICATOR ............................. INDICATOR. ..................................... INDICATOR ...................................... ALTIMETER. ...................................... .................................................
C-8684B/A ANIASN-146 ANIASW-47 ID-663DIU AAU-18/A AVU-30/A AAU-39/A AQU-5/A
Figure 1-3. Electronic Nomenclature
I-5 (Reverse Blank)
ORIGINAL
I
I
NAVAIR Ql-F74AAD-I
CHAPTER 2
Systems 2.1 AIR INLET CONTROL SYSTEM Thepurposeof theAICS is to deceleratesupersonicair and to provide even, subsonic airflow to the engine throughoutthe aimrat?Sight envelope.The AICS consists of two variable-geometryintakes,oneon eachsideof the fuselageattheinters&ion ofthe wing gloveandfuselage. Intakeinlet geometryis variedby threeautomaticallycontrolledhingedrampson the uppersideof the intakes.The rampsampositionedto deceleratesupersonicair by creating acompressionfield outsidetheinlet andto regulatethe amountandquality of air going to the engine.The tectangularintakesare spacedaway from the fuselageto minimize boundarylayer ingestion and are highly raked to optimizeoperationat high angleof attack Inlet ramps arepositionedby electrohydraulicactuators that respondto fixed schedulesin the AICS programmers. Separate programmers, probes, sensors, actuators,and hydraulic power systemsprovide completely independentoperationof the letI and right air inlet control systems. Figure 2-1 shows the basic elementsof AICS mechanization.
2.1.1.1 Ground and Low-Speed Operation. During ground static and low-speed (Mach dO.35)operation, theinlet rampsaremechanicallyrestrainedin thestowed (retracted)position.The predominantairflow is concentratedaboutthe lower lip of the inlet duct and is supply mentedby reverseairtlow throughthe fixed bleed door, aroundthe forward lip of the third ramp. As flight speed is increasedto 0.35Mach, hydraulic power is portedto the ramp actuatorsbut the ramps arenot scheduledout of the stowedposition until Mach 0.5 (seeFigure 2-4). The fixed bleeddoorbleedslow-energy,boundarylayer air from the movable ramps. 2.1.1.2 Subsonic and Transonic Speeds. At airspeedsgreater than 0.5 Mach, the ramps program primarily as a function of Mach for optimum AICS performance.At transonicspeeds,a normal shockwave. attachesto the secondmovable ramp. ‘Ihe third ramp deflects above 0.9 Mach to maintain properbleed slot height (Ah) for transonicand low-supersonicflight. At supersonicspeeds,four shock waves compress and deceleratethe inlet air. The bleed slot removes boundarylayer air and stabilizesthe shockwaves.This designresultsin substantiallyhigherperformanceabove Mach 2 than simpler inlet designs.
Electrical power for the AICS programmersis provided by the ac and dc essentialNo. 2 buses.The ramp stow function is poweredby the dc essentialNo. 1 bus. Hydraulic power is supplied individually to the left AICS from the combined hydraulic system and to the right AICS from the flight hydraulic system. The leg AICS programmer also functions as a wing-sweep backupcomputer.
2.1.2 AICS Test. Two types of AICS tests are provided to checkthe generalcondition of the AICS andto pinpoint systemcomponentscausingdetectedfailures: AICS built-in test and on-boardcheck. 2.1.2.1 AICS Built-h Test. BIT in the AICS computer programmer is automatically and continually initiated within the programmer to check AICS componentswhen the programmeris energized.
2.1.1 Normal AICS Operations. No pilot control is requiredduring the normal (AUTO) mode of operation. Electronic monitoring in the AICS detectsfailures that would degradesystem operationand performance (referto AICS BIT). AICS cautionlights (L andR INLET, L and R RAMPS) and INLET RAMPS switches areshown in Figure 2-2.
The operationalstatusof the AICS dependson BITdetectedfailuresin AICS components.Failuresof static or total pressuresensors;rampNo. 1,2, or 3 positioning; programmer continuous end-to-endBIT; or hydraulic pressureto any of the ramp actuatorswould seriously degradeAICS performance.Detected failures of these items causethe AICS to automatically transferto a significantly degradedfail-safe mode of operation,indicatedby illumination of an INLET caution light.
Sectional side views ofrepresentative variable geometry inlet configurations scheduled by AICS programmersand descriptive nomenclatureare shown in Figure 2-3. 2-1
ORIGINAL
NAVAIR @I-Fl4AAD-I
.
I
INLET
1
RAMP
HYcJRNJL,C
RAMP
NO. 2 STOW COMMAND
Figure 2-I. Air Inlet Control System
ORIGINAL
2-2
SERVOVALVE
NO. 1
SERVOVALVE
NO. 2
SER”O”P,L”E
NO. 3
NAVAIR
NOMENCLATURE 0
0
WFI4AAD-1
FUNCTION
INLET RAMPS switches
RAMPS caution light
AUTO -
Inlet ramp position Is determined
by the AICS programmer.
STOW -
Electrically commands the respective inlet ramp actuator to the stow position; opens the appropriate hydraulic shutoff valve.
l
DO NOT take off with the switches in STOW. Hydraulic may drive the ramps out of during certain servocylinder causing an engine stall.
l
If wing sweep advisory light illuminates, cycling L AICS circuit breaker (LFl) may cause unintentional wing sweep unless WING SWEEP DRIVE NO. 1 (LDl) and WG SWP DR NO. YMANUV FLAP (LB) circuit breakers are pulled.
Indicates ramps not positioned condltlons (see figure 2-5).
INLET RAMPS power Is on and the stow locks failure modes
In either stow or trail locks during critical flight
Figure2-2. AICSControlandIndicators(Sheet1of 2)
2-3
ORIGINAL
NAVAIR 0%Fl4AAD-l
FUNCTION
NOMENCLATURE 0
INLET caution light
Indicates AICS programmer/system failure: Reduce airspeed to Mach 1.2 and check AICS acronym for failure indication. AICS FAILURE Less than Mach 0.5: Ramps should be restrained by actuator stow locks. Greater than Mach 0.5: Ramp movement Is restrained by trapped hydraulic pressure and mechanical locks, depending on Mach when INLET light illuminates. Greater than Mach 0.9: Ramp movement is mlnlmized by actuator spool valves and the aerodynamic load profile In this Mach range and a RAMP light should Illuminate.
Figure 2-2. AICS Control and Indicators(Sheet2 of 2) Detected failures of angle of attack, engine fan speed,or out-of-calibration detectionof the difference betweenPl and P2 (AP), Psor Pt sensorswill causethe AICS to revert to the slightly degradedfail-operational mode of operation.Nominal values of angle of attack, total temperature,or enginefan speedaresubstitutedfor the failed values in the AICS programmer,without illumination of an INLET caution light.
l
l
In both fail modes of operation,detectedfailures are continuously registered by the in-flight performance monitoring system and displayed with air inlet control acronymson the multifunction display and the tactical information display (Figures 2-5 and 2-6).
l
2.1.2.2 AICS On-Board Check. OBC, initiated by the pilot during poststart or ground maintenance checks,performs a dynamic check of the left and right AICS. In addition to the regular AICS BIT program, sensor calibration checks are made. The status of the programmer electronics and the ramp actuators are checked throughout an altitude and airspeedschedule aspsuedopneumaticinputs to the programmer arevaried to simulate a flight sequenceof maximum airspeed condition and back to static sea level conditions within 65 seconds. This cycles the ramp actuators through their full range, illuminates the ramp lights, exercisesthe complete AICS for preflight failure detection, and ensuresthe ramps are in their stow locks. OBC is the only way to ensure stow lock integrity since it verities the ramps are in the stowed position and then removes ramp hydraulic power. Detected AICS failures are indicated by AIC acronyms or AIC acronym(s) with associated INLET caution light(s) displayed after completion of OBC.
ORIGINAL
Note With INLET RAMP switches in STOW, AICS OBC will fail testandINLET lights will illuminate. If the engine enterssecondarymode dnring OBC, the ramps will stow and fail OBC. To reinitiate OBC, selectprimary mode and resetthe AICS. AnS4acmnymindicatestheAICSpmgrammersmay be operatingon the REV 4 (TF30/F14A) schedule. As a result, below 25,000 feet at airspeedsgreaterthan 1.1 Mach,unloadingthe aircraftto lessthan Ig will reduceinlet stability andmay resultin inlet buzz andpossiblyanenginestall. Cycling AICS circuit breakersat a constant subsonicMach number should eliminate the S4 acronym andresettheprogrammer to the REV 5 (F-l 10) schedules.
2.1.3 AICS Failure Modes of Operation. AICS mode of operationfollowing a BIT-detectedfailure may be either fail-operationalmode (Figure 2-5) or fail-safe mode (Figure 2-6). 2.1.3.1 Fail-Operatlonal. Failures in the AICS are detectedby the AICS programmer,which automatically initiates appropriate corrective action. Mode entry is indicatedby the display of a fail-operational AIC acrenym. The fail-operationalmode resultsin no significant degradationin AICS operation,and the mission canbe continued without any flight restrictions or corrective action by the pilot. 2-4
NAVAIR Of-FI4AAD-1
-------
-__Z ----
------
SlmoNlC -4 OlWJSER
-__---
-+
----
SHOCK
--
WAVES
Figure 2-3. Variable-GeometryInlet Configuration
2-5
ORIGINAL
NAVAIR
Ol-Fl4AAD-1
FLIGHT CONDITION
HYDRAULIC POWER RAMP ACTUATORS
M<0.35
OFF
Mechanically restrained by stow locks in stowed position; electrical stow commands output from AICS programmer.
to ~0.5
ON
Electrical stow commands
M>0.5 to <2.2
ON
Variable position function of math angle-of-attack. Mach 0.5; ramp
M>2.2
ON
Variable posltlon scheduled function of Mach number.
M20.35
ACTIVATOR POSITION 1 RAMPNO. )
RAMP NO. 1
RAMPNO.
output from AICS programmer.
scheduled by AICS programmer as a number, corrected engine fan speed, and Ramps no. 1 and no. 2 begin positioning at no. 3 beglns at Mach 0.9. by AICS programmer
as a
Figure 2-4. AICS Normal Operating Mode
FAILURE MAINTENANCE IEADOUT ACRONYM AIC Sl (Possible only durlng OBC) NONE
-r
DETECTED FAILURE P,, Pt, or programmer calibration
CAUSE Limits exceeded.
RESULT fqamps may not program during OBC. beset AICS Land R circuit breakers I:LFi, LGl) prior to attempting another (3BC.
Loss of englne fan speed slgnal.
Substitutes 7,399 rpm. Ramps do not lrogram durlng OBC. I IMask continuous monitor (CM) so that subsequent AIC acronyms are ,displayed.
out of
Englne fan speed rpm from AFTC.
;
IIN FLIGHT: Substitutes +2’ Bngle-of-attack or 7,390 rpm. AIC 54 (During OBC)
AIC A4
Alpha delta pressure sensor out of calibration or engine fan speed.
Llmlts exceeded. Augmenter fan temperature controller (AFTC) may be In secondary mode.
l
Substitutes +2O angle-of-attack value until reset.
l
Substitutes 7,300 rpm.
Open wire
Open wire
I None
AIC symbol has Lor R appended (AICL, AICR) to identify on tilch side failurewas detected.
Figure 2-5. Fail-OperationalMode -No
ORIGINAL
2-6
INLET Light
NAVAIR FAILURE MAINTENANCE READOUT ACRONYM 14lC P
Ol-Fl4AAD-1
RESULT DETECTED FAILED AICSprogrammer P)
CAUSE Failed end-to-end BIT
4lC si Static pressure (P,) /4lC s2
Total pressure (Pd
I4lC Al IUC A2 IUC s3 I4IC Al, I UC A2,
Minimum or maximum limits exceeded
Ramp No. 1 Ramp No. 2 Ramp No. 3
Sustained command and feedback error
Hydraulic pressure loss of ramp No. 1, No. 2, or No. 3
Sustained error due to loss of hydraulic pressure
MACH co.5 Hydraulic shutoff valve remains closed. Ramp actuators remain mechanically restrained within stow locks, provided they failed within stow locks.
I &?A3 (‘INLET caution light ftventually illuminates
Kt.5 Mach) Fr]ONE (No INLET caution light :0.5 Mach)
MACH 20.5 Ramp movement is restrained by actuator mechanical locks if failure occurred with ramps within locks. Otherwise ramp(s) move slowly with aerodynamic loads.
Ramp(s) may move if failure occurred with ramp(s) out of mechanical locks. RAMP light will illuminate.
Loss of hydraulic pressure Note
AlC symbol has L or R appended side failure was detected.
(AICL, AICR) to identify on which
-. _ I - . - ^ Ftgure Z-b. P~aU-Sate Mode -
INLET Light Illuminated I and No. 2 ramp within trail locks and No. 3 ramp in stow locks arerestrainedbytrappedhydraulic pressure). Engine operationsmay be successfulbelow 1.2 Mach in this configuration; however, corrective procedures shall be performed.
Note
Transferring to SEC mode will revert the AICS programmers to the REV 4 (TF3OIF14A)schedulebecauseof the lossof the AFTC Nl speedsignal andwill display an S4 acronym.Below 25,000feetandat airspeeds greaterthan 1.1Mach, unloadingthe aircraft to lessthan lg will reduceinlet stability and may result in inlet buzz and possibleengine stall. To restorefull REV 5 (FllO/F14B/D) scheduleandeliminateS4 acronymfollowing anairborneenginemoderesetto PRI, recycle AICS circuit breakersat constant subsonic Mach number.
Note Fail-safe operations result in a slight degradation of cruise and excess thrust performance because of the off-optimum configuration. Ifthe hydraulic shutoffvalve closesaboveMach 0.9, the ramps are normally in an unsafeconfiguration and the appropriateRAMPS caution light will accompany the INLET cautionlight (Figure 2-7). Above Mach 0.9, theNo. 3 ramp normally beginsprogramming below the actuator stow lock. When the fail-safe mode is entered aboveMach 0.9, the unpoweredNo. 3 ramp will eventually move and may causecompressorstalls at higher power settings.The aircrafi shall be deceleratedbelow 1.2 Mach, and the appropriateINLET RAMPS switch shall be selectedto STOW.
Fail-Safe Mode. The fail-safe mode results in significantly degradedAICS operation.Mode entry is indicated by the display of a fail-safe AIC acronym andillumination ofthe appropriateINLET cautionlight. Undertheseconditions,theAICS programmerprovides .a shutoff signal to close the ramps’ hydraulic shutoff valve. If the hydraulic shutoff valve closesbelow Mach 0.9,the rampsare normally in a safeconfiguration (No. 2.1.3.2
2-7
ORIGINAL
NAVAIR Ol-F14AAD-I
Figure 2-7. Ramp Monitor Logic
Do not select STOW at speedsgreaterthan 1.2 Mach. Compressorstalls may occur becauseof ramp mispositioning. 2.1.3.3 Stow Mode of Operation. The STOW position of the INLET RAMPS switch commandsthe appropriate hydraulic shutoff valve to open and provides a direct electrical signal to the ramp actuators,porting hydraulic pressuredirectly to the retract side of the actuator.When therampsareretractedto the stow position, the RAMPS light will extinguish and the stow locks should remain engagedeven if hydraulic power is subsequently lost. Once in STOW, AICS programmerdetected electronic failures may be reset below Mach 0.5. 2.1.3.4 Hydraulic Shutoff and Dump inhibit. The AICS hydraulic systems include a hydraulic shutoff valve to control hydraulic systempressure.The hydraulic shutoff valve is normally controlled by the AICS programmer,which removesthehydraulic-on signalbelow 0.35M or in the eventof a programmerfailure. The STOW position of the INLET RAMPS switch bypasses ORIGINAL
2-8
the AICS programmerto energizethe hydraulic shutoff valve, providing pressurefor ramp motion. To ensure hydraulic pressureis shut off, the respectiveAICS programmer must be deenergizedby pulling the circuit breaker (LFl, left or LGl, right) and the INLET RAMPS switch placed in the AUTO position. Whenever the hydraulic shutoff valve closes (i.e., fail-safe mode entry), hydraulic spool valves in the ramp actuators sensethe absenceofpressureandblock the actuator pressure and return ports, causing a hydraulic lock (dump inhibit). This feature reducesramp movement whenanAICS failure occursandthe rampsarenotbeing restrained by mechanical actuator locks. Although dump inhibit preventsthe ramp from rapidly extending and causingan engine stall, the ramps will still slowly move. Under normal circumstances,the pilot will have sufficient time to select STOW and prevent an engine stall. F-14A flight test results show that with dump inhibit, the time interval between illumination of a RAMPS caution light and engine stall following an AICS failure was 15 to 40 secondson the ground at military power, andapproximately50 secondsat 10,000 feet at military power. 2.1.3.5 Ramp Actuator Mechanical Locks/ Positioning. In addition to the actuatorstow locks,the first and second ramp actuators have another set of
NAVAIR 0%F14AAD-1
latches(trail locks) that prevent further ramp actuator extension aAer a failure within these trail locks. The actuatorstow andtrail locks restrainactuatormovement in tensiononly. Hydraulic pressure(500 psi) is required to disengagethe lock finger latches. Safe positioning of the ramp actuatorsis monitored by the ramp monitor logic shown in Figure 2-5. A RAMPS light should always be accompaniedby an INLET light with the landing gear handle UP. With the landing gear handle DOWN, a RAMPS light can be illuminated without an INLET light. The emergency procedurein any caseis the same. RAMPS lights will extinguishwhen a safe configuration is attained. Note Following anAICS programmer/rampsfailure, the safestconfiguration resultswhen the rampsarein the stow position. The programmers are disabled by pulling the affected AICS circuit breaker and returning the INLET RAMPS switch to AUTO. In the event of an engine or hydraulic failure, the following conditions exist with respectto AICS reset:
the trail locks becauseof aerodynamicloads. The hydraulic restriction of all ramps during loss of hydraulic power and after fail-safe mode entry, should prevent rapid ramp movement. Internal failure of an actuator, especially the No. 3 ramp actuator,may allow rapid ramp extension and cause engine stall. Additionally, failure to stow the ramps in a reasonableamountof time after INLET light illumination or inability to stow following a hydraulic system failure may result in compressor stalls at high power settings. Engine start attempts may not be successfulunless the ramps are stowed(RAMPS caution light extinguished). 2.1.4 AICS Anti-Ice. AICS anti-ice is activatedonly by selecting ORIDE/ON with the AICS ANTI-ICE switch and airspeedbetween0.35to 0.9 Mach (hydraulic power is available at 0.3 Mach). Above and below theseairspeedsthe AICS anti-ice is disabled.When the ENG/PROBE anti-ice switch is in AUTO, the AICS anti-ice is off. When AICS anti-ice is activated, the AICS programmer repositions the No. 1 and No. 2 rampsto positionsbelow theNo. 3 ramp (Figure 2-8) so that ice will not form above the No. 3 ramp. 2.2 ENGINE The aircraft is poweredby two Fl IO-GE-400turbofan engines(Figure 2-9) with variable exhaustnozzles andAB augmentation.They aredual-rotorenginesconsisting of a three-stagefan driven by a two-stage,lowpressure turbine and a mechanically independent, aerodynamically balanced, nine-stage, high-pressure compressordriven by a single-stage,air-cooled highpressure turbine. Engine operation is automatically regulatedandmaintained electrically by the augmenter fantemperaturecontrol unit andby throttle inputs to the main enginecontrol.
1. If hydraulic pressureis zero, there is no need to safe the ramps (by stowing ramps, pulling AICS circuit breakers,and returning to AUTO) since selecting STOW will have no effect without hydraulic pressure. 2. If airspeedis less than .35 Mach, there is no need to safethe ramps sincehydraulic pressurehas already been removed and ramps should be in the stow locks. If the ramps arenot in the stow locks, the RAMPS light will illuminate when thelanding gear handle is lowered. If the RAMP light does illuminate, then the ramps should be stowed and the AICS programmerreset.
Each engineis slung in a nacellewith the thrust axis laterally offset approximately 4-112 feet from the aircraft centerline. The installed static enginethrust at military power is 13,800pounds and at maximum AB power thrust is 23,600 pounds.Installed enginethrust at maximum AB at 0.9M at sealevel is 30,200pounds. Accelerationtime from idle to military power is approximately 4 seconds.
3. If hydraulic pressureis greaterthan zero and airspeedis greater than .35 Mach, then the ramps should be stowed and the programmer resetafter engine failure or a low-hydraulic-pressuresituation. This will ensurethat ifthe ramp is out ofthe stow lock (as is normal above .5 Mach), it will be returnedto the stow lock andkept therefor landing regardlessof subsequenthydraulic or electrical malfunctions.
During operation,air entering the engineis directed into the fan, which initially pressurizesthe air and directs its flow into the engine core compressorand fan bypassduct. Direction of airflow into the fan is optimized by variable-geometryinlet guidevanes(IGV) and into the compressorby variable geometrystatorvanes. The high-pressurecompressorfurther compressesthe air throughthe nine-stagecompressorbefore discharging it into the annularcombustion chamberto mix with
2.1.3.6 AICS Failure In-Flight Operation. Most AICS failures occurring in flight do not require rapid pilot responsebecauseof system design features for fail-safeoperation.In flight, theNo. 1 and2 ramps tend to blow backto the stow position or arerestrainedwithin 2-9
ORIGINAL
NAVAIR 01.Fl4AAD-1
WSHLD
AIR fNG/PROBf
--
---
-_
RAMP
-----------
Figure 2-8. AICS Anti-Ice System
Figure 2-9. Fl lo-GE-400 Engine ORIGINAL
2.10
NAVAIR 01.Fl4AAD1
fuel from the fuel nozzles.This fuel-air mixture is initially ignited by the main spark igniter in the combustion chamber.As a resultof this combustion, expanding gasesdrive the high- and low-pressureturbines.Power to drive the two accessorygearboxesis obtained from the high-pressurerotor. From the turbine section,the exhaustgasespassinto the section and are mixed with air from the fan bypass duct. During AB operation, fuel is sprayed into this mixed airflow and ignited for additional thrust.
During night and/or IFR conditions, the increasedaccelerationduring AB usewill result in inner ear disturbances that may cause flightcrew confusion/disorientation. The large amount of light generatedby the AB exhaust reflecting around the aircraft will compoundthis condition. These factors may result in severeaircrew disorientation/ vertigo. 2.2.1 Engine Control. The engine is controlled by three units: the hydromechanicalmain engine control, the electronic augmenterfan temperaturecontrol, and the AB fuel control. Thereare two modesof operation, primary (electronic)and secondaty(mechanical),with provisionsfor automaticandmanual switchover to secondary.Manual selectionis controlledthroughthe ENG MODE SELECT panel (Figure 2-10). Automatic or manual selectionof the secondarymode illuminates an ENG SEC caution light. When one engine reverts to secondarymode, the otherenginecontinuesin primary mode. Cycling the ENG MODE SELECT switch may resetthe AFTC if the faults aretemporary.If the change back to primary mode is successful,the ENG SEC light will go out. Automatic or manual selectionof secondary mode is possiblethroughoutthe flight envelope.Selection of secondarymode will causea loss of fan speed signal to the AICS.
SEC mode transfers with throttles in AB above450 KCAS could result in pop stalls anddamageto the IGV linkage.
2.11
Note SEC mode transferwhile in AB may result in pop stalls. Nonemergencymanual selection of SEC mode on the ground should be performed in basic engine. Nonemergency manual selection of SEC mode airborne should be performed in basic engine with power set aboveSS-percentrpm. Transferringto SEC mode will revert the AICS programmersto theREV 4 (TF-30/F 14A) schedulebecause ofthe lossofthe AFTC N1 speedsignal andwill display an OBC AICS - LEFT (RIGHT) and ANGLE OF ATTACK acronym. Below 25,000 feet and at airspeeds greaterthan 1.1TMN, unloadingthe aircraft to lessthan 1g will reduceinlet stability andmay result in inlet buzz and possible engine stall. To restore the full REV 5 (F1 lO/F14B/D) scheduleand eliminate the OBC acronym following an airborne engine mode reset to PRI, cycle AICS circuit breakersat constantsubsonicMach number. 2.2.1.1 Main Engine Control. The MEC is a hydromechanicalcontrol thatprovidesfuel shutoff,variable stator vane scheduling,and main fuel metering in both primary and secondarymodes.The MEC controls fuel flow until 59-percentt-pm and provides high-pressure compressorrotor overspeedprotectionautomatically by securing fuel flow to the engine when an overspeed condition of 110percentis reached. Note To regain engine operationfollowing an automaticengineovetspeedshutdown,the throttlemustbe cycledto OFF thenIDLE. An overspeedcondition in excessof 110 percentwill result in momentary loss of ‘pm indication until N2 rpm falls below 110 A.5 percent. EGT and FF indicators will continueto function normally. 2.2.1.2 Augmenter Fan Temperature Control. The AFTC is a modularsolid-stateelectronicdevicethat performs control schedule computations, integration and logic functions, limit control, failure detection,and provides enginecore speed(N2) signal for instrument display andenginefan speed(Nt) signal to the AICS. It also controls the distribution of electrical power to the entire engineelectrical and monitoring systems.Figure 2-l 1 shows the various interface signals used by the AFTC. Normally the CADC supplies Mach number value to the AFTC. If this signalis erroneous,the AFTC assumesa default Mach number value in order to continue operation. ORIGINAL
NAVAIR
Ql-Fl4AAD-1
NOMENCLATURE 0
02
0
ASYM LIMITERswitch
L/R ENG MODE SELECT swftch
L/R ENG SEC caution IigM
FUNCTION ON(guarded)
Reduces AB thrust asymmetry in the event of AB blowout or tf one engine fails to light when commanded to AB. Limits operating engine to minimum AB until other engine attains minimum AB.
OFF -
Either engine may operate at any AB power setting independently of the other engine.
PRI -
Primary mode, AFTC controls main and AB fuel flow, fan inlet guide vanes, nozzle area, and ignition.
SEC -
Secondary mode, main fuel flow Is scheduled by the MEC. AB is inhibited.
hydromechanlcally
liiumlnates when the engine is in secondary mode. AB operation is inhibited for engine with light illuminated. AICS on affected engine side reverts to REV 4 (TF-30/F-14A) schedule.
Figure 2-10. ENG MODE SELECT Paneland ENG SEC Lights
2-12
NAVAIR Ql-W4AhD-1
,f?&:R
ENG
MODE SELECT @
Figure 2-11. AFTC Functiional Relationships positioning; VSV positioning is controlledby theMEC. The AFTC incorporatesindependentconbol schedules that are prioritized so that the optimum amount of fuel flow is provided to the main combustor.At any given time, only one of theseschedulesis actually in control of fuel flow. The remaining schedulesarealways active and are calculating the changein fuel flow required(if any) to attainthe desiredvalueof their assignedparameter. The selectionof the schedulein control is accomplishedby a seriesof minimum andmaximum selectors. These selectorscontrol schedulingof the following:
The loss of Mach number signal Tom the CADC resultsin the lossof both airflow limiting and idle lockup functionsof the AFTC. This may result in pop stalls at supersonic speeds(on a cold day) at high power andinlet b~resultinginpopstallsatidlepower. Ifthis occurs,decelin military poweruntil subsonic. 2.2.1.3 Afterburner Fuel Control. The AFC is controlled by the AFTC for afterburner operation. The AFTC computesAB fuel flow ratios andprovidesthem to the AFC. The AFC convertsratio commandsto meteredfbel flows into local core and fan AB fuel manifolds. When staging up the AB, local fuel flow is initiated first, followed by coreand fan flow last. When staging down, the reverse sequenceoccurs. Thrust changesare smooth when staging up or down.
1. Acceleration/deceleration 2. Minimum/maximum pressure
compressor discharge
3. Minimum/maximum rpm 4. Fan speedlimiting
2.2.1.4 Primary Mode. In the primary mode, the AFTC controlsthe MEC, AFC, andAB nozzle hydraulic pump to provide optimum engine operation with unrestrictedthrottle movementthroughoutthe flight ena velope. The AFTC computations are used to control basic engine and AB fuel flow, IGV, and AB nozzle 2-13
5. Maximum turbine blade temperahxelimiting 6. Idle lockup speed. Other AFTC functions include enginestart control, asymmetric thrust limiting, reducedarrestmentthrust, automatic relight, and fault detection. Fault detection ORIGINAL
NAVAIR Ol-IWAAD-1
automatically switchesthe enginecontrol to the secondary mode in the event of core overspeed,fan speed signalloss,AB nozzle demandfull openwhennot atidle or maximum AB, AFTC power deviations, fuel flow demandtit11increaseor full decrease,fan speedgreater than 800 rpm below scheduleand not accelerating,or throttle signal error. 2.2.1.4.1 AS Operation (Primary Mode). For AB operational characteristics, refer to Figure 2-12. Unrestricted throttle operation into and out of AB is permitted throughout the flight envelope. During AB operation, rpm, EGT, fuel flow, and nozzle position vary with altitude and airspeed. The nozzle position will also increase as the throttle is transitioned from minimum AB to maximum AB. If an AB blowout occurs, the autorelight feature attempts to reinitiate AB without throttle movement. The engine has reduced AB region of operation at high altitudes and low airspeeds. The automatic AFT control feature, rich stability cutback, reducesor limits the maximum AB fuel flow in this region to prevent AB instabilities (Figure 2-12). Indication of rich stability cutback is a nozzle position of approximately 30 to 50 percent at maximum AB rather than the normal 60 to 70 percent. Also, because of airflow and temperature characteristics, AB light-off characteristics are slower at high altitudes and low airspeeds. 2.2.1.5 Secondary Mode. Basic engine operation in SEC mode is extremely reliable. In the secondary mode, the electronicfunctions performed by the AFTC are eliminated. The MEC provides complete control of the engine with the exception of fan speed limiting, which is poweredby the higher of 2%Vdc aircraft electrical power or enginealternatorelectrical power.When SEC mode is manually selectedor an automaticdefault to SEC mode occurs,the exhaustnozzle is commanded full closed, the nozzle position indicator goes to the not-poweredposition (subzeroindication), the IGVs are fixed full open, high-energy ignition is continuously energized,AB is inhibited, and idle lockup protectionis lost. In SEC mode, enginestall margin is decreasedat low ‘pm becauseof IGV positioning. The FEMS engine stall detection circuit is inoperative,but overtemperature warning is still available. A low-level vibration/rumble may be sensedin ground idle operationin secondarymode. This vibration/rumble has no adverse affect on the engineand disappearswhen the throttle is advancedslightly up to 5-percentrpm increase.Maximum thrust available at military power in SEC mode is depicted in Chapter 14,Figure 14-4.
ORIGINAL
2-14
SEC mode transfers with throttles in AB above 450 KCAS could result in pop stalls and damageto the IGV linkage. Note a SEC modetransferfrom AB may result in pop stalls. Nonemergencymanual selection of SEC mode on the ground should be performed in basic engine. Nonemergency manual selectionof SEC mode airborneshouldbeperformedin basicengine with power set above85-percentrpm. a If the fan speedlimiter circuit hasfailed, enginerollback may occur with selection of SEC mode. In the event of enginerollback, PRI mode must be reselectedabove 59-percentrpm or flameoutwill occurand airstartwill not he possible. 2.2.1.6 Engine Alternator. Each engine’selectrical system is poweredby an alternatormounted on the engine afi gearbox.The alternatorconsistsof four windings.Two windings areredundantin providing powerto theAFTC and its components.A third winding provides power for both main high-energyignition andAB ignition. The fourth winding provides power to the engine monitoring system processor(for FEMS), and a signal for the rpm gauge.The last winding is also an alternate sourceof power for the fan speedlimiting circuit. The fan speedlimiting circuit may bepoweredby eitherthe essentialNo. 2 dc bus or the engine-drivenalternator winding, depending on which source has the highest stableoutput. Ifengineahematorpoweroutputdropsbelowapreset value, enginecontrol will automatically transferto SEC mode, illuminating the respectiveengine SEC light. If the enginereverts to SEC mode as a result of a sheared alternatorshaft, enginehigh-energyignition will not be available and the engine SEC light will not illuminate.. Cockpit indicationswill be lossofenginerpmand nozzle position indicating below zero.In failure modes,redundant aircraft electrical power will be available for fan overspeedprotection. The engineis completely operableshouldtheaircraft experience a complete electrical failure. The engine operatesin either PRI or SEC mode, which can be selectedautomatically or manually. In caseof a complete electrical failure all engine lights and indicators are inoperative.
NAVAIR WIWAAD1
RICH STABILITY CUTBACK
Figure 2-12. Rich Stability Cutback 2-15
F1 IO-GE400Engine
ORIGINAL
NAVAIR Of-Fl4AAD1
2.2.1.7 Turbine Blade Temperature (Pyrometer). The pyrometer is a fuel-cooled,photodiode,optical unit that measuresinfraredradiation from the metal surfaceof the high-pressureturbine blades.This temperaturesignal is transmitted to the AFTC and is used to regulate engine fuel flow, which maintains turbine blade temperaturewithin limits. Cockpit indications of turbine blade temperatureappearon the MFD. 2.2.1.8 Flame Sensor. The flame sensoris anuitmviolet radiation sensingunit in the AB duct. During AB operation, ultraviolet rays detected through a quartz window activate a gas tilled sensor that electrically transmits a flame-presentsignal to the AFTC. Without this signal,only minimum AB fuel flow is available.AB will be inhibited ifthe flame sensorfails on. A L/R AUG acronymis displayedin theENGINE FAULTS block of the MFD enginepage. 2.2.4.9 Asymmetric Thrust Limiting. The asymmetric thrust limiting circuit is designedto hold both enginesto minimum AB until both ABs arelit off. The AFTC releasesthe hold on the AB when both engine AB pumpsareon andboth enginesflame sensorsareon. Selecting the ASYM LIMITER switch to OFF (guard coverup) overridesthe comparisonof left andright AB statusand allows eachAB to operateindependently.
A malfunctioning or deselectedATLS can greatly increasethe magnitudeof asymmetric thrust becauseof enginestall or failure.
The RATS light will be illuminated anytime the aircraft circuit is enabled,evenif the engines are operatingin SEC mode or the engine circuit hasbeenoverriddenby selection of AB. 2.2.2 Variable Exhaust Nozzle. Engine exhaust gases at higher thrust settingsare dischargedthrough the nozzlethroat at sonic velocity andare acceleratedto supersonicvelocity by the controlled expansionof the gases.Varying nozzle throat areacontrolsfan stall margin, which optimizes performance. The variableexhaustnozzleis a three-flap,convergentdivergent-typenozzle.Nozzle variation is accomplished by axial movementof four hydraulic actuatorsmechanically synchronized for geometric stability. These hydraulic actuatorsuseoil from a separatecompartmentin the engineoil storagetank andareoperatedby a hydraulic pump that respondsto AFTC signals. A failed open nozzlemay be causedby an oil leak, but if the leak is in thenozzJesystem,onlyaportionofthemain enginelube oil will be lost. During basicengineoperation,thenozzle areais modulatedto a near-closedposition, and,in AB, the nozzle areais infinitely variable to a full-open position. The nozzle will go full open airborne with the throttle at IDLE at low altitude and airspeeds(Figure 2-13). A gaugefor each engineon the pilot instrument panel next to the engine instruments indicates nozzle position in percentagefrom 0 to 100.Normal indication for maximum AB is approximately 70 percent. Note
2.2.1.10 Reduced Arrestment Thrust System. The RATS is a featureof the AFTC provided to reducethrustfor carrierlandingsto a level consistentwith carrier(CV) wind-over-deckoperations.When activated, the AFTC automaticallyreducesthe military power core speed(Nz) by approximately4.5 percent.This resultsin an approximate20- to 25-pementdecreasein thrust. RATS employstwo enablingcircuits:anenginecircuit within eachengine’sAFTC, andan aircraft circuit. The enginecircuit is enabledby the aircraftcircuit via switch closure.Sincethe enginecircuit is a functionof the AFTC, it is not available in SEC mode and can be overriddenin PRI modewith selectionofAB. The aircraft circuit is enabledwhen weight is placedon eitheror both main landinggearswith thehook handledown or thehook out of thestowed position.The RATS light, locatedon the pilot advisory panel,illuminates when the aircraftcircuit is activatedbut it is not an indicationthat the enginesare operatingat reducedthrust. incorp~mted
ORIGINAL
Note
2-16
When AFTC is operating in secondary mode, the nozzle is commandedclosed and the exhaustnozzle indicator is inoperative. With the landing gear handle down, engine at IDLE, and weight off wheels, the nozzle is restricted to a near closed position (maximum 26 percent) to prevent exhaustnozzle flap contactwith the deck/hook during landing.Five secondsafterweight on wheels,the nozzle resetsto full open to reduce idle power during landing roliout and while taxiing. On deck in PRI mode with throttle aboveIDLE detent,nozzle position varies linearly with throttle position. 2.3 FATIGUE ENGINE MONITORING SYSTEM 2.3.1 FEMS Functional Description. The FEMS is a solid-stateelectronic systemthat provides dataacquisition, processing,and storage. FEMS information is displayed on the MFDs (Figure 2-14). The system accumulates airframe stress and fatigue data and
NAVAIR Ol-Fl4AAD.1
0.1
0.2
0.4
0.6
0.8 TRUE
NOZZLE
POSITION
WITH
THROTTLE
1.0
1.2
1.4
1.6
MACH
AT IDLE
IN-FLIGHT,
GEAR
UP ,~,”-----
Figure 2-13. Variable Area ExhaustNozzle
2-17
ORIGINAL
NAVAIR 01.Pl4AAD-1
Figure 2-14. FEMS Multifunction Display Configuration relevant engineperformancedata,both in flight and on deck, from the engine monitoring system processors. Engine faults detectedare isolated to the appropriate WRA or combinationsof WRAs and recordedfor later transfer to the DPGS for diagnostic analysis, troubleshooting,andappropriatemaintenance.‘Ihe DPGS also computesand storesengineparts life tracking and failure-trendingdata.This tracking of enginedata extends the life andsafety of fleet aircraft by permitting maintenanceroutinesatperiodic intervals.FEMS alsoprovides a signal to the stall warning system that initiates a losecondwarning tone(identical to overtemperaturetone) and illuminates the L or R STALL warning legend on the MFD/HUD indicating an engine stall. FEMS will recordaircraft overstresswhen it determinesthatnormal accelerationhasexceeded: 1. 7.5g with landing gear UP and Mach greater than .24 2. 4.5g with landing gear DOWN (as in hard landing) 3. 4.5g when Mach is .24 or less. The FEM.9 consistsofthe following components(see Figure 2-15).
ORIGINAL
2.18
2.3.1.1 Engine Monitoring System Processor. The EMSP is enginemountedand enginepoweredand converts control system electrical signals from the AFTC into digital format for transmissionto theADAC. It also receivesand digitizes other noncontrol systemrelated data such as anti-icing system status,lube oil level, and lube temperaturedata for transmissionto the ADAC. In addition, the EMSP calculates and stores enginecycle count data,making this datareadily available for each serial numbered engine even when the engine is not installed in an aircraft. EMSP is only operationalwith theenginesinprimary mode. 2.3.1.2 Airborne Data Acquisition Computer. The ADAC is the central processorof FEMS and executes airframe and engine fatigue algorithms. The ADAC acquiresaircraft databy direct analoganddigital inputs. Additional aircraft data receivedby the ADAC from the CIU to bestoredasaresultof structural,engine, or other mission events are transferredto the DSS for postflight analysis.In addition, ADAC storesfault code messages,in nonvolatile memory, for display on the FMI. ADAC is poweredby the 28-Vdc right main bus.
NAVAIR Ol-F14AAD-1
Figure 2-15. Fatigue Engine Monitoring System Diagram
2-19
ORIGINAL
NAVAIR
Ol-F14AAD.1
Date Storage Set. The DSS, located in the RIO cockpit, and a removableDSU provide automatic preflight en&y of JTIDS mission data and in-flight recording of engine data for analysis. Refer to JTIDS Chapter19. In flight, the MCS transfersengine-related datavia the 1553busto the DSU for postflight analysis. This datais collectedfor enginediagnosticpurposesand compiled for long-term maintenancerecords.A fault code on the FM1 will alert the maintenancecrew when the DSU has reached 80 percent of its capacity for engine data recording. If the DSS is inoperative or is not loadedwith a DSU, enginepart-life tracking datais maintainedonly by the EMSP.
2.3.1.3
2.3.1.4 Flight Maintenance Indicator. The FM1 (Fignre 2-16) displaysto the maintenancecrew ADAC datafor engine/airframestatus.It is mountedin aneasily accessiblelocation on the forward bulkheadin the nose wheelwell. After eachflight, theFM1 FAIL, CAUTION, and/orFLUIDS fault trip indicatorswill be eitherblack, signifying the absenceof a FEMS-detected failure, or white, indicating FEMS detecteda failure. The indicators shouldnormally be resetby maintenancepersonnel prior to flight. With electrical power applied to the aircraft, pressingthe STATUS SWITCH button displays either a fault code (if a fault is present)or NONE in the STATUS window. All fault codesmay be scrolled line by line by pressingthe STATUS SWITCH button once for eachline. When no more fault codesare displayed, the display will readEND*. When END* is displayed, pressingand holding the CLEAR button changesthe display from END* to CLR for approximately5 seconds followed by NONE, erasingall fault codes.
Figure 2-16. Flight MaintenanceIndicator 5. Exhaustnozzleoff scheduleor signal out of range 6. Fan inlet guide vanesoff scheduleor signal out of range 7. AB fuel valve operation(dry power)
Note The FMl is designedto bea maintenancetool only and should not be used as a go/no-go deviceby aircrew on preflight. Likewise, aircrew should not take it upon themselvesto resetthe device. Do not pressboth CLEAR and STATUS SWITCH at the same time. Failure to comply will result in the FEMS onboardclock being altered.
8. AB fuel schedulefault or signal out of range 9. AB signal on but not selected IO. No AB light-off signal 11. AB blowout
The following is a compositelisting of the dataautomatically recordedin memory for maintenanceand displayed in numeric code on the FMI:
12. Secondarymode operation 13. Pilot-initiated EMS data
1. Fan/coreoverspeed
14. Anti-icing fault
2. Decay in core speedor signal out of range
15. Low oil quantity or signal out of range 16. Oil overtemperature
3. Compressorstall
17. AFTC power out of limits
4. Turbine blade temperaturelimit exceededor signal out of range ORIGINAL
2-20
NAVAIR 01.Fl4AAD-1
18. Tbrottle/AFTC signal fault 19. Mach signal to AFTC fault 20. Aircrafi 28-volt supply to AFTC fault 2 1. EMSP fault 22. ADAUEMSP interfacefault 23. ADAC BIT fault andsystem failure 24. ADAC battery low 25. Data storageset memory full and requiresservice 26. Aircratl overstress 27. SystemDSS 28. ADAC A-6 failure 29. RATS failure. 2.3.2 FEMS Operation. FEMS data acquisition for monitoring engineperformanceis automatic.However, the pilot may encounterunusual enginebehavior of a nature.that does not automatically initiate data recording. This data is valuable for diagnosisof the causeof mmsualbehaviorandshouldbe recordedby the pilot by depressingthe ENG RCD button on the fuel managementpanel.Pressingthe ENG RCD buttonmomentarily causes21 secondsof enginedatato be recorded:6 secondsbeforeand 15 secondsafter switch initiation. It is important to rememberthat if a transientproblem is to be recordedby FEMS, the ENG RCD button must be activatedquickly sothe actualeventis not missed.Manual recordingwill not interferewith dataautomatically savedby the FEMS. 2.3.3 FEMS and OBC. FEMS is checked during OBC preflight and in flight (Class III). It is designated by a FEM acronym. This acronym is displayed at the comoletion of OBC if FEMS fails its BIT durine OBC. Engine-life tracking datais still availablethroughYEMSP if FEMS is lost. 2.4 ENGINE FUEL SYSTEM The engine fuel system, which is identical for each engine,providesmotive flow fuel to effect fuel transfer and meteredfuel for combustion as a function of pilot throttle commands and numerous engine parameters (Figure 2-17).
2-21
2.4.1 Motive Flow Fuel Pump. The motive flow fuel pump is a gear-drivencentrifugal pump on each engine accessorygearbox that returns high-pressure fuel to the fuselageandwing tanksto effect normal fuel transfer.Motive flow is used to power the boost pump in the respectivesump tank.This fuel continuesthrough control valvesto ejectorpumps in the fuselageandwing fuel tanks. There is no cockpit control for the motive flow fuel pumps. Failure of one pump illuminates the R or L FUEL PRESScaution light andreducestbe rateof fuel transferbut doesnot inhibit the transferof fuel from any tank. Motive flow pump failures causethe engine to draw fuel throughsuction feed. Higher altitudesand decreasedambientpressureresult in reducedfuel flow, which may causeengineflameout becauseof fuel starvation. With a single motive flow fuel pump failure, AB selection above 15,000 feet MSL may cause engine flameout. With failure of both motive flow fuel pumps, high power settingsin basic enginemay causeflameout above25,000feetMSL. Ifa dual motive flow fuel pump failure occurs,wing fuel will not be available. 2.4.2 Engine Fuel Boost Pump. The engine(total flow) fuel boost pump is an engine-drivencentrifugal pump on theaft accessorygearboxthat providesboosted pressureand flow from the fuel supply system to meet main andAB fuel requirements.The pump receivesfuel at aircraft boost pressureand boosts fuel pressureto levels adequateto operatethe engineat all power settings (maximum 40-psi pressurerise). During non-AB operation,somefuel is circulatedbetweenAB fuel control andthe enginefuel boostpump sothat fuel pressure is readily available to the spraybars for AB light-off. 2.4.3 Main Fuel Pump. The main fuel pump is a two-stagepump that receivesfuel flow from the engine fuel boost pump. It provides additional fuel pressurization andtransmitsmechanical-gear-drivenpower to the MEC from the gearbox. 2.4.4 Main Engine Control. The MEC is a fueloperated,bydromechanicalfuel flow regulatorthat operatesin tandemwith the main fuel pump andis capable of operating in two modes. In the primary mode, it metersmain fuel flow ascommandedby the AFK and provides VSV scheduling. The secondary mode hydromechanically meters main fuel flow to govern Nz speedbasedon pilot throttle commands and provides basicenginecontrolexceptfor AFTC fan speedlimiting. VSVs aerodynamicallymatch high- and low-pressme compressorstagesby changingtheangleatwhich airflow entersthecompressorrotorblades.The MIX containsthe schedulingmechanismandprovidesmeI pressureto vary VSV positioning.A flexible mechanicalcable provides feedbackfrom the compressorstatorto the MEC. ORIGINAL
NAVAIR M-FlUAD-
ELECTRICAL FUEL HYDRAULlC
--FUEL
SUPPLY
Figure2-17. EngineFuelSystem ORIGINAL
2-22
NAVAIR Ol-FI4AAD-I
2.4.5 Afterburner Fuel Pump. The AB fuel pump is a centrifugalgear-drivenpump that receivesfuel from the engineboostpump, increasespressure,anddelivers tie1 to the AB tieI control. During non-AB operation, Abelis circulated betweenthe AB fuel control and the engineboostpump; the AB fuel pump impeller runsdry with the bearingslubricated by the engine oil system. Failureofan AB fuelpump will resultinan AB blowout. 2.4.6 Afterburner Fuel Control. The AB fuel control is a fuel-operated,electrohydromechanicalunit that regulatestie1 flow in responseto AFTC schedulingand compressordischargepressure.Fuel pressurefrom the AB fuel control provides on-off signals to the AB fuel Pump. The AB fuel control splits fuel flow into three meteredstreams(local, core, and fan) on a sequentialbasis into theAI3 manifolds for distribution throughspraybars in the AB duct. Throttle commands initiate local fuel flow and AB ignition (minimum AB). Once local fuel flow and flame are established,core fuel flow commences.As maximum core fuel flow is established,fan fuel flow commencesand increasesuntil maximum AB is achieved.The transitionsbetweenlocal, core,and fan fuel flow are smoothand unnoticed(Figure 2-18). During non-AB operation, fuel flow is circulated through the AB manifolds to preventthrustlagsandsurgeswhen AB is initiated. 1 WARNING
2.5 THROTTLES Two throttle leversfor regulatingenginethrustareon the left console of the forward cockpit. Unrestricted engineoperationunder independentcontrol is afforded; however, normal symmetric thrust control is provided by collective movementof thethrottle levers.Numerous engine control and subsidiary functions are performed by movement of the throttle leverswithin the full range of travel as shown in Figure 2-19. The forward and aft throw of eachthrottle lever in the quadrantis restricted by harddetentsat the OFF, IDLE, MIL, andMAX (AB) positions.At the OFF andIDLE detents,the throttlesare springloadedto the inboardposition. At the MIL detent, the throttles canbe shifted outboardto the AB sectoror inboardto thebasicenginesectorofoperationby merely overcominga lateralbreakout force. Lateral shifting of the throttles at the MIL detent does not affect engine control. Thus, placementofthe throttleoutboardatMIL provides a natural catapult detent to prevent unintentional retardingof the throttles during the launch. This, however, doesnot inhibit the selection of afterburner. The friction control lever on the outboard side of the quadrantpermits adjustment of throttle friction to suit individual requirements.With the friction lever in the full aft position, no throttle friction is applied at the quadrant;increasedthrottle friction is obtainedby forward movementof the lever. A locking pin device preventsthe left throttle from moving into the cutoff position when the right throttle is eithertraversingor at reston thefaceofthe right-hand idle stopblock.
1
a Zero or negative-g flight longer than 10 secondsin AB or 20 secondsin MIL or lesswill depletethe fuel sump tanks(cells 3 and 4), resulting in flameout of both engines.
2.5.1 Throttle Control Modes. Manual, boost,and automatic are the three modes of throttle control over engineoperationselectableby the THROTTLE MODE switch located outboard of the quadranton the pilot console.The toggle switch must be IiRed out of a detent to select MAN from BOOST or BOOST from MAN. The switch is solenoid held in AUTO upon successful engagementof the automatic mode. A functional schematic of throttle control modes,including systemmajor components,is shown in Figure 2-20. Except for the autothrottle computer and mode control switch, the throttle control system for each engine is completely redundant.Independentengineoperationis possible in the manual or boost mode of throttle control; however, full systemoperationis necessaryinthe automaticmode sinceoperationunder single-enginecontrol is impracticablebecauseof asymmetric thrust considerations.
a To preventengineinstability and/orflameout, avoid holding zem or negativeg when doingalow-altitude,maximum-thrust acceleration. a With fuel in feed group below 1,000 pounds,AB operationcould result in AB blowout. Note Fuel dump operationswith either engine in AB are prohibited. The fuel dump mast can be torched.
2.5.1.1 Manual Throttle Mode. The manual throttle is a degradedmode ofoperation andwasdesignedas a backup system.Becauseof hysteresisand friction in themanualsystem,engine‘pm may vary from theboost 2-23
ORIGINAL
NAVAIR Ol-F14AAD.1
CORE
EXHAUST
CORE
EXHAUST
Figure 2-18. Afterburner Fuel Sequencing
ORIGINAL
2-24
NAVAIR Ol-Fl4AAD-1
Figure 2-19. Throttle Interlocks mode at a given throttle position. If an engine fails to securewhen the throttle is moved to the OFF position, the throttleshave probablyrevertedto themanual mode andareslightly out ofrig. Cycling the throttle switch to MAN andback to BOOST may allow engineshutdown. If shutdown is unsuccessful,then the engine may be securedwith the FUEL SHUTOFF handle.
l
Engine shutdown at high power settings using the FUEL SHUTOFF handle may resultin damageto theaircraftfue1system.
. Enginestartupin manualmodemay cause tailpipe fires as fuel flow may not be secured. In the manual mode of operation,movementof each throttle is mechanically transmitted to the respective engineby a push-pullcableanda rack andsectormechanism mounted to the main enginecontrol power lever shaft. An electric clutch in the throttle servoactuator, which is also mounted to the power lever shaft, is disengagedin the manualmode to reduceoperatingforces.
2-25
With thethrottle friction lever in OFF, approximately 8 poundsof forceper throttle must be appliedat thegrip to operatethe throttles in the IDLE to MAX range. 2.5.1.2 Boost Throttle Mode. The boost mode of throttle is usedfor normal operations.A force of 2 to 3 pounds at the grip is required to move each throttle throughoutits rangewith the throttle friction lever OFF. Essentially, the boost mode provides electric throttle operation,with the push-pullcablesservingasa backup control path.Throttle movementis detectedby thethrottle position sensor.The signalis resolvedin theamplifier to provide positional followup commandsto the actuator. Movement of the actuatorrotatesthe enginepower lever shaft, which drives the push-pull cable. If a boost system malfunctions, applying approximately 17poundsat the throttle grip automatically reverts the throttle control to the manual mode by disengagingthe actuator electric clutch. The throttle control revertsto manual mode in 0.25 second.In the eventof aboostsystemmalfunction, the throttle MODE switch will remain in the BOOST detent.By manually placing the throttle MODE switch in MAN and then backto BOOST, transientfailures in theboostmodecan bereset.Additionally, ifan actuatorseizes,amechanical clutch in the actuatorwill slip when a force of approximately 50 pounds is applied at the throttle grip. Thii ORIGINAL
NAVAIR Ol-FlUAD-
/ \
Figure Z-20. Throttle Control
ORIGIPIAL
2-26
NAVA1W Of-FluAD-
permits the pilot to override an actuatorseizure.There is no visible warning oftheseanomaliesonly thenoticeable increasein the forces required to manipulate the affectedthrottle. 2.6.1.3 Approach Power Compensator (Automatic Throttle Mode). The automaticmode of throttle control is a closed-loopsystem that automatically regulates basic engine thrust to maintain the aircraft at an optimum approachangleof attackfor landing.All componentsof the throttle control systemexceptthe throttle position sensorare usedin the automatic mode of control. The AOA signal Born the AOA probe on the left sideof the forward fuselageis the controlling parameter within theautothrottlecomputer.Additional parameters areintegratedwithin thecomputerto improve response. The air temperatureswitch on the pilot left consoleeffects a computer gain changeto compensatefor pilot prefermdreactionrate.In orderto engagethe autothmttle, throttlesmust be between7% to 90-percentrpm with weight off wheels,gearhandledown, andthrottletliction off. With all conditions met, the throttle MODE switch will be held by an electrical solenoid when placed in AUTO. The throttle control modeautomatically reverts to the boost mode upon interruptionof any interlock in the system or by manually overriding the throttleswith a force of approximately 11poundsper throttle in either direction. The throttle MODE switch automatically returns to BOOST and the AUTO THROT caution light illuminates for 10 seconds. See Figure 2-21 for autothrottlecontrols. The pilot canrevertfrom automaticto boostmodeby selecting the CAGE/BRST (UP) position on the CAGE/SEAM switch located on the inboard throttle grip. This provides a smooth throttle override for an automatic-to-boostmode approach,while maintaining a grip on both throttles. 2.5.1.3.1 Autothrottle Test. An automatic check of the autothrottlecontrol system while on deck is accomplished during OBC. Signals to the servoactuators areinhibited during theOBC autothrottletestso that the enginesremain at idle thrust.A malfunction is indicated by an APC acronym at the conclusionof OBC. Rotatingthe MASTER TEST switch to FLT GR DN and depressingit bypassesthe autothmttle weight-onwheels interlock and an end-to-end check of the autothrottlesmay be performed on deck. The throttles should be placed at about 80-percent ‘pm and the THROTTLE MODE switch placed in AUTO. The throttlesmust be positionedaboveidle before selecting AUTO to ensurea valid test. Once AUTO is engaged, the control stick should be programmedfore and aft to checkfor the appropriatepower response.
High-power settings may result during aft stick deflection. If the THROTTLE MODE switch doesnot remain engagedor the APC doesnot respondproperlyto indicatedAOA and longitudinal stick movements,a malfunction exists in the autotbmttle system. Depressingandholding the autopilotemergencydisengagepaddleswitch with weight on wheelscausesthe throttle control systemto be placedin the manualmode. If the automatic mode was selectedbefore depressing the paddleswitch, the THRO’lTLE MODE switch will automatically move to BOOST. The THROTTLE MODE switch must be moved from BOOST to MAN while holding thepaddleswitch depressedifthe manual mode is desiredat?erthepaddle switch is released.
Bleed air is extracted from the high-pressurecompressorto perform engine-associatedservices and to supply high pressureand temperatureair for operation ofauxiliaryequipment. Fifth-stagebleedairsupplieshot air for the engineanti-icing systemand is usedto draw cooling air throughthe aircrafi hydraulic heatexchangers to cool flight and combined fluids and to ventilate the nacelle when weight is on wheels (Figure 2-22). Ninth-stage bleed air supplies hot air to the environmental control system, provides air for crossbleedengine starts,and draws air through the integrateddrive generatorheat exchanger(ventral tin) when weight is on wheels. 26.1 Engine Anti-ice. The fan IGV and nosedome are susceptibleto icing under a wider rangeof conditions,particularlyat staticor low speedwith high engine rpm, than that which causeice to form on externalsurfacesof the airframe. Ice formation at the fan face can restrict engine maximum airflow, which results in a thrustloss,decreasedstall margin, anddislodgementof ice, which candamagethecompressor.The engineantiicing systemis designedto preventthe formation of ice ratherthandeice the IGV andnosedome.Hot bleedair (5th stage)is passedthroughthe hollow IGV to thenose dome and is dischargedinto the enginealong the vanes and at the rotor hub. Cockpit control of the engineantiicing system is effectedthrough the ANTI-ICE switch (Figure 2-23).
NAVAIR 01.Fl4AAD-1
A “.FS”“-911. Figure 2-21. Autothrottle ControlsandIndicators (Sheet 1 of 2) ORIGINAL
2-20
NAVAlR Ql-PIMAD-1
NOMENCLANRE
0,
MROlTLEMODEswltch
FUNCTION AUTO-
Ulglne th~st Is automaticallyregulatedto maintain optimum angle of attack for landing by the throttlecontrol Computer.
BOOST - Normal operatingmode. Reduces effortrequiredto move throttlesmanually with friction control aft. MAN -
02
0S
THROTTLETEMP switch
Movementof each throttleis mechanicallytransmittedto the respectiveengine cross-shaft by a push-pull cable.
Used with the AUTOthrottle mode to effect throttle computergain changesto compensatefor pllot preferredreactionrate. HOT -
Increasesnormalthrottle computergain.
NORM -
Normal throttlecomputergain.
COLD -
DecreasesnMmal throttle computergain.
AUTOTliROT caution llghf Auto throltle mode Is disengaged.Duringpreflightcheck, remainsilluminated for 10 seconds,thengoes off and throttlemode switch automaticallyreturnsto BOOST. Note Ifthe auto throttleIs disengagedby deselectingthe throttle MODE switch, the AUTO MROT light will not Illuminate.
@
0B
When lnTU4 mastermode with theTHROlTLE MODEswitch In AUTO,selecting the CAGE/SRSTposltlon on the CAGE/SEAMswitch revertsthe throtflesto ths BOOST mode.
CAGE/SEAM switch Autopilot emergency disengagepaddle
Revertsthrottlesystem from AUTO or BOOST mode to MAN mode only while depressedand with weight on wheels.
Figure 2-21. Autothrottle Controls andIndicators (Sheet2 of 2) dc No. 2 bus throughthe ENGD’ROBEIANTI-ICE circuit breaker(RG2).
Note Becauseof its adverseeffectson engineperformance, the engine anti-icing system should be.used only when icing conditions exist or areanticipated. During enginestart,theengineanti-ice valve remains opentobleedthecompressortopreventenginestaKThe valve closes when the engine approachesidle rpm. In flight, thevalve is normally closedunlessthe ANTI-ICE switch is in ORIDWON, or AUTO/OFF, when the ice detectorprobein the left inlet is activated.Ice accumulation on the ice detector illuminates the INLET ICE caution light. Tbe engineanti-icing control valve on the engineis poweredclosed (fails open)tirn the essential 2-29
2.6.2 Environmental Control System Leak Detection. Thermal detectioncircuits areroutedin proximity to ECS ducts and componentsto . provide __ cockpit . indications of high-temperatureau leaks. No& air temperaturesrangefrom 520to 1,180“F insidethebleed air portion of the ECS, and from 400” to 500 “F inside the hot air portion (400 “F manifold). The entirebleed air portion of the ECS, from engine bleed air shutoff valves to the primary heat exchanger, is monitored by two detection systems.Fii detection circuits monitor the bleed air system from eachengine to its respectivetirewall. When a fire detection circuit ORIGINAL
NAVAIR Ql-Fl4IUD-1
Figure 2-22. Engine Bleed Air/Compartment Ventilation in an engine compartment sensestemperaturesabove threshold, the appropriateL or R FIRE warning light illuminates (refer io fire detectionsystem).The remainder of the bleed air system,from enginefirewalls to the primary heatexchanger,is monitored by bleedair leaksensingelements.When thebleed air leak-detectioncircuit detects temperatures in excess of 575 “F, the BLEED DUCT caution light illuminates. The hot airportion ofthe ECS is monitoredby hot air leak-sensingelements.The hot air systemextendsfrom the primary heat exchangerthrough the 400” manifold to the cockpit floor. When the hot air detectioncircuit detectstemperaturesin excessof 255 OF,the BLEED DUCT caution light illuminates. 2.7 ENGINE COMPARTMENT VENTILATION Each engine compartment is completely isolated f?omtheprimary air inlet, andthe efficiency andcooling of the variable-areaexhaust nozzle are not dependent upon nacelle airflow. Therefore, within the boundsof the forward firewall (landing gear bulkhead) and the nozzle shroud,the cooling system for eachenginecompartment is a separateentity. Cooling requirementsfor the turbofan engine are minimized by the annular fan bypassduct. Figure 2-22 showscooling airflow patterns through the engine compartment during ground and flight operations.Two air-cooled heat exchangersare ORIGINAL
2-30
also shown;however,only thehydraulic heatexchanger cooling airflow is associatedwith enginenacellecooling. Fire accessdoors are on the outboard side of the nacelles at the forward end to permit insertion of fire suppressingagentsby groundpersonnelin event of an enginecompartmenttire. 2.7.1 Engine In-Flight Ventilation. In-flight cooling of the engine compartmentis accomplishedby nacelle ram-air scoops, circulating boundary-layer air throughthe length of the compartmentandexpelling the air overboardthroughlouveredexits,just fonvardofthe enginenozzle shroud. 2.7.2 Engine Ground Ventilation. With weight on wheels,cooling airflow throughthe enginecompartment is inducedby the hydraulic heatexchangerejectorin the forward end of the compartment.Air entersthroughthe nacellemm-air scoopon the left side,passesthroughthe hydraulicheatexchanger,andis dischargedinto theengine compartment.The air flows throughthe full lengthof the nacelle to dischargeoverboardthrougha louveredport atopthenacelleon theoutboardsideofthe verticaltail. 2.8 ENGINE IGNITION SYSTEM There are three electrical ignition circuits, eachutilizing a dedicated igniter, for each engine: main high energy,afterburner,and backup.
I I
EXT ENVIRONMENT
I
I
NOMENCLATURE
a
FUNCTION
,DRIDE/ON - Overrides ice detector system to turn on INLET ICE caution
ANTI-ICE switch
light, and acttvaie external probe heaters and engine anti-ice. Commands the anti-ice mode to the AICS programmers. AUTO/OFF - When icing is sensed, Ice detector activates engine anti-ice system and turns on INLET IcE cactlon light. External probe heaters activated with weight off wheels. Disables antl-ice mode to AICS programmers.
,OFF/OFF -
02 0
Engine anti-ice system and probe heaters shut off. INLET ICE caution light disabled. Disables anti-ice mode to AICS programmers.
INLET ICE caution light
IIlluminates when ice accumulates
BLEED DUCTcaution
Illuminates when bleed air leak sensing elements detect temperatures greater than 575°F between the left and right firewalls, past the primary heat exchanger and up to the right diverter area. An additional sensor, detecting temperatures of 255O or greater, senses from the right diverter area, along the 400” manifold and into the bootstrap turbine compartment.
on ice detector with ANTI-ICE switch in AUTO/OFF or if ORIDE/ON is selected. Does not illuminate with switch in OFF/OFF.
light
i
Figure 2-23. Anti-Ice Control 2-31
ORIGINAL
NAVAIR 01-Fl4AAD-1
2.8.1 Main High-Energy Ignition. The main highenergy ignition provides ignition in the combustion chamber for ground and air starts.It is poweredby one of the four windings in the engine-drivenac alternator. The AFTC provides logic to control main high-energy ignition automatically. Ignition is available when N2 rpm is 10 percent or greaterand is automatically provided from lo- to 59-percentrpm when the throttle is abovecutoff. Ignition is secured0.5 secondafterN2 ‘pm rises above 59 percent.At ‘pm above 59 percent,ignition is provided if Nz decelerationexceedsa 5 percent ‘pm per secondrate. Ignition continuesfor 20 seconds after N2 decelerationfalls below the 5 percent‘pm per secondrate.Main high-energyignition is providedcontinuously when the engine is in the secondary(SEC) mode. 2.8.2 Afterburner Ignition. The AB ignition provides ignition for AB light-offs, andrelights in the event of anAB blowout. It is poweredby the samewinding in the engine-drivenalternatorthatpowersthemain energy ignition. The AFTC provides logic to control AB ignition automatically andpreventssimultaneouspowering of the main high-energyand AB ignitions. In the event of an AB blowout, relight is normally provided within 1.5seconds.AB ignition is not poweredifthe engineis in SEC mode.
2.9.1 External Airstart. Ahigh-pressure(75psi)air sourceand 115 volt, 400 Hz ac power arerequired for enginestarton the deck. The air hoseis connectedto the aircraA fitting in the left sponsonarea,behind the main gear strut. Ground start air is ducted into a central bleed air (9th stage) manifold, which interconnectsthe air turbinestarterson both engines.The air supply to eachair turbine starter is pressureregulated (52.5 psi) and controlled by a shutoff andregulating valve at the turbine. Each pneumatic starteris composedof a turbine, geartrain, sprag clutch with a speed-sensingdevice, and an overspeed disengagementmechanismwith a shearsection.Shutoff valves in the bleed air manifold selectively isolate the other starter, subsidiary bleed lines, and the environmental control system air supply for effecting a start. Maximum engine motoring speedwith the pneumatic starteris approximately 30-percent‘pm.
2.8.3 Backup Ignition. The backup ignition providesignition in thecombustionchamberfor groundand air startswhen the BACK UP IGNITION switch on the THROTTLE CONTROL panel is set to ON. It is powered by the essentialNo. 1 ac bus and provides less power than main high-energy ignition. After use, the BACK UP IGNITION switch should be set to OFF. To allow ground checkout of backup ignition, main highenergyignition is disabled when the BACK UP IGNITION switch is ON and weight is on wheels.
2.9.2.1 Engine Crank Switch. The ENG CRANK switch is held in L or R by a holding coil. At approximately 50-percent ‘pm, a centrifugal cutoff switch closes the turbine shutoff valve and returns the ENG CRANK to the centeror off position. A START VALVE caution light illuminates if the startervalve remains in the openposition after the ENG CRANK switch automatically returnsto the center(on) position.
l
pii-1 The BACK UP IGNITION switch shall be selectedto OFF prior to applying external electrical power to prevent ignition of fuel puddled in the engine.
If the startervalve does not close during engineaccelerationto idle rpm, continued airflow through the air turbine starter could result in catastrophicfailure of the starterturbine.
a If the START VALVE caution light illuminates after the ENG CRANK switch is OFF, selectAIR SOURCE to OFF to preclude starteroverspeed.
2.9 ENGINE STARTING SYSTEM Each engineis providedwith anairturbine starterthat may bepressurizedfrom anexternalgroundstartingcart or by crossbleedinghigh-pressurebleed air from the other engine. Figure 2-24 shows the componentsassociated with the enginestart system.
ORIGINAL
2.9.2 Engine Crank. Placing the ENG CRANK switch in either L or R opensthe correspondingstarter pressureshutoff valve to allow pressurizedair to drive the turbine. The ENG CRANK switch, energizesthe appropnateshutoff valves to condition the bleed manifold for starting.
2-32
a If the ENG CRANK switch doesnot automatically return to the OFF position by 50 percent, ensure that the ENG CRANK switch is off by 60-percent‘pm to avoid starterturbine failure as a result of an inoperativeautomatic startercutout.
NAVAIR 01.F14AAD.1
Figure 2-24. Engine Start System
2-33
ORIGINAL
NAVAIR QW14AAD1
a When attempting a crossbleedor normal ground start, do not attempt to reengage the ENG CRANK switch if the engine is spooling down and ‘pm is greaterthan 46 percent. At rpm’s of 30- to 46-percent rpm, the ENG CRANK switch may not stay engaged becauseof normal variations in startercutout speed.
This action, in turn, resets the bleed air manifold valves to permit 9th-stagebleed air to flow to the environmental cooling system and ejectors in the engine compartment. Startercranking limits: 1. Crossbleed - 2 minutes continuous then 10 minutes OFF. 2. Start cart - 5 minutes continuous then 10 minutes OFF.
a The ENG CRANK switch should automatically disengagebetween 49- to approximately 51-percent rpm during a crossbleedor normal ground start.
2.9.3 Crossbleed Start. Engine crankingprocedures during a crossbleedstart are the sameas with a ground startcart. Engine crossbleedstart on the groundcan be accomplishedwith the throttle on the operatingengine at or aboveidle rpm. When high-residualEGT (remains from a hot start)and/orthrottlesare advancedfrom OFF to IDLE prior to 20-percentmm, higher than normal EGT readingsmay occur.
2.9.4 Airstarts. AFTC logic provides main highenergy ignition automatically during automatic and manual spooldown, crossbleed,and windmill airstarts. Selecting the BACKUP IGNITION switch to ONprovides continuousbackup ignition to both engines,and backs up main high-energy ignition during manual spooldown,crossbleed,and windmill airstarts.
When initiating crossbleedstartswith ambient temperaturelessthan 40 “F (4 “C), the startertorque load is increased.Above 80 “F (27 “C), engine bleed air provides less energypotential to the starterturbine. Either extreme can affect engine starting accelerationrates, resulting in hotter-than-normalstarts.When crossbleed starting with an operating engine at idle, the operator should be aware of either condition and increasethe operatingenginerpm in S-percentincrementsuntil normal startingaccelerationrate is achieved.Low percentage rpm-to-EGT ratio can increase turbine distress without necessarilyexceedingthe EGT limit. When performing an idle crossbleedstart, advance the throttles from OFF to IDLE at 20-percent‘pm or greaterwhile monitoring EGT. If EGT rises rapidly, advancethe operatingenginerpm to slightly aboveidle. The exhaustnozzles start to close when rpm is slightly aboveidle. Note To prevent possible engine overtemperature during crossbleedand backup ignition start attempts, select AIR SOURCE for the operating engine and return to BOTH after ‘pm stabilizes at idle or above.
Each engine has a self-contained, dry sump nonpressureregulatedoil systemthat providesfilteredoil for lubricating and cooling enginemain shall bearing,oil seals,gearboxes,accessories,and provides a hydraulic medium to operatethe engineexhaustnozzles(FO-5). A storagetank feedsoil to an oil pump that supplies oil under pressureto the forward sump in the engine front hub, the mid sump in the fan hub, the aft sump in the turbine hub, and the inlet and accessorygearboxes. Oil is recoveredthrough scavengingfrom the sumpsand accessorygearboxes,pumped past a chip detector,and cooled in a fueVoil heat exchangerbefore returning to the storagetank. A separatecompartmentin the storagetank provides oil to the exhaustnozzlehydraulic system.Oil returning from the nozzleto the tank providesauxiliary oil supply to the No. 3 bearingwhen normal supply is interrupted or during engine spooldown. The oil system permits engine operation under all flight conditions. During zero- or negative-gflight, oil pressuremay decreaseto zero but will return to normal whenpositive-g flight is resumed.Normal oil consumption is 0.03gallon per operatinghour with themaximum being 0.1 gallon per operatinghour. Capacity of the oil storagetank is 3.7 gallons, with 2.9 gallons usable. A sight gauge on the side of the storagetank indicates down to a 2-quart-low oil level. The protrusion of a bypassindicator underneaththe oil scavengepump indicatesa clogged filter element.
If attempting a ground restart after a hot stat, windmill the engine until EGT is below 250 ‘C prior to advancingthethrottle from OFF to IDLE to avoid a subsequenthot start. ORIGINAL
2.10 ENGINE OIL SYSTEM
2-34
NAVAIR
Note l
Engine oil level must be checkedwithin 30 minutes ofengine shutdown,otherwise nm engineat SO-percentrpm or greaterfor 10 minutes to ensureproper servicing.
l
A failed-opennozzle may indicate an oil leak; however, if the leak is in the nozzle hydraulic circuit, only that portion of the main enginelube oil will be lost.
2.11
Oil Cooling. Filtered and scavengedoil is cooledby a fuel/oil heatexchanger.This oil is thenused in a heat exchangerto cool the exhaust nozzle oil. A cold-oil bypassvalve opens when the heat exchanger pressuredifferential is 44 psi, becauseof reducedoil temperatureor exchangerblockage,allowing oil flow to bypassthe heat exchanger(for example, during cold enginestarts). 2.10.1
Oil Pressure Indicators. An oil pressure transmitter in each engine’s oil supply line provides a continuoussignal to the oil pressureindicator. Another, independentoil pressureswitch in eachoil supply line activatesthe OIL PRESS light when either engine’soil pressuredecreasesto 11 psi. The oil pressureswitches andlights receiveelectricalpower from the essentialNo. 2 acbus.The OIL PRESSlight andoil pressureindicator are independentof eachother.
2.10.2
Note l
l
ENGINE
014=14AAQ-1
INSTRUMENTS
Instruments for monitoring engine operationare on the pilot left kneepanel(Figure 2-25). Engineoperating parametersaredisplayedon theengineinstrumentgroup which is a single WRA with LCD readouts.The display provides white readoutsegmentsand scaleson a dark backgroundand is red backlighted for night operations. Left andright enginecompressorspeed(rpm),EGT, and FF are displayedon the EIG. Adjacent to the EIG are circular instrumentsfor both engine’s oil pressureand nozzleposition. Takeoff checksat military (MIL) thrust shoulddisplay evenly matchedtapeson corresponding vertical scaleinstrumentsandall pointerson thecircular instrumentsshould be at the 9-o’clock position. Data on engineoperatinglimits are provided in Chapter4. 2.11.1 Engine RPM Indicator. The RPM indicators (Figure 2-25) have a rangeof 0 to 110percent.The tapedisplay stepsin 5-percentincrementsandtheupper segmentflashesto indicate ‘pm increasingat more than 0.4 percentper secondfrom 0- 1060-percent‘pm. The tape steps in l-percent increments when greaterthan 60-percent‘pm. Nominal indications are 62 to 78 percent at idle and95 to 104percentat military andabove. At 107.7 percent and above, the affected engine(s) exceededportionsof the chevronswill flash at a rateof 2 to 3 flashespersecond.At 20-percentrpm a horizontal segmentwill illuminate giving an indication of proper motoring speedto start the engine. There is an rpm readingfor eachengine. Note
During cold starts, oil pressuremay exceed 6.5psi. The 65 psi oil pressurelimit should not be exceededfor more than 1 minute.
An overspeedcondition in excessof 110percent will result in momentary loss of rpm indication until Nz rpm falls below 110M.5 percent.EGT andFF indicatorswill continue to function normally.
Maneuversthat result in zero or negative g’s on the engine (such as rapid rolls, pushovers, or bugout maneuvers) may cause oil pressure fluctuations and momentary illumination of the low oilpressure light.
2.11.2
OIL HOT Caution Lights. The L or R OIL HOT caution light may be illuminated by either high engineoil temperatureor by high forward-enginegearbox scavengeoil temperature.The caution lights illuminate when respective engine oil temperatureexceeds 300 “F during a temperature increase and go out at 280 “F minimum during a temperaturedecrease.The caution lights also illuminate when respectivefonvard engine gearboxscavengetemperatureexceeds375 “F during a temperatureincrease,and go out at 345 “F minimum during a temperaturedecrease.
2.10.3
2-35
Exhaust
Gas Temperature
Indicator.
The
EGT indicators(Figure 2-25)provide a nonlinearvertical scalewith a rangeof 0 to 1,100“C. The compressed lower portion hasa rangeof 0 to 600 “C. The expanded upper portion of the scale has a rangeof 600 to 1,100 “C. The display moves in 50” increments in the compressedportion and 10” increments in the expanded portion of the display.Tbe normal indicationsare350 to 650 “C at idle and 780 to 935 OCat MIL and above. Above 940 “C, the affectedengine(s)exceededportions ofthe chevronsflash. With a readingof 940 “C, the stall warning light and the aural warning tone will be activated signifying an engine overtemperaturecondition. The toneis presentfor a maximum of 10secondsunless the fault clearssooner.There is an EGT readingfor each engine. ORIGINAL
NAVAIR 0%F14AAD-1
Figure 2-25. Engine Instruments(Fl IO-GE-400) ORIGINAL
2.36
NAVAIR 01.Fl4AAD-1
2.11.3 Fuel Flow indicator. TheFFindicatorshave a nonlinear vertical scale, with a rangeof 0 to 17,000 pph.The expandedlower portion ofthe scalehasa range of 0 to 5,000pph. The compressedupperportion of the scale ranges from 5,000 to 17,000 pph. The display moves in 100 pph incrementsin the expandedportion and in 500pph incrementsin the compressedportion of the display. Normal indications on deck are 350 pph starting, 950 to 1,400 pph at idle, and approximately 10,100pph at military andabove.The fuel flow reading for eachengineindicatesonly basicengineconsumption and doesnot indicate AB fuel flow.
2.11.7 Exhaust Nozzle Position indicator. The nozzleposition indicators(Figure 2-25)havea rangeof 0- to loo-percent open. Normal indications (Figure 213)are 100percentat idle with WOW andvary in flight: 3 to 10 percent at MIL thrust, 5 to 12 percentat MM AB, and 60 to 90 percentat MAX AB.
2.11.4 Engine instrument Group BIT. A degraded modeof EIG operationis indicated if the BIT segment onthetopleftsideoftheEGTindicatorilluminates. This means that either the primary or backup microprocessors, or the primary or backup power supply channels (internal to the EIG), have failed. An automatic switch to the operativemicropmcessorf takesplace if a failure is detected.The instrumentstill monitors engine operationand accuratelyreflects rpm, EGT, and FF. If the input processingcircuit fails, the affectedscalereading goesto zero.
2.11.6 Engine Monitor Display Format A display of engineparameters(Figure 2-26) canbe selectedon the MFD by pressing the pushbutton adjacent to the ENG legend on the own-aircraft menu. The display presentsNl (fan speed),TBT (turbine blade temperature), FF/M (fuel flow main engine)or FFfC (fuel flow total, main engine and AB), and NP (exhaustnozzle position). FF/h4 scale indicates main engine fuel flow and is similar to the fuel flow displayedon the EIG. NP is the sameas the nozzleposition indicators.Numerical readoutsbelow theNI and TBT vertical scalesdigitize the indicatedvalue. The TIME readoutbelow the FF/M vertical scale indicates time in hours and minutes that fuel will last based on current consumption rates.Directly below the TIME readout,engine faults are displayedbasedon current engineoperatingconditions of both enginesprocessedby FEMS. If more than three faults exist at the sametime, the acronymswill continuously scroll upward. The ten possible acronyms and their definitions are:
2.11.5 Engine instrument Group Self-Test. EIG self-test is selectedby the MASTER TEST switch in INST. Whenmastertestis selected,all display segments illuminate, scales drive to maximum readings, and warningchevrons(stripes)flash for 5 seconds.BIT seg ment on the top left side of EGT indicator illuminates. L andR STALL warning acronymsappearon the HUD andMFD and stall warning/overtemptone is presentin pilot earphonesfor 10seconds.After 5 seconds,all EIG scalesdecreaseto predeterminedvalues of equal height that correspondto an EGT reading of 950 +lO “C. If BIT segmentremains illuminated, EIG has failed self. test and BIT remains illuminated until self-test is reinitiated. Total self-test time is 15 seconds.If mastertest is deactivatedprior to this, EIG returnsto normal mode after the 15-secondtest.If the MASTER TEST switch rernainsinINSTformorethanl5seconds,theEIGretains equalheightreadingsuntil mastertestis deselected. 2.11.6 Engine Oil Pressure indicator. The engine oil pressureindicatorsdisplay oil pressurefrom 0 to 100 psi. Normal oil pressureis 25 to 6.5psi and increasesin proportionto enginerpm within thepressurelimit range. Stabilizedidle oil pressuremay be a minimum of 15psi. The OIL PRESS caution light illuminates at 11psi with decreasingoil pressureand extinguishesat 14 psi with increasingoil pressure. Maximum allowable oil pressurefluctuation is *5 psi.
2-37
Note When operating engine in SEC mode, the nozzle position indicator is inoperativeand indicatesbelow zero.No nozzle position indication is available in SEC mode.
1. L MACH # or R MACH # - Mach number signal to designatedenginehas failed. 2. L LO THR or R LO THR - Designatedengine may be producing less than expectedthrust. 3. L A/ICE or R A/ICE - Designated engine anti-ice is on or anti-ice valve has failed opposite commandedposition. 4. L OIL LO or R OIL LO - Designatedengineoil level is approximately two quartslow. Postflight, engineat idle. 5. L AUG or R AUG - DesignatedAB control systemhas failed. AB is not available. Refer to Chapter 12, WARNING/CAUTION/ ADVISORY LIGHTS/DISPLAY LEGENDS for the appropriatepilot/RIO response.
ORIGINAL
NAVAIR gl-Fl4AAD-1
Figure 2-26. MFD Engine Monitor Display 2.11.9 MFD Engine Caution Legends. In addition to the engine caution lights on the pilot CAUTION/ ADVISORY panel, illumination of the READ MFD caution light indicatesthat one or more of the following caution legendson the upper left quadrantof the MFD is activated: 1. L N2 OSP or R N2 OSP N2 overspeedcondition.
Designatedengine
2. L Nl OSP or R NI OSP NI overspeedcondition.
Designatedengine
3. L TBT OT or R TBT OT - Designatedengine turbine bladeovertemperature. 4. L FLMOUT or R FLMOUT engine flameout.
-
Designated
5. L IGV SD or R IGV SD - Designatedengine inlet guide vaneoff schedule. 6. L STALL or R STALL - Designated engine stall detected(also on HUD). 7. L FIRE or R FIRE - Designated engine fire/ overheat condition in engine nacelle (also on HW.
ORIGINAL
2-30
Refer to Chapter 12, WARNING/CAUTION/ ADVISORY LIGHTS/DISPLAY LEGENDS for the appropriatepilot/RIO response. 2.11.10 Engine StalllOvertemperature Waming. An enginestall detectioncircuit in FEMS monitors eachengine.When a stall condition is detected,a L or R STALL warning legendis displayedon the HUD and MFD until the condition is cleared.In addition, an aural warning tone is activatedthroughthe pilot ICS for up to 10 seconds.There is no pilot check ofthe FEMS engine stall detectionsystem. Note In SEC mode, FEMS and, therefore,the engine stall detection circuit, is inoperative. However, overtemperaturewarning is still available and will activateboth the STALL warning legendsand aural warning tone. When an overtemperaturecondition occurs,the EGT display risesabove940 “C, the warning chevronsbegin to flash, and a signal from the EGT indicator activates the STALL warning legend and the aural tone. The overtemperaturewarning systemis checkedby the pilot during prestartaspart of the MASTER TEST check in INST test.
NAVAIR 0%F14AAD-1
2.12 FIRE DETECTION SYSTEM The fire detection systemprovides a cockpit indication of fue or overheatingin eitherenginecompartment. Thereis a separatesystemfor eachenginecompartment, eachconsisting of a thermistor-typesensingloop moaitoed by a transistorized control unit. The system is powered by 28 volts from the essentialdc No. 1 bus. Figure 2-27 is a functional schematicof the system. The sensingloop for eachenginecompartmentconsists of a 45foot continuous tubular element routed throughoutthe entire length of the enginecompartment onboth sidesabovethe nacelledoorhingeline. The tube sheath,which is clamped in grommets to the engine compartment structure, contains a ceramic-like thermistor material in which are embeddedtwo electrical conductors;one of the conductorsis groundedat both endsof the loop. Electrical resistancebetweentwo conductorsvariesinverselyas a function of temperatureand length, so that heating of less than the full length will require a higher temperaturefor the resistanceto decreaseto the alarm point. The L or R FIRE warning lights in the cockpit illuminate when the respectiveeatire sensingloop is heatedto approximatel; 600 “F or when any 6-inch section is heated to approximately 1,000“F.
The tire alarm output relay to the light is a latching type that remains in the last energizedposition in& pendentof power interruptionsuntil the fault clears. False alarms triggered by moisture.in the sensing elementand co~ectors or by damageresulting in short circuits or groundsin the sensingelement are unlikely becauseof the system design.Additionally, thereis no loss or impairment of fire detector capability from a singlebreakin the sensingelementas long asthereis no electricalshort.With two breaksin the sensingelement, the section between the breaks becomes inactive althoughthe remaining segmentendsremain active. Fire detection circuits in the engine compartments detecta leak in thehigh-temperatureduct andilluminate the appropriateFIRE warning light and activate the L FIRE or R FIRE warning legendon theMFD andHUD. The warning legendis a repeatof a discretefrom the tire detectsystem. 2.12.1 Fire Detection Test. An integrity test ofthe tire detectionsystem can be performed by selectionof FIRE DETiEXT on the pilot MASTER TEST switch. The integrity testsimultaieously checksthesensingele ment loops of both enginecompartmentsfor continuity
WUDANDMFD WARNING LEOENDS~
SHORT
TEST
THERnilSTOR
Figure 2-27. Fire Detection System 2-39
ORIGINAL
NAVAIR 01-Fl4AAD-1
FJRE EXT and AUX FIRE EXT, illuminate when containerpressuredrops 90 psi below a nominal pressureof 600psi at 70 OF (seeFigure 2-28).
and freedom from short circuits, andthe fire alarm circuits and FIRE warning lights for proper functioning. Presenceof a short circuit or control unit maltiction causesthe warning light to remain out. Fii detection test is not available on the emergencygenerator. 2.13 FIRE EXTINGUISHING SYSTEM The fa extinguishingsystemis capableof discharging an extinguishingagentinto eitherenginenacelleand its accessorysection.The system consistsof two containers of extinguishing agent, piping and nozzles to route and dischargethe agent,cockpit switchesto activate.the system,andadvisory lights that alert the flightcrew to a drop in system pressurebeyond a predetermined level. The fue extinguishing agent is a clean, colorless, odorless, and electrically nonconductive gas. It is a low-toxicity vaporthatchemically stopsthe combustion process.It will not damageequipmentbecauseit leaves no water, foam, powder,or other residue. The retention time of an adequateconcentrationof the extinguishing agentin the enginecompartmentwill determineprobability of reignition, and, therefore,the probability of aircraft survival. At high airspeeds, where airflow through the engine compartment is increased,agentretentiontime is reduced. The slower the airspeedat the time the extinguisher is fued, the higher the probability of fire extinction and the lower the probability of reignition. Circuit breaker protection is provided on the RIO essentialNo. 1 circuit breakerpanelby theR FIRE EXT cf7ircuit breakerand the L FIRE EXT (7C5) circuit 2.13.1 Fire Extinguisher Pushbuttons. The dischargepushbuttonsfor the tire extinguishingsystemare located behind the FUEL SHUT OFF handles. The FUEL SHUT OFF handlefor the at&ted enginemust be pulled to make the pushbutton for that engine accessible (see Figure 2-28). If the letI or right fm extinguishing pushbutton is activated, the contents of both extinguishing containersare dischargedinto the selectedengine and its accessorysection. Since it is a one-shot system, both system advisory lights, ENG FIRE EXT and AUX FIRE EXT, will illuminate and remain illuminated after containerpressuresdrop below a presetlevel. 2.13.2 Fire Extinguisher Advisory Lights. tie advkoty lights areprovided to indicate low pressurein the fire extinguishingagentcontainers.The lights, ENG ORIGINAL
240
2.13.3 Fire Extinguisher Test. The fue extinguishingsystemistestedbyraisingandmtatingtheMASTER TEST switch to FIRE DETiEXT and depressingthe knob the FIRE warning lights will illuminate. The fm extinguishing system initiates a self-test indicated by eithera GO or NO GO light. If the fm extinguishertest passes,the GO light illuminates; if the NO GO light illuminates or if both or neither GO andNO GO lights illuminate, the system has not tested properly and a failure exists somewherein the system. 2.14 AIRCRAFT FUEL SYSTEM The aircraft fuel system normally operatesas a split feedsystem,with the let3andaft tanks feedingto the left engineandthe right and forward tanks feedingtheright engine(referto FO-6). Except for the externaltanks,the systemusesmotive flow fuel to transferfuel. The supply of high-pressurefnel fk3m engine-drivenmotive fuel pumpsoperateslkel ejectorpumpsto transferfuel without the needof moving parts. The system is not dependent on eleztrical power for normal fuel transferand feed. Total internal and external fuel quantity indication is provided,with a selectivequantityreadoutfor individual tanks.Fuel systemmanagementrequirementsare minimal under,normaloperationfor feed,tmnsfer, dumping, and refueling. Sutlicient cockpit control is provided to managethe systemunderfailure conditions.The aircrafi fuel systemis designedso that all usable fuel will normally be depletedunder two- or single-engineoperating conditions before an engine flameout occurs from tie1 starvation. However, with complete motive flow failure, enginefuel starvationcanoccur with usablefuel aboard. Note All fuel weights in this manual arebasedon the useof JF-5 fuel at 6.8 poundsper gallon, JP-4 tieI at 6.5 pounds per gallon, or m-8 fuel at 6.7 poundsper gallon. 2.14.1 Fuel Tankage. Figure 2-29 shows the general tkel tankagearrangementin the aircraft. The fuel supply is stored in eight separate.fuselage cells, two wing box cells, two integral wing cells, and (optional loading) two external foe1tanks. 2.14.1.1 Sump Tanks. The engine feed group, consisting of the left and right box-beam tanks and the left andright sump tanks,spanthe fuselageslightly forward ofthemid-ce.nterofgravity,Fuelineachbox-beamtank gravity flows to its respective sump tank. The sump
NAVAIR Ol-FlrlAAD-1
Figure 2-28. Fire Extinguishing Switchesand Advisory Lights
FUEL PERSPECTIV FUEL DUMP MAST WJx AFT FUSELAGE
O-FSOD-,
Figure 2-29. Fuel Tanks 2-41
ORIGINAL
NAVAIR 01-F14AAD-1
andthe extensivespan(20 feet)of thewing tanks,wing fuel loading provides a variable aft cg contribution to the aircraft longitudinal balanceas a function of wingsweep angle. Each wing panel consists of the integral fuel cell, which is designedto withstand loads because of fuel sloshing during catapulting and extremerolling maneuverswith partial or full wing fuel. Fuel system plumbing (transfer and refuel, motive flow, and vent lines) to the wing tanks incorporatetelescopingsealed joints at the pivot areato provide normal operationindependentof wing-sweep position.
tanks (self-sealing) are directly connectedto the boxbeamtanksandcontainthe turbine-drivenboostpumps. The feed tanks supply fuel to the engine. A negative-g checkvalve trapsfuel in the feedtank during negative-g flight.
. Zero- or negative-gflight longer than 10 secondsin AB or 20 secondsin MIL or lesswill depletethe fuel sump tanks (cell Nos. 3 and 4). resulting in flameout of both engines. l
2.14.1.5 External Tanks. Fuel, air,electrical,andfuel precheckline connectorsare under the enginenacelles for the externalcarriageof two fuel tanks.Check valves in the connectorsprovide anautomaticsealwith thetank removed.Although the location is designatedas armament stationNos. 2 and 7, no other store is designedto be suspendedthereso that the carriageof externalfuel tanks does not limit the weapon-loadingcapability of the aircraft. Suspensionof the drop tanks and their fuel contenthasan insignificant effect on the aircraft longitudinalcenterof gravity,and,evenunderthemostadverse asymmetricfuel condition,theresultantmovementcanbe compensatedfor by lateral trimming.
AB operationin the zeroto negativeOSg regime may result in air ingestioninto the fuel boost pumps, causing possible Al3 blowout or engineflameout.
. With fuel in feed group below 1,000 pounds,AI3 operationcould result in AB blowout. Note AB operationwith lessthan 1,000poundsin either feed group may illuminate the FUEL PRESS light becauseof uncovering of the boost pump inlet.
SeeChapter4 for externaltank limitations.
2.14.1.2 Forward Tank. The forward fuselage fuel tank is in the centerfuselage,betweenthe inlet ductsand immediately aheadofthe feedgroup. The forward tank is partitioned into two bladder cells (Nos. 1 and 2) that are interconnectedby openports at the top for vent and overflow purposes.Flapper valves at the baseprovide for forward-to-aft fuel gravity transfer.
2.14.2 Fuel Quantity System. The fuel-quantity measurementand indication systemprovidesthe flightcrew with a continuous indication of total internal and external fuel remaining, a selectivereadoutfor all fuel tanks, independentlow-fuel detection, and automatic fuel systemcontrol features.
2.14.1.3 Aft Tank. The aft fuselagefuel tank groupis partitioned into four bladder cells @Jos.5, 6, 7, and 8) and a vent tank. The forward-most cell in the aft tank group (cell No. 5) lays laterally acrossthe center fuselage.Extending aft aretwo coffin-shapedtanksthatcontain two cells (Nos. 6 and 8) on the right side and one cell (No. 7) plus an integral fuel vent tank on the left side. The coffin tanks straddle the centertrough area, which contains the control rods. Sparrow missile launchers,and electrical and fluid power lines. All fuel cells in theaft tankgroup areinterconnectedbyone-way flapper valves at the basefor aft-to-forward fuel gravity transfer. 2.14.1.4 Wing Tanks. There ,areintegral fuel cells in the movable wing panels between the front and aft wing spars.Becauseof the wing-sweep pivot location ORIGINAL
2-42
piikETo preventfuel spills from an overlilledvent tank causedby a failed level-control system, set the WINCVEXT TRANS switch to OFF if the left tapereadingreaches6,200pounds or theright tapereadingreaches6,600pounds. If either fuel tape reading is exceeded,the aircraft shall be downed for maintenance inspection. Note Fuel in the vent tank is not gauged.
NAVAIR Ol-F14AAD-1
Thequantitymeasurementsystemusesdual-element, capacitance-typefuel probesto provide the flightcrew with a continuous display of fuel quantity remaining. Fuel thermistor devicesand caution light displays provide a backup FUEL LOW level-indicating system, independent of the capacitance-type gauging system. Additionally, the pilot is provided with a BINGO set capability on the fuel quantity indicator to preset the total quantity level for activation of a BINGO caution light. Note Fuel quantity systemmalfunctionsthat result in erroneoustotalizer readings will invalidate the useof the BINGO caution light. 2.14.2.1 Fuel Quantity Indicators. The pilot and RIO fuel quantity indicators are shown in Figure 2-30 with a definitive breakdownof tape and counter readings.The white vertical tapeson thepilot indicator show fuselagefuel quantity.The let?tapeindicatesfuel quantity in the let? feedand aft fuselage;the right tape indicatesfuel quantity in theright feedandforward fuselage. The “L” and “R” labeled countersdisplay either feed group,wing tank, or externaltank fuel quantity on the side selectedusing the QTY SEL rocker switch on the fuel managementpanel, The rocker switch is spring loadedto FEED. The pilot TOTAL quantity display and the RIO display indicate total internal andexternal fuel. Note The RIO fuel quantity indicator is a repeater of the pilot total fuel indicator. The differencebetweenthe two shouldnot exceed300 pounds. 2.14.2.2 FUEL LOW Caution Lights. AL FUEL LOW or R FUEL LOW caution light illuminates with 1,000i200 poundsof fuel remaining in the respective feed group. The RIO is provided with a single FUEL LOW caution light that illuminates with one or both of the pilot FUEL LOW caution lights. EachFUEL LOW caution light is illuminated by two thermistorsoperatingin series.One set of thermistorsis in the right box-beamtank and cell No. 2. The other set of thermistors is in the left box-beamtank and cell No. 5. The FUEL LOW light illuminates only if both thermistors operatingin seriesare uncovered.
If the thermistors in either cell No. 2 or No. 5 remain coveredduring a fuel transfer failure, it is possibletopartially deplete the sump tank without illuminating the respectiveFUEL LOW caution light. When both FUEL LOW cautionlights illuminate, less than 1 minute of fuel is available if both enginesare operatingin zonefive AB. If the BINGO CAUTION circuit breaker (8F6) is pulled, the L and R FUEL LOW caution lights will be disabled. 2.14.2.3 Fuel Quantity Indication Test. Actuation of the mastertest switch in INST causesthe fuselage tapesand total and feed/wing/externalfuel quantity indicators to drive to 2,000 pounds and illuminates the FUEL LOW caution lights. The test can be performed on the ground or in flight. The test does not check the fuel probesor the thermistors.A test of the BINGO set devicecan be obtainedconcurrentlywith the INST test by settingtheBINGO level at greaterthan2,OOOpounds. In this case, the BINGO caution light will illuminate when the totalizer readingdecreasesto a value lessthan the BMGO setting. 2.14.3 Engine Feed. The feedgroupforeachengine is comprisedof a box-beamtank and a sump tank. Each box-beam tank holds approximately 1,300 pounds of fuel andis fed from externaltank transfer,wing transfer, and fuselagetransfer from cell No. 2 or 5. When a box-beam tank is full, excess fuel is returned to the fuselage tanks through an overflow pipe. The sump tanks, which hold approximately 300 pounds of fuel each, are locateddirectly beneaththe box-beamtanks and havethreesourcesof fuel (seeFigure 2-31 for identification of tank interconnects): 1. InterconnectA or B provides gravity sump from the respectivebox-beamtank. 2. InterconnectC or D connectsthe sump tank to its respectivefuselagetank (cell No. 4 to cell No. 2/ cell No. 3 to cell No. 5). 3. The sump tank interconnectline and valve E connect the two sump tanks.
2-43
ORIGINAL
NAVAIR Ol-F14AAD1
Figure 2-30. Fuel Controlsand Indicators(Sheet 1 of 3)
ORIGINAL
2-44
NAVAIR
NOMENCLATURE 0
0
0
WING -
QTY SEL switch
FEED switch
WlNG/EXl TRANS switch
FUNCTION Fuel quantity in each wing Is displayed pilot’s fuel quantity Indicator.
ill-Fl4AAD.1
on Land R counter of
FEED -
Rocker switch spring returns to FEED when not held in WING or EXT. FEED group fuel quantity displayed on L and R counter of pilot’s fuel quantity indicator.
MT-
Fuel quantity in each external tank displayed counter of pilot’s fuel quantity Indicator.
FWD-
Both engines feed from right and forward tanks. Opens sump tank interconnect valve, box beam vent valves, fuselage motive flow Isolation valve, defuellng and transfer selector valve, and shuts off motive flow fuel to all afl tank ejector pumps.
NORM (guarded position)
Right engine feeds from forward and right tanks. Left engine feeds from aft and left tanks.
AFT-
Both engines feed from aft and left tanks. Opens sump tank Interconnect valve, box beam vent valves, fuselage motive flow Isolation valve, defueling and transfer selector valves, and shuts off motive flow fuel to forward tank ejector pumps.
DRIDE -
Airborne - Allows transfer of wing fuel, fuselage tank
on Land R
pressurization, and pressurization and transfer of external tanks will landing gear down, and with electrical malfunction In transfer System. Weight on Wheels -Allows transfer of wing and external tank fuel. AUTO -
A&borne - Normal position. Wing fuel Is automatically transfened. Transfer of external fuel and fuselage pressurization Is automatic with landing gear retracted. Automatic shut off of Wing and edema\ tanks when empty.WelgM on Wheels -Automatic transfer of wing and external tank fuel cannot be accomplished; switch must be set to OAIDE for wing fuel transfer.
OFF -
Closes solenoid operated valve to shut off motive flow fuel to wing and also inhibits external tank transfer and fuselage pressurization. Spring return to AUTO when master test switch Is actuated in INST. and when either thermistor in cell 2 and 5 is uncovered, when DUMP Is selected, and when REFUEL PROBE switch is In ALL MTD.
Illuminates whenever probe cavity forward door Is open during retraction or extension of probe. OFF -
Dump valve closed.
DUMP -
Opens a solenoid operated pilot valve, which ports motlve flow fuel pressure to open the dump valve and allows gravity fuel dump overboard from cells 2 and 5. Wing and external tank transfer automatically Initlated. Dump electrically inhibited with weight on wheels or speed brakes not fully retracted.
Figure 2-30. Fuel Controlsand Indicators (Sheet2 of 3)
2-45
ORIGINAL
NAVAIR
01.Fl4AAD1
NOMENCLATURE @
FUNCTION
REFUEL PROBE switch
ALL DCTD -
Extends refueling probe. Shuts off wing and external tank fuel transfer to permit refueling of all tanks. Returns transfer switch from OFF to AUTO.
FUS EXTD - Extends refueling probe. Normal transfer and feed. Used for practice piugins, fuselage-only refueling, or flight with damaged wing tank. RET-
0
09 @
010
Retracts refueling probe.
Left and right FUEL SHUT OFF PULL handles
Pulling respective handle manually shuts off fuel to that engine. Push forward resets englne fuel feed shutoff valve to open.
L and R FUEL LOW caution lights (Also single light on RIO CAUTION panel.)
Fuel thermistors uncovered in aft and left or forward and right feed group. iliuminates with approximately 1 ,ooO pounds remaining in individual feed group and the respective fuselage tanks empty.
BINGO caution light
iiiuminates when total fuel quantity indicator reads lower than BINGO counter value.
Land R FUEL PRESS caution lights
indicates insufficient discharge pressure (less than 9 psi) from respective turbine driver boost pump.
Figure 2-30. Fuel Controls and Indicators (Sheet 3 of 3) The proportion of fuel supplied to each sump tank through the five interconnects(A through E) is a function of the pressuredifferential existing at eachof the interconnects.The interconnectwith the highest pressuredifferential will provide the most fuel. Valve E is commandedopenduring low-fuel statesandduring fuel balancing when the FEED switch is selectedFWD or AFT.
interconnectC or D by the fuel in either cell No. 2 or 5. Therefore, fuel to replenish the sump tanks will come from the box-beamtanksthroughinterconnects A and B. 2. Situation 2 a. Fuel in cell Nos. 2 and 5
In a normal sequence,threesituationscan be defined
b. FEED switch in NORM
1. Situation 1
c. High-engine fuel demands(afterburner).
a. Fuel in cell Nos. 2 and 5 b. FEED switch in NORMAL c. Normal engine fuel flow (MIL thrust or less). Under theseconditions, the sump tank interconnect valve is closed, and the left and right systems are isolated. The transfer capacity into the box-beam tank exceedsthe enginedemand,ensuringa full boxbeam tank. The pressureheadat interconnectA or B createdby the higher vertical location of the fuel in the box-beam tank, is greater than that createdat ORIGINAL
2-46
Under theseconditions the sump tank interconnect valve is closed and the left and right systems are isolated.Engine fuel demandcanexceedthe transfer rate into the box-beam tank. If this occurs, the fuel level in thebox-beamtankwill startto drop; however the box-beam tanks are not vented, resulting in a pressuredrop above the declining fuel level. This reducedpressurelowers the total pressureat A and B, below the pressureat C and D. Therefore, the majorityofthe fuel to replenishthesump tankscomes directly from fuselagecell Nos. 2 and 5 through interconnectsC and D, respectively.The reduction in box-beam tank fuel quantity should not normally
NAVAIR Ol-F14AAD.1
Figure 2-3 1. Engine Fuel Feed
2-47
NAVAIR
01-Fl4AAD-1
result in a feed groupquantity indication of lessthan 1,200pounds.If the feed groupsdrop and then hold in the 1,200-poundrangeduring a high-speeddash, the system is working normally. 3. Situation 3 a. Fuel in either cell No. 2 or 5 hasbeendepleted. b. FEED switch in NORM.
fore a fuel quantity imbalance will result. Use of the FEED switch to balancefuel quantity will override the low-fuel pressuresignal to the fuselage motive flow shutoff valve, allowing normal fuel balancing procedures.Illumination ofboth FUEL PRESS cautionlights indicates reduced(~9 psi) or loss of boostedfuel pressure to both engines.Fuel will continue to be supplied by suctionfeed;however,thrustsettingsshouldbe minimized and AB usedonly in emergencies.Suction feed is drawn from an inlet at thebottom of the fuel cell that doesnot incorporatea flexible pendulum pickup.
c. Any normal engine demand. When the low-level thermistor in either cell No. 2 or 5 is uncovered,both box-beam tanks arevented and the sump tank interconnectvalve is opened.The two groups become a common system and will seek a common level to equalize the static pressurehead. Fuel will flow throughthe open sump tank interconnect valve only as a function of differential pressure. With open vent valves, the fuel in both box-beam tanks has a positive vent pressure,forcing the fuel into the respectivesump tank throughinterconnectA or B. Fuel in the sump tank is picked up by the turbinedriven boostpump througha flexible pendulumpickup, boosted to greaterthan 10 psi, and fed to the engine through the enginefeed line. Normally the right boost pump only feedstheright engineandtheleft boostpump only feeds the left engine; however, the boost pump output lines are connectedby a normally closedengine automatic crossfeedvalve. If either boost pump output pressurefalls below 9 psi, as indicatedby the illumination of the appropriateFUEL PRESS caution light, the engineautomatic crossfeedvalve is commandedopen. The engineautomalic crossfeedvalve allows fuel from the operatingboost pump to supply pressurizedfuel to the engine on the failed side. The engine automatic crossfeedvalve is also openedwhen either of the Iowlevel thermistors in cell No. 2 or 5 is uncovered;howeverif equalboostpump pressuresexist, negligible flow will occur throughthe valve. 2.14.3.1
L/R FUEL PRESS Caution
Lights.
With both FUEL PRESS caution lights illuminated, thereis a potentialthat total lossof motive flow pressure has occurredbecauseof both motive flow pumps not functioning. Total loss ofmotive flow pressurewill preclude tmnsfcr of any remaining wing fuel or fuel dump and result in total segregationof the FWDMGHT and AFT/LEFT systems since motive flow provides the force to openthe sump tank interconnectvalve. Without motive flow pressure,all fuselage fuel transfer is by gravity, which makesthe quantity of usablefuel a functionofaircraftattitude. Atcruiseattitude,appmximateIy 400 pounds of usable fuel will be trapped in the afl fuselage. After illumination of both fuel pressurecaution lights, any of the following events indicate that some motive flow pressureis available: 1. Wing fuel transfer 2. With the FEED switch in FWD or AFT and no transferof external fuel a. The feed group of the selectedside remains full. b. Fuel migration from one side to the other.
IlIumi-
nation of the L or R FUEL PRESS caution light results from a malfunction of the boost pump, failure of the motive flow pump, exhaustionof fuel, or fuel flow interruption. With illumination of the caution light, the engine automatic crossfeedvalve is commandedopen andthe fuselagemotive flow shutoff valve on the failed side is automatically closed. Because of the reduced pumping andtransfercapacity while operatingon a single boost pump, afterburneroperation is restricted to altitudesbelow 15,000feet.Fuel to both enginesis supplied from the sidewith the operatingboostpump; thereORIGINAL
With a left or right FUEL PRESS light, flight at zero or negative g should be avoided or enginefuel starvationmay result.
2-48
2.14.3.2 Engine Fuel Feed During Afterburner Operations. High Al3 fuel consumptionplacesextreme
demandson the engine feed system. In addition, the g forces experiencedwith AB use,especially during URloaded accelerations (bugouts) and low-g nose-high maneuvering,tend to reduceforward fuel transferto cell No. 5 and the left enginesump tank (cell No.3). When theseconditions are sustained,fuel in cell No. 5 is depleted by both high suction feed through the gravity transfer line (C, Figure 2-32), and by reducing gravity
NAVAIR 0%F14AAD-1
Figure 2-32. Aft FuselageFuel Transfer fuel transferfrom cell Nos. 6 and 7. Zero- or low-g (less than 0.5) flight tendsto force the fuel remaining in cell No. 5 toward the aft wall of the tank or, at reducedfuel level, uncoversgravity transfer line (C) and allows air to be drawn into the sump tank. Continued zero- or low-g (lessthan0.5) maneuverswill aggravatethis condition andincreasethe probability of air ingestion.Ifair entersthe boost pump and engine feed line, the fuel pressurelight will illuminate. If the maneuver is continued,the left AB will blow out andsubsequentleft-engine flameout can occur. Right-engine flameout can follow after left-engine flameout becauseengine feed crossfeedoperationwill reducethe effective output of the right boost pump. Aircraft decelerationcan further interrupt fuel transferfrom cell No. 2 to the right sump throughthe gravity transferline (D, Figure 2-33). Once initiated, this sequencecan occur rapidly and is independentof total fuel state.
to continue the maneuverto the point of AB blowout and engineflameout. e In the presenceof a fuel pressurelight, fuel demandmust be reducedandpositive g restored to prevent possible engine flameout. 2.14.3.3 Fuel Shutoff Handles. Individual engine fuel feed shutoff valves in the IeA and right feedlines at thepoint of nacellepenetrationareconnectedby control cables to the FUEL SHUT OFF handles on the pilot instrumentpanel.During normal operation,thehandles should remain pushedin so that fuel flow to the engine fuel feed system is unrestricted.If a fire is detectedin the enginenacelle,the pilot shouldpull (approximately 3 or 4 inches) the FUEL SHUT OFF handle on the affectedside to stop the supply of fuel to the engine.
pi-G-1 Securing the engine at high power settings using the FUEL SHUTOFF handlesmay result in damageto the aircraft fuel system.
. During zero- or negative-gflight, the oil pressure light will normally illuminate andactivatethemastercaution light. Subsequent illumination of a fuel pressure light may go unnoticed,allowing the pilot 2-49
ORIGINAL
NAVAIR 01.Fl4AAD-1
Figure 2-33. Forward FuselageFuel Transfer The pathofthe motive flow fuel is essentiallythesame for eitherside.Fuel 6om theenginefeedline is pressurized by theengiwdrivenmotive flow pumpandinitially muted throughthe boostpump turbine.The motive flow fuel is then routedthroughits respectivetransfersystem.As the pressurizedfuel passesthrougheachejectorpump, it inducestransferfuel to flow alongwith themotive flow fuel. This combinationof fuel eventuallyis transferredinto the respectivewing box-beamtank.
Note Engine tlameout will occur approximately4 aaxmls afterthe FUEL SHUT OFF handle(s) ispulledwiththethrottle(s)atMIL.Withlow~~ power settings!,time to tlameoutwill increase (appmximately30 secondsat IDLE). 2.14.4 Fuel Transfer 2.14.4.1 Motive Flow Transfer. With the exception of the external tanks, which utilize bleed air, all fuel transferis accomplishedby gravity and motive flow. In motive flow, a relatively small amount of pressurized fuel moves at high speedthrough ejector pumps, using the venturi effect to induce flow of the transferfuel. The ejector pumps haveno rotating parts or power requirements other than motive flow. Like other elementsof the fuel transfer system,motive flow transferis initially segregatedto right and left. The motive flow pump driven by the right engineprovides motive flow and pressureto drive the right boost pump and to run the ejector transferpumps in the forward fuselage and right wing. The motive flow pump driven by the left engineprovidesmotive flow andpressure to drive the left boost pump and runs the ejector transferpumps in the aft fuselageand left wing.
ORIGINAL
Z-50
There are four valves that control motive flow transfer: 1. Motive flow isolation valve - Normally closed, but when the low-level thermistor in cell Nos. 2 or 5 is uncovered or the FEED switch is out of NORM, the valve is commandedopen,providing a path for motive flow fuel from a normally operating side to crossover and power a malfunctioning oppositeside. 2. Forward fuselage motive flow shutoff valve Normally open exceptwhen the R FUEL PRESS caution light is illuminated or the FEED switch is in AFT. When the valve is closed,all motive flow transfer in the forward fuselageis shut off. If the valve is closed becauseof the R FUEL PRESS caution light, positioning the FEED switch to FWD will open the valve.
NAVAIR
3. AFT fuselagemotive flow shutoff valve - Normally openexceptwhen the L FUEL PRESS caution light is illuminated or the FEED switch is in FWD. When the valve is closed,all motive flow transferin the aft fuselageis shut off. If the valve is closedbecause.of the L FUEL PRESS caution light, positioning the FEED switch to AFT will openthe valve. 4. Wing motive flow shutoff valve - The motive flow to eachwing passesthroughseparatepathsin a single motive flow shutoff valve. The valve is normally openexceptwhen: a.
Excess fuel in the box-beam tank passesthrough an overflow pipe back into cell No. 5. When cell No. 5 is full, the fuel cascadesinto cell Nos. 67, and8. The at? fuselagefuel will continueto circulateuntil consumedby the engine.When their respectivecell is empty, the motive flow ejector pumps will be shutoff by their own low-level floats. The scavengeejector pumps do not incorporate shutoff floats. In the event of loss of aft fuselagemotive flow transfer,fuel may be gravity fed forwardto cell No. 5 andeventuallyto thelefi sumptank through interconnectC. Wing Transfer. Wing fuel is transferredby two motive flow ejectorpumpslocatedin eachwing. To preventoverfilling the fuselage,entry ofwing fuel into thebox-beamtank is controlledby the refuelingAmnsfer shutoff valve. In the forward fuselage,excessfuel overflows throughan overflow pipe from therightbox-beam tank into cell No. 2, and then cascadesinto cell No. 1. A high-level pilot valve senseswhen cell No. 1 is full and sendsa signal to close the right refuelingltransfer shutoff valve, preventingadditional wing fuel from entering. When enginefuel consumptionprovidesroom in cell No. 1 for additional fuel, the high-level pilot will signal the refueling/transfershutoff valve to open.The sequenceis identical for the left box-beamtank and aft fuselage with the exception that the high-level pilot valve is located in cell No. 7 and controls the let? refueling/transfer shutoff valve (see Figure 2-34 for wing and externaltank fuel transfer). 2.14.4.4
The WING/EXT TRANS switch is in OFF or in AUTO with both left and right wing thermistors dry.
b. Weight is on wheels. C.
01 -F14AAD-1
The REFUEL PROBE switch is in ALL EXTD.
In any case,the wing motive flow shutoff valve can be commandedopenby selectingORIDE on theWING/ EXT TRANS switch. 2.14.4.2 Fotward Fuselage Transfer. Fuel in cell No. 1 flows by gravity into cell No. 2 wheretwo motive flow ejectorpumps transfer it into the right wing boxbeam tank at approximately 18,000 pounds pph. Fuel entering the box-beam tank beyond engine demands overflows through an overflow pipe back into cell No. 2. There is no fuel level control associatedwith fuselagemotive flow transfer; therefore,the fuel will continueto circulate from cell No. 2 into the right boxbeam tank and back through the overflow pipe. When the fuel in cell Nos. 1and 2 is depleted,the motive flow ejectorpumpsareshutoff by their own low-level floats, In the event of failure of the forward fuselagemotive flow, the fuel can reachthe right sump tank by gravity flow throughinterconnectD. Aft Fuselage Transfer. Fuel in the aft fuselageis transferredforward by scavengeejectorpumps in cell No. 8 and the vent tank, single ejectorpumps in cell Nos. 6 and 7, and two ejector pumps in cell No. 5. All atl motive flow transfer is into the left box-beam tank, producing a rate of approximately 36,000 pph. This flow rateis approximatelytwice thatofthe forward fuselagetransfer rate becausethere are more motive flow ejectorpumps in the aft transfersystem.More fuel tanks and thus more motive flow ejector pumps are requiredin the aft transfersystemthanthe forward transfer system becauseof the aircratl structural contigumtion. Like the forward fuselage, aft fuselage transfer doesnot have any high-level control associatedwith it.
2.14.4.3
2-51
Normally wing fuel canonly transferto thebox-beam tank on its respectiveside,exceptwhen thethermistorin eithercell No. 2 or 5 is uncoveredor the FEED switch is selectedFWD or AFT. For either condition, the motive flow isolationvalve opens,making motive flow pressure availableto either wing from either engineand the two defuektransferselectorvalvesopenpermitting fuel from eitherwing to transferto eitherbox-beamtank. Total loss of wing motive flow will preclude transfer of any remaining wing fuel. Failure of either high-level pilot valve or refueling/transfershutoff valve to the closed position could causea single-wing transferfailure. Selection of FWD or AFT on the FEED switch opensthe defueVtransferselectorvalves allowingthetmppedwing fuel to transferto the oppositebox-beamfuel tank. Note
Prematureautomaticwing motive flow valve shutoff may occur becauseof formation of air bubbles in the wingtip fuel thermistors. Pilot selection of ORIDE with the WING/EXT TRANS switch will reenable fuel transfer.
ORIGINAL
NAVAIR 01-F14AAD-1
TRANSFER REFUELINGSHVTOFF SHUTOFF VALVE
HIGH-LEVEL PILOTVALVE
OEFUELINGiTRANSFER SELECTOR
VALVES
VALVE
\
SIGHT
VENT
HlGH-LEVEL
FUEL AND AIR OVICK-DISCONNECTS
FUELING
AND
TRANSFER
REFUELING AND TRANWER SHUTOFF VALVE /
OVERbOARD VENT
LOW-LEVEL PILOT VALVE
Figure 2-34. Wing and External Tank Fuel Transfer
ORIGINAL
LOW-LEVEL PILOT VALVE
LINE
NAVAIR
Since FLT GR UP servesto bypass the landing gear down interlock in the externaltank transfercircuit, the WtNG/EXT TRANS switch may remain in the AUTO (normal) position for this check.
Note l
l
01.Fl4AAD-1
ORIDE transfer should not normally be usedunless AUTO transfer fails to completetransferofwing or externaltank fuel. ORIDE use when the wing tanks are dry may allow air to enterthebox-beamtanks, reducingthe efficiency of gravity transfer to the sump tanks.
l
When the thermistor in either cell No. 2 or 5 is uncovered, the WING/EXT TRANS switch will be deenergizedfrom OFF to AUTO. This automatic feature is to ensureall wing and external fuel has beentransferred.AAer 5 seconds,thepilot may resetthis switch to OFF.
l
Note Verifying tank operation by observing fuel transferis both time consumingwith a full fuselagefuel load and aggravates fuel slosh loads in the externaltanks during catapultlaunch. Engine rpm aboveidle may be requiredto provide sufficient bleed air pressurefor a satisfactorycheck.
2.14.4.5 External Tank Transfer. External tank transfer is also controlled by the WMG/EXT TRANS switch. When externaltanks areinstalled,transferfrom thewings andexternaltanksoccursconcurrently.Transfer from the wings and externaltanks cannotbe accomplished separately;however,the externaltanks should complete transferbefore the wing tanks. External tank fuel is transferred by bleed air pressureregulated to 25 psi. Maximum transfer rate of each external tank is approximately45,000pph.External tank fuel transfer into the fuselageis controlled by the same valves that control wing transfer. Fuselage level is controlled by the refueling/transfershutoff valves and, until both the defuel/transfervalves are commanded open, external tank fuel can only transfer into the box-beam tank locatedon the sameside of the aircraft.
Vent Valve Failure. The vent valves in the right and left box-beam tank are always commanded openwith thesump tank interconnectvalve, making the right and left feedgroupsa common system.This function occurswhen the low-level thermistor in cell No. 2 or 5 is uncovered.To equalizethe static pressurehead at the interconnectvalve, the fuel in the sump tankswill seeka common level. At matchedenginedemands,each enginewill feed from its own side and negligible flow will occur acrossthe sump tank interconnectvalve. If a vent valve fails to open,the additional vent pressureon top of the fuel on the vented side createsa pressure differential between the let? and right sump tanks and resultsin migration throughthe interconnectvalve to the side with the inoperative vent valve. Therefore, sump tank replenishmentof fuel to the sidewith the failed vent valve will come primarily from the oppositesump tank becausethe head pressureat the interconnectvalve (E) may be higher than that at interconnectsA, B, C, or D (Figure 2-31).A fuel quantity imbalancewill occurwith the side of theproperly operatingvent valve decreasing more rapidly than the malfunctioning side. The boxbeamtank with themalfunctioning ventvalve will eventually vent through the overflow pipe when the respectivefuselagetank (cell No. 2 or 5) is empty. If for any reasonthefuel is not transferredout of therespective fuselage tank, the imbalance will continue until the ventedsumptank fuel quantity is low enoughto uncover the interconnectvalve and line (256 pounds approximately). This permits venting of the unventedside and permits useof the balanceof the fuel in the sump tanks.
Externaltank transfercanbe checkedon the deck by placing the WMG/EXT TRANS switch to ORIDE, or selectingFLT GR UP with the MASTER TEST switch and noting depletion of external tank fuel quantity. In addition,when FLT GR UP is selected,the GO/NO GO light on the MASTER TEST panel is illuminated by a pressureswitch in the aircraft pressureline leading to the externaltanks and indicates statusof line pressure.
Vent valve malfunctionscancreatedisconcertingfuel imbalances.Although engineoperationis not affectedand all of the fuel in the aircraftis available,AB useshouldbe avoidedwhenlow-feedgroupfuel quantitiesareindicated. If both engine/boostpumps areoperating,thereis no advantagein usingthe cockpit fuel FEED switch to attempt to correct the imbalance.Positions other than NORM may simply aggravatethe imbalance.
2.14.4.6
A weight-on-wheelsinhibit function preventsopening of the wing motive flow shutoff valve. To transfer wing fuel during ground operations,the WINCYEXT TRANS switch must be set to ORIDE to bypass the weight-on-wheelsfunction. Activation of fuselagefuel dump automatically initiates wing fuel transfer in sequenceafter external tank transfer by automatically moving the WINCYEXT TRANS switch to AUTO if in OFF. Positioning the REFUEL PROBE switch to ALL/EXTD also releases the solenoidholding the WING/EXT TRANS switch in OFF.
2-53
ORIGINAL
NAVAIR 01-F14AAD-1
2.14.5 Fuel Quantity Balancing. Fuel quantity balancing is not normally requiredprior to completion of wing/external tank transferor until one fuselagetape drops below 4,500 pounds.The procedurerequiresuse of the FEED switch that opensthe sump tank interconnect valve, joining the FWD/R and AFT/L systems. With a high quantity in the FWDiR group, the greater staticheadpressure,particularly in noseupattitudes,can causeoverfilling of the AFT/L group. To preventthis, the FEED switch should be returnedto NORM before the AFT/L tapereaches6,200pounds.
2.14.6 Fuel Transfer/Feed During Single-Engine Operation. Loss of an engine before the low-level thermistor in either cell No. 2 or 5 is uncoveredwill terminate all motive flow transfer on the failed side. External tank fuel will continue to transfer if room is available in the failed side fuselagetanks. If no pilot action is taken,the operatingenginewill feedonly from its own side.This will lead to a fuel imbalancethat can normally be correctedthroughthe useof the fuel FEED switch. Selectingthehigh side(inoperativeengineside) resultsin the following:
When the FEED switch is moved to selectthe highfuel quantity side, the following occurs:
1. Selectedside fuselagemotive flow shutoff valve is opened.The valve wascommandedclosedwhen the FUEL PRESS caution light illuminated.
1 Sump tank interconnectvalve opensand provides a fuel path betweenthe right and left tanks.
2. Operatingsidefuselagemotive flow shutoff valve is closed and stops operating side fuselagefuel transferinto the box-beamtank.
2. Both box-beamtank vent valvesopenandprovide equalvent pressureon top of the fuel in eachboxbeamtank, regardlessof the fuel level.
3. Motive flow isolation valve opens.Operatingside motive flow pressurenow powersthe inoperative side. Failed side fuselagefuel will begin transferring into its respectivebox-beamtank.
3. Fuselagemotive flow shut off valve on the nonselected(low-fuel quantity) side closesand terminatesthe lastsourceoftransferofthat fuselagefuel into its respectivebox-beamtank. 4. Motive flow isolationvalve opensandprovidespath for nonselectedside motive flow pressureto reach the oppositeside.Thus motive flow transfershould maintaina 6111 box-beamtank on the selectedside. 5. Both defuel/transfcrselectorvalves openandpermit either wing/externaltank to transferinto either wing box-beamtank. The higher static pressurehead createdby the full box-beamtank on the selectedside resultsin the nonselectedside enginefeedingprimarily from the sumptank interconnect rather than interconnectsA, B, C, or D. With both enginesfeedingfrom the fuel in primarily one side, the correction rate of the fuel quantity imbalance is essentially a function of engine demand.
4. Sump tank interconnectvalve opensand provides a path for the inoperative side fuel to reach the operatingengine. 5. Wing box-beamtank vent valvesopen andequalize the pressureabovethe fuel in eachwing boxbeam tank, permitting the higher static pressure created by the full wing box-beam tank on the inoperativeside to induce flow through the open sump tank interconnectvalve to the operatingengine. 6. Both defuel/tmnsferselector valves open and allow either wing or external tank fuel to transfer into either wing box-beamtank. If no crew action is takenwith the FEED switch, the same fuel system functions are automatically provided when the thermistor in either cell No. 2 or 5 is uncovered. Additional actions that will occur when the cell No. 2 or 5 thermistor is uncoveredare:
During AB operations,NORM shall be selected.FWD or AFT could depletefuel in sump tanks.
1. Both right and let? fuselagemotive flow shutoff valves open, overriding any previous commands to close. Manual override of each valve is still provided through the FEED switch.
Aircraft attitudewill havea significant influenceon the direction of fuel movement if FWD or AFT is selected.Nosedown attitude will transfer fuel forward, and noseupattitude will transferfuel aft.
2. Engine crossfeedvalve receivesa redundantcommand to open. An initial command was provided when the FUEL PRESS caution light illuminated.
ORIGINAL
2-54
NAVAIR 01.Fi4AAD-1
3. WING/EXT TRANS switch will automatically go to AUTO if originally in OFF. If desired,OFF can be reselectedafter 5 seconds. 2.14.6.1 Sump lank Interconnect Valve Failure. The major fuel system considerationwhile operating single engine is that the sump tank interconnectvalve openswhen commanded.This constitutesthe only path throughwhich inoperativeside fuselagefuel can reach the operatingengine.While tbe probability of an inoperative sump tank interconnectvalve is very low, the consequencesofa malfunctionundersingle-engineconditions are severe,particularly at landing fuel weights. With a failed closed sump tank interconnectand full tltselagecells on the inoperativeside,only the wing titel on the inoperative side and external fuel can be transferred into the operating side fuselage. Attempts to transferthefuel from theinoperativesidewith the FEED switch compound the problem when the motive flow isolationvalve and inoperativesidemotive flow shutoff valve open. Operating side motive flow fuel, pumped throughthe openmotive flow isolation valve to permit inoperativesidewing and/orfuselagemotive flow tmnsfer cannotbe retrieved.Fuel migration is approximately 100 pcunds per minute becauseof wing transfer,and approximately 200 pounds per minute for fuselage transfer.Coupled with a normal engine demand of approximately 100poundsper minute, abalancingattempt will result in usable fuel in the operative side being depletedat approximately400 poundsper minute. Note Operating side fuel remaining can be protectedby pulling the FUEL SHUT OFF handle for the inoperativeside and concurrently selecting the operative side on the FEED switch. This will eliminate a potential fuel path acmss the engineautomatic cmssfeed valve, through the inoperative sump tank boostpump into the inoperativeside.
2.14.7 F~ei Dump. Figure 2-35 shows aircraft fuel system components associated with fuel dump operation.Fuel dump standpipesin the fonvard(cellNo. 2) aud aft (cell No. 5) fuselagetanks are connectedto the fuel dump manifold at the dump shutoff valve. The manifold extendsaA to the fuselageboattail. Actuation of the fuel DUMP switch to DUMP suppliespower (dc essential No. 2) to open the solenoid-operatedpilot valve, which portsmotive flow till pressureto openthe dump shutoff valve with weight off the main landing gearand the speedbrakesretracted. The fuel DUMP switch circuit is deactivatedon deck or with speedbrakesextended. Fuel dump with the speedbrakesextendedis inhibited becauseof the resulting flow field disturbance,which would result in fuel impingement on the fuselageboattail and exhaustmuzles.The speedbrakeswitch is electricallybypassedduring a combined hydraulic system failure, enablingthe pilot to dump fuel when the speedbrakesam floating. The electrical bypass is accomplished whenever the combined pressurefalls below 500 psi.
The speedbmke/fueldump interlock doesnot preventspeedbrakesfmm being deployed if fuel dump is activated. It only preventsthe dumping of fuel if the speedbrakesare already extended. Note . The FUEL FEEDKHJMF circuit breaker is on the pilot right-knee circuit breaker panel.
If the sump tank interconnect is failed closed, the following additional considerationsapply: With the FEED switch selectedto the operatingside. 1. Wing and externaltank fuel from both sides will transferinto the operatingside fuselageifrhe inoperativesidehelage isjLII. 2. IfDIMP is selected,wing motive flow is automatically activated; therefore, approximately 100 poundsper minute of fuel available to the operating enginewill be lost.
2-55
.
Dump operationswith eitherenginein afterburnershouldbe avoidedsincethe fuel dump mast dischargewill be torched.
.
After terminatingfuel dump,wait appmximately 1 minute to allow residual fuel in the fuel dump line to drain beforeextending speedbrakesor lighting afterburners.
Fuel in the wings and external tanks is dumpedby transferring to the fuselage. When the titselage fuel dumpcircuit is activated,wing andexternaltanktmnsfer to the box-beam tanks is automatically initiated. Fuel dump is by gravity flow with a nominal dischargerate of 1,500poundsper minute. The dump rate is affected by aircraft pitch attitude andtotal fuselagetitel quantity with dischargeflow inhibited at nosedownconditions. ‘Ihe standpipesin the fuel cells control the minimum ORIGINAL
NAVAIR Ol-Fl4AAD-1
Figure 2-35. Fuel Vent andDump fuel dump level in the tanks, which, under normal operations (feed group full), is approximately 4,000 pounds. 2.14.8 internal Tank Pressurization and Vent. The internal fuel vent system is shown in Figure 2-35. It is an open-vent-typesystem, pressurizedby ram air and enginebleedair from the 25-psi externaltank pressure system that is reduced to 1.75 psi by a fuselage pressureregulator and distributed to all tanks through the fuselagevent system.This air is automatically supplied when the landing gear handle is UP or the WING/EXT TRANS switch is in ORIDE. When the WING/EXT TRANS switch is in OFF, thelow-pressure bleed air is cut off. In flight, the vent tank is maintained at a positive pressureup to 2.5 psi maximum. This pressureis fed by connectinglines to all internal tanks.These connecting lines are routed to provide venting to both the forward and afl end of each fuselagetank so it can function as both a climb and dive vent. Venting of the box-beam tanks is controlled by solenoid-operatingvalves, which when closed,provide suctiontransferthroughthe gravity flow pathsin cell Nos. 2 and 5 to the sump tanks.
ORIGINAL
2-58
2.14.9 Fueling and Defueling. Figure 2-36 shows the refueling system. The aircraft is equippedwith a single-point refueling system, which enablespressure tilling of all aircraft fuel tanks from a singlereceptacle. The receptacleis at the recessedground refuel and defuel station, behind a quick-accessdoor on the lower right side of the forward fuselage.The maximum retitcling rate is 450 gallons per minute at a pressureof 50 psi. Since ground and air refueling connectionsuse a common manifold, the refueling sequenceis the same. Standpipesrefuel the aft and forward fuselagetanks by overtlow from the left and right box-beamtanks.A high-levelpilot valve at thehigh pointofthe forwardtank shutsoff the fuselagerefueling valve in the right boxbeamtank whentheforward tankgroupis full. Fuel flows from the left box-beamtank to cell No. 5, after which it overtlowsto the right side,thentheleft side.Ahigh-level pilot valve at thehigh point ofthe left box-beamtank and aft tank (cell No. 7) shutsoffthe fuselagerefuelingvalve in the let?box-beamtank when the aft tankgroupis 111. Individual wing andexternaltank tilling is accomplished by flow througha shutoff valve in eachtank.
NAVAIR 01.Fl4AAD-1
“TOFF
AFT HIGWLEVEL PILOT VALVE
VALVE
Figure 2-36. Refueling System mcnt panel.The direct-readingvent pressureindicator monitors pressurein the vent lines. The gaugeconsists of a pointer on a scalehaving two bands,onegreenand one red.
Gravity refueling of the aircraft fuel system should be accomplished only under emergency situations.While performing such an operation, avoid introducing contaminants into the fnel tanksor damagingthe Fuelqnantity probesandwiring.
The greenbandindicatesa safepressurerange(0 to 4 psi),andtheredbandindicatesanunsaferange(4 to 8 psi).
2.14.9.1 Precheck System. Groundretireling con, trol is by two precheckselectorvalves and a vent pres, sum gaugeadjacent to the refueling receptacleon the ground refuel and defuel panel. The precheck valves functionally test high-level pilot valve operation inci, dentto groundpressurerefueling; the valves separately checkthepilot valves in the fuselagetanksandthe wing andexternaltanks.In addition to this precheckfunction, the precheckvalves can be used for ground selective refueling of only the fuselageor all tanks. Since the precheckvalves,which aremanually setby the groundcrew, port pressurizedservo fuel to the high-Levelpilot valves and subsequently to the shutoff valves, no electrical power is necessaryon the aircraft to perform ground refueling operations.Additionally, ground refueling control without enginesrunning is completely independentof switch positioning on the fuel manage2.57
During ground refoeling operations,the direct-reading vent pressure indicator shall be observedand refueling stoppedif pressureindicatesin the red band (above 4 psi). 2.14.10 In-Flight Refueling Note See paragraph 9.1 for in-flight refueling procedures. The in-flight refueling systempermits partial or complete refueling of the aircraft fuel tanks while in flight. The retractablerefueling probe hasan MA-Z-type nozzle, which is compatiblewith any drogue-typerefueling ORIGINAL
NAVAIR 01.F14AAD-1
system. A split refueling system is provided with fuel routed into the left and right box-beamtanks for initial replenishmentof sump tank fuel. Selectablefuel managementcontrols dictate the extent of further distribution to the wing tanks, external tanks, and/or fuselage tanks. The maximum refueling rate is approximately 475 gpm at a pressureof 57 psi.
combined hydraulic system. It can be extendedand IB tractedby meansof the hydraulic handpumpin the event of combined system failure.
Loss of combinedpressuremay indicateimpending fluid loss. Without fluid in the combined system return line, the in-flight refueling probe will not extend with the handpump.Early extensionof the refueling probe at the first indication of a combined system malfunction is recommended in a carrier environment.
(,,,,,,,I To prevent fuel fumes from entering the cockpit throughtheECS becauseof possible tire1spills during in-flight refueling, selectL ENG air source.
Note To extend or retract the refueling probe using the hydraulic handpump requires the refuel probe switch to be placed in EXT or RET (as appropriate),combined system fluid in the return line, and essential dc No. 2 electrical power.With a total loss of combined hydraulic pressure in flight, fluid trapped in the return line/ handpumpreservoircanbe isolatedexclusively for refueling probe extensionif the landing gear handle is in the up position. Extension of the refueling probe requires ;i;;;imately 25 cycles of the pump
Maximum airspeedfor extension or retraction in flight of the refueling probe is 400 knots (0.8 Mach).
l
l
Note With the in-flight refueling probe extended, the pilot and RIO altimeter and airspeedand Mach indicaton will show erroneousindications becauseof changes in airflow aroundthe pitot static probes. Flight operationswith the in-flight refueling probe door removed are not recommended becauseof the effects of water intrusion,exposureto elements,andstructural fatigue to electrical hydraulic hardware assemblies.If operationalnecessity dictates,the in-flight refueling probedoor may be removedto preventdamage,loss, or engineFOD.
Probe retraction is not available if the FUEL P/MOTIVE FLOW ISOL V (PPUMP) circuit breaker(RGl) is pulled.
a The RUDDER AUTH caution light may illuminate when the in-flight refueling probe.is extended. Press the MASTER RESET button to resetthe light. 2.14.10.1 in-flight Refueling Probe. The retractable in-flight refueling probe is in a cavity on the right side of the forward fuselagesection, immediately forward of the pilot vertical consolepanel. Extension of the refueling probe is provided through redundantcircuits by the REFUEL PROBE switch. A hydraulic actuatorwithin the probe cavity extendsand retractstheprobe.The probeactuatoris poweredby the ORIGINAL
2.58
2.14.10.2 Refueling Probe Transition Light. The red probe transition light immediately above the REFUEL PROBE switch illuminates wheneverthe probe cavity forward door is not in the closedposition. Since the closed-doorposition is indicative of both the probe retractedand extendedposition, the light serves as a probe transition indicator as well as a terminal status indicator.The probe externallight illuminates automatically upon probe extensionwith the EXT LTS master switch ON. 2.14.10.3 in-flight Refueling Controls. Regardless of fuel managementpanelswitch positioning,at low-fuel statesthe initial resupplyof tire1is dischargedinto the let? andright box-beamtanks.The split reiirelingsystemto the left and right enginefeedgroupprovidesfor a relatively balancedcg conditionduringrefueling.Selectivemtireling of the fuselageor all fuel tanksis providedon theREFUEL PROBE switch with the probe extended.In FUSiEXTD,
NAVAIR 01.Fl4AAD.1
normal fuel transferand feed is unaltered,This position is used for pm&e plug-ins, tiazelage*niy refueling,or return flight with a damaged wing tank. The ALL/EXTD position shuts off wing and external drop tank transferto permit the refuelingof all tanks. 2.14.11 Hot Refueling. Hotrefuelingcanbeaccomplished with the refueling probe extendedor retracted. If the probeis extended,control of the tanks to be refueled is accomplishedin the samemanneras during inflight refueling. If the probe is not extended, select WING/EXT TRANS switch to OFF to refuel all tanks. SelectORIDE to refuel the fuselageonly. 2.14.12 Automatic
Fuel Electrical Controls
2.14.12.1 Automatic Low-Level Wing Transfer Shutoff. Athermistor is locatedatthelowpoint ineach wing cell. When both areuncovered,a discreteelectrical signal is generated,and through a control, the wing motive flow shutoff valve is energizedand closes,terminating ail wing transfer.If either or both thermistors areagain submerged,wing transferresumes. Failure of this overridesystem could result in a wing transfer failure. Selection of WING/EXT TRANS switch to ORIDE removes all power from the wing motive flow shutoff valve, permitting it to open. 2.14.12.2 Automatic Fuel Low-Level Override. Under normal operating conditions, the forward and right fuselagetank complex is isolated from the aft and left tank. This is necessaryfor proper longitudinal cg control andbattle damageconditions.However, as fuel depletion progressesto the point of sump tank only remaining,it becomesmandatorythat the tanksbe connectedto maintain an equalbalance.To accomplishthis, two thermistorsarelocatedat the low points in ceil Nos. 2 and 5, and when either is uncovered(approximately 1,700to 2,000poundsperside)the following operations areelectrically performed. 1. Sump tank interconnectvalve is opened. 2. Motive flow isolation valve is opened. 3. Box-beam vent valves are opened. 4. Engine crossfeedvalve is opened. 5. WING/EXT TRANS switch is energizedto move from OFF to AUTO. This signal is maintainedfor 5 seconds.
1 WARNING
1
Uncoveringeitherthermistor in cell No. 2 or 5 will only move the WING/EXT TRANS switch from OFF to AUTO but, under no circumstances,will it override a wing transfer failure. 2.15 ELECTRICAL POWER SUPPLY SYSTEM In normal operation,ac power is suppliedby the engine-driven generators.This ac power is convertedby two transformer-rectifiers(T/R) into dc power (refer to FO-8). Onegeneratoris capableof assumingthe full ac power load andone T/R is capableof assumingthe full dc power load. Additionally, a hydraulically driven emergencygeneratorprovides an independentbackup supply of both ac and dc power for electrical operation of essentialbuses.Ground operationof ail electrically powered equipment is provided through the supply of external ac power to the aircraft. Switching between power supply systems is automatically accomplished without pilot action; however, sufficient control is provided for the flightcrew to selectively isolate power sourcesand distribution in emergency situations. See Figure 2-37 for a functional description of the control switches.Ail electrical circuits areprotectedby circuit breakersaccessiblein flight to the pilot and RIO. 2.151 Normal Electrical Operation 2.15.1.1 Main Generators. Twoengine-driven,oilcooled, IDGs produce the normal 115-volt, 400 Hz, three-phaseac electricalpower.The normal ratedoutput of eachgeneratoris 75 kVA. Each main ac generatoris controlled by a separateswitch on the pilot MASTER GEN control panel. Indication of a main power supply malfunction is providedby a L GEN andR GEN caution light. The IDG oil system is usedfor cooling as well as lubricating the IDG. The oil is normally cooled by the IDG air/oil cooler and returned to the constantspeed drive for recirculation. When AB is used, additional cooling is provided by the AB fuel/oil cooler before returning to the IDG. Should an excessiveamount of heatbedevelopedin an IDG, a thermal (390“F) actuated device automatically decouplesthe input shaft from the remainder of the CSD, protecting both the CSD and generator.There are no provisions for recoupling the IDG unit in flight.
6. Defuel transferselectorvalves are opened.
2-59
ORIGINAL
NAVAIR
01.Fl4AAD-1
NOMENCLATURE a
MASTER GEN switch (lock lever)
FUNCTION Connects the generator to the main buses through the line contactor.
NORM
OFF/RESET - Disconnects generators from the buses. Reset the generator If tripped by an overvoltage, undervoltage, or fault condition.
0
EMERG generator switch
TEST -
The generators are energized but are not connected to the buses. Provides a means to analyze a system malfunction indicated by a generator caution light when an attempt to reset a generator Is unsuccessful.
NORM -
Safety guard down. Emergency generator Is automatlcally connected to the essential buses lf both dc power sources fail.
OFF/RESET
Safety guard must be lifted. Disconnects the emergency generator from the essential buses. Resets the generator W trlpped by an undervoltage or underfrequency condition.
GEN caution lights are on the pllot’s caution/advisory light panel. Each light Is tied to its respective main ac contactor and is powered by the essential bus no. 2. Illumination of the L GEN or R GEN caution light indicates that the corresponding generator is not supplying power due to a fault in the generator, generator control unit, or electrical distribution system. @
TRANS/RECT advisory light
A TRANWRECT advisory light Is on the lower half of the pilot’s caution/advisory Indicator panel. Illumination of the TRANS/RECT advisory light Indicates either a single or dual transformer-rectifier failure has occurred.
Figure 2-37. GeneratorPanel ORIGINAL
2-60
NAVAIR
Failure ofthe weight-on-wheelscircuit to the in-flight mode while on the deck will cause theloss ofECS enginecompartmentair ejectorpumps,causinga subsequentIDG disconnect and illumination of the GEN light. Generator Control Units. Generator output voltage and frequency are individually monitored by GCUs, mat prevent application of internally generatedpower to the aircraft bus system until the generatoroutput is within prescribedoperating limits. With the main generatorswitch in NORM, the applicable generatoris self-excited, so that during the engine startcycle, it automatically comeson the line at approximately 60-percentrpm under normal load conditions. Likewise, during engine shutdown,the GCU automatically trips the generatoroff theline asthe power output decreasesbelow prescribedlimits at approximately 55 percent. 2.15.1.1.1
During normal operations, the generator control switchesremain in NORM continuously.However,subsequentto an engine shutdown, stall, or flameout in flight where the GCU has tripped the generatoroff the line, the reattainmentof normal engine operation will not automatically resetthe generatorunless the engine speeddecreasesbelow about 30-percentNZ ‘pm, If a transientmalfunction or condition causesthe generator to trip, the generatormust be manually resetby cycling the applicablegeneratorcontrol switch to OFF/RESET then back to NORM. When normal resetcannot be accomplished,TEST, on the generatorcontrol switch, allows the generatorlo beexcitedbut not connectedto the aircraAbuses.In test, a CSD, generator,or GCU failure causesthe GEN light to remain illuminated. If the light goesout, the problem is in the distribution system. 2.15.1.2 Transformer-Rectifiers. Two transformerrectifiersconvertinternalor externalac power to 2%Vdc power. A single TRANS/RECT advisory light on the pilot advisory panel provides failure indication for one or bofh transformer-rectifiers.No flightcrew control is exercised over transformer-rectifier operation aside from controlling the acpower supply or circuit breakers for the power converters. The transformer-rectifiers have a ratedoutput of 100 ampereseach.Each unit is capableof assumingthe complete dc electrical load of the aircraft. Forcedair cooling is provided with engines running to dissipate the heat generatedby the power converters.
Ol-Fl4AAD1
2.15.1.3 External Power. Ground power is applied through a receptaclejust aft of the nosegear.The pilot has control over external power application only through hand signals to the plane captain. An external power monitor preventsapplication of external power that is not within tolerancesand disconnectsexternal power from the busesif undervoltage,overvoltage,underfrequency,overfrequency,or phase-reversaloccurs. Power can be reapplied to the aircrafi by pressingthe reset button adjacent to the receptacle,provided it is within prescribed limits. External electrical power is automaticallyinhibited from HUD, MFD, AICS, APX76, CADC, and CIU without external air-conditioning connectedto the aircraft. When the left generatorcomes on the line during start, it automatically disconnects externalpower. Although there is no direct cockpit indication of externalpower being applied after onegenerator is operating,the HYD TRANSFER PUMP will not operateif the external power plug is still in the aircraft receptacle. Electrical Power Distribution. Electrical power is distributed through a series of buses.Under normal operation,the ac generatorpower distribution is split betweenthe left and right main ac buses.Failure of either main ac generatortrips a tie connectorto connectboth busesto the operativegenerator.Ifthe bus tie fails to trip when the generatorgoesbad, the respective transformer-rectifierwill not be powered and the indication of this double failure will be a L GEN or R GEN caution light and a TRANSRECT advisory light. The left and right main ac buses in turn supply ac power directly to the respectivetransformer-rectifiers,and the left main ac bus also suppliespower to both essentialac busesundernormal operation. 2.15.2
External power is distributed through the aircraft electrical systemin the same mannerasmain generator power. Like the main ac generators,dc power distribution from the two transformer-rectifiersunder normal operationsis split betweenthe let?andright maindc buses. Failure of eithertransformer-rectifiertrips the respective tie contactorto connectbothmain dc busesto theoperative transformer-rectifier.The TRANSmECT advisory light provides a direct indication of dc bus tie status. An intermption-freedc bus interconnectsthe left and right main dc buses to provide a continuous source of dc power with failure of either main ac generatorand/or transformer-rectifier.The left main dc bus additionally suppliespower to both essentialdc busesundernormal operations.Powerto theAFCS bus is normally supplied from the interruption-freedc bus; however,with an output failure from both transformer-rectifiers,the AFCS busload is automatically transferredto the essentialNo. 2 bus.Lossofmain dc powerautomaticallyactivatesthe emergency generator, which, in turn, trips power ORIGINAL
NAVAIR Ol-Fl4AAD-1
transferrelays to changeessentialac and dc bus loading f?om the left main ac and dc buses to the emergency generator,regardlessof main generatoroutput status. 2.15.2.1 Circuit Breakers. Individual circuit protection from an overloadcondition is providedby circuit breakers,which areall locatedin the cockpits for accessibilityin flight, The appropriatecircuit breakerwill pop out andisolatea circuit that drawstoomuch current,thus preventingequipment damageand a possible tire.
will be found.The innermost column of eachpanel 1,2, $8, and 9 or aft most column on eachpanel 3,4,6,7 L and R is designated “1,” the next outboard/forward column is 2, etc. Figure 2-38 is an alphanumericlisting of circuit breakers.
l
l
Note PanelNo. 1 row A, the column numbering is different from rows B to J. Panel No. 2 rows A to F, the column numbering is different from Rows G to I.
2.15.3 Degraded Electrical Operation Popped circuit breakersshould not be reset more thanoncenor held depressedunlessthe associatedequipment is absolutely required by operational necessity. A popped circuit breakerindicates an equipment malfunction or an overloadcondition. Repeatedresetsor forced depressionsof popped circuit breakers can result in equipment damageand/or seriouselectrical tire.
2.15.3.1 Emergency Generator. The emergency generatorprovides a limited but independentbackup sourceof ac (5 kVA, 1IYZOOvolts) anddc (50 amperes, 28 volts) power for flight-essential components.It is driven by combined hydraulic system pressure.
Cockpit circuit breaker panels are shown on FO-8 and FO-9. Circuit breakersin the pilot cockpit comprise the majority of thoserequired for essentialaircraft systems. The circuit breakersare arrangedin rows and are orientedso that the white bandedshaftofpopped breakers is readily visible for flightcrew surveillance.Panels, rows, andcolumns ofbreakersareidentified to facilitate breaker location and designation.Placardsadjacentto the breakersidentify individual circuit breakersby affected components;amperageratings are indicatedon top of eachcircuit breaker. 2.15.2.1.1 Circuit Breaker Location. The alphanumeric system for locating circuit breakersin the aircraft is as follows. The panels in the RIO cockpit are labeled 1 through 9 starting left-aft and proceedingclockwise (seeFigure 2-38). Thus, panels 1 to 5 are on the RIO’s left and panels 6 to 9 are on the RIO’s right. The pilot left and right knee panelsare designatedL and R, respectively. The first digit in the three-partlocator is the alphanumeric that identities the circuit breakerpanel.The second part is a letter and designatesthe row in which the circuit breakerwill be found. The top row is designated A, the next row lower is B, etc.The third part is a number and designatesthe column in which the circuit breaker
ORIGINAL
2-62
With the normal combined hydraulic system operation, the emergencygeneratorpowers the essentialac and dc No. 1 and No. 2 busesand the AFCS dc bus. Operation of the generator is automatically initiated with the loss of dc left main bus even if other dc buses remainenergized.Approximately 1secondelapsesfrom the time of automatic initiation beforethe generatordelivers rated power to flight-essentialac and de buses. Pilot control of the emergencygeneratoris through the guarded EMERG switch on the MASTER GEN control panel.With theswitch inNORM, theemergency generatoris automatically activatedwhen all main aeor dc power is lost. The switch OFF/RESET provides the pilot with the capability of isolating emergencyelectrical power from the aircraft buses(as in the caseof an electrical fire) or resettingthe generator. 2.15.3.1 .l Emergency Power Distribution. An emergency generatorcontrol unit monitors the emergency generatoroutput. If it sensesthat the emergency generatorcannot supply power within the proper fiequencyand voltagetolerances,it disconnectsthe essential ac and dc essentialNo. 2 and the dc AFCS buses from the emergency generator.It is possible that this could happenif the combined hydraulic system is not operatingnormally. Ifcombined hydraulicpressuresubsequently recovers, the emergency generator switch must be cycled through OFF/RESET and back to NORM to regain the essentialNo. 2 and AFCS buses.
NAVAIR OH=I4AAD-1 3F8 3F7 4Fl 4F2 214 3ca 8D8 as1 RC2 LFl 215 aE2 7A8 LGl 218 8El 7A5 RD2 ac2 9B8 985 RBI 4F4 2Hl 2H3 2H8 2H9 788 9F5 9D1 7A3 3F3 4F5 9c2 8Cl 9Aa lC2 1c4 1C8 ac2 8El 211 RG2 8C3 ac2 ac1 9A2 2G3 2G8
28 VAC BUS FDR AC ESS BUS NO. 2 FDR PH A AC ESS BUS NO. 2 FDR PH B AC ESS BUS NO. 2 FDR PH C ACM LT/SEAT ADJ/STDY POS LT ADF AC ADF DC AFCS BUS FDR AFCS/NOSE WHEEL STEER AICS L AICS L HTR AICS L LKUP PWR/EMER GEN TST AICS L RAMP STOW AICS R AICS R HTR AICS R LKUP PWWANTI SKID AICS R RAMP STOW AIR SOURCE CONTROL AIR/ANTI ICE CONTR HOOK CONT/ WSHLD ALE-39 CHAFF/FLARE DISP ALE-39 SEQ 1 & 2 SQUIBS ALPHA COMP/PEDAL SHAKER ALPHA HTR ALR-87 CMPTR ALR-87 RCVR PH A ALR-87 RCVR PH B ALR-87 RCVR PH C ALT LOW WARN ALR-87 CONTR AMC BIT/R DC, TEST ANGLE OF ATTACK IND DC ANGLE OF ATTK IND AC ANL Al-TK/TOTAL TEMP HTR ANN PNL DIM CONTR ANN PNL PWR ANT LOCK EXCIT ANT SVO HYD PH A ANT SVO HYD PH B ANT SVO HYD PH C ANTI ICE CONTR HOOK CONTiWSHLD/ AIR ANTI SKID/R AICS LKUP PWR ANTICOLUSUPP POS/POB LT ANTI-ICE/ENG/PROBE ANIAWW 4 PH A ANIAWW 4 PH 0 ANIAVvW 4 PH C APG-71 ANT APG-71 PUMP PH A APG-71 PUMP PH B
2G7 9A3 111 8E8 4D8 7F7 7C2 7Cl aA 9A4 1D2 lD5 lD8 IF1 IF3 IF8 IF2 IF4 lF5 9G5 9G8 lJ2 IA3 1Jl 987 8G3
APG-71 PUMP PH C APG-71 XMTR DC APG -71 XMTR AC APN-154 APX-1OOAC APX-100 DC ARC- 182 NO. 1 ARC-182 NO. 2 ARMT GAS/L ENG AFT CONTIRAT IND ASC ASCPHA ASC PH 0 ASC PH C ASPJ AUG PH A ASPJ AUG PH 6 ASPJ AUG PH C ASPJ BASIC PH A ASPJ BASIC PH B ASPJ BASIC PH C ASPJ DC ASW-27 ASW-27 AC AUTO PITCH DRIVE TRIM AUTO THROT AC AUTO THROT DC AUX FLAP/FLAP CONTR
385 7D3 3D4 8E7 IS3 8F8 8F2 4B4 7A4
BAR0 ALTM AC BAR0 ALT/lURN SLIP BDHI INST PWRIJTIDSIDPG BDHI/JTIDS DPG BEAM PS BINGO CAUTION BLEED AIR/L OIL HOT BLEED DUCT AC SOS CONTRIBIU OXY LOW BRAKE ACCUM SOV B/U OXY PRESS IND
9D5 7A2 8Al ac5 IA2 LB2 LC2 LD2 3E7 4El 4E2 383
9F4 8D8
CABIN PRESS CAN/LAD CAUTION/EJECT CMD IND CHAN 1 CADC PH A CHAN 1 CADC PH 0 CHAN 1 CADC PH C GHAN 2 CADC CIU PH A CIU PH B CIU PH C COMB HYD PRESS IND COOLING INTLWGND PWR CURSOR CONT/SNSR
Figure 2-38. Circuit BreakerAlphanumeric Index (Sheet 1 of 5) 2-83
ORIGINAL
NAVAIR 01.F14AAD-1 785 aA 7A7 9Dl 982 918 3A5 3F4 4F3 4F8 lG2 lG4 lG8 963 I REl 9E7
DC ESS NO. 1 FDR DC ESS NO. 2 FDR DC L TEST/RUDDER TRIM DC R TEST/AMC BIT DD ENABLEIRDP DEKI DEKI LTS DPI PHA DPl PHB DPI PHC DP2PHA DP2PHB DP2PHC DSS DUMP/FUEL FEED DYHR UNIT
LCl RF2 2Al 2Cl 2El 304 3A2 REl aF7 RDI 8Fl RGl 3c3 7Dl 8E4 8F9
FLT CONTR AUTH AC FLT CONTR AUTH DC FLT HYD BACKUP PH A FLT HYD BACKUP PH B FLT HYD BACKUP PH C FLT HYD PRESS IND FORM LT/TAXl FUEL FEED/DUMP FUEL LOW CAUTION FUEL MGT PNL FUEL PRESS ADVSY FUEL P/MOTIVE FLOW ISOL V FUEL QlY IND AC FUEL Ql?’ IND DC FUEL TRANS ORIDE FUEL VENT VALVE
8D4 4A3 9H3 702 781 912 8E2 7E3 7E2 RCI 7D5 7D4 aA 3A3 301 8A4 3A4 382 8Dl aD3 8FlO RF1 RG2 8A4 8GlO
ECS TEMP CONTR DC EIG WHT LTS ELECT COOLING EMER FLT HYD AUTO EMER FLT HYD MAN EMER GEN CONTR EMER GEN TEST/L AICS LKUP PWR EMER JETT #l EMER JElT #2 ENG ANTI-ICE VALVES ENG INST NO. 1 ENG INST NO. 2 ENG L AFT CONT/ARMT GAS/RATS IND ENG L BACKUP IGN ENG L OIL PRESS ENG R AFT CONT/EXAHUST NOZZLE ENG R BACKUP IGN ENG R OIL PRESS ENG OIL COOL ENG SEC ENG STALL TONE ENG START ENG/PROBE/ANTI-ICE EXHAUST NOZZLE/R ENG AFT CONT EXT LT CONTR
8F5 8F4 9F4 8G1 9D8 8Al 5D2 5C2
GEN GEN GND GND GND GUN GUN GUN
1Hl lH5 lH7 3Cl 4c5 4ca IA1 lA3 lA5 783 8Gll 8E.5
HUD CAMERA PH A HUD CAMERA PH B HUD CAMERA PH C HUD PH AIMFD 1 HUD PH B/MFD 1 HUD PH C/MFD 1 HV PWR SUP PH A HV PWR SUP PH B HV PWR SUP PH C HYD PRESS IND HYD PUMP SPOILER CONTR HYD VALVE CONTR
9D2 7c7 7c5 7C8 7c4 8G3 3D8 RA2 988
FEMS FIRE L DET LT FIRE L EXT FIRE R DET LT FIRE R EXT FLAP CONTR/AUX FLAP FLAP INDITAIURUDDER FLAP/SLAT CONTR SHUT-OFF FLARE DISP/ALE-39 CHAFF
LE3 7F3 7F2 lJ7 9F8 ac7 3E5 4E3 4E4 8G9 117 3c7
ICE DET ICS NFO ICS PILOT IFF &‘A AC IFF A/A DC ILS ARA-83 DC ILS ARA-83 PH A ILS ARA-83 PH B ILS ARA-83 PH C INBD SPOILER CONTR INS BAT PWR INS PH A
L CAUTION R CAUTION PWR/COOLING INTLK ROLL BRAKING/SPOILER TEST CONTRL PWR AC PWR NO. 1 PWR NO. 2
Figure 2-38. Circuit BreakerAlphanumeric Index (Sheet2 of 5) ORIGINAL
2-64
POS IND
N2/97
NAVAIR Ol-F14AAD.1
4Cl 4C2 3E4 3Al 3F5 112 9F3 915 911 9ca 9D4 2G2 2G5 268
INS PH B INS PH C INS SYNC INST LTS INSTR BUS FDR INTEG TRIM AC INTEG TRIM DC INTRF BLANKER INTRPT FREE DC BUS FDR NO. 1 INTRPT FREE DC BUS FDR NO. 2 IRST DC IRST PH A IRST PH B IRST PH C
lJ4 lJ3 lJ5 lJ8 aE7 3D5 403 4D4 3D4 7c3
JTIDS BAlT HEATER JTIDS DPG PH A JTIDS DPG PH B JTIDS DPG PH C JTIDS DPGlBDHl JTIDS RT PH A JTIDS RT PH B JTIDS RT PH C JTlDSlDPGlBDHl INST PWR KY-58IZ-AHP
LFI 215 8E2 7A8 7A7 8A5 3A3 381 7c7 7c5 8FS lA8 8F2 387 481 482 4E5 acs 2H10 984
L AICS L AICS HTR L AICS LKUP PWR/EMER GEN TST L AICS RAMP STOW L DC TEST/RUDDER TRIM L ENG AFT CONT/ARMT GAS/RATS IND L ENG BACKUP IGN L ENG OIL PRESS L FIRE DET LT L FIRE EXT L GEN CAUTION L MAIN XFMR RECT L OIL HOT/BLEED AIR L PH A TEST/P-ROLL TRIM L PH B TEST/P-ROLL TRIM L PH C TEST/P-ROLL TRIM L PITOT STATIC HTR LAD CAUTION/EJECT CMD IND/CAN LIQUID COOLING CONTR AC LlOui~ COOLING C~NTR DC
LE2 RE2
MACH TRIM AC MACH TRIM DC
lA8 2F4 LEI 5A2 9H4 9G4 3Cl 4c5 4C8 IGI lG3 lG5 1Gl lG3 lG5 8G5 8G4 7F5 7F4 9D3 RG1 582 8D3 8D2 8Dl 887 883 882 8Bl 3c5 4c3 4c4 ID1 lD3 ID7
MAIN L XFMR RECT MAIN R XFMR RECT MANUV FLAPIWG SWP DR NO. 2 MASTER ARM MASTER TEST MFA MFD l/HUD PH A MFD l/HUD PH B MFD l/HUD PH C MFD 2/MFD 3 PH A MFD 2/MFD 3 PH B MFD 2/MFD 3 PH C MFD 3 PH AIMFD 2 MFD 3 PH B/MFD 2 MFD 3 PHC/MFD 2 MLG HANDLE RLY NO. 1 MLG HANDLE RLY NO. 2 MLG SAFETY RLY NO. 1 MLG SAFETY RLY NO. 2 MONITOR BUS CONTR MOTIVE FLOW ISOL V/FUEL P MPRU DC PWR MPRU PH AISMP MPRU PH B/SMP MPRU PH C/SMP MS.1PWR HUD TEST MSL PWR SUP PH A MSL PWR SUP PH B MSL PWR SUP PH C MSN CMPTR NO. 2 PH A MSN CMPTR NO. 2 PH B MSN CMPTR NO. 2 PH C MSN CMPTR NO. 1 PH A MSN CMPTR NO. 1 PH B MSN CMPTR NO. 1 PH C
aA RC2 212
NLG STRUT LCH BAR ADVSY NOSE WHEEL STEEWAFCS NFO CONSOLE LT
3c4 7Al 8F2 8D2 9c5 283 2H5 3c4 8F8
OBOGS CONC OBOGS CONTR OIL L HOT/BLEED AIR OIL R HOT OUTBD SPOILER CONTR OUTBD SPOILER PUMP OXY CONC HTR OXY CITY IND OXY/BINGO CAUTION
Figure 2-38. Circuit BreakerAlphanumeric Index (Sheet3 of 5) 2-85
ORIGINAL
NAVAIR Ql-Fl4AAD-I
387 481 482 4A6 RBl 387 481 ‘482 2H2 2H4 2H8 4A5 4A3 083 LB1 4E5 4E6 6F3 211 4A4 RG2 LGl 216 6El 7A5 0A5 9Dl 0A4 3A4 382 7C6 7c4 0F4 6 2E4 6D2 2H2 2H4 2H8 4E6 483 1c3 lC5 lC7 9Bl lE4 lE5 lE6 982
P-ROLL TRIM/L PH A TEST P-ROLL TRIM/L PH B TEST P-ROLL TRIM/L PH C TEST PANEL FLOOD LTS PEDAL SHAKER/ALPHA COMP PH A L TEST/P-ROLL TRIM PH B L TEST/P-ROLLTRIM PH C L TEST/P-ROLL TRIM PH A R TEST PH B R TEST PH C R TEST PILOT CONSOLE LTS PILOT LCD INST LTS PITCH CMPTR DC PITCH CMPTR AC PITOT STATIC HTR L PITOT STATIC HTR R PLT ANN PNL AUX PWR/TR ADVSY POSLT/ANTICOLL/SUPP POS PROBE LT PROBE/ANTI-ICE/ENG R AICS A AICS HTR R AICS LKUP PWR/ANTI SKID R AICS RAMP STOW RAT INDIL ENG AFT CONTIARMT GAS R DC TEST/AMC BIT R ENG AFT CONT/EXHAUST NOZZLE R ENG BACKUP IGN R ENG OIL PRESS R FIRE DET LT R FIRE EXT R GEN CAUTION R MAIN XFMR RECT R OIL HOT R PH A TEST R PH B TEST R PH C TEST R PITOT STATIC HTR RADAR ALTM RADAR DD PH A RADAR DD PH B RADAR DD PH C RDP RDP PH A RDP PH B RDP PH C RDPIDD ENABLE
2G4 9El 281 2Dl 2Fl lE2 9E2 9E4 9E3 IA6 4A6 5Kl 5Jl 511 5Hl 5G1 5F1 5El 5Dl IA1 882 9A7 182 185 lB6 3D7 4Dl 4D2 7A7 3D6
RECON ECS CONT AC RECON ECS CONT DC RECON HTR PWR PH A RECON HTR PWR PH B RECON HTR PWR PH C RECON POD RECON POD CONTR RECON POD DC PWR NO. 1 RECON POD DC PWR NO. 2 RECT/L MAIN XFMR RED FLOOD LTS REL PWR/STA 1 TYPE I DCDR REL PWR/STA 1 TYPE II DCDR REL PWR/STA 3 DCDR REL PWWSTA 4 DCDR REL PWWSTA 5 DCDR REL PWRISTA 6 DCDR REL PWRISTA 0 TYPE I DCDR REL PWR/STA 6 TYPE II DCDR ROLL CMPTR AC ROLL CMPTR DC RSP RSP PH A RSP PH B RSP PH C RUDDER TRIM PH A RUDDER TRIM PH B RUDDER TRIM PH C RUDDER TRIM/L DC TEST RUDDER/FLAP lND/TAlL
913 II3 II5 II6 214 RA2 7E5 6D3 6D2 6Dl 8D8 lB1 184 187 RB2 0Gl 503 2110 513
SAHRS DC SAHRS A SAHRS B SAHRS C SEATADJ/STDY POS LT SLAT CONTR SHUT-OFF/FLAP SMP ESS SMP/MPRU PH A SMP/MPRU PH B SMP/MPRU PH C SNSRtCURSOR CONT SOL PWR SUP PH A SOL PWR SUP PH B SOL PWR SUP PH C SPD BK P-ROLL TRIM ENABLE SPOILER POS IND/GND ROLL BRAKING STA 1 AIM-9 COOL STA 1 BOL PWR STA 1 IFOL
Figure 2-38. Circuit Breaker Alphanumeric Index (Sheet4 of 5)
ORIGINAL
2-66
N2197
NAVAIR Ol-F14AAD-1 5Hl se1 6A3 583 5J2 6A6 6A5 6A4 5Fl 512 686 685 684 5H3 5El 5H2 6C6 6C5 6C4 5G3 5Dl 5G2 6D6 6D5 6D4 5Cl 5F2 6E6 6E5 6E4 SC3 I 219 5F3 5El 5Al 6F3 5A3 5E2 6F6 6F5 6F4 6F8
STA 1 TYPE I DCDRIREL PWR STA 1 TYPE II DCDR/REL PWR STA IA AIM-9 PWR AC STA IA AIM-9 PWR DC STA 1 B NO. It2 DC STAIBPWRPHA STAIBPWRPHB STAIBPWRPHC STA 3 DCDWREL PWR STA 3 NO. II2 DC STA 3 PWR PH A STA 3 PWR PH B
3A7 4Al 4A2 211 216 3D6 3A2 lH2 lH3 lH6 9c3 485 4F5 8F3
STA 3 PWR PH C STA 3/S IFOL STA 4 DCDRIREL PWR
STBY ATTD IND STBY ATTD IND STBY ATTD IND SUPP POS/POS STORM FLOOD
PH A PH B PH C LT/ANTICOLL LTS
TAIURUDDER/FLAP TAXI/FORM LT
IND
TCS PH A TCS PH B TCS PH C TCS SEL TEMP CONT AC
STA 4 NO. 1 I2 DC STA 4 PWR PH A
7D3
TOTAL TEMP HTR/ANL ATTK TR ADVSY/PLT ANN PNL AUX PWR TURN SLIP/BAR0 ALT
BTA STA STA STA STA STA STA STA STA STA STA STA
7F6 3A6
UHF CONTR/VHF UTILITY LTS
7F6
VHF/UHF CONTR
LEI 7D6 216 3F2 7D2 LDl ac3 ac2
WG SWP DR NO. 2/MANUV FLAP WHEELS POS IND WHITE FLOOD LT WING POS IND AC WING POS IND DC WING SWEEP DRIVE NO. 1 WSHLD DEFOG CONTR WSHLDAIR/ANTI ICE CONTR/HOOK CONT
aB6 LD3 885
YAW SAS A YAW SAS A PWR SUP
4 PWR PH B 4 PWR PH C 4/5 IFOL 5 DCDR/REL PWR 5 NO. 112 DC 5 PWR PH A 5 PWR PH B 5 PWR PH C 6 DCDR/REL PWR 6 NO. 112 DC 6 PWR PH A 6 PWR PH B
STA 6 PWR PH C STA a AIM-9 COOL STA a BOL PWR STA a IFOL ETA a TYPE i DCDR~REL PWR sTA a TYPE ii DCDIUREL PER STA aA AIM-9 PWR AC STA aA AIM-9 PWR DC STA aB NO. II2 DC STA aB PWR PH A STA aB PWR PH B STA aB PWR PH C STARTER VALVE LT
LC3 884 LB3 3F6
YAW SAS B YAW SAS B PWR SUP YAW SAS M YAW SAS M PWR SUP 26 VAC BUS FDR N2/97
Figure 2-38. Circuit BreakerAlphanumeric Index (Sheet5 of 5)
2-67
ORIGINAL
NAVAIR OI-Fl4AAD.I
Theexactpressureatwhich theemergencygenerator is unable to power all three busesis dependenton the loadplaced on the generatorandcanvary from 2,000to 1,100psi indicated. If the emergencygeneratoris required and there is a hydraulic emergencythat could lowercombinedsystemoperatingpressure,theessential ac and dc No. 2 and AFCS busescan be poweredwith lowerhydmulicpressurebyreducingtheelectricalload, such as turning off the HUD and not jettisoning ordnance.
2.16.1.1 Engine-Driven Pumps. The flight and the combined systems are each pressurized by enginedriven pumps. The flight hydraulic system pump is driven by the right engine and the combined hydraulic system pump by the left engine. Each of the main systems is normally pressurizedto 3,000 ilO0 psi at any time the respectiveengine is operating. 2.16.1.2 Hydraulic Pressure Light. A HYD PRESS caution light illuminates when the dischargepressure from either engine-drivenhydraulic pump falls below 2,100psi; thereafter,the light goesout when pressurein both systems via the engine-driven pumps exceeds 2,400 psi. If the HYD PRESS caution light has been illuminated by low pressure in one main system, pressurefailure in the other system will not causethe MASTER CAUTION light to illuminate again. The COMB and FLT gaugeson the hydraulic pressureindicator reflect system pressureprovided by either the engine-driven pumps or the hydraulic transfer pump. With both systemsnormally pressurizedto 3,000psi, the gaugeneedlesform a horizontal line.
Note When the emergencygeneratoris operating with one main hydraulic systeminoperative, large hydraulic flow requirementsfor flight controls may causeloss of the essentialac and dc No. 2 and AFCS buses.To regain thesebusesthe emergencygeneratorswitch must be cycled through OFF/RESET to NORM after thehydraulic pressurerecovers. Engine instrumentsarepoweredby essential ac bus No. 1. Engine instruments will be availableorrestoredatlower enginerpm.The airspeedat which engine instrumentationis restored(eitherautomatically or by pilot cycling the emergencygeneratorswitch) could be higher than minimum airspeed. 2.15.3.1.2 Emergency Generator Test. An operational checkof the emergencygeneratorcanbe accomplished anytime thecombined systemis pressurizedand at least one main generatoris on the line by selecting EMERG GEN on the mastertest switch anddepressing the switch. This provides 28 Vdc to activatethe emergency motor-generatorand checksthe tie contactorsby connecting electrical power to the essentialac and dc buses.The GO light on the MASTER TEST panelindicatesa satisfactorycheck. A malfunction in the emergency generatoroperationis indicated by the NO GO light. 2.16 HYDRAULIC POWER SUPPLY SYSTEMS The aircraft employstwo main, independent,enginepowered hydraulic systems, supplemented by two electrohydraulicpowermodules,abidirectionaltransfer unit, anda cockpit handpump.The systemsarepressurized to 3,000psi and use MIL-H-83282 hydraulic fluid circulatedthroughstainlesssteelandtitanium lines. Hydraulic fluid is cooledby heat exchangersthat use ejector air on deck. Hydraulic power system controls and indicators are shown in Figure 2-39. The components servicedby eachhydraulic power system areshownon FO- 10.
ORIGINAL
2.16.1 Flight and Combined Systems
2-68
Note High-rate lateral movementsmay illuminate the HYD PRESS light when enginesare at idle power. 2.16.1.3 Hydraulic Transfer Pump (Bidirectional Pump). To assurethe continuanceof main systemhydraulic pressurewith an engineor engine-drivenpump inoperative,a secondsourceof pressureis provided by the hydraulic transfer pump. This unit consists of two hydraulic pumps, one in each of the main hydraulic systems,interconnectedbya common mechanicalshaft. Thus, a pressuredeficiency in one system is automatically augmentedusing pressurein the other system as the motive power.The result is bidirectional transferof energywithout an interchangeof system fluid. The efficiency of the pump is such that a 3,000 psi systemon one side will pressurizethe other system to approximately 2,400to 2,600 psi. To prevent damage to the hydraulic transfer pump with the loss of system fluid on onesideandto conserve hydraulic power in the remaining good system, the pump is automatically securedwhen pressurelessthan 500 psi is detected on either side of the pump for 10 seconds.In addition, the pilot can manually shut offthe hydraulic transfer pump by lifting the guardedHYD TRANSFER PUMP switch, located aft on the right outboardconsole.
NAVAIR 01.Fl4AAD-1
Figure 2-39. Hydraulic SystemControls and Indicators(Sheet 1 of 2) 2-69
ORIGINAL
NOMENCLATURE 0
0
03
@
@
@
HYD PRESS indicator
HYD ISOL switch
BRAKE PRESSURE gage
FUNCTION COMB and FLT - Indicates pump discharge pressure on each engine, normally 3,OGO psi, or hydraulic transfer pressure approximately 2,400 psi. SPOIL -
When the outboard spoiler hydraulic module is pressurized (1,950 to 2,050 psi) the ON flag appears. Pressure below 1,900 to 1,950 psi: the OFF flag appears.
EMER FLT -
When pressure from the backup flight control hydraulic module reaches 500 * 50 psi the ON flag appears. Pressure below 350 + 50 psi: the OFF flag appears.
FLT -
Combined system hydraulic pressure is shutoff to landing gear, nosewheel steering, antiskid, and v&eel brakes.
T.O./LDG -
Hydraulic pressure is avallable to all combined components.
AUX -
Green segment lndlcates hydraulic pressure (2, f 50 & 50 to 3,000 psi) In the auxiliary brake accumulator; auxiliary braking may be applied by rudder toe pedals (approximately 13 to 14 applications available). Red segment lndlcates 1,900 to 2,150 psi (approximately 5 applications available).
PARK -
Green segment indicates hydraulic pressure (2,150 of: 50 to 3,000 psi) In the parking brake accumulator. The parking/emergency brake handle must be pulled to apply emergency braklng (approximately 3 applications available). Red segment Indicates 1,900 to 2,150 psi.
system
HYD PRESS caution light
lllumlnates when hydraulic pressure from either englne-driven pump is below 2,100 psi. It will go out with pressure In both systems at 2,400 psi or above, If pressure Is provided by engine-driven pumps.
;HY;rRANSFER
SHUTOFF -
Guard must be lifted. Shuts off hydraulic transfer pump. me pump should be secured when hydraulic pressure drops below 500 psi and does not rise agaln within 5 seconds.
NORMAL (Guarded)
Safety guard down. Pressure loss below 2,100 psi In one hydraulic system activates hydlaullc transfer pump to supply pressure from the other system.
HIGH -
Guard must be lifted. Activates the power module (high speed mode) bypassing flight and combined 2,100-psi switches.
LOW -
Guard must be lifted. Activates the backup power module (low-speed mode) bypassing flight and combined 2,100-psi switches.
AUTO (LOW) -
Safety guard down. The backup flight control system is automatically activated (low-speed mode) when pressure in both the flight and combined systems is less than 2,100 psi.
PUMP
EMERG FLT HYD switch
Figure 2-39. Hydraulic
ORIGINAL
System Controls and Indicators (Sheet 2 of 2)
2-70
NAVAIR 0%F14AAD-1
selected.The recommendedrateof operationisapproximately 12 cycles per minute (a cycle is a complete forward andat?movement of the pump handle). If pressurein either system remains below 500 psi for 5 seconds,immediately lift the guard and select SHUTOFF with the HYD TRANSFER PUMP switch. Failure of the hydraulic transfer pump to automatically shut off after 10 secondsbelow 500 psi may causethe driving systemto cavitateandoverheat. Witb ground electrical power connectedto the aircraft,the hydraulic transferpump is deactivatedandcan onlybe energizedbyaswitchonthegroundcheckpanel. Normally, with both engines running, the hydraulic transferpump is off. However with less than 2,100 psi hydraulic pump dischargepressurefrom either system, the pump will automatically come on and supply hydraulic power to the faulty system. The pilot has no direct control over the direction of pump flow, the system automatically shitls in the direction that supplemental power is requited. Because of the location of the flight andcombined systempressureswitches,the pressurizationcontribution ofthe hydraulic transferpump is reflected on the hydraulic pressure indicator but the HYD PRESS cautionlight will remain illuminated. Operation on the hydraulic transfer pump may produce slight pressurefluctuations. If the failed system dischargepressureis restoredto normal operatingpressure (>2,400 psi) by the engine-driven pump, this HYD PRESS light will go out andthe hydraulic transferpump will shut off. 2.18.1.4 Cockpit Handpump. A manually operated pump handle is provided as a supplementarysourceof power for ground operationswith engines shut down andasa backupfor the lossofcombined systempressure to operatethe in-flight refueling probe or charge the brakeaccumulator.It is an extendiblehandlein the pilot cockpit betweenthe left consoleand ejection seat.Forward and aft stroking of the handpump operates a doubleacting wobble pump. The pump, which draws fluid from the combined system return line, recharges wheelbrakeaccumulatorpressurewhenthe landinggear handle is down. It also servesas a backup means of extendingor retracting the in-flight refueling probe by placing the REFUEL PROBE switch in the desiredposition (EXT or RET). The handpumpis the only meansof pressurizingthe radome fold actuator,an operationthat must be manually selectedand the radomeunlockedon deck from the nosewheelwell. The operationrateusing the handpump power sourceis a function of the numberof components
2.16.2 Hydraulic Power Distribution. The distribution of hydraulic power in the flight and combined systemsis shown on FO-10. Except for the left empennage control surfaces,the flight system services only those componentson the right side of the aircraft and doesnot penetrateinto the wings. The combinedsystem distribution is more.extensivethroughout the aircraft, yet its servicesare predominantly concentratedto the left side and extendto the inboardsectionsof the movable wing panelsand to the landing gear.Although the flight and combined systems are completely independentof eachother,in certaincomponentsboth pressure soumesare used without an interchangeof fluid. Both systems operatein parallel to supply power for operationof the primary flight control surfaces(except spoilers) and stability augmentationactuators; if one system fails, the other can continueto supply pressure for operation (with reducedpower capability of such components).If either or both main hydraulic systems should fail, backup soumesprovide the capability for safe return flight and landing. Major componentsin the combined and flight hy draulic power supply systems are shown on FO-10. Each systemhas a piston-typereservoirand filter module in the sponsonat?of the main landing gear strut on the respectiveside (combined-lett,flight-right). Protrusion of mechanicalpins on eachfilter module indicates a cloggedfilter. 2.16.2.1 Hydraulic Priority Valves. The combined and flight hydraulic systemseachincorporatetwo priority valves (1,800psi and 2,400psi) shown on FO-10. Hydraulic fluid will not passthroughthe one-waypriority valvesunlessthe input pressureexceedsthecracking threshold of the valve. Basically, the 2,400 psi priority valves give priority of the individual engine driven pump dischargepressureto the primary flight controls (horizontaltails, rudders,inboardspoilers)and stability augmentationactuators.Conversely,the 1,808 psi priority valvesgive priority to the remabringsystems on the other side (inlet ramps, wing sweep,em.) with pressuresuppliedby thehydraulic transferpump. Under such circumstances,the pilot should be.aware of the hydraulic energyavailable and demandsof the various system components. Large and abrupt control commands can rapidly consume total energy with the engine(s) at IDLE speed. For example, during a single-enginelandingrollout, ifexcessive horizontaltail movementsarecommanded,thenosewheelstewingand wheelbrakeoperationcould be temporarily lost.
ORIGINAL
NAVAIR Ol-Fl4AAD-I
2.16.2.2 Normal Hydraulic Isolation. The combined system incorporatesisolation circuits to limit distribution of flight essential components. With the LDG GEAR handle UP, normal isolation may be selectedby the pilot to prevent loss of hydraulic fluid in the event of material failure or combat damage to the isolated systems.Normal isolation electrically shutsoff hydraulic pressureto wheelbrakes,antiskid, landing gear,and nosewheelsteering.It is activatedby placementof the HYD ISOL switch to FLT on the landing gear panel. Placementof the gearhandleto DN mechanically cams the HYD ISOL switch to T.O./LDG or the pilot can manuallyselectitbeforeloweringthelandinggear. Such action returnsall combined-systemcomponentsto normal operation. 2.16.3 Outboard Spoiler System. The outboard spoilersare poweredby a separateclosed-loopsystem, independentof the main hydraulic systems(seeFigure 2-40). An electrohydraulic power module supplieshydraulic pressurefor outboardspoilerdeflection andprovidesa backuppower sourcefor the main flapsandslats. Outboard spoiler operation is electrically inhibited at wing-sweepanglesgreaterthan 62” andthepower module isdeactivatedatwing-sweepanglesgreaterthan65”. A thermal cutout circuit securesthe system in the eventofoverheating.Normal operationis automatically restored when fluid temperature falls below the prescribedlimit. The thermal cutout circuit is disabledwith the gearhandledown and weight off wheels to prevent overtemperatureshutdownsduring takeoff or landing. To avoid overheatingbecauseof prolongedground operations,the outboardpower module is deactivatedwith theflap handleup when on internal electricalpowerwith weight on wheels. Electrical power for the outboardspoiler system motor is supplied from the right main ac bus. The module can be activatedusing externalac electricalpower. With the module pressurized,the ON flag appearsin the SPOIL window at the bottom of the hydraulic pressure indicator; otherwise, an OFF indication is displayed in the window. Reservoirservicing level is shownby anindicator rod protruding from the integral power package.A fluid temperaturegauge that registers current and retained peak systemtemperaturesis on the power module. Protrusion of a red-tippedpin on the integratedfilter package is an indication of a clogged filter. 2.16.3.1 Flap and Slat Backup Operation. AIthough normal operationof the main flap and slat segments is powered by a combined system motor on the ORIGINAL
2-72
flap andslat gearbox,an auxiliary motor poweredby the outboardspoiler system is gearedto the same shaft to provide for emergencyoperation(retractionand extension) of themain flaps andslatsat a reducedrate.Failure of combinedsystempressureactivatestheauxiliary motor to drive the flap and slat gearboxwhen selectedby the normal flap handle or maneuvering flap thumbwheel. 2.16.4 Backup Flight Control System. The backup flight control systemconsistsof a two-speedelectrohydraulic power module known as the backup flight control module.The BFCM providesfluid energyto operate the horizontal tails and rudders at a reducedrate (see Figure 2-41). Emergency power provides sufficient pitch, roll, andyaw control for return flight andlanding with both main hydraulic power systemsinoperative. Returnflow from the combinedsideofthe rudderand stabilizer actuatorsis first used to ensure the BFCM reservoiris filled. When tilled, a reservoirbypassvalve opens,which allows return flow to the combined system. A priority valve connectsthe BFCM return to the aircraft’s combined systemreturn. When the combined system pressurefalls below 300 psi, the priority valve closes, isolating the BFCM return from the combined system return. When the combined pressureexceeds 500 psi, the priority valve opens allowing the backup system returnto flow into the combined system return. A check valve isolatesbackupsystempressurefrom the combined systemwhen the BFCM is energized. 2.16.4.1 Backup Flight Control Operation. The BFCM may be operatedin two modes: emergencyand groundtest.In the emergencymode, the BFCM is controlled by the EMERG FLT HYD switch, on the MASTER TEST panel. The switch has three positions: (AUTO) LOW, LOW, and HIGH mode. Electric power to the motor is supplied by the right main ac electrical bus through the FLT HYD BACKUP PH A (2Al), PH B (2Cl). and PH C (2El) circuit breakerslocated on right main ac circuit breakerpanel (No. 2) in the rear cockpit. Lossofboth engine-drivenelectricalgenerators eliminates in-flight use of the BFCM.
Never use the three-phasecircuit breakers (PH A, PH B, and PH C) to start or shut off the BFCM as damageto the motor may result. Thesecircuits must be engagedprior to any systemtest.
NAVAIR 01.Fl4AAD-1
Automatic control of the BFCM is provided by the closing of both flight and combined hydraulic system pressureswitches. Since the switches are set at 2,100 psi, both flight and combined hydraulic system pressuresmust drop below 2,100 psi before the BFCM is turnedon in the automaticlow mode. Oncein this automatic mode of operation,the BFCM cannotbe turned offunless eitherorboth flight andcombinedsystemsare pressurizedabove 2,400 psi. The EMERG FLT HYD switch is usedto selectthe low or high mode. Either of thesepositions overridesthe circuitry of the automatic low mode and the BFCM will remain on evenif either or both system pressuresbecome pressurized above 2,400psi. When the BFCM pump reaches500 psi, the ON flag appearsin the selectedwindow at the bottom of thehydraulic pressureindicator.
Whenoperatedin conjunctionwith zerocombinedsystempressure,someBFCM hydraulic fluid will be forcedout by thermalexpansion. TheBFCM will remainfully servicedandwill operatenormally aslong as the elevatedtemperaturesaremaintained.Onceoperating,the BFCM shouldnot beturnedoff in flight without combinedsystempressureavailableto reservice it. Doing so would result in fluid contraction and an underservicedcondition thatcouldpreventsubsequent pump operation.
should indicate zero in order to fully test independent operationof the BFCM.
A 180 “F thermal cutoff switch is bypassedwhen the BFCM is selected on with the EMERG FLT BYD switch. Prolongedgroundoperationin theemergency mode will result in BFCM burnout. Since flight control demandscan exceed BFCM capability, all surface demands must be performedslowly and cautiously in ordernot to exceedthe outputrateof the system. Excessive system demandswill causethepump to cavitateandthemotor to overheat.Checksshould be made slowly enoughto ensurecontinuouson indication in the hydraulic pressureindicator. 2.16.4.2.1 Ground Test Mode. The ground test mode of operation is controlled by the AUX BYD CONT switch on the groundtestpanel in the rearcockpit. In this mode,the BFCM operatesin the high mode only. Ground test from the rear cockpit is electrically inhibited when the aircraft is on internal electrical power.For groundinspectionpurposes,protrusionof a red-tippedbuttonon either the inlet or outlet filter cases is a positive indication of a dirty filter. Both such indicationsmay be observedthroughan accessdoor on the undersideof the aft fuselage. f7jYjlJ
If eitherthe flight or the combined hydraulic systempressuredropsbelow 2,100psi without illuminating the HYD PRESS caution light, the automatic low mode of the backup flight control systemmay be inoperative. 2.16.4.2 Ground Operations. Ground checks of the BFCM areperformedby the pilot using the EMER FLT BYD switch. Before performing ground checks, the combinedand brake system accumulatorsmust be charged.The BFCM hasa small volume capacity,1,000 cc (61 cubic inches) when full, but will decreasein volume to 500 cc (30.5 cubic inches)when the aircratt is not in use.Below 500 cc (30.5 cubic inches),cavitation of the pump and overheatingof the motor may occur.If the accumulatorsarenot chargedprior to starting the BFCM, depletionofthe reservoirhydraulic fluid will occur.If this occurstoo frequently,systemdamage andfailure may result. Both hydraulic systempressures 2-75
The ground test mode incorporatesa solenoid valve that allows the BFCM to pressurize the entirecombinedhydraulic system. If thecombinedandbrakeaccumulatorsarenot fully charged(brakepressureindicatorat top of green),or if the combined system is not fully serviced,the reservoirwill be depleted and the motor will cavitate and overheat. This could result in motor failure prior to activation of the thermal cutoff switch. In thelow-speedmode,the systemcanoperateindefinitely and should be used for maximum rangeand endurance. Emergency power (high mode) provides a maximum unloadedhorizontal tail deflection rate approximately onefourthof that availablefrom a full powered hydraulic system (IO’ per second vice 36Oper second).The maximum deflection rate available will decreaseas airloadsincrease. ORIGINAL
NAVAIR
Ol-Fl4AAD-1
Emergency Gear Extension. Tbebottlethat supplies the pneumatic force for a single emergency extensionof the landing gear is on the right side of the nosewheelwell. Expenditureof bottle pressureis controlled by a twist-pull operation of the landing gear handle. Minimum bottle pressure for accomplishing emergency extension of the gear to the down-andlocked condition is 1,800 psi. Normal preflight bottle pressureis 3,000psi at 70 “F.
2.17.3
Prolongeduse(approximately8 minutes cumulative time) of the BFCM in the high mode may result in a failure of the BFCM. 2.17
PNEUMATIC
POWER
SUPPLY
SYSTEMS
Thepneumaticpowersupply systemsconsistof three independent,storedpneumaticpressuresourcesfor normal andauxiliary operationof thecanopyand for emergencyextensionof the landing gear.The high-pressure bottles for normal canopy operation and emergency landing gear extensionare ground-chargedthrough a common filter connectionin thenosewheelwell to 3,000 psi at 70 “F ambient temperature.Individual bottle pressureis registeredon separategaugeson the right sideof the nosewheelwell. An auxiliary canopy-openNz bottle, filter valve, andgaugeis on the turtlebackbehindthe cockpit to allow openingthe canopyfrom the cockpit or ground.Chargesmay be compressedair; however,pressurizeddrynitrogenispreferredbecauseofitslowmoisture contentand inert properties. The bottle that suppliesapressurizedchargefornormaloperationofthe canopy is on the right side of the forward fuselage, inboard of the air refuel probe cavity. Expenditure of bottle pressurefor normal operation of the canopy is controlled by three (pilot, RIO, and ground) canopy control handles. A fully chargedbottle provides approximately 10 completecycles (openandclose) of the canopy before reaching the minimum operatingpressureof 225 psi. 2.17.1
2.17.2
Normal
Auxiliary
Canopy
Canopy
Control.
Open Control.
The aux-
iliaty canopy air bottle suppliesa pneumatic chargeto translatethe canopyaft so that the counter-poiseaction of the canopy actuator facilitates opening.It is on the turtlebackbehind the canopy hinge line. Activation of theauxiliary modecanbeeffectedfrom eitherof thethree(pilot, RIO, or ground)canopycontrol handles.After activationof the auxiliary openmode,the control system will not return to the normal mode of operation(canopywill lower but will not translateforward) until the auxiliary selectorvalve on theaft canopy deck is manually reset(lever in vertical position). Servicing of the auxiliary canopy air bottle is through the small accesspanel immediately behind the canopy on the turtleback. The reservoir is normally serviced to 3,000psi at 70 ‘F ambienttemperature.A fully charged bottle providesmore than20 operationsin the auxiliary open mode. Minimum preflight pressureis 800 psi. ORIGINAL
2-76
Note
Emergencyextensionof the landing gear shallbe logged in the MaintenanceAction Form (OPNAV Form 3760-2). Once the landing gear is extended by emergencymeans, it cannot be retracted while airborneandmust be resetby maintenancepersonnel. Use of emergencygear extensionresults in loss of nosewheelsteering. 2.18.
MISSION
COMPUTER
SYSTEM
The MCS consistsof two AN/AYK-14 digital computer (MC1 and MC2) and the dual redundantMILSTD-1553B buses. The MCS is operatedat 16 MHz clock speedto perform 1million instructionsper second using up to I megabyteof memory. The 1553B bus system in the F-14D uses time division multiplexing (TDM) with information coded into 20-bit words. Communication protocol is establishedby a command responsesystem in which all bus transmissions occur under command of a bus controller or, in caseof failure of primary bus controller, a backupbus controller. Each bus is capableof addressingup to 31 remote terminals;however,address31 is not usedin theaircraft. Figure 2-42 depicts the physical connection of the WRAs in the MCS data bus system.Remoteterminals incapableof communicating directly with the MCS on the 1553 data buses are routed through the converter interfaceunit for requiredanalog-to-digitaland digitalto-analogconversion. Aircrew Interface. The principle aircrew interfacewith the MCS is accomplishedthroughthepushbuttons on each MFD. The RIO has an additional interfacethroughthe DEU communicatingdirectly with the MCS as a remote terminal. The RIO can also interface indirectly with the MCS throughthe radarsystem digital display.
2.18.1
NAVAIR
Figure. 2-42. Mission Computer
2-77
01-Fl4AAD-1
System Architecture
ORIGINAL
NAVAIR 2.18.2
01-Fl4AAD-1 Operational
States.
2.19
The MCS has three op-
erationalstates:startup,full up, andbackup.Thesestates are mutually exclusive and are determined automatically basedon aircraft operationand MCI/MC2 condi-
1. The MCS immediately stopsexecutingthe OFP. 2. The mission computersgo off line and run software BIT.
CENTRAL
AIR DATA
Note
tion.
The SYS RESET button on the NAV MODE panel forcesbothmission computersto transitionto the startup stateandexecutecold startlogic. It canbe usedto assure the aircrew that the MCS is functioning properly and/or to reinitialize the MCS by restarting the OFP. When SYS RESET is pressed,the following events occur:
STANDARD COMPUTER
The acronyms SCADC andCADC areused interchangeablythroughoutthis manual. The SCADC CPU-175/A is installed in F-14D aircraft incorporatingAFC 793. The SCADC is functionally interchangeablewith the CADC 1166B/A with one difference,the SCADC softwareincorporatesfhestaticerror source-correctioncurve required for the true values of Mach number, airspeed,and altitude. Aircraft prior lo AFC 793 (CADC 1166B/A) aircrew should refer to NAVAIR 01-F14AAP-1.1 for BUD displayed altitude and Mach number correctioncurves. Note
3. The OFP is automatically restarted.
The standby airspeed indicator is not correctedfor position error.
4. The aircraft goesinto the TLN mastermode.
The CADC is a single-processordigital computer with a separate,independent, analog, backup wingsweepchannel.It is capableof making yes andno decisions, solving mathematical problems, and converting outputs to either digital or analog form as requiredby each aircraft system. The CADC gathers,stores,and processespitot pressure,static pressure,total temperatureandAOA data from the aircraft airstream sensors. (seeFigure 2-43). It performs wing-sweepand flapand slat schedulecomputations,limit control and electrical interlocks, failure detection,andsystemstest logic. Major systemsthat dependon all or part of theseCADC functionsare shown in Figure 2-44.
5. Displays revertto defaults. Recycling power (by cycling circuit breakers) to the MCS has the same effect as pressing the SYS RESET except that both hardware and software BIT is performed. Note
Cycling subsystemcircuit breakersinitiates acold start for thatsubsystem.A systemreset may be required to resynchronizethe MCS andthe restartedsubsystem. Refer to NAVAIR 01-Fl4AAD-IA for a completedescription of the MCS architecture, operational states, and backup operation.
The following legendsappearon the MFD when activated by the CADC:
There are three aircraft master modes of operation: takeoff-landingnavigation (TLN), air-to-air (A/A), and air-to-ground (A/G). The controls, displays, and avionics equipment aretailored as a function of the mastermode selectedby thepilot. The TLN mastermode is enteredautomatically when power is applied to the aircraft, when the landing gearis down, or when the TLN mastermodepushbutton is selectedon the PDCP. The A/A master mode is enteredby pressing the A/A master mode pushbuttonon the PDCP, selecting an air-to-air weapon with the weapon select switch on the pilot control stick, or by commanding a radar dogfight mode. The A/G master mode is enteredby pressingthe A/G mastermodepushbutton on the PDCP.
1. RDC SPD (warning legend) - (REDUCE SPEED) - Indicates flaps down above 225 knots; maximum safeMach exceeded(2.4 Mach/ total temperatureabove388 “F).
2.18.3
Aircraft
Master
Modes.
2-78
2. W/S (caution legend) - (WING SWEEP) Indicates dual wing-sweep channel failure or wing-sweepdetentdisengaged. 2.19.1 2.19.1.1
Central Built-In
Air Data Computer Test.
Tests
BIT capabilities provide con-
tinuous monitoring of the CADC and its inputs and outputs. The failure indicator matrix (Figure 2-45) tabulatesthe functionsthat aremonitoredandassociated fail indications.
NAVAIR Ol-F14AAD-1
USlNG
. . . . . . . .
SYSTEM
CADC PROCESSOR
: . . .
Figure 2-43. CADC Functional Relationships
PITOT
TOTAL PRESSURE TRANSOVCER I ’ L--------A
SWEEP COMPUTER I
b
I
0.F5co366
Figure 2-44. CADC Processor 2-79
ORIGINAL
NAVAIR 01-F14AAD-1
Figure 2-45. CADC ProcessorIndicators
ORIGINAL
2-80
NAVAIR Ol-Fl4AAD-l
2.19.1.2 On-Board Checkout. TheCADCperforms a self-test during OBC only with weight on wheels. WhenOBC is initiated, normal air datainputsarelocked out andin their placeconstantsfrom thecomputermemory are received. Self-test detected failures may be manually resetby pressingthe MASTER RESET pushbutton.
for maximum maneuveringperformance.The pilot can selectively position the wings at sweep angles aft of optimum.
Pressingthe MASTER RESET pushbuttonfor 1 secondresetstransientfailuresin theCADC. Activating the masterresetcircuit recyclesthefailure detectionprocess in the CADC. This recycling processputsoff thecaution andadvisorylight(s) andmay take aslong as 10seconds to check out the statusof the system.If a failure exists, the light(s) will illuminate again. If a transient failure existed,the light(s) will remain off.
The outboardlocation of the wing pivot reducesthe changein longitudinal stability as a function of wingsweep angle. Two independently powered, hydromechanical screwjack actuators, mechanically interconnectedfor synchronization,position the wings in responseto pilot or CADC commands.In flight, the wings can be positioned between 20” and 6S0 wing leading-edgesweep angle. On the deck, the range is extendedatI 75O(oversweepposition)to reducethe span for spotting.Suchauthorityresultsin avariation of wing spanfrom approximately64 to 33 feet.
A mechanicalbackupcontrol systemis provided for emergencyand oversweep operations.Details of the wing-sweepsystem are shown in FO-11.
The following caution and advisory lights are activatedby the CADC:
Cavities above the enginenacellesand the midfuselage accommodate the inboard portions of the wing panels as they sweep aft. Sealing of the underside is by a wiper seal and airbag. The bag is pressurizedby engine bleed air. Airbag pressureis releasedduring oversweep to avoid overloading of the flap mechanism. An overwing fairing enclosesthe wing cavity andprovides a con-toured sealalong the upper surface of the wing for the normal range of in-flight sweep angles. The left and right overwing fairing actuators are pressurizedby the combined and flight hydraulic systems,respectively.
1. CADC 2. FLAP 3. WING SWEEP (advisory) - If the WING SWEEP advisory light does not recycle when MASTER RESET pushbutton is depressed,the light is activatedby the wing flap controller. Three independent CADC fail signals drive the AFCS failure detection circuits. If thesesignals exist, the AFCS will illuminate the following lights: 1. CADC fail signal pitch computer -
No Light
2. CADC fail signalto yaw computer AUTH andHZ TAIL AUTH 3. CADC fail signal to roll computer TRIM.
RUDDER MACH
PressingMASTER RESET pushbuttonwill also updatethewing-sweepandflap commandsto their respective feedback signals. As a result, there may be movementin thewings andmaneuverflaps whenMASTER RESET pushbuttonis depressed. 2.20 WING-SWEEP SYSTEM The variable geometry of the wing-sweep system providesthe pilot with considerablelatitude for controllingwingliftanddragcharacterlstics to optimizeaircraft performanceover a broadflight spectrum. Under normal operating conditions, the wings are automatically positioned to the optimum sweep angle 2-91
2.20.1 Wing-Sweep Performance. Maximum wing-sweeprate (approximately 15’ per second)is adequate for most transient flight conditions; however, wing-sweepratecan be significantly reducedor stalled by negative-gor large positive-g excursions.Sufftcient capability hasbeen provided in the system, consistent with the sustainedperformancecapabilities of the aircraft. With a failure of either the combined or flight hydraulic systems,the wings will move at a reduced rate. Note a The overwing fairings and flaps are susceptibleto a high frequency(60 cyclesper second), low-amplitude oscillation that canbe felt in cockpit. This overwing fairing and flap buzz is normal and is influencedby rigging of the fairings and air in the hydraulic systems. l
Overwing fairing and flap buzz is usually encounteredbetween0.9 and 1.4 Mach. ORIGINAL
x$&i ;,,!q~.&wwp Modes. Normal control of the wing-sweepposition in AUTO, AFT, FWD, andBOMB modes is by the four-way wing-sweep switch on the inboard side of the right throttle grip (Figure 2-46). As an emergencymode of conno& changesin wing-sweep position can be selectedmanually with the emergency WING S-WEEPhandleon the inboardsideofthe throttle quadrant.The handleis connecteddirectly to the wingsweephydraulic valves. The command sourcefor positioning the wings dependsupon the mode selectedby the pilot or, in certain cases,is automatically selected. Electrical andmechanicalwing-sweepcommand paths areshown on FO-11. Wing-sweepmodesare shown in Figure 2-47.
mode, the four-way wing-sweep switch can be in the centerposition without changingthe command mode. 2.20.2.2 Manual Mode. The manual wing-sweep modeiscommandedbyselectingAFTorFWDt?omthe neutral position of the wing-sweep switch, driving the wings in the commandeddirection to any wing-sweep position aft of the automatic program. The switch is spring loaded to return to the centerposition. Manual command mode exists unlessthe wing-sweepprogram isintercepted,atwhichpointtransfertotheAUTOmode is automatic.Indication of the existingmode is provided by the AUTO and MAN flags in the wing-sweep indicator. 2.20.2.3 Bomb Mode. Bomb mode is selectedby moving the wing-sweep switch to the down (BOMB) position. With the switch in BOMB, the following occurs:
Anytime hydraulic pressureis on, the wings cm bemovedinadvertently.Whenpositioning thewings during groundoperationotherthan pilotpoststartorpostlandingchecklistprocedures, use the emergency WING SWEEP handleto minimize the possibility of moving the wings inadvertently.
1. Wing SWEEP indicator showsh4AN flag. 2. If wing sweepis lessthan 5S0,wings will drive to 550. 3. If wing sweepis greaterthan 5S0,wings will not move.
Note :j When positioning the wings, do not command oppositediition until wings have stoppedin original commandedposition (all sweepmodes) to increasemotor life.
4. If maneuverflaps are extended,they will retract andwings will sweepto 5S”. As the aircraft accelerates and the AUTO wingsweepscheduleis intercepted,the wings will follow the AUTO schedule even though the switch remains in BOMB mode.Upon decelerating,the wings will sweep forward to 55’ and stop.
e Theoptimumwingposition(triangularindex) and the AUTOMAN flags may be unreliable when the CADC caution light is illuminated. 220.211 AUTO Mode. Selectionof theAUTO mode is made by placing the four-way wing-sweep switch in the upper detented position, AUTO, permitting the CADC Wing-sweepprogramto position the wings automatically. The programpositionsthe wings primarily as a fonction of Mach number but includes pressurealtitudebiasing.Wing position is scheduledto the optimum sweep angle for developing maximum maneuvering performsnce.Iuadditiontoprovidmganautomaticwing positioning fimction, the programmer also defmes the forward sweeplimit that cannotbe penetratedusing any of the &her eleetrieat(manual or bomb) modes. The forward sweep limiter preventselectrical mispositioning of the wings from a wing stmctore standpoint. Pilot selectionof theAUTO modeor automatictmnsf?r Tom the manual mode causesthe AUTO flag to Oppe.%in the wingsweep indicator. Once in the AUTO ORIGINAL
2-82
2.20.2.4 Emergency Mode. During normal mode operationof the wing-sweep system, the wing-sweep control drive servodrives the hydraulic valve command input through a spider &tent mechanism. The emergency handle under a tmnsparentguard is moved in parallel with the servo output. The emergencymode provides an emergency method of controlling wing sweep. It bypassesthe normal command path of the fly-by-wire system (CAM: and control drive servo loop). To select emergencymode, the handle must be extendedvertically. The guardshouldbe moved out of the way beforethe handle is operated.Vertical extensionof the emergencyhandle provides for better accessibility andleverage.The detentis not disengagedby raisingthe handlevertically. An initial fore or aft force of up to 30 poundsbreakoutand 13poundsmaximum is necessary for operation.
NAVAIR 01.FI4AADI
NOMENCLATURE 0
FUNCTION
Wing sweep switch
AUTO -
Wing sweep angles are determined by CADC according to wing sweep program. Detented switch position.
BOMB -
Wings are positioned at 55’ or further aft if commanded CADC program. Detented switch position.
by the
AFT/FWD - The pilot can select AFT or FWD wing positions within limits imposed by the wing sweep program. Switch is spring-loaded the center position. When the forward limit is intercepted, the mode is transferred to AUTO.
to
0
Emergency WING SWEEP handle
Provides a mechanical means of wing sweep control that overrides the CADC program commands. Wing sweep SngleS between ZOO and 66O are mrestricted except for flap interlocks. Oversweep 75’ is provided with weight-on-wheels, horizontal stabilizer authority restricter in reduced range, and air bag pressure dumped.
@
Wing SWEEP indicator
lisplays (from right to left) actual wing sweep position, commanded position and wing sweep program position, which is the maximum forward angle at Iresent airspeed and attitudes. Indicator windows show the operating mode.
@
W/S caution legend on MFD
ndicates failure of both wing sweep channels and/or disengagement of spider detent. Wing sweep positioning requires using the emergency wing sweep handle.
Figure 2-46. Wing-Sweep Controlsand Indicators(Sheet 1 of 2)
2-83
ORIGINAL
NAVAIR
01.Fl4AAD-1
NOMENCLATURE 0
@
FUNCTION
CADC caution light
indicates hardware failure and/or that certain computations of the air data computer are unreliable. Illumination of WING SWEEP advisory light and/or W/S caution legend on MFD determines pilot action.
;;G
Indicates failure of a single channel in the system. Illumination of both WING SWEEP advisory and CADC caution light indicates failure of one channel in CADC.
SWEEP advisory
Figure 2-46. Wing-Sweep Controlsand Indicators (Sheet2 of 2) The spider detentis reengagedif the handleis repositionedto the detent(servo)position. The emergencyWING SWEEP handle incoipomtes locks at approximately 4Oincrementsbetween20” and 68”. Theselocks areprovidedto eliminate randomwing movement in the emergency mode should electrical system transientsbe experienced.When the locks are engaged,wing movement is inhibited provided that wings match handle position. The wing-sweep locks eliminate the need for the installation of wing-sweep servocutout switches.Locks areengagedby raising the handle 1 inch from the stowed position. In order to bypassthe locks and select a wing position, the handle is raisedan additional 1 inch (2 inchesfrom stowed)and moved to the desired position. The handle is spring loadedto retnrnto the lock position when released.The handlecanbe raisedhorn 20” to 68” andoversweep,but can only be returnedto the stowedposition at 20” and oversweep.This featureis intendedto preventinadvertent engagementof theAUTO MODE, commandingthe wings to spreadcausingpossible damageto the aircraft or injury to personnelin a confined area.The handleis spring loadedtoward the stowed position, but requires depressingthe releasebutton on the inboard side of the lever in orderto returnthe handleto the stowedposition.
In certain failure modes, the flap indicator may not accuratelyreflect the position of all flaps. Since the wing-sweep program acts as a forward liter only for the normal modesof operation,thepilot must follow the following schedulein the emergency mode: 1. 0.4 Mach -
20’
2. 0.7Mach -
25’
3. 0.8Mach -
50”
4. 0.9 Mach -
60”
4. 1.OMach -
68’.
When operatingin the emergencymode, pulling the WlNGSWEEPDRIVENO.l(LDl)andWGSWPDR NO. 2MANUV FLAP (LEl) circuit breakerson the pilot letI kneepanelassuresthat the electrical command path cannotinterferewith the emergencymode. 2.20.2.5 Oversweep Mode (75’). The wing oversweepmode allows sweepingthe wings aft of 68’ to 75” during on-deck operation only, thereby reducing the overall width of the aircraft for deck spotting. At 75”, the wing trailing edgeis over the horizontal tail surface.
a Except for wing flap (main and auxiliary) and oversweepinterlocks in the control box, the emergencymode does not prevent pilot mispositioning the wings from a structuralstandpoint. a If operatingin the emergencywing-sweep mode, positively confirm all flaps are retracted prior to attempting AFT wing sweep.
ORIGINAL
With the wings at 68O,oversweepcan be initiated by raising the emergencyWING SWEEP handleto its full extensionand holding. Raising the handle releasesair pressurefrom the wing-seal airbags and activatesthe horizontal tail authority system, restricting the surface deflectionsto 18Otrailing edgeup and 12“ trailing edge down.During motion of thehorizontal stabilizerrestrictom.,the HZ TAIL AUTH caution light is illuminated. When the horizontal tail authority restriction is accomplished (approximately 15 seconds), the HZ TAIL AU’IH caution light will go off and the OVER flag on : 1-84
NAVAIR
OMWAAD-1
68 60 SWEEP ANGLE DEGREES
4o
20 MACH
SWEEP ANGLE DEGREES
SWEEP ANGLE DEGREES
PROCEDURES ENCY OPERATION
20 EMERGENCY
MACH 75 68 SWEEP
ANGLE DEGAEES
I
INOPERATIVE WHEN AIRBORNE
1 OVERSWEEP
Figure 2-47. Wing-SweepModes
2-85
ORIGINAL
NAVAIR Ol-F14AAD-1
electrically inhibited at normal accelerationsless than -0.5g.
the wing-sweep indicator will be visible. This advises thepilot that the oversweepinterlocksaretree,allowing movementof the emergencyWING SWEEP handleto 7Y andstow.The EMER andOVER onthewing-sweep indicator will be visible.
2.20.3.1 Flap and Slat Wing-Sweep Control Box. Electromechanical (auxiliary flaps, oversweep enable) and mechanical (main flap) interlocks in the control box limit aft wing-sweep commandsat 21’15’, 50”, and 68”. Interloclm in the control box areshown in Figure 2-48. Theseinterlocks, which serveasa backup to the electronic interlocks in the CADC, are imposed on both the normal and the emergency inputs to the control box and assure.noninterferencebetweenmovable surfacesand the fuselage.
Failure of the oversweepinterlocks while trying to achieveoversweepmay result in damageto the wingtip and horizontal tail trailing edges, and the maneuver flap actuator.
2.20.4 Wing-Sweep System Test.
If unusualresistanceis encounteredwhile attempting to put the wings into oversweep, continued aft pressure on the WING SWEEP handlemay causefailure of the wing-sweep actuator. Avoid stick movementswith the wings in oversweepandthe HZ TAIL AUTH light illuminated and/orthe OVER flag not displayed in the wing-sweepindicator. The reverseprocesstakesplace when sweepingforward from oversweep.However, there is no need to hold the emergencyhandlein the raisedposition at 68”. Motion out ofoversweepis completed(wing-sealairbag pressureestablishedandhorizontaltail authorityrestriction removed) when both the OVER flag and the HZ TAIL AUTH cautionlights areoff. Six secondslaterthe WING SWEEP advisory light will illuminate. Upon engagementof the spiderdetentby furtherunsweeping the emergencyhandle,MASTER RESET pushbuttonis pressedto clear the WING SWEEP advisory light, thus activating the electrical command circuits of the wingsweepsystem.
2.20.4.1 Continuous Monitor. The command and execution of the wing-sweep system is continually monitored by a failure detection system. The failure detectionsystem in the CADC governsthe changefrom wing-sweepchannel 1 to channel2 or the disabling of wing-sweepcharnel 1 or 2 by switching the respective control drive servo off. A single channel failure in the wing-sweep electrical command path is indicated by illumination of the WING SWEEP advisory light followed by normal operation on the remaining channel. Failure of the remaining channelis indicated by a W/S caution legend on the MFD and requires that wingsweep control be exercised through the emergency WING SWEEP handle.Transientfailures in the CADC canbe resetby pressingtheMASTER RESET pushbutton, which recyclesthe failure detectionsystem. 2.20.4.2 Preflight Check. A preflight check of the wing-sweep system to assureproper operation of the electrical command circuits without moving the wings shouldbe accomplishedafter startingengineswhile the wings are in oversweep(759. 1. Set wing-sweepmode switch to AUTO. Note The CADC caution light will illuminate and test will not run if AUTO is not selectedon the wing-sweep switch.
When coming out of oversweepand a 68O wing position is desired,the wings shouldbe moved fotward to approximately 60° and thenback to 68”.
2. PressMASTER RESET pushbutton.
2.20.3 Wing-Sweep Interlocks. Automatic limiting of wing-sweep authority is provided under normal inflight control modes to prevent mispositioning of the wings at conditions that could result in the penetration of Structuralboundaries.Wing-sweepinterlocks within the CADC areshownin Figure248. Wing sweepis also ORIGINAL
2-88
3. Set MASTER TEST switch to WG SWP. 4. Monitor test by observing: a. Wing-sweep limit pointer drives to 44O. b. Illumination of the WING SWEEP advisory light andFLAP caution light.
NAVAIR Ol-FUAAD-1
Figure 2-48. Wing-SweepInterlocks
2-87
ORIGIhlAL
NAVAIR Ql-F14AAD-l
Note The WING SWEEP advisory light will illuminate 3 secondsafter test starts,then go off andilluminate again at 8 secondsinto test.
A slip clutch assembly is installed between the combinedsystem forward flap hydraulic motor and the center gearbox assembly. While this will relieve some stall torque on the hydraulic motor, extremely fastreversals of flap direction while flaps are in motion may result in eventualfaihue.of the flap and slat flexible driveshaft.
c. RDC SPD warning legendon MFD. d. At end of test (approximately 25 seconds)the limit pointer will drive to 20’ and the above lights will go off. 5. SetMASTER TEST switch to OFF. Note Ignore illumination of RUDDER AUTH cautionor MACH TRIM advisorylights and motion of thecontrolstick ifthey occurduring the test. 2.21 FLAPS AND SLATS The flaps and slats form the high-lift system,which prwides the aircraft with augmentedlift during the two modesof operation:takeoffor landing,andmaneuvering ilight, The flaps am.of the single-slottedtype, sectioned into threepanelsoneachwing. The two outboardsections amthemain Sapsutilixed duringboth modesof operation. The inbeardsection(auxilii flap) is commandedonly duringtakeoffor landing.The slatsconsistoftwo sections per wing mechanically linked to tbe main flaps. Flaps down greaterthan lo0 enablesthe wheelswarning light interlock, and greaterthan 25’ enablesdirect li8 control andpowerapproachspoilergearing.
2.21.1.2 Maneuver Flap and Slat Thumbwheel. The maneuver flap and slat thumbwheel is locatedon theleft sideofthe stick grip andis springloaded to the center position. With LDG GEAR and FLAP handlesup, automatic CADC flap and slat positioning can be overriddenwith pilot thumbwheelinputs to partially or frilly extend or retract the maneuveringflaps and slats;however,the next time angleof attackcrosses an extensionor retractionthreshold,the automaticcommandwill againtakeprecedence,unlessmanually overridden again. Manual thumbwheel command is a proportional command. 2.21.1.3 Main Flaps. The main flaps on eachwing consist of two sectionssimultaneously driven by four mechanical actuatorsgearedto a common flap driveshaft.Each wing incorporatesa flap asymmetry sensor and flap overtravel switches for both the extensionand retraction-cycles.
2.21.1 Flap and Slat Controls Pilot controls for flap and slat takeoff, landing, and maneuveringmodesare illustrated in Figure 2-49. 2.21.1.1 FLAP Handle. The FLAP handle, located outboardof the throttles, is used to manually command flaps and slatsto the takeoff and landing position. Flap handlecommandsaretransmittedby controlcableto the flap andslat andwing-sweepcontrol box wherethey are integrated with CADC electromechanical inputs to commandproper flap and slat position. 2.21 .I .I .l Emergency Flaps. EMER UP enables the pilot to override any electromechanicalcommands that may exist becauseof malfunction of theCADC. Te position the flaps, move the FLAP handle to the endof thenormal travel range;then,move the handleoutboard andcontinuemoving to extremeEMER UP.While moving the handle, forces may be higher than normal. EMER DN has no function. ORIGINAL
2-08
Cove doors, spoilers,eyebrow doors,and gussesoperatewith the flaps to form a slot to optimixe airflow over the deflectedflap. The cove doors are secondary surfacesalong the undersideof the wing forward of the flap (Figure 2-50.) As the flaps pass 25’ deflection, a negativecommand received from the AFCS depresses the spoilersto 41/2O to meet with the cove doors.Be causethe spoilersdo not spanthe entire wing as do the flaps, gussesinboard and outboardof the spoilersperform the flaps-down function of the spoilers.With the flaps retmcted, the eyebrow doora,which are the forward uppersurfaceof the Saps,are springloadedin the up position to closethe gapbetweenthe trailing edgeof the spoiler or guss and the leading edge of the flaps. Mechanical linkage retractsthe eyebrowdoor when the flaps are lowered to provide a smooth contour over the uppersurfaceof the deflectedflap. 2.21 .1.4 Auxlllary Flaps. The auxiliary flaps areinboard of the main flaps and are poweredby the combined hydraulic system. The actuator is design& to mechanically lock the auxiliary flaps when in the up position. In the event of high dynamic pressureconditions, a bypass valve within each control valve opens
NAVAIR
Ql-F14AABI
,MFO WAR LEG ..._._.. _..-. 1 1 i RDCSPD 8 ,.......... . ... .. .. . J \
FUNCTION
NOMENCLATURE
3
FLAP handle
UP -
Normal retraction of main and auxiliary flaps.
DN-
Normal efienslon
of main and auxiliary flaps.
EMER UP - Emergency retraction of main flaps to full up overrldlng any electromechanical command faults. EMER DN -No function.
Figure 2-49. Flap and Slat Controls andIndicators(Sheet 1 of 2)
2-89
ORIGINAL
MAVAIR
O-I-Fl4AAD-l
FUNCTION
- Power off; maneuver slats extended.
-
Slats extended
(17 ).
Slats position is an electrical pickoff of right slat position only
- Slats retracted (0”).
3
RDC SPD legend on MFD and HUD
- Flaps full up (0”).
$7 0
- Maneuver flaps down (10”).
0”,/ III
- Flaps full down (35”).
Main flap comparator failures with flaps not retracted and airspeed >225 KIAS (see figure 2-43). Maximum safe Mach exceeded Total temperature
3
Flap position is pickoff from hydraulic motor for main flaps only i
z? cl
(2.4 M).
exceeds 355°F
Disagreement between main and/or AUX flap position (10 second light) or asymmetry lockout (3 second light).
FLAP caution light
CADC failure. WG SWP DR NO. 2/MANUV FLAP (LEl) circuit breaker pulled.
3
Maneuver flap and slat thumbwheel
Forward -
Commands
maneuver flaps and slats to retract.
Neutral -
Automatic CADC program.
An -
Commands
maneuver flaps and slats to extend.
Figure 2-49. Flap and Slat Controls and Indicators(Sheet 2 of 2) ORIGINAL
2-90
NAVAIR Ol-F14AAD-1
Figure Z-50. Wing Control Surfaces 2-91
ORIGINAL
NAVAIR 01.FMAAD-1
causingthe auxiliary flap to be blown back, thus avoiding possible structuraldamage.During loss of electrical power, the control valve is spring loadedto retract,retracting the auxiliary flaps within 1 minute. The auxiliary flaps use cove doors, eyebrow doors, and gusses identical in purposeandoperationwith thoseassociated with the main flaps.
extended.In a similar manner, upon extension of the main flaps, the wings are electrically andmechanically limited to wing-sweep anglesless than 50’. The FLAP handle is mechanically preventedfrom moving to the down position if wing position is aft of SO”.If flaps are lowered with wings between 21” and 50°, main flaps will extendbut auxiliary flaps will remain retracted.
2.21.1.5 Slats. The slats on each wing are divided into two sections,both of which are driven simuhaneously by a single-slatdriveshat?.The slatsaresupported and guided by sevencurved tracks.
If flaps are extendedwith wings between 21° and SOD,auxiliary flap extension is inhibited and a largenosedownpitch trim changewill occur.
2.21.2 Flap and Slat Operation
l
Note There is no automatic flap/slat retraction.
Pulling the FLAP/SLAT CONTR SHUTOFF circuit breaker(RA2) will eliminate flap overtravelprotectionandcould eliminate mechanical or electrical main and auxiliary flap interlocks and may allow the wings to be swept with the flaps partially or fully down in the wing-sweep emergencymode.
e With flaps extendedby the FLAP handle and an airspeedof 225 knots or greater, the RDC SPD legendappearson the MFD and HUD. 2.21.2.1 Normal Operation. The main flap andslat portion of the high-lit? system is positioned with a dual redundanthydromechanical servoloop in responseto the FLAP handlecommand. The auxiliary flap is a twoposition control surfacepowered by the combined hydraulic system. With the FLAP handle exceeding5’ deflection, the auxiliary flaps fully extend.Conversely, they retract for a FLAP handle position equal to or less than 5“. ‘Ihe torque of the flap and slat drive hydraulic motor is transmitted by flexible driveshafts to each wing. 2.21.2.2 Degraded Operation. In the event of a combined hydraulic system failure, outboard spoiler module fluid is automatically directed to a backuphydraulic motor to lower main flaps and slats only. In the eventof main flap asymmetty greaterthan3”. slat asymmetry greaterthan4O,or flap surfaceovertravel,the flap and slat system is disabled.Flaps and slatswill remain in the position they were in when failure or malfunction occurred. The auxiliary flaps are automatically commandedto retract.There is no asymmetryprotectionfor the auxiliary flaps.
2.21.2.4 Maneuver Flap and Slat Mode. The main flaps canbeextendedto 10’ with theslatsextended to 7” within the altitude and Mach envelopeshown in Figure 2-51. Maneuver flaps and slats areautomatically extended and retractedby the CADC as a function of angle of attack and Mach number (Figure 2-52). The schedule commandsfull maneuver flaps and slats as soonas the slattedwing maneuveringefficiency exceedsthat of the clean wing. Note CADC maneuver flap commands are automatically resetwhen theflap handleis placed down greaterthan 2’, wing-sweep BOMB mode is selected,or maneuverflaps arecommandedto lessthan lo by the CADC because of dynamic pressure. The angle-of-attackinput to the CADC from the alpha computerisinhibitedandwillretractthe~euv~devices if they areextendedwhen theLDG GEAR hgndleis lowered.Thisistoensurethatthemaneuverdevicesareretracted before lowering the FLAP handle. Maneuver devices extendedcondition is indicated by a SLATS barberpoleand an intermediate(10”) flap position.
2.21.2.3 Flap Wing Interlocks. The main flap and auxiliary flap commandsareinterlockedelectrically and mechanically with the wing sweepto preventflap fuselage interference.An electrical interlock in the CADC and a mechanical command in the wing-sweepcontrol box prevent wing sweepaft of 22” with auxiliary flaps
ORIGINAL
2-92
NAVAIR 9l-FMAAD-1
5 0 0.3
0.4
0.6
0.5 MACH
0.7 NUMBER
0.6
a.9
1.0
-TRUE
Figure2-51. ManeuverFlapEnvelope
@F600.2370
Figwe2-52. ManeuverSlat/FlapAutomaticSchedule for CAJX!
2-93
ORIGINAL
NAVAIR 01.Fl4AAD-1
To avoid fuel impingement on the fuselageboattail and nozzles,tieI dump operationsare preventedwith the speedbrakesextended. Ifmaneuver devicesarenot retractedprior to lowering the FLAP handle, a rapid reversal of the flaps will occur with possible damage to the flap system.
Note Loss of combinedhydraulic pressurewith the speedbrakesretractedor extendedwill causethe speedbrakesto move to a floating position.
l
2.22 SPEEDBRAKES The speedbrskesconsistof threeindividual surfaces, one upper and two lower panels on the aft fuselage betweenthe engine nacelles(Figure 2-53). The speedbrakesmay be infinitely modulatedonthe extensionand retraction cycle. Operating time for full deflection is approximately 2 seconds.Hydraulic power is supplied by the combinedhydraulic system(nonisolationcircuit), and electrical power is through the essentialNo. 2 dc bus with circuit overload protection on the pilot right circuit breaker panel (SPD BK P-ROLL TRIM ENABLE) (RBZ). 2.22.1 Speedbrake Operation. Pilotcontrolofthe speedbrakesis effected by use of the three-position speedbrakeswitch on the inboardside of the right throttle grip (Figure 2-54).Automatic retractionof the speedbrakesoccurswith placementof either or both thmttles at MIL or loss of electrical power.
. The speedbrake/fuel dump interlock is electrically bypassedduring a combined hydraulic system failure, enabling the pilot to dump Abelwhen the speedbmkesare floating or modulating. The electrical bypass is enabled whenever the combined pressurefalls below 500 psi. l
Do not extend the speedbrakesin flight within 1 minute (nominal) after terminating fuel dump operationsto allow residual fuel in the dump mast to drain.
l
A throttle must be held in MIL (or greater) for approximately 3 secondsin order for the automatic function to completely retract the speedbrake.Anything less will causepartial retraction.
Figure 2-53. Speedbrakes ORIGINAL
2-94
NAVAIR
NOMENCLATURE 0
2 3
Speed brake switch
01.F14AALb1
FUNCTION EXT-
Momentary position used for partial or full extension. When released, switch returns to center (hold) positlon.
RET-
Normal position of switch. Retracts and maintains speed brakes closed.
SPEED BRAKE indicator
- Partial extension (hold)
- Full extension (6OO).
•l
IN
- Full retracted position.
- Speed brakes power is off. Note Automatic retraction of speed brakes occurs when either or both throttles are at MIL.
Figure 2-54. SpeedbrakeControl and Indicator
2-95
ORIGINAL
NAVAIR 0%F’l
The speedbrakes will start to blowback(close)at approximately 400 knotsandwill cominuetowardthe closedpositionasaimpeedincreases to preventStructuraldamage. A reductionin airspeed will not automaticallycausethe speedbrakes to extendto theoriginally commanded position. 2.23 FLIGHT CQblTRfX SYSTEMS
Flight wntrol is achievedthroughan irreversible, hydraulicpowersystemoperated by a controlsti& and rudderpedals.Aircraftpitchis controlledby symmetricaldeflectionof thehorizontalstabiliiem.Roll wntrol is effectedby differentialstabilizerdeflections andaugmentedby spoilersat wing-sweeppositionslessthan 62”. Directionalcontrolis providedby dualrudders. Duringpowerapproach maneuvers, theaircraftflightpathcanbe controlledthroughsymmetricspoilerdisplacementby the pilot selectingdirect lift control. Controlsurfaceindicatorsareshownin Figure2-55.
forces,proportionalto normalacceleration (8 forces) andpitch accelemtion, am producedby fore andaft bobweights. Airmutt overstmsse-s from abruptstickinputsareminimi&byaneddycurmntdamperthatre sistslarge,rapidcontroldeflections. 2.23.9.2 kr~@~dlru,al Mm. Longitudinaltrim is providedby varyingtheneutralpositionof thecamand roller feel assemblywith an electromechanical screwjack actuator.Themanualpitchtrim buttononthe stickisafiveqositionswitch,springloadedto thecenter (off) position(Figme2-B). The fore andaft switch positionsproducewtmspondingnosedown andnoseup trim,respectively. Themanualtrim switchisdeactivated whentheautopilotis engaged.
Thehorizontalstabilizerandruddersarepoweredby tbetlightandcombined hydmulicsystems andwntrolled by pushrodsandbellcranks. A third independent flight control hydraulicpower sourceis providedby the backupmodule.Spoilercontrolis effectedby enelectmhydraulic.fly-by-wire systemandpoweredby the combinedhydraulicsystem(inboardspoilem)andoutboardspoilermodule(outboardspoilers).
2.23.d.3 Mach Trh. Machtrim wntml is provided by the ARCSandis contimumslyengaged to provide automaticMach trim compensation duringtmnsonic andsupersonic flight. A failureof Machtrim wmpensationis indicatedby theMACH TRIM advisorylight. Transientfaihuescanberesetby depressing theMASTSRRESETpushbutton. ~emsyllaal~dcbFCSautombtic~and~htrim ~3~tuator ic instelledin parallelwitb the Sightwntrol system.Trim ectuatiotrmoducesBwrrespondingstick an8wntrol surfecemovement.
2.232 $~QQ@R&& Krh ystem. TheITS is inwrpored to redw longituditmltrim changes because of the exten$i5nendretix&on of Sapsendspe&mkes. Disagreementof comnnmdpositionremovespower fromthemot03andilhuninates ti BITEGTRIM advisorylight.Transientfailurescanberesetby pressing the 2.23.1 LongitudlmaI 0mQroI.Longitudinalcontrol EvllhS~RWES~T:Tgushbutton.ITSschedulesareshown (Figure2-56) is providedby symmetricdeflectionof in Figure2-59. independently actuatedhorizontalstabilizers.Control stickmotionis trsnsmittedtothestabiliirpower actuatorsbypushrods andbellcmnkstodurdttmdemactuators independently poweredby thefligbt andcombined hydmulii systems.ThepoweractuatorscontrolthestabiWtm the AIM-54 weaponrail pallet(s)is lizers symmetrically for longitudinal control and installed, the speedbrakecompensation differentiallyfor~~~~.~is~lishedby ,w&dde h the i~tegmtedtrim cumputa mech8nically summingpitchandrollwmmandsatthe chmgee.If kes thanfour ADA-54missiles pitch-rollmixerassembly. hJonlm= stick-to-stabilizer areumiedontheweq3onmils,thelTsmay gearingprovidesappropriatestick sensitivityfor reovercompensate for the speedbrake trim sponsiveand smoothcontrol. Longitudinalsystem chauge.IQ the worst case(low altitude,beauthotityis showyin Figure2-57. tween0.7end0.8Mach,pitchSASotf, and weapon wits withoutAIM-54 missilee),the 2.23.1.1 Longltudlna! FoeP.ArtitTcialfeel devices llscP!ncauseeQincmmentalagQosedowQ in the controlsystemprovidethepilot with forcecues trim changewhen the speedbrakeis exandfeedback. A spring-loaded camrindrollerassembly tended.LMertbesewnditionswiththepitch producesbreakoutforce when the stick is di.splwc~I sAseQ@ge&me$dmmQticluulgeisre from neutraltrim andprovidesincressmS stick forces duced to epproximately 1~ proportional to controlstickdisplacement. Controlstick TheAFCSincludesa stabilityaugmentation system anautopilotandauxilii wntrol fimctionsfor spoiler wntrol, rudderauthoritycontrol,lateralsticksuthority wnttol, andMachtrim wmpensation.
QRlGlNAh
2-m
a
SPOILERpositIon indicators
A rightinboardor outboard spoiler positlon lndlcator showlngoneposition hlgher than the,corresponding spoilers ac$ualposition Indlcates a posslblllty of groundroll brakingIn flight and loss of spoiler asym metry protectlon due to a failed zero degreeswkh.
0
RUDDERpositlon Indicator
-Spollers down (flushwith wing surface).
-Either spoiler of the approprlatepalr Is extended more thanOO. -Both spoilers of the appropriatepair at a droppedposition (O-41/2Obelow wing surface)
idlvldual ruddarpolntersmarked R (right)and L (left) display the ailing-edge position of the ruddersin degrees (0 to 30).
ORIWUU.
FUNCTION
NOMENCLATURE
0 @
HORIZONTAL tail stabilizers position
Indicated by two pointers marked R (tight) and L (left) on a scale 35” up and 15” down. Scale is graduated in 2” increments. The inner pointer indicates lefl wing down or right wing down (diierential stabilizer position).
,WTWT;tKr SPOILER
BOTH -Antiskid activated. Spoiler brakes bperate with weight on wheels and throttle at IDLE. OFF -Antiskid wheels.
and spoiler brakes Inoperative with weight on
SPOILER BK - Spoiler brakes operate with weight on wheels and both throttles at IDLE. Antiskid is deactivated.
0
HZ TAIL AUTH caution light
Failure of lateral tail authority actuator to follow schedule or CADC failure.
c9
RUDDER AUTH caution light
Disagreement between command and position, failure of rudder authority actuators to follow schedule, or CADC failure. Note The RUDDER AUTH caution light may illuminate when the in-flight refueling probe is extended. Press the MASTER RESET button to rese the light.
0
EILERS
caution
Spoiler system failure, causing a set of spoilers to be locked down. Note SPOILERS caution light will not illuminate with SPOILER FLR ORIDE switches in ORIDE position.
@
INTEG TRIM advisory light
Discrepancy between input command signal and actuator position or an electrical power loss within the computer. Failure of Mach trim actuator to follow schedule.
@
MACH TRIM advisory light
Note Transient failures involving HZ TAIL AUTH, RUDDER AUTH, or SPOILERS caution lights and INTEG TRIM and MACH TRIM advisory lights can be reset by pressing the MASTER RESET pushbutton.
010
RUDDER TRIM switch
Controls the electromechanical actuator that varies the neutral position of the mechanical linkage for rudder trim.
Figure 2-55. Control SurfaceIndicators(Sheet2 of 2) ORIGINAL
2-98
Figure 2-56. Longitudinal Control System COCKPIT CONTI OL MOTION izi%qiF
Maneuver Flap Integrated Trim System (ITS) and DLC Thumbwheel
4 Inches forward 5.5 inches aft
L
STABILIZE AUTHORITV
ISURFACE RATE
1 PARALLEL TRIM 1AUTHORITY ( AVERAGE RATE
10’ TED 33’ TEU
38’ per second
f3O
22: 1 - (
9’ TED 18O TEU
Parallel Automatic Carrier Landing (ACL only)
4 Inches forward 5.5 inches aft
IO’ TED 33” TEU
36” per second
9’ TED 18’ TEU
Series
f450 DLC Thumbwheel Mode
8.4’ TED Maxlmum
36” per second
-
3O per second
-
f45” Maneuver Flap Mode
1 o per second
-
0.1 o per second
-
Figure 2-57. Longitudinal System Authority 2-99
ORIGINAL
NAVAIR
OI-FI4AAD.1
NOMENCLATURE
0 0
0
@
FUNCTION
Bomb release button
Pilot control for release of stores. In aircraft with the weapons rail defense electronic countermeasures (DECM) chaff adapter, the bomb release button Is used to dispense chaff.
Pitch and roll trim button
Spring-loaded to (center) off position. Up and downpositions control pitch trim and left and rlght positions control roll trim. Manual trim Is Inoperative during autopilot operation.
Weapon Selector switch
LR-
Selects Phoenix missiles.
MR -
Selects Sparrow missiles.
SR -
Selects Sldewlnder missiles.
GN -
Selects gun.
Maneuver flap, slat, and DLC command
Sprlng-loaded to a neutral posltlon. With DLC engaged: Forward rotation extends spoilers (aircraft down); afl rotatlon retracts spoilers (aircraft up). With gear and flaps up: Forward rotation retracts maneuvering flaps/slats; aft rotation extends maneuverlng flaps/slats.
Figure2-58. ControlStickandTrim (Sheet1 of 2) ORIGINAL
2-100
NAVAIR 0%F14AAD1
FUNCTION
NOMENCLATURE 0
DLC engage, disengage, and chaff switch
Momentary depression of the switch with flaps greater than 25 degrees down, throttle less than MIL, and no failures In spoiler system engages DLC. With flaps up, switch will dispense chaff or flares. DLC is disengaged by momentarily pressing the switch, raising the flaps, or advancing either throttk to MIL.
c3
Autopilot reference and nosewheel steering pushbutton
With weight on wheels, nosewheel steering can be engaged by depressing switch momentarily. Weight off wheels and autopilot engaged; switch engages compatible autopilot modes.
0
Autopilot emergency disengage paddle
Disengages all autopilot modes and DLC. Releases all autopilot switches. Disengages the pitch and roll servos and causes the pitch and roll SAS switches to move to OFF. The yaw SAS channels In either case are not affected. Depressing the paddle switch reverts throttle system from AUTO or BOOST mode to MAN mode only while depressed and with weight on wheels.
63
Camera and forward weapon firing trigger
Pilot control of CTVS, gun camera, andfor forward firing weapons. First deten of trigger starts gun camera and cockpit television sensor (CTVS).
Figure 2-58. Control Stick sad Trim (Sheet2 of 2) 2.23.2.1 Preflight. The ITS is automatically
eoergized with hydraulic and electrical power applied. It can
be checkedby operatingflaps or speedbrakesand observinga changein indicated stabilizerposition. 2.23.3 Lateral Control. Lateralcontrol(Figure2-60) is effectedby differential displacementof thehorizontal stabilizers and augmentedby wing spoilers at wingsweeppositionaoflessthan62°.A*l/2-inchstickdeadbandis providedto precludespoileractuationwith small lateralstick commands.The spoilersarecommandedto the flush-down (O”) position at wing-sweep angles of greaterthan 62”, androll control is provided entirely by differential stabilizer.At wing-sweepanglesof 65’ and greater,the hydraulic power to the spoiler actuatorsis cut ofE,locking the spoilers in the 0” position. Lateral stick commandsare transmitted by pushrodsand bellcranksto the independentstabilizerpower actuatorsand electrically to the spoiler actuators. Lateral system authorityis tabulatedin Figure 2-61.
screwjack.Left or right deflection of the roll trim button on the stick grip producescorrespondingstick movement andletI or right wing-down trim, respectively.The normal stick grip trim switch is inoperativewhen the autopilot is engaged. Note With lateral trim set at other than O”, maximum spoiler deflection is reducedin the direction of applied trim.
2.23.3.1 Lateral Feel. An artificial feel systemprovides thepilot with force cuesandfeedback.The lateral feel mechanism is a spring roller-cam assemblywith a neutralstick position detentand a constantstick deflection force gradient.
2.23.3.3 Lateral Control Stops. To limit the torsional fuselageloads, variable lateral control authority stopsareinstalled.The lateral stick stopsvary according to dynamic pressureairloadsfrom full stick authority at low Q, to one-half-stick throw limits at high-Q conditions. Failure ofthe lateral stick stopsis indicatedby the HZ TAIL AUTH cautionlight. Transientfailurescanbe resetwith the MASTER RESET pushbutton.Failure of thestopsin the one-half-stick positionlimits low-Q rolling performance.However, ample roll control is available for all landing conditions and configurations. Failure in the open condition with SAS on requiresthe pilot to manually limit stick deflection at higher speeds to avoid exceeding fuselage torsional load limits, as lateral stopsdo not limit SAS authority.
2.23.3.2 Lateral Trim. Lateral trim is by differential deflection of the horizontal stabilizers.The wing spoilersarenot actuatedfor lateral trim control. Trim is provided by adjusting the neutral position of the spring roller-cam-feel assembly with an electromechanical
2.23.4 Spoiler Control. Four spoiler control surfaces (Figure 2-62) on the upper surfaceof eachwing augmentroll control power andimplementaerodynamic ground-rollbraking. The inboardspoilersprovideDLC.
2-101
ORIGINAL
NAVAIR 01-FlUAD-1
Figure 2-59. IntegratedTrim Schedules
DUAL POSITION . AFCSCONTROL . WlNOSPolLER
TRANiDUCER (4 AUOHENTATION INPUT
INPUT
FEEL’CAM ANDROLLER
I LONOlT”DlNAL CONTROL INPUT IREFERENCE,
Figure 2-60. Lateral Control System
ORIGINAL
2-102
STASlLlZER ACTUATOR
MAXIMUM LATERIA CONTROL OUTPUT WITH SAS ENOAOEO ,*,a MAXIMUM WITk SASOFFI
NAVAIR OW14AALb’I
CONTROL SURFACE Wferential jlabilizer
COCKPLT CONTROL ACTUATION MQDE MOTION Control Stick
Manual
3.5 Inches
PARALLEL TRIM AUTHORITY RATE
SURFACE AUTHORITY RATE f7’
36" per
left
second
f3
3/%* per second
33O per
-
3.5 inches right
Series
None
zw
second !
Iboard and )utboard ipollers
Control Stick
Manual for Cl 162"
f6V
250" per second
None
None
None
15” maximum
260” per second.
None
None
DLCI Maneuver Flap cxminand Thumb-
fnbd only 17.50 neutral -4.5" down +55’up
125" per second (mlnimum)
None
None
55” up
260” per second
None
None
3.5 Inches
lefl 3.5inches
right AFCS (ACL)
DLC/Maneuver Flap
Manual ,
wheel f45”
Lateral tops
Ground Roll Braking Armed, Welgnt- onWheels
Series
None
Control Stick Restricted
Manual
1.75 inches
&3-l/2’ Diff. lefl Stabllizer 1.75 Inct-faS *WY Spoi\er right
36’ per second 2BW per second
-
-
* Programmed by CADC (Horizontal Tail Authorlty) as a function of dynamic pressure. ** Maxtmum SAS off deflection tirnlts with tuk taterat stops engaged.
Figure 2-61. Lateral System Authority 2-103
cw?mMAL
NAVAIR Ol-F14AAD-1
P -P-\----.E .i N \ I lYDRA”LlC SERVO L: .CT”ATOR ?PER PNRI g w\LI Figure 2-62. Spoiler Control System The inboardandoutboardspoilersarepoweredandcontrolled by separatehydraulic and electrical command systemsand areprotectedby separatefailure-detection circuits. The pitch computer and outboardspoiler module control the outboardspoilers,and the roll computer andthe combined hydraulic systemcontrol the inboard spoilers(referto FO-12). Hydraulic actuationof the servoactuatorsis controlled by electric servovalvesat the actuatorand commandedby control stick displacement. The aircraft hastwo spoiler gearingcurvescalled cruise andpower approach.Cruisespoiler gearingis the scbedule that spoilersfollow in the clean configurationandis shown in Figure 2-63. Power approachis the schedule that spoilersfollow with the flaps down greaterthan25” and is shownin Figure 2-63 @LC engaged).With DLC engagedin the power approachmode, inboard spoilers are positioned from normal -4.5” to +17.5Oposition. Lateral stick inputs result in the spoilers extendingon one side in the direction of stick displacementand depressingtoward the landing flaps down drooped(-4.5”) position on the otherside.This is theprimary reasonfor better roll responsein the landing configuration with DLC engaged. 2.23.4.1 Lateral Trim. As mentionedearlier,lateral trim is provided by adjusting the neutral position ofthe ORIGINAL
stick. This movement of the neutral position has an effect on the amount of spoiler deflection available. That is, as lateral trim is applied away from the zero trim position, maximum spoiler deflection is reduced in the same direction (right trim, less right wing spoiler deflection). Full lateral trim in the samedirection as lateral stick displacement will still provide approximately 25’ of spoiler deflection to counteractan asymmetric flap and slat condition (see Figure 2-63). This is sufficient to control full-flap asymmetry with symmetrically down slats.
Full slat asymmetry (17’) can result in an out-of-control situation at 15 units AOA or greater,evenwith 55” of spoilersavailable. 2.23.4.2 Ground-Roll Braking. Aerodynamic ground-rollbraking is providedby symmetric deflection ofall spoilersto +55”. Ground-rollbrakingis controlled by the ANTI SKID SPOILER BK switch on the pilot
2-104
NAVAIR
_ . . ..-_..-.-. ,.I..
01.F14AAD-1
z&c MEUTRAh ..“. _” ,,....-- _-- .._.~.-,._^^
Figure 2-63. Spoiler GearingSchedule
2-405
GRIGINAL
4. Inability to reset computersthrough master reset and reengagepitch and roll SAS switches.
left vertical console.The three-positionswitch allows optional selection of BOTH (spoiler brake and antiskid wheelbraking), SPOILER BK (spoiler brake only), or OFF whereneitherspoilersnor antiskid arearmed.With SPOILER BK or BOTH selected,two conditions are requiredto actuatethe spoilers:
On deck, when the flap handle is cycled to UP, the outboard spoiler module is shut down. This may cause the outboardspoilers to indicate a droop or down position. If this occurs,position the flap handle to DN and move the control stick laterally. This will result in a properspoiler indication.
1. Weight on wheels 2. Both throttles a idle. Failure lo satisfy any oneofthe aboveconditionswill causethe spoilersto return to the down position.
During initial spoiler brake operation,it is normal for the indicators in the SPOILER window to momentarily flip-flop. 2.23.4.3 Spoiler Fsailure. Simultaneous deflection ofcorrespondingspoilerpairsgreaterthanlg”,orastick displacementof 1 inch to opposea symmetric spoiler greaterthan 1So,will signal a spoiler failure, removeall electrical commandsto the affectedspoiler set,hydraulically power the failed spoiler pairs to the -4-1/2Oposition; and illuminate the SPOILER caution light. Transient spoiler failures can be reset by pressingthe MASTER RESET pushbutton.With either SPOTLER BK or BOTH selectedandweight on wheels, the symmetric spoiler failure logic is disarmedto permit symmetrical 5.5”spoiler deflection for ground-roll braking. With DLC engaged,inboard symmetric spoiler failure logic is disarmed. Failure of the AFCS roll computer fails the inboard spoiler pairs. An AFCS pitch computer failure renders tbe outboardspoiler pairs inoperative. A spoiler failure override (SPOILER FLR ORIDE) panel on the pilot right inboardconsoleallows the pilot to manually override the automatic shutdownfunction. If a stuckup spoiler failure occurs, selectingthe appropriate INBD or OUTBD spoiler switch to ORIDE (Figure 2-64) and then depressingMASTER RESET allows the remaining spoilersin that set to operate. Varying acvoltageduring anelectricalshortcondition may yield one or more of the following chamcteristics: 1. LOSSof oneor both channelsof computer operation. 2. Differential tail and rudder hardoversfor up to 3 seconds. 3.
X23.4.4 Spo!ler TIM. The spoiler test provides a continuity and logic test for the spoiler 18” and stick switches.The test is conductedwith the flaps down and spoilersup. Select STICK SW on the MASTER TEST switch (SPOILERS caution light illuminates, spoilers droop). Move the stick left and right of center 1 inch. ObserveGO light illuminate on the MASTER TEST panel after moving the stick in each direction. Return the MASTER TEST switch to off anddepresstheMASTER RESET pushbuttonto resetthe spoilers. 2.23.5 %\v CspnBroB. Yawcontrol(Figure2-65)iseE fected by twin rudders,one on each vertical tail. The rudder pedalsadjust through a lo-inch rangein l-inch incrementswith the adjust control on the lower center pedestal,forward of the control stick. Yaw commandsare transmitted mechanically from the rudder pedals to tbe rudder power actuators by pushrodsand bellcranks. Tandem power actuatorsare poweredindependentlyby the flight and combined hydraulic systems.Yaw system authority is tabulatedin Figure 2-66. 2.23.5.‘I War&& %zi. Artificial feel is provided with a spring roller-cam mechanism similar to the longitudinal and lateral feel systems. Rudderforce with pedal deflection is nonlinearwith a relatively steepgradient about the neutral detent and graduallydecreasingwith increasedpedal travel. 2.23.5.2 Z&&B T&c. Rudder trim is effected by varying the neutralposition of the feel assemblywith an electromechanicalscrewjackactuator.Ruddertrim control is actuatedby a three-positionswitch on the left consoleoutboardof the throttle quadrant.L&I (L) and right @) lateral switch movement commands left and right rudder trim, respectively. The switch is spring loaded to the center off position. Trini actuation produces an associatedmovement of the rudder pedals, rudders,and rudderindicator.
Inoperative spoilers and SAS outputseven when voltage is resetto nominal 115volts.
OWlelNAL
2.106
NAVAIR 0%F14AAD-1
NOMENCLATURE @
;;;poiler
override
FUNCTION ORIDE -
Overrides inboard spoiler symmetry protection logic. If an inboard spoiler fails more than lSO up, allows remaining inboard spoilers to operate after MASTER RESET is depressed.
NORM Safety guard down. Allows inboard spoiler symmetry protection. (guarded - If an inboard spoiler falls up, all inboard spoilers are position) commanded to the droop position and the SPOILERS light illuminates.
0
OUTED spoiler override switch
ORIDE -
Overrides outboard spoiler symmetry protection logic. If an outboard spoiler fails more than 18” up, allows remaining outboard spoilers to operate afler MASTER RESET Is depressed.
NORM (guarded position)
Safety guard down. Allows outboard spoiler symmetry protection. If an outboard spoiler fails up, all outboard spoilers are commanded to the droop position and the SPOILERS light illuminates.
Figure 2-64. Spoiler Failure OverridePanel 2-107
ORIGINAL
m*icE
S”J-“T
PARALLEL TRIM ACCNATOR
FEEL CAM AN0 ROLLER
Figure 2-65. Yaw Control System
COCKPIT CONT
OL MOTION 3 Inches left, 3 Inches right
RUDDER SURFACE 1AUTHORllY 1 RATE I f300 1OW per maximum second
1 Inches left 1 ~inches, right
f9.50 minimum
106” per second
None
**19o
60° per second
PARALLEL TRIM 1AUTHORITY 1 AVERAGE RATE 70
1.13O per second
70
-
_p
*Stops programmed
by CADC (rudder authority) as a function of dynamic pressure.
Figure 2-66. Yaw SystemAuthority ORIGINAL
2-108
-
NAVAIR 0%F14AAD-I
2.23.5.3 Rudder Authority Stops. Rudder authority control stopslimit rudderthrows in the high-Q flight environment.Rudderdeflection limits are scheduledby the CADC, commencing at about 250 knots. Above approximately 400 knots, the stops are fully engaged, restricting manual rudder deflection to 9.5”. Disagreement between command and position removespower from the motor and illuminates the RUDDER AUTH cautionlight.
Upon engagementof DLC, theroll computerextends the inboard spoilers from the landing flaps down drooped(4-1/2”)positionto+17.5”abovetheflush(O”) position. The pitch computerdisplacesthe trailing edges of the horizontal stabilizers2.75” down from their trim position. If the thumbwheel control is rotated fully forward, the spoilers extendto their 55Oposition and the stabilizer trailing edgesremain at 2.75”. This increases the rate of descent.If the thumbwheelcontrol is rotated fully aft, the spoilers retract to their -4.5” position and the stabilizer trailing edgesreturn to the trim position. This decreasesthe rate of descent. 2.24 AUTOMATIC FLIGHT CONTROL SYSTEM
A CADC failure may drive the rudder authority stops to 9.S’. This condition should be determinedprior to making a single-engine or crosswind landing. With the 9.5” stops in, rudder control may be insufficient to maintain directional control with single-engine afterburneroperation or during crosswind conditions. Nosewheel steering authority is greatly reduced with the 9.5” stops engaged.
The AFCS (FO-12) augmentsthe aircraft’s natural damping characteristicsand provides automatic commands for control of attitude,altitude, heading,and approachmodesselectedby the pilot. All AFCS functions are integratedinto the primary flight control system.A BIT capabilityis providedto exercisein-flight monitoring and to conductan automatic operationalreadinesstest for preflight checks. AFCS rates and authorities are tabulatedin Figure 2-67.
2.23.5.4 Rudder Pedal Shaker. The rudder pedal shakeroperatesonly during OBCNAW BIT and is disabledduring flight. 2.23.6 Direct Lift Control. During landing approaches,the inboardspoiles andhorizontal stabilizers can be controlled simultaneously to provide vertical glidepathcorrectionwithoutchangingenginepowersetting or angle of attack. Before DLC can be engaged,the following conditions arerequired: 1. Flaps down greaterthan 25’. 2. Throttles less than MIL power. 3. Inboard spoilersoperational. 4. Pitch and roll AFCS computersoperational. 5. Operablecombined hydraulic pump. 2.23.6.4 DLC Operation. DLC is engagedwith the control stick DLC switch and commanded by the thumbwheel.The thumbwheelis springloadedto a neutral position. Forward rotation of the wheel extends spoilersand aft rotation retractsthem proportionally to the degreeof thumbwheel rotation.DLC is provided by the pitch and roll computers.
2.24.1 Stability Augmentation System. Stability augmentation is provided for all three aircraft axes (pitch, roll, and yaw). Control surface commands are generatedby the roll, pitch, and yaw computersin responseto inputs from AFCS sensors. Computeroutputs are fed through the flight control system dual-seriesactuatorsthat drive the control system mechanical linkages in series(no stick motion) to producesurfacemotion. Stability augmentationis controlled by the three STAB AUG switches on the upper half of the AFCS control panel (Figure 2-68). SAS is engagedby placing theseswitchesto ON during normal poststart procedures.The PITCH and ROLL STAB AUG switches are solenoid held and the YAW STAB AUG switch is a manually operated toggle switch. PITCH and YAW SAS switches should normally remain in ON throughout the flight. Roll SAS reduces departureresistanceand shall be placed OFF prior to conducting maneuvering flight above 15 units AOA. Pitch androll SAS axesconsistof two redundantchannels that provide fail-safe operation. Yaw SAS consists of three electronic channelsto provide fail-safe operationalcapability. 2.24.2 Voltage Monitor Control Unit. TheVhJCU detects abnormal voltage transients in the aircraft electrical supply systemandreducesthe voltageto a low enough level to allow the AFCS to detect it and disengagethe SAS. If theVMCU detectsa low-voltage
2-109
ORIGINAL
NAVAIR Ql-Fl4AAD-1
Figure 2-67. AFCS Ratesand Authorities condition of 97 volts or less in the ac, phaseA supply, the unit will activatea relay to drop the voltage to zero and maintain that level for a minimum of 1.25seconds plus the durationof the detectedlow-voltage condition. Activation of the VMCU becauseof a low-voltagecondition results in the simultaneous illumination of the following lights for the duration of the transient:
AUG switchesare setto ON andthe illuminated light(s) will resetwith the MASTER RESET pushbutton. 2.24.2.2 VMCU Check. The VMCU is checked prior to flight during the poststartprocedure.The voltage drop obtained when the emergency generatoris turned off is sufftcient to activate the VMCU and illuminate the affectedcautionand advisory lights.
1. PITCH STAR 1 and 2 2.24.3 Autopilot. The autopilot is controlledby four switches on the lower half of the AFCS control panel (Figure 2-68) andtheautopilot referenceandnosewheel steeringpushbuttonon thestick grip. With all threeSAS axes engaged,autopilot operation is commanded by placing the ENGAGE/OFF switch to ENGAGE. No warmup period is requited. The autopilot may be engagedwith the aircraft in any attitude. If, however,aircraft attitude exceedsti0” in pitch andi60” in roll, the autopilot will automatically return the aircrafi to these limits. Normally, IMU is the prime referenceand attitude headingreferencesystem(SAHRS) a backup.
2. ROLL STAR 1 and 2 3. YAW STAR OP and OUT 4. SPOILERS 5. HZTAILAUTH 6. RUDDER AU-l-I-I 7. AUTO PILOT 8. MACH TRIM. 2.24.2.1 VMCU Operation. While the VMCU is activated,all spoilerswill be commandedto 4.5”, all SAS andAFCS ti~ctions will beturnedoff, andthePITCH and ROLL STAR AUG switchesdrop to OFF. When normal supply voltage is sensed,the VMCU is deactivatedand normalpoweris restoredto thephaseA bus,all lights will go out, exceptthe RUDDER AUTH light at low speeds and the HZ TAIL AUTH light at high speeds,and SAS will be availablefor the yaw axis sincethe YAW STAR AUG switchremainsON. SAS operationof thetenraining axis will be availablewhen the PITCH andROLL STAR ORIGINAL
2.24.3.1 AFCS Series Actuator. The AFCS series actuatoris a dual-channelsetvoactoatorthat is controlled and commanded by the AFCS computers to provide a low-authority input that can be mechanically overriddenby the pilot. Each servoof the dual actuator is monitored to provide failure detectionand automatic shutdownof a malfunctioning actuatorchannel.PITCH STAR and ROLL STAB caution lights notify the pilot of a malfunction. The remaining functional channelwill continue to provide half authority for the pitch and roll axes.Autopilot modes may be engageablebut will have reducedauthority.
2-110
NAVAIR 01.Fl4AAD-I
Figure 2-68. AFCS Controls and hiicato~
2-111
(Sheet 1 of 3)
ORIGINAL
NAVAIR
Ol-IWAAD-1 FUNCTION
NOMENCLATURE 0
PITCH STAB AUG engage switch
Engages dual-channel pitch stability augmentation. Spring-loaded to OFF
0
ROLL STAB AUG engage switch
Engages dual-channel roll stability augmentatlon. Sprlng-loaded to OFF
@
YA$TAB
Engages three-channel
@
AUTOPILOT ENGAGE-OFF switch
0
@
0
@
AUG engage
HDG-OFF-GT
switch
ALT-OFF switch
VEC/PCD-OFF-ACL
Solenoid held in ON.
Solenoid held in ON.
yaw stability augmentation.
ENGAGE -
Engages autopilot. PITCH, ROLL, and YAW SAS must be engaged. No wanup required. Engages attitude hold. Requires weight off wheels.
OFF -
Dlsengages
HDG -
Autopllot will lock on constant aircraft heading when aircraft is less than f5 degrees roll.
OFF -
Disengages
GT-
Selects autopilot ground tracking computed at time of engagement using inertial navigation system (INS) data. Engaged by nosewheel steering pushbutton
ALT -
Autopilot will maintain barometric altitude. Engaged by nosewheel steering pushbutton.
OFF -
Disengages
VEC/PCD -
Autopilot roll axis commands steer aircraft using data link for VSCtOrlng. If the preclslon course direction (PCD) discrete is present both roll and pitch axis commands are used. Engaged by nosewheel steering pushbutton,
autopilot.
heading hold and ground track.
altitude mode.
SignSIS
ACLS/AP caution light
OFF -
Disengages
VEC/PCD and ACL modes.
ACL -
Autopilot will accept data link signals for carrier landing, using spollers for roll and parallel servo for pitch. Only pitch commands are transmitted to stick movement. Engaged by nosewheel steerlng pushbutton.
Autopilot and automatic carrier landlng system (ACLS) mode disengaged.
Figure 2-68. AFCS Controlsand Indicators (Sheet2 of 3)
ORIGINAL
2-112
NAVAIR 0%Fl4AAD-1
NOMENCLATURE A/P CPLR advisory legend on MFD
FUNCTION lndlcates the aircraft can be coupled to the ACL system for a mode I or mods IA approach. A/P CPLR legend remains In conjunction with the CMD CTRL legend after coupling Is accomplished.
010
zMFi
AutopIlot mode is selected but Is not engaged. hold.)
0
PITCH STAB 1 and PITCH STAB 2 caution
One light, illuminated channel inoperative. Single channel 53% loss of authority. Both lights Illuminated, indicates PITCH STAB failure.
0
ROLL STAB 1 and ROLL STAB 2 caution Iiqhts
One light lllumlnated channel Inoperative. Single channel, 50% loss of authority. Both lights Illuminated, Indicates ROLL SAS failure.
0
YAW STAB OP and YAW STAB OUT caution lights
@
advisory legend
I
(Except attitude and heading
OP-
One channel Inoperatlve.
OUT-
Two channels inoperative. Yaw stabilization
inoperative.
@
AUTO PILOT caution light
Indicates failure of one or more of pllot relief modes
0
Autopilot reference and nosewheel steering
Engages the ALT, GT, ACL or VEC/PCD autopilot mode selected. Autopilot must be engaged and compatible autopilot modes selected. Requires weigh t off wheels.
emergency 63 Autopilot disengage paddle
Disengages all aulopllot modes and releases all autopilot switches. Disengages the pitch and roll servos and causes the pitch and roll SAS switches to move to OFF. The yaw channels in either case are not affected.
Figure 2-68. AFCS Controls and Indicators(Sheet3 of 3) The YAW STAB OP caution light indicates one of the threeyaw channelsis inoperative.Full authority is retained.
Taxiing with one engineshut down and the HYD TRANSFER PUMP off may ill&natethe pitch, roll, and/oryaw cautionlights. 2.24.3.2 AFCS Pitch Parallel Actuator. The AFCS pitch parallel actuator is a single-channel electrohydraulic servoactuatorthat providesautomaticlongitudinal control during mode I and mode IA ACLS approaches.Pitch commandsreceivedby the datalink are suppliedto the parallel actuatorvia the AFCS pitch computer.As a safety feature,the parallel actuatorsystem containsa mechanicalforce link that is designedto
disconnect the actuator ~.^_ from the control when ._ torte _.. 1ssystem excessive (greaterthan YUpounds) encounterea at the actuatorcontrol rod, thusuncouplingtheautopilot from the ACL system.Upon ACL engagement,the parallel actuatorcentersitself automatically as a function of stick position, pitch rate.,andpitch attitude.Coupling with the aircraft out of trim or in a climb or descentwill result in improper centeringof the parallel actuatorand decreasedactuatorauthority in one direction. This will greatlyincreasethe probability of uncouplingduringthe approachsincethe actuatormay command the control systemagainstthe physical stop in the direction of reducedauthorityanddisconnectthe force link. Similarly, it is possiblefor the force link to disconnectduring pilot OBC iflongitudinal trim is not properly setprior to OBC commencement.Once the force link is disconnected, farther mode I or mode IA approacheswill be impossible until the force link is resetby maintenance.
2-113
ORIGINAL
2.24.4 Pilot Relief and Guidance Modes
.
It is absolutelyimperativethat the aircraft be trimmed hands-off in level, on-speed, wings-level flight with landing checks complete prior to coupling in order to achievepropercenteringof the pitch parallel actuator.Engagementof ACL in any other flight condition will seriously degrademode VIA flight characteristicsand may result in a force link disconnect.The recommendedmethod for coupling is to engageACL after 1.5to 30 seconds of flight in the landing configuration with AFCS attitude and altitude hold engaged to utilize the AFCS automatic pitch trim system.
. OBC commencement with less than 3” noseuptrim with flaps down or less than zerodegreeswith flaps up may result in a force link disconnectwhen the stick hits the forward stick stopduring thepitchparallel actuatorchecks. 2.24.3.3 Automatic Pitch Trim. Automatic pitch trim is used in all autopilot pitch modes to trim the aircraft in order to minimize. pitch transientswhen disengagingautopilot functions. The pitch servo position is monitored to drive the aircratl pitch ttim motor at one-tenthmanualtrim rate.The pilot manualtrim button on the control stick is inoperative during all autopilot operations. 2.24.3.4 AFCS Emergency Disengage. Operation of the autopilot emergencydisengagepaddleon thecontrol stick (Figure 2-68), disengagesthe autopilot and DLC. All autopilot switches will retum to OFF. The pitch androll SAS servosaredisengagedwhile the paddle is held depressed.Depressingthepaddlewith weight on wheels reverts throttle system from the AUTO or BOOST mode to theMAN mode only while depressed Depressingthepaddledisengagesthepitch androll SAS servos and causesthe pitch and roll SAS switches to move to OFF. The yaw SAS switch is not affected by operationof the autopilot emergency disengagepaddle and will remain ON. Note The AUTO PILOT light may or may not illuminate when the autopilot is disengagedwith the autopilot emergencydisengagepaddle.
ORIGINAL
2.24.4.1 Control Stick Steering. With the autopilot engaged,the aircraft may be maneuveredusing control stick steering.In control stick steeringmode, the AFCS automatically synchronizesto the new attitude. 2.24.4.2 Attitude Hold. Attitude.hold is selectedby settingtheAUTOPILOT ENGAGE switch to ENGAGE. To changeattitude,usecontrol stick steering.Reengagement is achievedby releasingpressureon the stick. The autopilot will hold pitch attitudesup to *30” andbank anglesup to %60”.Inertial measurementunit failure will causemode disagreementand the engageswitch will return off. The mode may be reengaged using the SAHRS as a reference. 2.24.4.3 Heading Hold. Heading (HDG) hold is engagedby setting the HDG-OFF-GT switch to HDG. AAer maneuveringthe aircrafi to the desiredreference headiig, releasethe control stick at a bank angleof less than i5O. The autopilot will thenhold the aircraft on the desiredheading.Headingreferenceis obtainedt?omthe SAHRS via the converterinterface unit. 2.24.4.4 Ground Track. To engagegroundtrack,set the HDG-OFF-GT switch to GT. When the A/P REF advisorylegend(onupperleft sideof the MFD) appears, pressthe nosewheelsteeringpushbuttonon the control stick grip. When the A/P REF legendgoesoff, themode is engaged. Disengagementwill occur if more than l-1/2 pounds lateral stick force is applied andwill be indicatedby the A/p REF legend.The ground-trackmode may be reengagedby releasingthe stick force andpressingthenosewheel steeringpushbutton. Ground-track steering computations are performed by themission computer,basedon inputs from the CID, IMU, andSAHRS. The computeroutput, in the form of ground-track error signals, is processedin the CID, which generatessteeringcommandsto the autopilot roll axis. Bank anglesare limited to i30”. Failure of INS or SAHRS will causeloss of ground-tracksteering. 2.24.4.5 Altitude Hold. Altitude hold mode is engagedby settingthe ALT-OFF switch to ALT. When the A/P REF advisory legend appear, pressthe nosewheel steeringpushbuttonwhen at the &sired altitude. This will engagethealtitudehold modeandtheA/P REF legend will go off. Applying 10 pounds longitudinal stick force will causetheA/P REF legendto appear.The mode may be reengagedby depressingthe nosewheel steeringpushbuttonon thestick grip, when at thedesired altitude, and observing that the A/P REF legend goes
NAVAIR 0%FMAAD-1
Todosccouldcauseabmptattitu&chauges and a possibleforce-Iinkdisconnect.The pilot shouldverbally instructthe appmachcontroller, “Downgrade to mode II.” Upon downgrading, the CMD CTRL legend should go out. The ACL RDY and A/P CPLR legendsmust appearprior to any attempt at recoupling.
off. Altitude hold should not be engagedduring any maneuversrequiring large, rapid, pitch trim changes becauseof limited servo authority and slow automatic trim rate. Disengagementof altitude hold is accomplished by applying 10 pounds or more longitudinal stick force or by placing the ALT-OFF switch to OFF. Note Do not actuatein-flight refueling probewith altitude hold engagedbecauseof large transients in pitot-static systems sensedby the CADC. 2.24.4.6 Data-Link Vector - Precision Course Direction. This mode is engaged by placing the VEWCD-OFF-ACL switch to VECiPCD, andpressing thenosewheelsteeringpushbutton.Mode engagementis evidencedby the A/P REF advisory legend going off. Disengagementof the mode is accomplishedby application of stick forces of 7-l/2 pounds lateral or 10 poundslongitudinal, or disengagementby placing the VEC/PCD-OFF-ACL switch to OFF. Ifthe switch is left in VECK’CD, the A/P REF legendwill appearand the mode may be reengagedby depressingthe autopilot referenceand nosewheelsteeringpushbutton. Determination of whether data-link or precision coursedirection signalsarepresentis made in the AFCS pitch and roll computersin responseto inputs from the datalink converterand ClU. If the data-link vector discrete is present,the autopilot roll axis will respondto data-link heading commandsand bank angle authority will be limited to *30”. When the PCD discreteis present,the autopilot roll and pitch axeswill respondto data-link commands. 2.24.4.7 Automatic Carrier Landing. To engage the ACL mode, place the VEC/PCD-OFF-ACL switch to ACL and pressthe nosewheel steeringpushbutton. Mode engagementis evidencedby the A/P REF legend going out. Disengagementof the ACL mode causes complete autopilot disengagement. All autopilot switches return to OFF and the AFCS reverts to SAS modes only. The AUTO PILOT caution light and the ACLS/AP caution light on the windshield frame are illuminated. They may be extinguishedby pressingthe MASTER RESET pushbutton.
Note Application ofmore than2 to 3 poundsof stick force while attempting to couple will cause the AUTO PILOT cautionlight to illuminate and coupling cannotbe accomplished.It is imperative that any stick force be avoided while depressingthe autopilot referenceand nosewheelsteering pushbuttonto preclude illumination of the AUTO PILOT caution light. The pilot can disengagefrom the ACL mode (and autopilot)by applicationof 7-l/2 poundsof lateralor 10 pounds of longitudinal force, by disengaging the AUTOPILOT ENGAGE switch, or by pressing the autopilot emergencydisengagepaddle. Pilot takeoversmay be requiredduring mode I or IA ACLS approaches.The recommended method for a PTO is to manually disengagethe autopilot ENGAGE switch on the AFCS control panel and then disengage the APC by useof thecagebutton.This may be difficult to accomplish,especiallyduring the final portions ofthe approach.If this method is not feasible,then 10 pounds of afl stick pressureand simultaneousdisengagementof APC will accomplishthe PTO. Ifthe all stick methodis used at or inside the in-close position, the pilot must avoid overrotation.The waveoff techniquedescribedin Chapter8 applies. pi&G-,,,,,,, A PTO initiated by APC disengagementwith large power additions prior to uncoupling from ACLS will result in large nosedown commands.A force-link disconnectmay occur if the control stick hits the forward stop. Note Routine downgradingfrom an ACL mode I or IA approachby depressingthe autopilot emergencydisengagepaddle is not recommendedsinceDLC, roll SAS, andpitch SAS will alsobe disengaged.
(,,,,,,I If the autopilot/ACLS uncouples after approachcommencement,do not attemptto recouplewith the CMD CTRL advisorylegend 2-115
ORIGINAL
NAVAIR Ql-F14AAD-I
The ACLS mode (and autopilot) will be disengaged automaticallyby lossof data-link A/P CPLR legend,no messagefor more than2 seoonds,or a waveoff discrete t?om the boat. ACL commands control the aircraft through the autopilot by spoiler commands in roll and by parallel servo in pitch. Pitch commandsmove the control stick SeeAFCS Pitch Parallel Actuator, paragraph2.24.3.2, for pitch actuatoroperation. Note If thepitch parallel actuatorforce Iii is me chanically disconnected,the A/P REF advisory legend indicating ACL engagement may go out when coupling is attempted,but the aircratl will not respondto SPN-42commandsand the autopilot will uncouple Born the ACL system when the first pitch commandsarereceived.
2.25 LANDING GEAR SYSTEMS
2.24.5 AFCS Test. Anindependenttestprogrsmand associatedhardwareis in eachAFCS axis computer. 2.24.5.4 AFCS OBC. Preflight indication of AFCS performancecanbe obtainedduring poststartOBC. All SAS switches should be engaged.After selectingOBC on the MASTER TEST switch, the autopilot switch should be placed to ENGAGE. A complete test sequenceencompassingall functions speciallyassociated with the selectedaxis (axes)will commenceupon test initiation and will cycle to OFF after completion. The PITCH STAB 1 and 2, ROLL STAB 1 and 2, YAW STAB OP, and YAW STAB OUT caution lights illuminate and serveas an AFCS BIT running indication. All other AFCS caution lights will illuminate momentarily during BIT testing. If the pitch parallel actuatoris functioning properly, large longitudinal control stick deflections should be observedduring OBC. An OBC with the flaps down requires a longitudinal trim of 3Oor more noseup; an OBC with the flaps up requiresnot lessthan0” nose.up. A disconnectedpitch parallel actuatorforce lii during OBC is indicatedby illumination of the AUTO PILOT caution light, a PC acronym, and the absenceof large control stick deflections.It is possiblefor the force link to be partially disconneoted,that is, disconnectedmechanically while electrical continuity is maintained. If this has OCCW&, the AUTO PILOT caution light or PC acronym may be absentatherOBC but no large stick deflection will be observed. The implications of this condition arethe sameas for a total disconneot.
ORIGINAL
2.2452 AFCS In-Flight BIT. AFCS in-flight BIT provides automatic failure-initiated testing for the AFCS pitch and roll axesonly. In-flight BIT is not provided for the yaw axis. If yaw axis faihnes occur,the appropriatecautionlight will illuminate andSight envelope restrictions must be observed as applicable. InSight testing in the pitch and roll axes is automatically initiated when an AFCS computer failure is de&&d. When this failure is deteoM the affectedaxeswill disengage,both SAS caution lights for the affectedareas will illuminate, and BIT will automatically run for 9 to 14 seconds,depending upon the axis affected. Upon completion of BIT, the failed channellight remainsilluminated and the other channel light goes out. WRA failure indications can be observedin flight by the RIO on the TID.
The aircmfi hasfblly retractable,tricycle landinggear operatedby combined hydraulic pressurein the normal mode of operation and a stored source of pressurized nitrogen for emergencyextension.The landing gearretract forward so that airloadsandgravity assiston emergency extension.Air-oil shock strutswith oil metering pins reduce landing loads transmitted to the airtkame, and the shuts are fully extendedwith the gear in the wells. AU landing geardoorsremain openwith the gear extended. 2.25.1 Landlng Gear Handle. The landing gear handlemechanicallypositionsthe landinggearvalve for normal operation.Pulling the handle meohanically selects emergencyextension of the gearusing the pneumatic backnp source.Both modesof gearoperationcan be.accomplishedwithout electricalpower exceptfor the gearposition indication, which requiresdc essentialNo. 2 bus power. Gear downlock actuatorsinwrpomte internal mechanical fmger locks that maintain the downlock inserted position in the absence of hydraulic pressure.The landing gearhandle wntains other interlocks that are discussedundertheir respectivesystems such asweaponsfiring, jettison systems,APC, maneuvering flaps, and groundpower systemtest panel. Designlit landing sink speedforthe ahcrag is 25.3 feetper second(nominal landing sink speedis about 11 feet per second).Normal and emergencywntmls and displays associatedwith operation of the landing gear areshown in Figure 2-69. 2.252 Main Landing Gear. Eachmain landinggear shock stmt consists of an upper outer cylinder and a lower internal piston, which has a maximum strokeof
2.116
NAVAIR 0%F14AAD-l
NOMENCLATURE
0
LDG GEAR handle
FUNCTION Normal -
Emergency
0
0
@
DOWN LOCK ORIDE lever
HYD ISOL switch
Landing gear transition light
Up and down overcenter action provides normal retraction and extension by the combined hydraulic system. - Down-push-turn clockwise pull actlon provldes emergency extension of all gear by a compressed nitrogen charge.
Down -
Weight-on-wheels Indication, prevents gear handle being retracted without pilot override (ralslng lever).
UP-
Weight-off-wheels Indication, does not Inhibit pilot raising gear handle. Automatic operation by electrical solenoid.
FLT -
Comblned system hydraulic pressureIs shut off to the landing gear, nosewheel steering and wheel brakes.
TO./LDG -
Switch Is automatically placed In this positlon with gear handle down. Combined hydraulic pressure Is available to all components.
On whenever gear and door posltlons (lncludlng maln landing gear sldebrace actuators) do not correspond to handle posltlon. Out when gear and doors are locked In posltlon selected by handle.
Figure 2-69. Landing Gear Controlsand Indicators(Sheet1 of 2) 2417
ORIGINAL
NAVAIR 0%F14AAD-1
NOMENCLATURE
0
I
FUNCTION - Landing gear down and locked (except main landing gear sidebrace actuator).
LDG GR indicator
E!l U
- Landing gear retracted and doors closed. - Unsafe gear or power off indication.
lal
@
WnEELS warning light
Llght flashes with flaps greater than 10’ deflection and either or both throttles less than approximately 85% rpm, and all landing gear not down and locked. Approach lights and indexer will illuminate when the LDG GEAR har idle is placed in the down position, but this is not an indication of gear down and locked.
Figure 2-69. Landing GearControls and Indicators (Sheet2 of 2) 25 inches.A hard step(31,000poundsrequired for fnr-
ther compression)in the strut air curve provides a consistent 4-inch stroke remaining in the ground static condition. A side-bracelink is mechanically extended tkoomthe inboard side of the strut outer cylinder to engagein anacellefitting andthusprovidesadditionalside load supportfor ground operations. The path of the wheel assemblyis controlled by the drag brace as it folds (jackknifes upwards) during gear retraction and unfolds during extension.The fully extended shock strut and jackknifed drag brace retracts forward and rotatesthewheel assembly90’ to lie flat in the wheelwell. Inboard and outboardand aft main gear doors are individually actuatedclosed in sequenceto provide fairing for the retractedgear. An uplock hook on the shock strut engagesa roller in the wheelwell to hold the gearin theretractedposition. The main landing gear actuatoron the inboard side of the shock strut retracts and extendsthe gearassembly.
groundlock device clamps onto the downlock actuator rod for safetyingthe main gear. Maximum strut extension and wheel alignment are controlledby torquearmsthat incorporatecam-operated microswitches to detect a weight-on-wheelscondition (greaterthan 5 inches of strut compression).The single split-type wheel assembly incorporates thermal fuse blow plugs and a pressurerelief deviceto preventoverinflation of the tire.
The geardownlockactuator,mountedat thedragbrace knee pin, extendsto preventunlocking (jackknifing) of the drag brace.Hydraulic pressuremust be suppliedto the downlock actuatorin order to retract it againstthe springaction ofthe integrallocking mechanism.A paint stripeacrossthe dragbracekneepin providesanexternal visual indication of the dragbrace locked condition. A
ORIGINAL
2-l 18
a Illumination of indexerlights doesnot indicatethat the main landing gearareclear of the runway. Raising the gear before a positive rate of climb is establishedwill result in blown main tires. a Illumination of indexer and approach lights is not an indication of gear down and locked. 2.25.3 Nose Landing Gear. The dual-wheel nose landing gear has a shock strut consisting of an outer cylinder anda lower internal piston thathasa maximum stroke of 18 inches. During normal ground operations,
NAVAIR 9%FMAAD-1
thestrutis fully extended.Pilot controlis providedto kneel the strut (4 inches strokeremaining) for catapultoperations. During retraction,the fully extendednosestrut is rotatedforward by the retractactuatorinto the well and enclosedby two fonvardand two aft doom.The fonuard doorsam opemtedby a separateactuatorthat alsoengages the gearuplock, whereasthe two aft doorsare mechanically linked to the shock strut.An uplock hook actuator engagesa roller on the lower piston to hold the gearand doorsin theretractedposition.During extension,thetelescopingdragbracecompressesso~atadownlockactuator mechanicallylocks the inner and outer barrel to form a rigid memberfor transmissionof loadsto the airhame. Note There is no foolproof visual check of the nose landing gear locked-down status. Neither the downlock mechanism, which is concealedin the fuselagenor insertion of the groundlock pin will provide a positive indication of gear-locked status. In flight, the pilot must normally rely on his indicator. Visual determination of nose landing gearunlocked statusis assistedby a red band painted on the nose landing gear drag brace. If red is visible, the nosegearis not locked,
2.25.4 Landing Gear Normal Operation. The landing gear handle is mechanically connectedto the landing gearvalve that directs combinedhydraulic fluid into the gear-upandgear-downlines andprovidesa path for return flow. In the down position, the handle mechanically setsthe hydraulic isolation switch to provide hydraulic pressure for gear operation. The handle is electromechanicallylocked in the down position with weight on wheelsto preventinadvertentgearretraction. Pilot overrideof the solenoid-operatedhandle lock can be effectedbylifbigthe downlocklevernexttothe gear handle.Vertical movement of the gearhandle causesa correspondingup anddown selectionof thelandinggear with the combinedhydraulic systempressurized.Three flip-flop indicatorsprovide a position display for each of the landing gear, and a gear transition light on the control panel illuminates anytime the gearposition and handle do not correspond. In addition, a WHEELS warning light alerts the pilot if the landing gear is not down with flaps deflectedgreaterthan 1O”andeitheror both throttlesset for lessthan approximately 85-percent Ipm.
. Unless attempting fast-cycle troubleshootingfor gearthat indicatesunsafe nosegeardown, transition light ilhnninated,wait for gearto completely transition (15 secondswith normal hydraulic pressure) before recycling the landing gear handle. When fast cycling the gear handle,the pilot must immediately return the gear handle to the down position to avoid damaging the main landing gear doors and inducing a possible combined hydraulic or brake systemfailure.
An additional sequencingswitch in series with the existing down-and-lockedswitch provides the pilot with a positive indicationof nosegearposition.Ifthenose landing gear is unsafe in the down position becauseof premature deployment of the nose landing gear locking pin, the nosegear indicator will indicate unsafe and the transition light will illuminate. Maximum strut extension andwheel steering angle are controlled by torque arms interconnecting the steering collar and the lower piston. The split-type wheel assembly incorporatesa tire pressurerelief device to preventoverinflation ofthe tire. Additional hardware on the nose landing gear include the launch bar, holdback fitting, approachlights, nosewheel steering actuator, and taxi light. The wheel axles incorporate recessedholesfor attachmentof a universaltow barwith maximum steeringangleof *120°.
Restrict nosewheeldeflection to i90” to prevent stmctural damageto the nosegearsteering unit.
l
Maximum landing gear tire speedis 190 knots.
2.25.4.1 Landing Gear Handle Up. Placementofthe landing gear handle to UP actuatesthe landing gear valve that ports hydraulic pressure.to the downlock actuators,gear retract actuators,and, in sequence,to the dooranduplock actuators.The gearshockstrut anddoor uplocks are hydraulically operatedinto a mechanical overcenterposition. An UP indication is displayedon the gear position indicators when the gear are in the uplock andall doorsclosed. 2.25.4.2 Landing Gear Handle Down. Placement of the LDG GEAR handleto DN actuatesthe gearcontrol moduleto port hydraulicpressureto the dooruplocks,
2-119
ORIGINAL
NAVAIR Ol-Fl4AAD-1
door actuators,and the strut uplc&s. The landing gear are hydmulically extendedand assistedby gravity and airloads. A gear-downsymbol (wheel) is displayedon the gear position indicators when the gear downlocks are in the locked position. The geartransition light will go out when the main gearside-bracelii areengaged.
ing is disabled.Once the landing gear is extendedby emergencymeans,it camrotbe retractedwhile airborne and must be resetby maintenancepersonnel.
Note
Emergencyextension of the landing gear shall belogged in theMaintenanceAction Form (OPNAV Form 3760-2).
With themain geardownlock insertedbut the side-brace link not engaged,landing sink speedis restrictedto 8 feetper second.Minimize yaw and sideslips on touchdown and rollout. 2.25.5 Emergency Gear Extension. Although emergencygearextensioncanbe initiated with thelanding gear control handlein any position, it is preferable that the LDG GEAR handle be placed in DN before actuatingthe emergencyextensionsystem.
2.26 WHEELBRAKE
SYSTEM
The wheelbrake system provides power boost hydraulic control of the multiple disk-type main wheelbrakesusing pressurizedfluid in the landing geardown line from the combined hydraulic system.Individual or collective wheelbmke control can be modulatedby depressionofthe ruddertoe pedalsor collective; umnodulated brake control is available with the parking brake. An antiskid system is provided to operate.electrohydraulically in conjunctionwith the nomml wheelbraking mode.Wheclbrakecontrolsareshownin Figure2-70.
The landing gear handlemust be held in the folly extendedemergencyposition for a minimum of 1 secondto ensurecompleteactuation of the air releasevalve. Approximately 55 poundspull force is requiredto fully actuate the emergencynitrogen bottle. The pulling motion should be rapid and continuous to ensurethe air releasevalve goescompletely overcenterto thelockedposition.The landing gearhandlewill be loose(fore and at?)in its housing as an indication of complete extension of thehandle.An incompletehandlemotion could causepartial porting of gaseous fluid initiating theemergencydumpsequence. Interruption of handle motion without completing the overcenteringaction of the valve could cause the extending gears to contact and damagethe strut doors.
Brakepedalandparkingbrakecontrolmotionsam mechanicallytransmmedtothepowerbmkemoduletogether with the antiskidvalve. Separatehydraulic lines transmit normal and emergencyfluid pressureCorn the power brakemodule to theleft andright wheelbmkeassemblies. At eachbrakeassembly,the normal andemergencylines input to the brakeshuttlevalve, which appliesbrakesasa functionof normal or emeraenc~line fluid messme.Two
The emergencylanding gearnitrogenbottle is located in the nosewheelwell. Normal preflight bottle pressure is 3,000 psi at 70 OF.Minimum bottle pressure.for accomplishing emergency extension to the down-andlocked position is 1,800psi. Pneumatic pressureis directed by separatelines to power openthe geardoor actuatorsin sequence,release the gear uplock actuators,pressurizethe nosegearactuator to extendthe gear(main gearGeefall), and pressurize the downlock actuators, A normal geardown indication is achievedupon emergencygearextension. Following emergencygearextension,nosewheelsteerORIGINAL
To facilitate in-flight refneling probe extension when the landing gear has been blown down, raisethe landing gearhandle to give priority to the refueling probe system.
liming wear fo; preflight mspedion. For ne& brakes, thesepins extendapproximatelyonehalf inch abovethe pistonhousing.Whenthepin is flush with thepistonhousing with the parkingbrakeapplied,the brakeassemblyis worn to the point of replacement. Four thermal relief plugs are mounted in each main wheel assemblyto relieve tire pressureandthus avert a blowout becauseof hot brakes if the local wheel temperatumexceeds428 OF. The capacitiesof the wheelbrakeassembliesaresufficient to restrain the a&rat? in a static condition on a dry surfacewith MIL power set on both engines.The minimum hydroplaningspeedforthemain tires on a wet runway is approximately 90 knots.
2-120
NAVAIR OI-Fl4AAD1
FUNCTION
NOMENCLATURE
0 3 0 @
0 @
Parking brake handle
Forward -
Parking brake released. Modulated with brake pedal depression.
4ft -
Parking brake set. No modulation main wheel brakes.
braking action available of control, locks both
BRAKES warning light
Indicates parking brake handle is pulled, antiskid has failed, or operation in auxiliary brake mode when brake pedals are depressed.
is
Brake Pedals
Press top of rudder pedals to command
Hand pump
Recharges auxiliary and parking brake accumulators with gear handle down. With REFUEL PROBE switch in FUS or ALL EXTD, provides emergency extension or retraction of refueling probe regardless of gear handle position. With the gear handle down priority is given to brake accumulator pressure.
BRAKE PRESSURE gage
Provides pilot indication of brake accumulator pressure remaining indicative of auxiliary and emergency brake cycles remaining.
ANTI SKID SPOILER BK switch
BOTH -
Antiskid activated. Spoiler brakes operative with weight on wheels and both throttles in IDLE.
OFF -
Antiskid deactivated,
normal or auxiliary braking.
which is
spoiler brakes inoperative.
SPOILER BK - Spoiler brakes operate with weight on wheels and both throttles IDLE. Antiskid is deactivated.
Figure 2-70. WheelbrakeControls and Indicators 2-121
ORIGINAL
NAVAIR
2.26.1
0%F14AAD-1
Brake Charactariatica.
Became~nbrakerakes
containsolid disk-shapedcarbonrotors andstators, they cannot shingle. The thermal characteristics prevent them from fusing together during or following heavy braking.
tained by the combined hydraulic system. Normal combined-systemoperationscan result in pressureexcursionsthat will be trapped in the brake system.This can causethe brake pressureindicatorsto read beyond the full rangeof the gauges.This will not affect system performance.
Carbon brakes may produce a sudden increase in braketorqueasbrakepedal forceis smoothly increased. This can produce grabbing at low brake pedal force inputs. This grabbing is causedby excessiveair in the combinedhydraulic system.Open-loopbleeding of the combined hydraulic system by maintenancepersonnel will reducethe amount of air in the system and should eliminate any associatedgrabbing.If grabbybrakesare experienced, smooth modulation to higher braking forces is easily accomplishedafter the initial grabbing. The suddenincreasein torqueis most noticeableat moderateto slow taxi speeds.As groundspeedincreases,the kinetic energy of the aircraft increasesandthe effect of thesuddentorqueincreaseis significantly reduced.Normal braking technique should be used during normal rollout. The pilot must apply maximum pressureon the brake pedalsto hold the aircraft static at MIL. If carbonbrakes havebeenheatedup by a full-stop landing, andfor about 45 minutes thereafter,they will probably not hold the aircraft static with military power set on both engines evenwith the parking brake set.In this ease,7.5to 100 poundsof pedal force will hold the aircraft static with afterburnerset on one engineand idle power set on the olher. In all cases,holding the aircraf? static at high power settings dependson adequaterunway and tire conditions. Degradedconditions such as wet runways or worn tires may result in tire skid at high power settings.
When the antiskid systembecomesinoperative at 15 knots during a maximum-effort stop,carbonbrakescan lock the wheels and pedal pressureshould be relaxed as the aircraft deceleratesthrough 15 knots during a maximum-effort antiskid stop. Normal Braking. In the normal mode of operation, wheelbrakeapplication is modulatedby brake pedal depressionusing pressurizedfluid f+om the combined hydraulic system through the brake module and throughthe normal brake line to the brake assembly.In the normal mode of operation,the brakepressuregauge indication should continue to indicate a full chargeon the brake accumulatorssince this fluid energyis main-
2.26.2
ORIGINAL
After heavy or repeatedbraking or if hot brakes are suspected, allow a 5- to lo-minute cooling period with the gear extendedbefore retractingthe gear. If heavybraking is usedduring landing or taxiing followed by application of the parking brake, normal brake operation may not be available following releaseof the parkingbrake if thebrakesarestill hot. Check for normal brake operation after releasingthe parking brake and prior to commencing taxiing. Antiskid. The antiskid system operateseleotrohydraulically in conjunction with thenormal modeof wheelbrakeoperationto deliver maximum wheelbmking upon pilot command without causinga skid. EssentialNo. 2 busdc power for antiskid operationis supplied through the ANTI SKID/R AICS LKUP PWR circuit breaker (8El) and controlled by the ANTI SKID SPOILER BK switch (Figure 2-70). When energized, approximately 200 milliseconds are required for antiskid system warmup. Individual wheel rotational velocity is sensedby skid detectorsmounted in the wheel hubsandtransmittedto the skid controlbox. The control box detectschangesin wheel decelerationand reduces fluid pressurein the normal brake lines to both wheels, simultaneously,to prevent a skid.
2.26.3
With the antiskid system srmed in flight, the touchdown circuit in the control box preventsbraking until weight is on both main gear and the wheels have spun up, regardlessof brake pedal application. The antiskid system is inoperative at groundspeedsof less than 15 knots. During maximum-effort antiskid braking, expect a rough, surging deceleration.When the ANTI SKID SPOILER BK switch is in BOTH during low-speedtaxi (less than 10 knot.9for more than a few seconds),subsequent acceleration of the aircraft through approximately 15 knots will causea temporary loss of brakes lasting from 2 to 10seconds.Shouldthis happen,useof the brakescan be regainedinstantly by turning antiskid OFF. To precludethis possibility, antiskid must be OFF during taxi.
NAVAIR Of-FlUAD-1
greaterthan 1.2 secondsby the control box, the system automatically becomesinoperative and iIluminates the BRAKESwaminglightwiththe ANTISKIDSPOILER BK switch in BOTH.
(WARNING1 a Failure. of the weight-on-wheels switch results in continuous releasesignal with antiskid selected.Normal brakingis available with antiskid off.
2.26.3.1 Antiskid Ground Test. During ground operation, a self-test of the antiskid system can be initiated on the face of the control box with the system energized,parking brake handle released,and the aircraft in a ground static condition. Before taxiing (chocks in place), but atter releasingthe parking brake and while the pilot pressesthe toe pedal brakes, the plane captainshould pressthe antiskid testpushbutton on the control box in the nose wheelwell. Approximately 10 seconds is required for self-test, which checks the operational status of the control box, brake valve, and wheel sensors.Any discrepanciesdetected will be displayed by the BIT flags on the face of the control box (Figure 2-71).
a If the antiskid system fails, allowing antiskid to operatebelow 15knots,place the ANTI SKID SPOILER BK switch in OFF; otherwise the aimmA cannot be stoppedusing normal braking.
Failure to releasebrakesprior to deselecting ANTI SKID may result in blown tires. The antiskid system is inoperativewhen the wheelbrakesarein the auxiliaty or parking modesof operation sincethe emergencybrake lines bypassthebrakevalve. If an electrical failure occursin the antiskid systemor if hydraulic pressure is withheld from either brake for
AvalidBITtestmquiresthatthreecriteriabemetzthe BIT flagson the faceof the controlbox must checkgood, thepilotmustfeelbothb~~releaseduringB~tesfend the BRAKES warninglight must not remainilluminated. A Sashof theBRAKES light coincidingwith brakepedal thumpsduringthe antiskidBlT checkis acceptable.
Figure 2-71. Antiskid BTI Box 2-123
ORIGINAL
NAVAIR Q%Fl4AAD-I
p&G-WARNING)
pi---
a Even though braking action is available at accumulator pressuresless than 3,000 psi, braking force is proportional to pressure remaining. Red band pressure (1,900 psi) is sufficient to hold the brakeslocked with the aircraft stationary in all deck conditions; however, rolling motion greatly increases pressure requirements. Accumulator pressureof up to 2,100 psi may be required to stop a moving aircraft in a 4Odeck roll. In deck rolls greaterthan 6“, 3,000 psi may not be sufficient to stop a moving aircraft.
Before initiating antiskid self-test by pressing the antiskid pushbutton on the control box, ensurethat the aircratt chocks arc in place. Initiation of antiskid self-test will releaseaircraft brakes. 2.26.4 Auxiliary Brake. Two differentauxilimy brake systemsare presentlyincotpomtedin the aimaft. Enby into theauxiliarybrakemodeis the samefor bothsystems. Transferof normal brakeoperationto the auxiliary mode is automaticwithout thetequirementfor pilot actionupon thelossof combinedhydmulic systempteasute.Both auxiliary braking systemshavetwo brakeaccumulatorsthat providepressurefor auxiliary andparkingbrakemodesof operationwhen combinedhydraulic systemis not available.Accumulatorsdeliver 3,000psi when fully charged by thecombmedhydraulicsystemorhydraulichandpump (with the gear handledown only). When the combiied hydraulic systempressuredecreasesbelow 1,425psi, the shuttlevalve in the power brakemodule shifts the brake systemto theauxiliary brakemode. Approximately 13 to 14 full dual-brakeapplications are available in the auxiliary mode. Dual pneumatic BRAKE PRESSURE gaugeson the front cockpit center pedestalshow auxilii and parking brake accumulator pressures.Full capability operationsof the brake accumulators in the auxiliary modes of operationis predicatedon the system servicedwith a nitrogenprecharge of 1,900%50psi. The green band of the dial indicates pneumatic pressurebetween3,000 psi at the top of the band to 2,150 psi; the red band indicates pneumatic pressuresbetween2,150 and 1,900psi at the bottom of the band. Approximately five auxiliary brake applications are available in the red band. Once the auxiliary braking system is depleted, braking must be accomplished by the emergency/parkingbrake.Threeapplications of the parking brake are available. With eitherauxiliary brakesystem,additionalbraking canbe achievedonly by pulling theparkingbrakehaudle atI. If the shuttlevalve in the power brakemodulesdoes not returnto the normalpositionwith combmcdhydraulic pressuregreaterthan 2,000 psi, the BRAKES warning light will illuminate when a brakepedal is depressed.In this instance the wheelbrake accumulatorscan be rechargedonly by thehydraulichandpumpwith the landing gearhandledown. Pilot manualisolation or systemautomatic isolation of thecombinedhydraulic systemcutsoff the supply of combined hydraulic pressureto the power brakemodule so that depressionof the bmke pedalswill causedepletionof the bmkes’ accumulatorcharge. ORIGINAL
l
Complete loss of hydraulic fluid through thewheelbrakehydraulic lines will render parking brake ineffective.
2.26.5 BRAKES Warning Light. Tbe BRAKES warning light will illuminate wheneverauxiliary brake pressureis applied to the brakesvia the brake pedals, indicating the combined hydraulic system pressureis not available to the brakes and cautioning the pilot to monitor brake applicationwith the auxiliary brakepressureindicator.A postlight is installedabovetheBRAKE PRESSURE gaugeto illuminate the dial. Note The postlight requires electrical power. Brakeridem on carrier night respotmust use a flashlight to check the cockpit brakepressuregauge. 2.26.6 Parking Brake. The parking brake mode provides a means for collective locking of the wheelbrakesto maintain a ground static position during normal operations or during emergency conditions. Aft movementof the parking brake handleprovides for unmodulated porting of accumulator fluid pressure through emergency lines to the shuttle valve at the wheelbrakeassembly.In the parking brake mode, the rudderpedalshave no effect on wheelbrakeoperation. Pushing the parking brake handle forward releases wheelbrakepressureand the power brake module reverts to the normal and auxiliary braking mode. When auxiliary mode braking action is no longer availableby depressionof the rudderpedals, sufftcient accumulator fluid pressureremains for a minimum of threeparking brake applications.
2-124
tion by the NOSE WHEEL STEEWAFCS circuit breaker(RC2) on the pilot right knee panel. Hydraulic pressureis derived from the gear-downline such that steering control is disabled subsequentto emergency extensionof the landing gear (Figure 2-72).
Note The AUX brake andparking brake pressure indicator should be pumped into the green bandprior to breakingdown andmoving the aircmf?without combmedhydraulic power. The indicator should be maintained in the greenband until the airmutt is secured.Full 3,000 psi pressureis quited if conditions are severe(greaterthan 4Oroll, wet brakes, etc.).
Note If nosewheel steering is inoperative, the emergencygear extension air releasevalve may be tripped, which will prevent gear retraction.
In the absenceof a pressurixedcombined hydraulic system,the wheelbrake accumulatorscan only be rechargedby the pilot hydraulic handpumpwith the landmg gearhandlein the down position.
Completeloss of hydraulic fluid throughthe wheelbrakehydraulic lines will renderparking brake ineffective. 2.26.7 Wheel Antlrotatlon. Dmingtheinitialphase of the landing gear r&action cycle, pressurizedfluid from the gear-up lines is directed to the power brake module to displacethe normal metering valves to stop main wheel rotation before the wheels enter the wells. This featureis not provided for the nosewheels.
Ebuninationof indexerlights is not apositive indication that the main landing gear is clear oftherunway. Raisingthegearbeforeapositive rate of climb is establishedwill result in blown main tires. 2.27 NOSEWHEEL STEERING SYSTEM The electrohydraulicnosewheelsteeringsystemprovidesfor on-deckaircmft directionalcontrol, nosewheel shimmy damping,andnosewheelcantering.The power unit is located on the lower portion of the noselanding gear shut outer cylinder, which, through a ring gear, controls the dimctional alignment and damping of the lower piston assembly. Combined hydraulic system pressureis the motive powerusedfor steeringand centering.Electrical power is suppliedt?om the essentialdc bus with circuit proteo-
2.27.1 Nosewheel Steering Control. Nosewheel steeringcontrolduringgroundoperationsis onorgixedby momentarily pressingthe autopilot referenceand nosewheel steeringpushbuttonon the lower forward sideof pilot stick grip (seeFigure 2-72).The systemcarmotbe engagedwithout weight on wheels. The systemwill ro main engageduntil weight is offwheels, electricalpower is interrupted,or thepushbuttonswitch is pressedagain Engagementof nosewheelsteeringis indicatedby illumination ofthe NWS ENGA cautionlight. An automatic nosewheel steering system disengagefeature is provided. If this featurehas been activatedby cycling the hookondeckwiththethmttlesatidle,thenthenosewheel steeringwill be disengagedand the NWS ENGA light extinguishedwhen the launchbar is lowered.The nose wheel steeringautomatic disengagefeature is deactivated if the nosewheelsteeringbutton is depressed. With the systemengaged,nosewheelsteeringis contmlled by rudderpedalposition. Centeringis unaffected by directional trim displacement. Maximmn steering authority is 70” either sideof neutral,andthenosewheel canswivel a maximum of 120° aboutthe centeredposition. With greaterweight on the nosewheel(wings forward, high gross weight, etc.) the steeringtorque can only tum the nosewheel +5” with the aircrag static. However, only a slight forward movementwill provide the pilot with lull-power steering authority. In a full pedal-deflectionmm using nosewheelsteering,the aircratt pivots about a point betweenthe main gear such that the inboad main wheel rolls backward.Under this condition, application of either main wheelbrake will only serveto increasethe radius of turn. Becauseof the outboard location of the engines, the application of thrust in tight turns should be made on the outboard engineto etliciently complement the turning movement of the nosegear.Nosewheelcenteringis enabledby the same latching relay that enables nosewheel steering automatic disengagementwith launch bar lowering. Therefore, if the nosewheel steering is automatically disengagedwhen the launch bar is lowered, the nosewheelswill be hydraulically centered,
2-125
ORIGINAL
NAVAIR
01-Fl4AAD-1
NOMENCLATURE
FUNCTION
NWS ENGA caution light
lllumlnatlon when function of rudder centers with hook weight-on-wheels
0
Autopilot reference and nosewheel steering pushbutton
Press to engage and disengage weight-on-wheels.
0
Rudder pedals
0
nosewheel steering engaged and will respond as a pedal displacement. Nosewheel steering automatically down. Nosewheel centering requires throttles at IDLE and with hook down.
nosewheel
Figure 2-72. NosewheelSteeringControls
ORIGINAL
2-126
steering. Requires
NAVAIR 0%Fl4AAD-1
2.27.2 Nosewheel Centering. The nosewheel is automaticallycenteredduring gearretractionbeforethe nosewheelentersthe wheelwell. During gearretraction with weight off wheels, hydraulic pressuret?om the combined system bypassesthe steering unit shutoff valve to center the nosewheel independentof rudder pedalmovement.Ifthe nosewheelis cockedbeyond 15” eitherside ofcenter after takeoff, the nosewheelis automatically preventedBorn retracting and the LAUNCH BAR advisory light illuminates. During carrier arrestmem,the nosewheelis centered with weight on wheels andhook down when both throttles are retardedto IDLE to prevent castoring during rollback. After arrestmentand rollback, the nosewheel will remaincentereduntil nosewheelsteeringis engaged. [WPIRUING) Nosewheel centering can contribute to launchbarmisalignment in the catapultshuttle, which could result in prematurelaunch bar separationduring launch.The nosewheel centeringlatching relay must be deactivated by depressingthe nosewheelsteeringbutton afterthe hook check andprior to enteringthe catapult. As this will also deactivate the nosewheel steering automatic disengagement function, the nosewheelsteeringmust be manually disengagedwhen entering the catapult. 2.27.3 Shimmy Damping. Shimmy damping is pmvidedin the steeringactuator.Increasedshimmy damping action is obtainedwith NWS disengaged. m
craft at shuttle release,thus providing for a hands-off launchflyawaytechnique. 2.28.1 Nose Strut Kneel. Prior to catapulthookup, the nose strut is compressed14 inches.Control of the nose strut kneel function is provided by the NOSE STRUT switch on the landing gear control panel (see Figure 2-73.) The three-position (EXTD, OFF, and KNEEL) toggle switch is spring loadedto return to the detentedcenterto OFF. The position of the strutremains in the last commandedposition independentof electrical or hydraulic power interruptions. In both cases, the transfercontrol valve source of electrical power is the essentialNo.2 bus andcombmedhydraulic systemfluid is usedas the transfermedium. With external electrical power on the aircraft, the combined hydraulic system must bepressurized(>500 psi) beforethe control switch can commanda position changeof the transfercontrol valve. The control switch needonly be held momentarily to effect a changein transfercontrol valve position. SelectionofKNEEL releaseshydraulic fluid from the shock strut transfercylinder to the combinedhydraulic system returnline, causingthe weight of the aircraft to compressthe shock strut 14inches.Stroking ofthe nose strut causesthe aircraft to rotateaboutthe main wheels. The aircraftmay be taxied or towed in the strut-kneeled position exceptfor the nuisancetrip of the launchbar at greaterthan 10” steeringangle; this is theposition used for taxiing onto the catapultand enhancesaccessibility to the forward fuselage compartmentsduring ground maintenance.Sincethe nosestrut is bottomedduring the catapult launch stroke, the energy stored in the last 4 inches of strut-piston stroke is releasedupon shuttle releaseat the end of the catapult stroke to impart a noseup pitching moment to rotate the aircraft to the fly-away attitude without any control requiredby the pilot. All the stonedenergyis expendedbeforethe nosewheelsleave the deck edge. Note Under certain launch conditions (high wind over deck and light aircraft gross weights) the nose strut will not be fully compressed during the catapult stroke. Subsequentnose rotation following shuttle releasewill be at a less than normal rate. Aircraft launch bulletins for the aircraft are written to ensurethat catapult launch pressuresare sufficient to provide safe launchpitch ratesand flyaway capability.
If excessivenosewheelshimmy is encountered,disengagenosewheelsteering. 2.28 NOSEGEAR CATAPULT SYSTEM Catapult connection componentson the noselanding gear shock strut piston provide nosegearcatapult capability. A launch bar attachedto the forward face of the nosegearsteeringcollar guides the aircraft onto the catapult track and serves as the tow link that engagesthe catapult shuttle. A holdback fitting secures the holdback restraint prior to launch. The two-piston nosestrut usesthe stored energy catapult principle to impart a positive pitch rotation movement to the air-
Full extensionof thenosestrutafterlaunchandweight off wheelsprovides a redundantand automatictransfer of the control valve to the extendposition. With weight off wheels,the NOSE STRUT switch is inoperative.
2.127
ORIGINAL
NAVAIR 0%MUAD-I
NOMENCLATURE 0
0
NOSE STRUT switch
LAUNCH BAR advisory light
EXTD -
FUNCTION Hydraulic pressure causes strut to extend. Combined hydraulic system must be pressurized before switch is activated on external power. Launch bar is lifted into the up-lock position by torque arms as strut extends 14 inches.
OFF -
Spring-loaded
return position.
KNEEL
Nose strut transfer control valve releases pressure In the shock strut, which strokes 14 inches. Combined hydraulic system must be pressurized before switch is active on external power. Launch bar uplock can be released manually to allow bar to lower to deck, or by turning nosewheel 3~10’.
illuminates under the following
conditions:
WeightOn Wheels l
l
Aircraft kneeled, throttles less than MIL (goes out when throttles are advanced to MIL to provide lights out criterion for catapult launch). Launch bar not up and locked (normal operation)
WeightOff Wheels(mhiblts nosegearretraction) l l l
@
LAUNCH BAR switch
Launch bar not up and locked Nosewheel not within &IV of center Nose strut not fully extended
ABORT -Enables pilot to disengage the launch bar from the catapult while remaining at MIL power and in the kneel position. NORM
Allows launch bar to be lowered.
Figure 2-73. Launch Bar Controls ORIGINAL
2-128
NAVAIR 0%Fl4AAD-1
2.28.2 Launch Bar. Thelaunchbarisattachedtothe nosegearand servesas the tow link for catapultingthe aircrafi (seeFigure Z-74). With the nosestrut extended, the launch bar is held in the retracted position. The launchbar can be lowered by kneeling the aircraft and turning the nosewheelgreaterthan ilOo from the centeredposition. The launch bar can also be lowered by the deck crew with no pilot action after the aircraft has beenkneeled.A proximity sensingswitch on the uplock detectsthe latch out of the locked position and ilhuninates the LAUNCH BAR advisory light (see Figure 2-73). Ears on the headof the launch bar engageunder the lip of the catapultlead-in track and the head serves as a guide to steerthe nosewheelon the catapulttrack and engagethe shuttle. For an abort, the launch bar cannotbe raiseduntil the shuttleis disengaged. 2.28.2.1 LAUNCH BAR Light. ‘Ihe LAUNCH BAR advisorylight is interlockedto go off whenboth throttles are at MIL even though the launch bar position and mechanismremain unchanged,this action is effectedto establisha “lights out” criterion for launch. The light circuit is disabledwith nosegearup andlocked. A pilotcontrolled LAUNCH BAR switch is installed that enables the pilot to disengagethe launch bar from the catapultwhile remaining at MB. power and in the kneel position.This switch is on thepilot left vertical console.
single-engine high power, the nose strut should be kneeledandslacktakenout of the holdbackmechanism, otherwise dynamic loads may exceedmechanism design strengthconditions. 2.29 ARRESTING HOOK SYSTEM The arrestinghook installation consistsof a stinger tailhook andassociatedcontrol mechanismmountadto the undersideof the centerfuselage.The hook shankis free to pivot up and down at its attachmentpoint. A pneumaticdashpotpreloadsthe hook down to minimize hook bounceon contactwith the deck. The hook shank isfieetopivot leftorright withina+26”swayanglewith positive centering action provided by a pneumatic damperhousedinsidethe tailhook shank.The trail angle of the arresting hook provides for hookpoint-deck contact even with the nose landing gear strut fully compressed. 2.29.1 Arresting Hook Operation. Normal operation of the arrestinghook requirescombined and flight hydraulic systempressure,dashpotcharged,and dc essential No. 2 electrical power. Becauseof a redundant meansofpilot control (electricalandmechanical),emergency extensionof the arrestinghook can be accomplished without thesesourcesof power. Note Hook retractionrequireselectrical andcombined hydraulic power.
To avoid damageto the launch bar retract mechanism, do not set the LAUNCH BAR switch to ABORT with the nosewheeldeflected off center. After the catapultlaunchstroke,extensionof the strut mechanically cams the launch bar up to the retractedand-lockedposition. If the launch bar is not engagedin the uplock with weight off wheels,the LAUNCH BAR advisory light will illuminate and nosegearretraction will be electrically inhibited. 2.28.3 Holdback Fitting. The holdback fitting is providedon the nosestrut for insertion of the holdback bar. A groundcrewmanmust manually attach the bar beforethe aimrat?is taxied into the catapult lead track. The holdbackbar is reusableand provides for repeated releasesat a tow force of 76,000pounds.Force greater than this on launch causesthe holdback bar to release the aircraft holdback fitting.
2.29.1.1 Normal Operation. Normal operation (Figure Z-75) on the pilot hook control consists of a straightdown-upmovement of the HOOK handle.This action actuatesswitches that provide electrical command signalsto thehook control valve. For lowering the hook, the uplock is released and the lit? cylinder is vented. Flight hydraulic pressureis the medium that disengagesthe hook uplock actuator.When flight hydraulic pressuredropsbelow 2,100 psi with weight off wheels,the hook/auxiliary flap isolation relay circuit is energized.This disablesthe arrestinghook control valve and, therefore,disallows normal hook extension.This condition remains until either the starboard enginedriven hydraulic pump (flight) produces greaterthan 2,400psi or weight on wheels is restored.
Single-engine,high-powertumup operationscanuse the holdback fitting to attach aircraft restraininghardwareto deck-securedfittings. Prior to the application of 2-129
Note If emergencyhook extensionis inoperative in conjunctionwith a flight hydraulic failure, cycling the HYD VALVE CONT circuit breaker (8E5) with the hook handle down will permit hook extension.
ORIGINAL
NAVAIR Ol-Fl4AAD-1
STRUT EXTENDED TO NORMAL STATIC POSITION (18 INCH STRUT)
FULLY COMPRESSED
CATAPULT STATIC POSITION I4 INCH STRUT)
0.F6cm3 Figure 2-74. Laud
ORIGINAL
2-130
BU (Cat@t)
NOMENCLATURE 0
Arresting HOOK handle
FUNCTION UP-
Electrically energizes hydraulic retract actuator to raise hook into uplock.
DN-
Electrically releases hydraulic uplock actuator and allows hook to extend by dashpot pressure and gravity,
EMERG DOWN -
0
0
(Pull-twist) mechanically releases uplock actuator and allows hook to extend by gravity and dashpot pressure.
Hook transltion light
Illuminates whenever arresting hook posltlon does not correspond with handle position. Light will not go out In down position until hook is In full trail angle.
HOOK BYPASS switch
FIELD -
Used for nonarrested landings. Bypasses the flashing feature of the approach lights and indexer when landlng gear Is down and hook retracted.
CARRIER
Used for arrested landings. Approach lights and indexer flash when landing gear is down and the hook retracted.
Figure 2-75. Arresting Hook Conkok 2-131
ORIGINAL
NAVAIR 0%FlUAD-I
2. OBGGS
2.29.1.2 Hook Retraction. For hook retmction, the control valve pressmixesthe retract side Of the. lift cylindor and the lock side of the actuator.
3. Cockpit pressurixation 4. canopy seals
fYijG&J
5. Windshield and canopy defogging not attempt to raise the hook when the hook is engagedin the arrestinggear.
DO
6. Windshield anti-ice
When the arresting hook roller engagesthe uplock mechanism,the lift cylinder is depressmixed.On deck, hook retraction time is approximately 3 seconds.The hook transition light is illuminated aslong as a discrepancy exists betweenthe hook and cockpit handlepositions. On-deck extension requires approximately 1 second.The transition light will remain illuminated, unless the a&aft is kneeled, as contact with the deck precludesfull hook extension. Note The hook transition light may remain illuminated when the hook handle is lowered at airspeedsgreaterthan 300 knots becauseof hook blowback. 2.29.1.3 Emergency Hook Extension. The emergencycontrol system lowers the hook by mechanically (cable) tripping the uplcck and venting the hook lit? actuator pressure.Emergency extension of the hook may be initiated when the handleis in eitherUP or DN. In either case,the hook handle is pulled aft (approximately 4 inches)and turned 90” counterclockwise.Rotation 90” counterclockwisewill lock the handle in the extendedposition. With thehandlelocked,thehook will not retractregardlessof thehandleposition (UP or DN). Note After emergencyhook extension,thehookcan be dracted airhomeor on deck providedthat thebsndleismtated90°clockwise,pushedfcll forward and placed in UP. Combined and flight hydraulic systempmssmesmresuired to r&act the hook while airborne.On deck, only combined hydraulic systempressureis requiredto retractthe hook
7. Anti-g suit inflation 8. Wing airbag seals 9. Gun-gaspurging 10. Electronic equipmentcooling andpressurization 11. Temperatom control of liquid coolant suppliedto APG-71 radar control system, television camera set, and intiamd searchand track. 2.30.1 ECS Air Sources 2.30.1.1 Bleed Air. The normal sourceof ECS air is ninth-stagebleedair from both engines.Througha series of manifolds andvalves, this air is cooledand mixed to reducetemperatumandpressureto usablelevels.The primary valves are the two enginebleedair shutoff valves, the dual pressureregulating and shutoff valve, and the turbmecompressormodulating and shutoffvalve, which areall contmlledby the AlR SOURCE selectorpushbuttons:L ENG, R ENG andBOTH ENG (Figure2-76.) 2.30.1.2 Ram-Air Source. If either the RAM or OFFpushbuttonisselectedbythepilot,thecoolingturbine compmssorisshutdowuandemergencyramaircanbc usedtoventilatethewckpits andprovidecoolingairtothe serviceand suit heat exchangerandthoseel&tonic subsystemsrquiring forced air cooling. However,if OFF is sel@ pressurizationto the service systems(canopy seal, anti-g suit, external fuel tank, wing airbag seal, OBGGS),and400°Fairsupplytothewindshieldairdefog andheatingsystemsislost.SelectingAlRSGURCERAM willprovideairtotbe~systemsand400’Fmmanifold air to the &fog andheatingsystems.
2.30 ENVIRONMENTAL CONTROL SYSTEM The ECS regulates the environment of flightcrew and electronic equipment. The system provides temperaturecontrolled, pressure-regulatedair for the following systems. 1. E~temal drop tank pressurixation ORIGINAL
2132
Selection of the AIR SOURCE pushbutton to RAM with a failure of the 400 OFtemperaturemanifold will continue to circulate 400 OFair throughoutthe system surromiding aircratt componentsandmay causea tire.
NAVAIR 0%Fl4AAD.1
RIO
CAUTION/ADVISORY PANEL
NOMENCLATURE
01
02
0
TEMP mode selector switch
CABIN PRESSswitch Lever-lock switch which must be lifted to be moved to DUMP
RAM AIR switch
AUTO -
FUNCTtON Cockpit and pressuresuit temperatureis automatically maintainedat that comfort level selected on the temperature control selector.
MAN -
Cockpit temperatureand air flow must be manuallyselected as airspeed and attitudechangeto malntaina desired temperature.
NORM -
Cockpit pressurewill be maintainedat an altitude of S,ooOfeet up to 23,WJ feat, above which the regulatormaintains a 5-psi pressuredifferential.
DUMP -
The cockpit Safetyvalve Is opened, depressurizingthe cockpit.
OPEN/ CLOSE-
Manually modulatesthe ram air door and regulatesthe amount of ram air supplied to the cabin and eiectronlcsbay aflerthe AIR SOURCEpushbuttonis selected to RAM or OFF, (Approximately50 seconds to full open.)
Figure 2-76. Air-Conditioning andPmsurization Controls and Indicators (Sheet1 of 2)
2133
ORIGINAL
NAVAIR 01-Fl4AAD-1
NOMENCLATURE
c9
I
FUNCTfON
I
AIR SOURCE selector pushbuttons
RAM-
Closes the bleed air flow modulator pressure regulator and shutoff valve, thereby securing the cooling bootstrap turbine compressor. Inhibits gun firing. The RAM AIR switch is enabled. Combined ram air and regulated 400°F bleed air are available to the cockpits and air cooled electronic equipment for temperature control.When either BOTH ENG, L ENG or R ENG are selected, the ram alr door automatically closes.
LENG-
The left engine is the source of bleed air for the environmental system and the right engine bleed air shutoff valve is closed.
RENG-
The right engine is the source of bleed air for the environmental system and the left engine bleed air shutoff valve is closed.
BOTH ENG -The right and left engine bleed air shutoff valves are open and both supply bleed air to the environmental control system. This Is the nomral position. Automatically closes ram air door. OFF -
controt
Both the left and right engine bleed alr shutoff valves and the dual pressure regulator valve are closed. Inhibits gun firing. Pressurization and air conditioning are not available. Enables the RAM AIR switch.
@
TEMP thumbwheel
@
CABIN PRESS ALT indicator
Displays cabin pressure altitude In 1 ,OCrO-foot increments from 0 to 50,OKt feet.
07
BLEED DUCT caution light
Indicates overheating (575OF or greater) along the high-temperature bleed alr duct routlng forward of the englne fire wall past the primary heat exchanger and then up to the right diverter area. An additional sensor, detecting temperatures of 255°F or greater, senses from the right diverter area, along the 405OF manlfold and Into the bootstrap turbine compartment.
@
CABIN PRESS caution light (RIO’s cockplt)
Indicates cab/n pressure Is less than 5-psi absolute pressure or cockpit altitude Is above 27,OKI feet.
Selects cockpit and suit air tetTIperatUre. It can be rotated through a 3CxY arc (0 to 14) with mechanical stops at each end placarded COOL and WARM. A mldpositlon temperature (7) is approximately 70°F In the automatic mode. With the TEMP mode selector switch in AUTO the temperature selected is automatically malntalned by the modulating temperature control valves. In MAN, the TEMP control thumbwheel must be repositioned to maintain cockpit and suit air temperature. Alr flow and temperature will not change as a function of airspeed and altitude.
Figure 2-76. Air-Conditioning andPressurizationControls and Indicators (Sheet2 of 2)
ORIGINAL
2-134
NAVAIR Wt=l4AAD-1
Interconnectsinhibit gun ftig with RAM or OFF selected.The emergencyram-air door is on the lower right side of the foselage,inboardof the right glove. To activatethe ram-air door, either the OFF or RAM AIR SOURCE pushbuttonmust be depressedandthe RAM AIR switch on the air-conditioning control panel must be moved to OPEN. To activatethe emergencyram-air door kom fully closed to fully open requires approximately 50 seconds.
l
l
Note With the systemin MAN to increaseairflow to forced-air-cooledequipment,place CANOPY DEFOG-CABIN AIR control lever in CANOPY DEFOG.
Before opening the ram-air door, reduce airspeedto 350 knots or 1.5Mach, whichever is lower, to preventram-air temperatures above 110 OF from entering the system. After ram-air flow is stabilized, airspeed may be varied as required for crew comfort or to increaseflow to electronic equipment
The third heatexchangeris the serviceair-to-air heat exchanger.This normally usescold air from the cold-air manifold as a heat sink but can use emergencyram air if the cold-air manifold is not operating.Air from the serviceheatexchangeris usedby thepressuresuit, anti-g suit, canopy seal,OBOGS, servo air, and for pressurization of waveguides, the radar liquid cooling loop tank, and the television cameraset.
With AIR SOURCE OFF selected,limit airspeedto lessthan 300 knots/O.8Mach to prevent damageto the deflated wing airbag seals.
For maximum cockpit ram-air flow, the cockpit pressurization must be dumped.Pressingeither L ENG, R ENG or both ENG pushbuttonsautomatically closesthe ram-air door if it is open. 2.30.1.3 External Air. The adapterfor connectinga groundair-conditioning unit is underthe fuselage,aft of the nosewheelwell. An additiOna provision for connecting an externalsourceof servoair is in this samearea. External electrical power is automatically inhibited !?omAYK-141,IRST,TRi,TR2,andtheCICJifexternal air-conditioning is not connectedto the aircraft. A pressureswitch interrupts electricalpower to the above forced-air-cooledequipment. 2.30.2 Cockpit Air-Conditioning. ing consistsof:
hot enginebleed air to a temperatureofapproximately 340 OF;the remainder is further cooled by the turbine compressor.Herethe air is compressed,run throughthe secondaryheat exchanger,and then expandedin the turbine section,resulting in cold air that is mixed with 340 OFair to obtain any temperaturedesired.The primary and secondaryheat exchangersare betweenthe let?and right engineinlets and the fuselage.At speeds above0.25Mach, ram air acrossthe heatexchangersis used for cooling. During ground operationsand at airspeedslessthan 0.25 Mach, airflow acrossthe heatexchangeris augmentedby air-poweredturbine fans.
ECS manifoid-
1. The high-temperature(bleedair) manifold 2. The 400° manifold 3. The cold-air manifold. High-temperatureenginebleed air is routed through the primary heat exchanger.The cooled output of this heat exchanger is split and a portion is mixed with
2.30.2.1 Temperature Management. The pilot can control cockpit temperatureby selecting either a manual (MAN) mode or automatic (AUTO) modewith the TEMP mode selectorswitch (Figure 2-76). In the AUTO mode, temperature(60 “F to 80 OF)is selected by the pilot with the TEMP thumbwheel control. This desiredtemperatureis maintained by a cabin temperature sensorin the forward left side of the cockpit. In the MAN mode,the TEMP thumbwheel control maintains airtlow and temperature.If cockpit inlet airtlow temperature(in either AUTO or MAN) exceeds250 OF,a cockpit overtemperature switch closes the hot-airmodulating valve. The conditioned air entering the cockpit is divided forward and aft, with 50 percentof the air going to each cockpit. A CANOPY air diffuser lever on the right console in eachcock-pitindividually controlsthe percentage of airflow throughthe cockpit diffusers andthe canopy defog nozzles.When the lever is in CABIN AIR (full aft), 70 percentof the air is directedthroughthe cockpit diffusersand30 percentthroughthe canopydefognozzles. In DEFOG, 100 percent of the air is directed throughthe canopydefog nozzles. 2.30.2.2 Vent Airflow Thumbwheel. This control hasno function.
2-135
ORIGINAL
NAVAIR Ol-FWAAD-I
2.30.2.3 Anti-G Suit. Each anti-g suit is connected to the aircraft pressurizationsystem by an anti-g suit hosethat deliverspressurizedair to the suit control valve and then to the suit through a composite disconnect. Below 1.5g, the suit remains deflated. A springbalanced anti-g valve automatically opens when g forces exceed 1.5g. Operation of the anti-g suit valve may be checked by depressingthe test button marked G VALVE on eachcrewman’s left console. 2.30.3 Electronic Equipment Cooling. Ambient cooled equipmentin the electronicbays is cooledby the air exhaustedfrom the cockpits. Equipment incapable of being cooled by free convection is cooled from the cold-air manifold. A schematic of the radar and electronic equipment cooling is shown in FO-14. Controls and lights are shown in Figure 2-77. 2.30.3.1 Radar Liquid Cooling. Radar equipment is cooledby liquid coolant(FO-14). The heatis rejected in the ram-air heat exchanger.This is accomplishedby circulating coolant fluid through the electronics and mm-air heatexchangerand/orthe radarheatexchanger. The cooling loop is also usedfor automatic warmup of the radarusing 400 OFmanifold. The radarliquid cooling loop incorporatesa separate ram-air liquid-heat exchanger.A ram-air door is located under the right glove, forward of the primary heat exchanger inlet. There are no cockpit controls for this ram-air door. It is controlled by the radarcontroller and is independentofthe air-conditioningandpressurization system. The radar systemram-air heat exchangerautomatically maintains the liquid temperaturewithin operating limits when ram air is used for cooling. 2.30.3.1 .I Controls and Lights. Figure2-77shows the controls andlights associatedwith the radarcooling loop. The radarcooling loop is activatedby theRADAR COOLING switch on the RIO left outboardconsole.In ON, the radar cooling loop is activated for airborne operation.A temperaturesensorin the heat exchanger outlet illuminates the SENSOR COND advisory light when the liquid temperaturegoesabove 104 OF.In addition, a pressureswitch in the radarpump illuminates the SENSOR COND advisory light when pump output pressureis too low. If the coolant pump temperaturerises to 230 A5 OF, the thermal switch opens, shutting down the pump to prevent pump failure and illuminating the SENSOR COND advisory light.
2.30.3.1.2 Ground Operation. During ground operationwith electrical power, externalair-conditioning, and servoair availableto the aircraft andthe GND CLG switch in RADAR, the cockpit low-flow sensoris overridden. The OFF position of the GND CLG switch enablescockpit air priority. With enginesrumiing on the ground,select OFF on the ground cooling switch. 2.30.3.2 Cockpit Air Priority Function. The cockpit air priority function is operationalduring all engineon operations (FO-14). It provides the cockpit with priority over the radar liquid-cooling loop in the event thereis a shortageof conditioned air. On enginepower, the GND CLG switch (Figure 2-77) should always be in OFF and the canopy locked to enablethe cockpit air priority function. Thereis no indication to the flightcrew that the cockpit priority action is taking placeunless it progressesto the point that the SENSOR COND advisory light illuminates. Even then, it is only one of severalproblems that could have triggeredthe light. 2.30.4 Pressurization 2.30.4.1 Cockpit Pressurization. From sea level to 8,000 feet altitude the cockpit is unpressurized.Between altitudes of 8,000 feet to 23,000 feet the system maintains a constantcockpit pressurealtitude of 8,000 feet.At altitudesabove23,000feet,the cockpit pressure regulator maintains constant 5-psi pressuredifferential greater than ambient pressures.An illustration of the cabin pressurescheduleis shown in Figure 2-78. 2.30.4.1.I Cockpit Pressure Indicators. A cockpit pressurealtimeter (Figure 2-76) is provided for the pilot. In the rear cockpit, the RIO has a low-pressure caution light on the CAUTION and ADVISORY light panel. This low-pressure caution light, placarded CABIN PRESS, illuminates when cockpit pressure dropsbelow S psi absolutepressureor cockpit altitude is above27,000feet. 2.30.4.1.2 Cockpit Pressure MalRnwtlons. Ifthe cockpitpressureregulatormalfunctions,thecockpitsafety valve will opento preventa cockpit pressuredifferential fmm exceedingapositive5.5~psior a negativedifferential of 0.25 psi. The cockpit pressureregulatorandthe safety valve are pneumatically operated and timction indo pendemlythroughseparatepressuresensinglines. 2.30.4.1.3 Cockpit Pressure Dump. Cockpit pressurizationcanbedumpedby thepilot by selectingDUIvlP with theCABIN PRESSswitch. WhenDUh4Pis selected the safetyvalve is immediately openedandthe cockpit is dt?pRSSurized
ORIGINAL
2-136
NAVAIR Of-F14AAD-1
I
NOMENCLATURE
a
RADAR COOLING switch
FUNCTION OFF -
Deactivates the radar cooling pumps.
ON
Activates the radar cooling pump for ground and airborne thermal conditioning.
-
@
;;A$AR ENABLE caution
Indicates that radar operation on the ground is possible.
0
COOLING AIR advisory light
Illuminates afler a delay of 25 to 40 seconds when insufficient cooling is provided to the electronic forced air cooling system. Degraded cooling may result from cooling system failure, turbine failure, or ECS duct failure.
@
SENSOR COND advisory
iigm
lllumlnates when coolant exiting the heat exchanger is greater than lC!PF, or pump output pressure is too low, or when the overtemperature switch shuts down the radar, television camera Set (KS), and the infrared search and track (IRST).
Figure 2-77. Avionic F,quipmentLiquid Cooling Controlsand Lights (Sheet1 of 2)
2-137
ORIGINAL
NAVAIR 0%FlUAD-I
NOMENCLATURE
0
FUNCTION APG-71 - Cockpit low flow sensor Is overridden.
GND CLG switch
CAUTION
OFF -
c3 C & D HOT caution
light
l
Servo air required to atiuate servo operated valves.
l
Use RADAR only when engines are shut down.
Cockpit low flow interlock Is operationaLOFF when engines are operating.
shall be selected
I
Indicates DD or TID overheat condltlon.
Figure Z-77. Avionic Equipment Liquid Cooling Controls and Lights (Sheet2 of 2) 2.30.4.2 Canopy Seal Pressurization. Pressurized air from the air-conditioning system is ductedthrough the cockpit to the canopyseal.The sealis automatically inflated whenthe canopyactuatoris moved to theclosed position. A check valve in the canopypressureregulating valve preventsthe loss of canopysealpressurization if the conditioned air manifold is depressurized.Initial movement ofthe canopyactuatorautomaticallydeflates the seal. 2.30.5 Windshield Air and Anti-Ice. Compressor bleed air at approximately 340 “F and at high pressure is directedover the outside of the windshield througha fixed-areanozzle. This blast of hot air over the windshield will evaporaterain and ice andpreventits fiuther accumulation. It is activatedby selecting ON with the WSHLD AIR switch. A temperatureoverheat sensor at the base of the windshield protects the windshield from overheating. When the sensordetectsoverheating (300 OF), a signal closes the pressureregulating valve and illuminates the WSHLD HOT advisory light on the pilot CAUTION ADVISORY light panel(Figure 2-79).
2.30.6 Gun-Gas Purging. External airflow is used to ventilate the gun compartment for gun-gaspurging. A flush air inlet on the fuselagegun bump and an at? louvered door containing a FOD screenprovide a continual flow of air to purge gun gases.Gun tiring is limited to 200-roundbursts. 2.30.7 Degraded ECS Operation. There arevarious temperatureand pressuresafeguardsystemsthat cause the ECS system to shut down if an unsafesituation is detected.A complete failure of the dual valve will cause it to shut down the pressurizationand air-conditioning system.Should that fail to close,a pressureswitch will closeboth enginebleedair shutoff valves if anoverpressure(155psi) situation existsin theoutlet oftheprimary heatexchanger.A shutdownofthe bleedair supplyduct, either automatically or pilot-selected AIR SOURCE OFF pushbutton,will causetotal ECS air shutdown.
9 SelectingWSHLD AIR ON prior to entering rain or icing conditions may cause windshield cracking becauseof the rapid cooling effects ofprecipitation. l
Note After an automatic shutdownof the system, the pilot should select either OFF or RAh4 AIR SOURCE to enabletheemergencyramair door and then hold mm-air switch to OPEN for approximately 50 secondsto provide ram-air cooling to electronicequipment and to the cabin.
Extended operationsin clear air with the windshield air on may causewindshield cracking and discoloration.
ORIGINAL
Failure of the left or right weight-on-wheels switchesto the in-flight modecan causeloss of engineejector air to theIDGs andhydraulic heat exchangerscausingthermal disconnect and/or heat damage to the generators and aircraft hydraulic systems.
2-138
NAVAIR Ol-F14AAD-1
J -0
Figure 2-78. Cabin PressureSchedule
l
l
Note Lossof electricalpowerwith bleedair still operatingwill result in smokeenteringthe cockpit throughthe ECS whenthe aircraft is on the deck. In flight, only cold air will be suppliedto the cabin and suit. Icing of the water separatormay occur, causing reducedflow to the cabin. Since the ECS panel is dependenton electrical power, selectorpushbuttonswill be inoperative.
3. RIO SENSORCOND advisorylight illuminated. 4. If ram-air cooling is not selected,extendedflight with AlR SOURCE OFF could cause an overheating condition of the converter interface unit anda subsequentloss of primary attitudeandnavigational indications (i.e., multifunction displays, HUD, NAVAIDs). The pilot shouldpressthe AIR SOURCE RAM pushbutton and set the RAM AIR switch to OPEN to open the ram-air door to provide forced-air cooling to the electronicequipmentand to the cabin.
Retardingthrottlesto IDLE above30,M)o feetmay result in a considerablereduction in ECS airflow, leadingto a lossof cockpit pressurization, SENSOR COND light, and/orCOOLING AIR light.
If the 400’ manifold reaches475 OF,a 400 “F shutoff valve closes,stoppingthe flow of unconditionedengine bleed air to the 400 OFmanifold. If eithercompressorinlet or turbine inlet tempemtum becomes excessive, the refrigeration unit will shut down. Cockpit indications will be as follows: 1. No cockpit airilow. 2. RIO COOLING AIR advisory light illuminated.
ECS duct failures may be indicated by diminishing cabin cooling airflow and/or cabin pressurizationwith or without COOLING AIR advisory light illumination. Duct failuresmay additionally be indicatedbypressurixation loss to theservicesystemsandairflow lossto rain removal, defog, and heating systems. This cannot be verified if the system is not in use. Selection of AIR SOURCE OFF andram air increaseis appropriatewhen any indication of duct failure exists. ECS malfunctions that arenot causedby duct failure areusually indicated by loss of temperaturecontrol without a cabin or system airflow/pressurizationdegradation.Failure of the400 OF modulating valve or duct should not causeillumination of the cooling air light. Any duct failure in this area
2-139
ORIGINAL
NAVAIR
Ol-Fl4iUtD-1
NOMENCLATURE a
FUNCTION
WSHLDAIR switch
ON-
Providesa continuousblast of hot air (34OV) over the exterior windshield. Used for windshield antl-ice.
OFF -
Closes the shutoffvalve aftera 5-second delay. The system Is deenerglzed.
0
WSHLDHOT advlsoly light
Light illuminateswhen a sensor In the warm air nozzleto the cent& wlndshleld lndlcates overheat(3OOOF).
0
CANOPYair diffuser lever (bothcockpits)
CABIN AIR -
70% of the conditioned alr dlrectedthroughthe cookplt alr diffusersand 30% Is throughthe canopy defog rails. This Is normal posltlon.
DEFOQ-
Alr flow Is dlrectedthroughthe canopy defog rails only.
Figure 2-79. CanopyDefog Controls and Windshield Air ORIGINAL
2-j40
NAVAIR OWl4AADl
Powerto themonitoris providedby 28VdcOBOGS controlpowert?omtheessential dcbusNo. 1whenthe OBOGSmasterswitchis intheONposition.Thesensor in themonitorisheatedfor properoperation. Uponinitial selectionof the OBOGSmasterswitchto ON, the OBOGSispoweredand8uwtioningbutthemonitorwi~ not beaccuratelydetectingoxygenconcentration until Actuationof the overtemperatum switchresultsin thesensoris warmedup. Thiscantakeupto 2 minute% on the ambienttemperature. The OBOGS cyclingof the400“F valve.Duringthisperiodtheheat- depending ingcapacityof the400OFmanifoldwouldbedegraded. lightwill notbeilluminatedduringthewarmupperiod. Thepilotmaytestoperationofthemonitorviathepress2.31 OXYGEN SYSTEM to-ventTESTbutton.Thebuttonactuatesa valvethat mustbe heldfor up to 1 minuteto ventoxygensensor. Breathingoxygenis providedto eachcrewmember Laborakxytestinghasdemonstrated that the test can by the OBOGS.A backupoxygensystemprovidesa normallybe completedin approximately15 seconds. supplyof gaseous oxygensufficientfor a maximum- Onceven~themonitorwillsenseinsufticientoxyg~ rangedescentin theeventof a failureof theOBOGS. illuminatingthe cockpitcautionlightsandshiftingthe In addition,emergencyoxygenis availableto each oxygensupplysourceto BOS.Themonitorwill autocrewmember througha high-pressure, gaseous oxygen maticallyshiftbacktoOBOGSoperationandextlnguish bottlelocatedin theejectionseatsurvivalkit. thecautionlight afterrelease of theTESTbutton.Testinghasdemonstrated thisoccurswithin5 to 7 seconds, 2.31.1 On-Board Oxygen Generating System. but maytakeup to 20 seconds. The OBOGSprovides95percentpurepressure-aed temperature-regulated oxygento eachcrewmember. p&iii--I Thesystemincludes anoxygenconcentrator, anoxygen monitor,andtwo regulators. Controlsandindicatorstbr theOBOGSareshownin Figure2-80. Theaircrewwill not haveanyindicationof a tkihneof the monitor.If the aircrewsusTheoxygenconcentrator is in the right sideof the pects the onsetof hypoxiaat anytime, imfuselageadjacentto andbeneaththe forwardcockpit. mediately selectBACKUP. The monitor FilteredandcooledECSserviceair is directedto tire maybetestedoncetlleaiKxa~hasoxygen concentratorwhen ON is selectedon tke to a cabinaltitudeof 10,000feetor lessand OBOGSmasterswitchon the pilot cockpitpanel.A the ON position on the OBOGSmaster molecularsievein .theconcentratorremoves the nikoswitchhasbeenreselected. gent?omthe compressed air, leavinga breathinggas equivalentin concentrationto 95percentoxygenat Theregulatorsarecheatmounted,pressmudemand 34,000feet.Theoxygenconcentrator receives115-WC typethroughwhichpressure-andtempemtum-mgulated motorpowerfrom thepilot ac essential busNo. 1 and oxygenisprovidedtoeachcrewman. Pressurebreathing heaterpower from the ac right main bus. OBOGS is activated above 34,000-foot cabin altitude. 28-Vdccontrolpoweris providedby essentialdcbus No. 1 viathe OBOGSCONTKcircuitbreaker. When the OBOGSmasterswitch is on, hltered, cooled enginebleedairis dire&d to theoxygenconcenTheoxygenmonitoris on thepilot right console.It tratorwhereamolecularsieverthenitmgenfmm constantlymonitor3the oxygenconcentrator outputto the compressed air, leavinga breathinggasconsisting ensurea sufiicientconcentration of oxygenis being of 95-percent oxygen Theoxygenmonitorcheckssysgenerated. Whenthemonitordetectsanoxygenpartial ternoperationto ensure thata sufticientconcentration pressurelessthan 182mm Hg, it generates an alarm of oxygenisbeinggeneratedprovidesacockpitindicasignalthat illumiaates theOBOGScautionlights,shuts off outputTomtheconceauutor andenables thebackup tion,andbringsthebaehtpgaseoussupplyonliueas requimdA teatbuttonon themonitorenables thepilot oxygensystem.Theconcentrator andthemonitorconto verifythatthemonitorandthebackupoxygensystem tinueto fonctionaslongastheOBOGSswitchis in the ON position.Themonitorwill automatically shiftback arefunctioning.Whenpre-w&theOBOGSadvisory indicatingthesystemis in backnp.The to theOBOGSsupplysourcewhenit detectsadequate lightilhtminates oxygenconcentrator receives115Vat 6om pilot ac concentrator output essentialbusNo. 1 and from the ac right mainbus, Contd powerandpowerto themonitoris28Vdefrom essentialdcbusNo. 1. associatedwith the COOLING AIR light is mictly coin-
cidental. However,theductfaihnebetweentheprimsry heatexchanger andthetmbinecompmssor assembly, or betweenthesecondary heatexchanger andtheturbine compressor assembly, couldcausedegraded coolingsirflow anda COOLINGAIK lightto illuminate.
Z-141
ORIGINAL
NAVAIR ill-Fl4AAD1
ypiiq (PILOT.
Figure Z-80. Oxygen System Controlsand Indicators (Sheet 1 of 2)
ORIGINAL
2-142
RIO)
AIRCRAFT
WITHOUT
AIRCRAFT
WITH
NOMENCLATURE a
0 0
OBOGS master switch
FUNCTION BACKUP - Deenergizes oxygen concentrator Valve. Enables Backup Oxygen.
and Process Air Shutoff
ON -
Applies power to oxygen generator and oxygen monitor. Opens solenoid valve providing ECS Service Air to Oxygen Concentrator.
OFF -
Removes power from OBOGS and BOS. Process air shutoff valve closes.
VENT AIRFLOW
NOT FUNCTIONAL.
OXYGEN SUPPLY valve
ON-
Opens oxygen supply permitting to crewmember.
OFF -
Secures OBOGS and BOS oxygen flow to crewmember.
OBOGS or BOS oxygen flow
OBOGS caution light
Illuminates when OBOGS has failed or OBOGS master switch is in OFF or BACKUP
@
l33J$XY LOW caution
Illuminates when pressure remaining in BOS assembly oxygen cylinder is below 200 psi.
@
$2;
Indicates pressure remaining in BOS assembly
oxygen cylinder.
0
OXYGEN MONITOR TEST Button
Provides functional test of the oxygen monitor, systems.
BOS, and OBOGS oontrol
@
OXY PRESS
Figure 2-80. Oxygen System Controlsand Indicators(Sheet2 of 2) 2.31.2 BackupOxygenSystem. The BOS consists of a BOS assembly, BOS controller, B/U OKY LOW cautionlight, anda BACKUP OXY PRESS indicator.This systemwsa designedto provide only enough oxygenfor maximum-range descent.In the event of au OBOGS failure, the aircrewmust takeimmediate action to conservebackup oxygen. Switching to the backupsystemcanbe accomplished threeways: 1. Automatically upon monitor detection of an OBOGS faihue or loss of OBOCX control power 2. Manually via direct selectionof BACKUP on the OBOGS masterswitch 3. Automatically with total loss of electricalpower or selectionof OFF on the OXYGEN systemmaster switch, whentheaimratl is above10,000feetMSL. Backupoxygencannotbe disabledabove10,000feet MSL by turning the OXYGEN system master switch off. Therefore, the individual OXYGEN SUPPLY
valves (Figure 2-80) in both cockpits must be used to turn off oxygen flow to the personnelregulators. The BOS assemblyconsists of an oxygen cylinder, pressuregauge,pressureregulator, fill pot$ pressure transducer,low-pressureswitch, manual shutoff valve, and quick disconnecton a pallet&d assembly that is removablefor servicing andmaintenance.A 2OOcubicinch, high-pressurecylinder containing500 to 590liters of gaseousoxygen at 1,800to 2,100 psi, respectively, provides a backup oxygen supply to the OBOGS. The BOS assemblyis locatedon theright forward side of the fuselage,just below the forward endof thepilot cockpit. The BOS controller enablesflow from the BOS assembly via a diaphragmvalve. This diaphragmvalve is controlled by two solenoidvalves and an aneroidvalve. The BOS controller is in the BOS assembly compartment. Power for automatic operationof the BOS controller is provided by 28 Vdc essentialbus No. 1 via the OBOGS CONTR circuit breaker. Alternate power is provided via the BOS CONTRB/u OKY LOW circuit breakerfor automaticactivationofbackup oxygenin the eventof a failure of the OBOGS control relay andwhen BACKUP is manually selected.
2-143
ORIGINAL
NAVAIR 0%PUAAD-I
The pitot-static system is composedof two separate systemswith individual pitot-staticprobes,oneon each side of the forward fuselage.
The BAJ OXY LOW caution light is actuatedby the BOS assemblylow-pressureswitch whentheBACK UP OXY PRESS gaugereads less than 200 psi, or when BOS CONTRiBN OKY LOW power is lost. Figure 2-81 provides backup oxygen breathing time for two crewmembers for various cabin altitudes based upon BOS oxygen cylinder pressure.
The left pitot pressure(PT) probe suppliesthe pilot standbyairspeedindicator and the left AICS programmer.The tight pitot pressurei,PT)probesuppliestheRIO standbyairspeedindicator, the right AICS programmer, andthe CADC with airspeedindications. An electrical
2.31.3 BOS Pressure Indicator. The BACK UP OXY PRESS indicator (Figure 2-80), on the right side of the pilot right knee panel, shows the pressurein the BOS assembly oxygen cylinder. The indicator will not function unless the BOS manual shutoff valve on the BOS assemblyis open.
PT~pUt~Omtheleft~CSprO~eriSSU~liedto
the CADC backup channel as airspeedindications for wing sweep.
2.31.4 Emergency Oxygen Supply. The 50cubic-inch oxygen cylinder in the survival kit of each ejection seatprovides a limited supply of gaseous oxygen.This oxygencylindercanbemanuallyactivated in the eventof a failure of the OBOGS anddepletionof the backup supply. The cylinder is chargedto 1,800to 2,100 psi and a pressuregaugeis visible on the inside face of the left-thigh support.Flow from the emergency cylinder is routedthrougha pressurereduceranda shuttle valve, then follows the path of the normal oxygen system,flowing throughthe oxygenregulatorto theface mask. The supply of oxygen available in the emergency cylinder is adequatefor up to 8 to 10minutes,depending upon altitude. The manual actuation handle is a green ring under the left side of the survival kit cushion.
The left andright forward static ports f&t) aremanifolded to provide static pressureto the pilot standby airspeedindicator, standby altimeter, vertical speedindicator, and the CADC. Static pressurefrom the right aft (Psz) static ports supply the RIO standbyairspeed indicator,standbyaltimeter,andtheright AICS progmmmer. The staticpressurefrom the left aft (PS2)staticports supply the staticpressmcto the left AICS PS sensor.An electricalPS input liom the left AICS programmeris sup plied to theCADC backupchannelfor wing sweep.
l
l
Turn the OXYGEN supply valve to OFF before pulling the emergencyoxygen manual actuatinghandleif contaminationof the normal systemis suspected.Failure to do sowill inhibit seatpanshuttle valve operation,pmventing flow of emergencyoxygen.
Note With the in-flight refueling probe extended,the pilot and RIO standbyaltimeters and airspeed indicators show erroneousreadingsbecauseof changesin airflow aroundthe pitot-static probes. The RUDDER AUTH caution light may illuminate when the in-flight refueling probe is extended. Press the MASTER RESET button to resetthe light.
2.32.1 Pitot-Static Heat. Bach pitot-static probe is equipped with electrical beating elements to prevent icing. Pitot-static heat is controlled by the pilot through the ANTI-ICE switch on the pilot right console. In AUTO/OFF, pitot probeheatis availableonly with weight off wheels. ORlDE/ON activates the probe heat elements independently of the weight-on-wheels switch and illuminates the INLET ICE caution light on the CAUTION ADVISORY panel.OFF/OFF removesheat Born the probes.
Note Flow of oxygenfrom the emergencycylinder can be stoppedby reseatingthe manual actuation handle. 2.32 PITOT-STATIC SYSTEM The pitot-staticpmssuresystemsuppliesimpact (pitot) andatmospheric(static)pressumtothepilotandRIOflight instruments,to the CADC, and to the engineAICS programmers.Somesystemsmquim staticpressureonly; othersrequirestaticandpitot pressure(seeFigure 2-82).
ORIGINAL
2-144
[-G&q The ANTI-ICE switch should normally be in AUTO/OFF during takeoff and landing. Engine anti-icing has adverseeffects on engine stall margin.
NAVAIR 0%Fl4AAD-1 BACK-UPOXYGENPRESSURE 1200 800
CABIN ALTITUDE
2000
1600
35 & ABOVE
100
80
60
30
72
58
25
52
20
1 400
200
40
20
IO
43
29
14
7
42
31
21
10
5
41
33
24
16
8
4
15
32
26
19
13
6
3
10
27
22
16
10
5
2.9
8
24
19
14
9
4
2.5
5
21
17
12
8
4
2.2
SL.
17
14
10
7
3
1.8
Minutes remaining
based on two-man
consumption.
Duration data should be used as a guide Consumotion
rate based on 13.1 liters oer minute oer man.
Figure 2-81. Oxygen Duration Chart 2.33 CONTROL AND DISPLAY SYSTEM The control and display system (Figure 2-83) provides the crew with control and display of navigation, aircraft status,and flight tactical information. The control anddisplays systemconsistsof two display processon @PI andDP2), threemultifunction displays @lot centerMFDI, pilot right MFD2, and RIO MFD3), and a heads-updisplay system, cockpit television sensor, HUD-VIDEO panel, pilot DISPLAYS control panel, anda multistatus indicator. The control and display system also sends display information to the digital display, the radio tiequency indicator, radio frequency/control indicator, and the mission video recorder. The dataentryunit is a remoteterminal that communicates with the mission computers via the multiplex buses. 2.33.1 Display Types. The following types of display information areprovided by the MFD system: 1. Calligraphic or stroke writing is displayed on the HUD, MFDs, and the DD.
2. Rastervideo (for example radar, television) generatedinternally (VDI formata)or provided by an &ems1 sensor,with or without a stroke overlay, is displayedon the MFDs and the DD. 3. Alphanumeric data is displayed on the multistatusindicator and the radio f?equencyandradio frequency/controlindicators. Displays presentedon the HUD andMFDs areidentified as formats.The formats arecategorizedasdisplay format groups. HUD format groups consist of takeofflanding/ navigation (TLN), air-to-air (A/A), air-to-ground (A/G), and multimode formats that can be overlaid on the otherthree.The HUD also displays a manualreticle and a testpattern. MFD display format groups are shown in Figure 2-84. The HUD and MFD MI format groupsarebasically the &me; however,HUD symbology is scaledto be overlaid on the real world, and certain differences, such as symbol location, addition, and deletion occur betweenthe HUD and MFD VDI formats. MFDs also display repeatsof the TID and DD as well as TCS and CTVS vi&o.
2-145
NAVAIR 01.F14AAD-1
Figure 2-82. Airstream Sensors
ORIGINAL
2-146
NAVAIR 01.Fl4AAD1
Figure Z-83. Display SystemsControls and Indicators(Sheet 1 of 4)
2-147
ORIGINAL
NAVAIR OWlMAD-‘I
““0.VIDEO PANEL
E
Figure 2-83. Display SystemsControlsand Indicators (Sheet2 of 4)
ORIGINAL
2-148
NAVAIR Ql-Fl4hU.bI
RIO’S
COCKPIT
Figure Z-83. Display SystemsControls andIndicators (Sheet3 of 4)
2-149
ORIGINAL
NAVAIR 01-Fl4AAD-1
H
TACTICAL
RADIO
FREQUENCY
INFORMATION
DISPLAY
CONTROUINDICATOR
ECM OVERRIDE SWITCH
M
L
Figure 2-83. Display SystemsControls and Indicators(Sheet4 of 4)
ORIGINAL
2-l 50
J
NAVAIR
FORMATS WITHIN GROUP
DISPLAY FORMAT !FD Vertical Display indicator
(VDI)/HUD Formats
0%Fl4AAD-1
TLN BASIC (TLN-GU,
TLN-GD)
TLN DESTINATION TLN MANUAL TLN TACAN TLN DATA LINK AWL (All Weather Landing) A/A BASIC A/A SPARROW SEARCH 9/A PHOENIX SEARCH MA SIDEWINDER
SEARCH
A/A PHOENIX TRACK A/A SPARROW TRACK A/A SIDEWINDER TRACK A/A TRACK WHILE SCAN A/A MULTIPLE MODE GUN SIGHT (MMGS) A/A GUN BACKUP AJG BASIC A/G CCIP A/G MANUAL RECON IRSTS TWS IFD Horizontal
Situatiin
Display (HSD) Formats
WAYPOINT TACAN CDI TACAN
IWN A/C and WAYPOINT Formats
OWN AIC BASIC OWN AIC GROUND OWN A/C CVA OWN A/C IFA WAYPOINT DATA 1 WAYPOINT DATA 2
Figure Z-84. Display Format Groups(Sheet1 of 2) 2-151
ORIGINAL
NAVAIR Ql-Fl4AAD-l
DISPIAY
FORMAT
I
FORMATS
WITHIN GROUP
CV MAN DATA
JAV Align Formats
CV Ships Inertial Navigation
System (SINS) DATA
IFA Standard Attitude Heading Reference System (SAHRS) (Norm Mag SHDG) SAHRS CV nertial Navigation :ontinuous
System (INS) UPDATE Format NAV AID CORRECTIONS
Update Formats
NAV AID ENABLED NAV AID OPTIONS SURFACE WAYPOINT POSITION Format stores Management System (SMS) Format SPIN INDICATOR Format INGINE MONITOR Format In Board Checkout (OBC) Formats
:ailure History Format (FHF) :ooperative Support Software (CSS) Format vfissile status Readout Formats Bectronic Counter Measures (ECM) Format 3econ Formats
Tactical Situation Display (TSD)
JTIDS Data Readouts (JDR)
Infrared Search and Track (IRST) Formats
OBC BASIC OBC Groups: CD, CNI, FLT, NAV, AUX. TAC, EW, SMST, and SNSR OBC Failed Data: CADC, CIU, SAHRS, DINS, DELI, DPI, DP2, MCI, MC2, DSS. APC, EMSPl, EMSP2, IFX, SMS, SWITCHES, RWR, and RDRKS MAINT Format
MISSILE SUBSYSTEM 1 MISSILE SUBSYSTEM 2 RECON DATA RECON WPT DATA1 RECON WPT DATA2 TSD MENU TSD PRIORITY TSD DECLUTTER 1 TSD DECLUTTER 2 TSD COMMAND TSD REPLY TSD TARGET MODIFIER JTIDS OWN A/C DATA JTIDS DATA - TSDflID (Non-F-14D PPLI Hook) JTIDS DATA - TSD/TlD (F-14D PPLI Hook) JTIDS DATA - TSD/TlD (Target Hook) IRSTS NORMAL IRSTS CSCAN IRSTS SUMMARY
Figwe 2-84. Display Format Groups(Sheet2 of 2) ORIGINAL
2-152
NAVAIR 01.Fl4AAD-1
2.33.2 Display Processors. Two display processors (DPl and DP2) drive the display system. The DPs receive various signal inputs from the aircraft systems. These signals are processedand converted to display information for the HUD, MSI, MFDs, DD, RFI, RFCI, and the mission video recorder.
After a short warmup (under2 minutes), the default formats appearon the displays.The default formatsare as follows: 1. HUD -
2.33.2.1 Normal Operation. During normal operation, DPl drives the HUD and MFDl, while DP2 drives MFD2 and MFD3. Should either DP fail, the mission computer commandsbackup operation,where the remaining DP provides limited functions. 2.33.2.2 DP Backup Operation. During backup operation,the remaining DP drives the HUD, MFDl, and MFD3, with MFD2 not operating. Should one of thesethreedisplaysbeOFF or subsequentlyselectedoff, thenMFD2 will operate.Ifboth strokegeneratorsin the remainingDP arein use,anMFD format that is normally producedby strokewriting may be generatedin raster. With the following exception, either DP can perform any display function: Mission video record is not performed during backup operation. 2.33.2.3 Data Failure Modes. In addition to the backupmode, there are other failure modes. Some examplesare as follows. If the DPs fail to receive pitch and roll data, the messagePITCH/ROLL FAIL will appearon the MFDs and all pitch/roll-relatedsymbols areremoved from the displays. The symbols are returnedif pitch and roll information is restored. Ifthe DPs lose communicationwith the MCS, a manual reticle will appearon the HUD and the MFDs will display only the messageDP-MC COMM FAIL and MENUI. The lighted MODE pushbuttonsalso turn off with a loss of MCS communication. Should communicationsbe restored,the DP-MC COMM FAIL message is removedand the MODE buttonsare lighted again.If the MC performeda cold startor a systemreset,default formats arepresentedon the displays. 2.33.3 System Operation. The display system requires 115V, 400 Hz electrical power. DPl , HUD, and MFDl receive power from ac essentialNo. 2 bus and DP2, MFDZ, and MFD3 areon the ac left main bus.All displays and DPs are electrically protectedby circuit breakers.Therearenopower switchesfor the DPs. Each of the displays has a power switch that is normally turned off at the conclusion of flight. The HUD power switch is on the PDCP,andthe MFD power switchesare on each MFD as a part of the DAY/AUTO/NIGHT switch.
TLN basic
2. MFDl -
VDI TLN basic
3. MFD2 -
OBC basic
4. MFD3 -
OWN A/C basic.
If the mission computersare not in communication, test patternswill appearon all four displays. Format selection for the HUD is madeby use of the MODE pushbuttonson the PDCP and by the type of steeringselected.MFD format families are selectedby pressingthe pushbuttonadjacentto a menu legendor by cursor designationof the legend. Every MFD format (exceptrepeats)has MENU select as the centerpushbutton on the lower edgeof the display. Also appearing on all formats for immediate selection are SMS to the let? of MENU and ECM to the right of MENU. Other selectionsvary accordingto format requirements.When a repeatformat (HUD, DD, or TID) is being displayed on the MFD, no legendsare available for format selection. To changeformats from a repeat,pressany pushbutton. This returns MENU1 to the MFD, permitting other format selectionsto be made. Cursordesignation of legendscannotbe usedwith repeatdisplays. 2.33.4 Heads-Up Display. The HUD (Figure 2-85) provides a combination of real-world cues and flight direction symbology,projecteddirectly on a combining glass assembly.The flight information on an optical combineris projectedin the pilot forward field of view. The display is focusedat infinity, therebycreatingthe illusion that the symbols are superimposedon the real world (andso that visual cuesreceivedfrom outsidethe aircraftarenot obscured).The pilot usually steersbased on interpretationof the visually observedreal world. The HUD can be selectedto be theprimary flight reference for all flight regimes displaying navigation and weapondelivery information. The HUD symbol brightnesscontrol is on the HUD; all other HUD controls are on the PDCP. 2.33.4.1 Pilot DISPLAYS Control Panel. The PDCP on the pilot right console(Figure2-86) providescontrol of the mode anddisplay presentationof the HUD, VDI, ECM, andTCS formats.Display information is dependent on the mode selectedwith the A/A, A/G, and TLN pushbuttons.
2-153
ORIGINAL
NAVAIR 01.Fl4AAD-1
Figure 2-85. Heads-UpDisplay 2.33.4.2 Cockpit Television Sensor. The CTVS is an electro-opticalsystemthat imagessymbology presenton the HUD combiner and outsideworld information as well. The unit consistsof a video sensorheadon the HUD and an electronic unit in the HUD-VIDEO panel (Figure 2-83). The sensorsignal canbe fed to the mission video recorder and can be displayed on the MFDs. Operation of the CTVS is controlled by the VIDEO CONTROL switch on the HUD-VIDEO control panel. 2.33.4.3 HUD-VIDEO Control Panel. Operation of the CTVS is controlledby the HUD-VIDEO control panel(Figure 2-83).The panelcontainsthetwo-position VIDEO CONTROL toggleswitch, aBIT button,a green GO light, and a yellow NO GO light. Setting the VIDEO CONTROL switch to ON providespowerto the CTVS; selecting OFF removes power. Depressingthe BIT button initiatesa CTVS self-test.A goodtestresults in a momentary flash of the yellow NO GO light followed by a steadygreenGO light. A failure resultsin a steadyyellow NO GO light. During BIT, ifCTVS video is being displayed on an MFD, or is being recorded, bright white flashes of video will be displayed or recorded.This is normal for BIT operation. 2.33.5 MultIstatus Indicator. The MS1 is an LCD panel on the lower center instrument panel below the ORIGINAL
centerMFD (MFDl) (Figure 2-83). The MS1 displays the weapontype and statuson eachstorestation. The lower row displays weapon status: ready, degraded, ready/selectedor degraded/selected.The se lected symbol never appears alone; it is always superimposedover the ready or degradedsymbol. Figore 2-87 provides a representativedisplay of available MS1 symbols along with their meanings. The upperrow of the display identities the weapon. Two dashedlines at a store station indicate that the missile at that station has failed or is hung. A blank display on a station indicatesno weaponis loadedor the weaponloadedis not recognized. There areno controls on the MSI. Power to the MS1 is provided by the HUD subsystem.The MCS must be transmittingdatafor a display to be presented.Selecting TEST on the HUD PWR switch causesall LCD segments on the MS1 to be displayed. An MFD displays tactical and flight command situations,navigation,and discreteinformation either separately or simultaneouslywith radarand TV data. There is also a power/brightnessselect switch abovethe display screen(Figure 2-88).
2-154
NAVAIR
NOMENCLATURE 0
MODE Switch
Ol-F14AAD-1
FUNCTION DAY -
Provides a full range of HUD symbol brightness control: 0 to 100%. Disables automatic brightness control.
AUTO -
Provides automatic symbol brightness operation superimposed on the level selected wtth the symbol brightness control.
NIGHT -
Provides a HUD symbol brightness control range of 0 to 1.O% of DAY level. Note When switching from NIGHT to DAY, the brightness level gradually increases until it reaches the level established for DAY
0
Display MODE pushbuttons
A/A-
Provides selection of air-to-air
NG-
Provides selection of air-to-ground
TLN -
Provides selection of takeoff/landing/navigation
Figure 2-86. Pilot DISPLAYS
display mode. display mode. mode.
Control Panel (Sheet I of 3)
2-155
ORIGINAL
NAVAIR
0%Fl4AAD1
NOMENCLATURE 0
c9
0
@
0
@
@
FUNCTION
TCS FOV (Television Camera Field of View)
ECM switch
NAR -
Selects TCS narrow field of view for display on pilot’s MFDl.
WIDE-
Selects TCS wide field of view for display on pilot’s MFDl.
ORIDE -
Enables ECM display to override whatever is being displayed on MFDZ for as long as the threat is being reponed.
OFF -
ECM display override not enabled.
ELEV LEAD Control
A continuous rotary control that provides a range of elevation positidns for the HUD manual reticle with the 0 mr setting coincident with the armament datum line (ADL). Clockwise rotation increases elevation lead.
HUDIVDI ALT source switch
BAR0 -
Selects barometric HUD and VDI.
RDR -
Selects radar altimeter as source for display of altitude on HUD and VDI. Radar altitude is displayed as follows: l Below 5000 feet AGL l Radar altitude valid . AOB s 45’
TEST -
(Momentary) Presents an intersecting vertical and horizontal line at the center of the HUD field of view, and illuminates all segments of the multistatus indicator (MSI).
ON -
Provides power to HUD and MSI.
OFF -
Removes power from HUD and MSI.
ANLG -
Selects analog dial format for HUD display of airspeed and altitude..
BOTH -
Selects a combination of analog dial and digital readout for HUD display of airspeed and altitude.
DGTL -
Selects digital readout format for HUD display of airspeed and altitude.
NORM -
Normal display symbology
LVL 1 -
Depending on MODE selected, the following symbols are removed: TLN - GEAR UP (AOA bracket and target pointer/AON are not displayed) l Vertical velocity l AOBscals l PeakG
HUD PWR switch (lever lock)
FORMAT switch
DECLUlTER
switch
altimeter as source for display of altitude on
is presented.
Figure 2-86. Pilot DISPLAYS Control Panel (Sheet2 of 3)
ORIGINAL
2.156
NAVAIR
NOMENCLATURE
01.Fl4AAD-1
FUNCTION TLN - GEAR DOWN (Target pointer/AON and Mach are not displayed) l Peak G (displayed as required in normal mode only) l AOBscale l Radar altitude A/A l Radar altitude readout A/A and AIG (Vertical velocity, AOB scale, and AOA bracket are not displayed) l AOA readout l Potential flight path marker (PFPM) LVL 2 -
@
CAGE ENBUDSBL Pushbutton
Depending on MODE selected, the following additional symbols are removed: TLN - GEAR UP . AOA l Mach l Navrange l PFPM l Radar altitude readout l Digital boxes TLN - GEAR DOWN . AOA l Digital boxes l PFPM l Vertical velocity AJA l Navrange AIG (Closer and target pointer/AON are not displayed) l Radar altitude readout A/A and A/G (AOB scale, AOA bracket, and vertical velocity are not displayed) l Mach number l PeakG l Digital boxes l Heading scale l Ghost FPM
Momentary contact pushbutton used to enable/disable HUD CAGE option. Caging restricts pitch ladder and flight path marker symbols in azimuth to the center of the HUD display.
Figure 2-86. Pilot DISPLAYS Control Panel(Sheet3 of 3)
2-157
ORIGINAL
NAVAIR
Of-FUAAD-1
1A
IB
3
4
5
6
8E
8A
LEGEND SYMBOL
STATUS READY
II --
FAILED CR HUNG - UNUSABLE READY AND SELECTED
Bk CII
DEGRADED
lul
SELECTED
AND DEGRADED
Figure 2-87. Multistatus Indicator Symbols/Meanings Nwltifunction Displays. The threeidentical MFDs are CRT displayswith 20 pushbuttonsaroundthe perimeter of the display screen.The MFD pushbuttons with adjacentlegendsareusedfor menu selection,data entry/readout,and systemtest and/orstatusindications. The threeprogrammableMFDs, two in the pilot instmment paneland onein the RIO instrumentpanelprovide display flexibility such that either crewmemberis able to select any display available, allowing the pilot and RIO to monitor andback up eachother.The HUD format may be repeatedon any MFD by depressingpushbutton No. 11 from the MEND 1 format.
2.33.6
Multifunction pushbuttonswith adjacent CRT legendslocated aroundthe perimeterof the MFD areused for menu selection,data entry/readout,and systemtest and/orstatusindications.An MFD displaystactical and flight command situations,navigation, and discreteinformation either separatelyor simultaneouslywith radar and TV data. Normally the pilot usesthe MFD below the HUD on the aircraft centerline as the primary in-the-cockpit flight instrument. Attitude information is displayed on the MFD VDI format by an aircraft reticle, a horizon line, anda calligraphic pitch ladder. The aircraft reticle is fixed at the ORIGINAL
2-158
center of the display, and the horizon line and pitch ladder move about it in accordancewith the aircraft pitch and roll attitudes. The flight parameters displayed include magnetic heading,data link (D/L), commandedairspeed(Mach number),airspeed,altitude, andvertical velocity. Note
If pitch or roll data is not updatedwithin 240 milliseconds,thepitchladderandrollmarker will be blanked and the horizon, sky, and ground plane will darken. 2.33.7 Cursor Controls. Both the pilot and RIO have cursor controls (Figure 2-89) that permit the remote selection of MFD pushbuttonoptions as well as symbol andspothooking. A symbol is hookedwhen the cursoris placedover a format symbol and cursordesignate is activated.Hooking is used to set waypoints on theHSD waypoint format andto selecttracksandother symbols, for the purpose of obtaining information, or identifying symbols of intereston the TSD format. The cursorsymbol is a small circle insidealarger circlewhen displayedon the MFDs and a circle with four tic marks extending from the circle inward at 0”, 90”, 180”, and 270’ when displayedon the HUD.
NAVAIR
NOMENCLATURE a
Power switch
01.F14AAD-1
FUNCTION OFF-
Power removed from MFD.
Selecting NIGHT, AUTO, or DAY applies power to the MFD, however a DP must be on and providing data to the MFD for a format to be displayed. NIGHT -
Disables automatic contrast adjustment and limits automatic brightness adjustment to a small percentage of the DAY range.
&UT0 -
Automatic adjustment of brightness and contrast to compensate for changing light conditions as seen by sensors above the BRT and CONT controls.
DAY -
Full range of manual brightness and contrast control. Disables automatic brightness and contrast adjustment.
Figure 2-88. Multifunction Display (Sheet1 of 2)
2-159
ORIGINAL
NAVAR
Ql-FUAAD-1
NOMENCLATURE 0
0
@
FUNCTION
Pushbuttons
20 momentary contact pushbuttons that provide for selection of display, operating modes, and system parameters. A selected legend is normally enclosed by a rectangular box. A dashed rectangular box indicates that a legend has been selected but is not available.
CONT control
Varies the amplitude of the shades of grey. Effects are most visible when viewing video or raster graphics.
BRT (brightness)
control
Varies intensity of overall display. As brightness shades of grey are discernable.
is decreased,
fewer
Figure 2-88. Multitimction Display (Sheet2 of 2)
I
2.33.7.1 Pilot Cursor Control. The pilot controls cursor position with the throttle designatorcontroller. The TDC is a circular disk that is a combination fourway force sensorandmomentaryswitch on the outboard thrde grip. Finger pressureon the outer edgesof the control will move the cursor in the direction selected. When cursor movement exceedsthe limit of a display that is adjacentto anotherdisplay (e.g.,the right edgeof MFDl or the bottom ofthe HUD), the cursorwill move to the adjacentdisplay. If the cursor symbol reachesa display limit that is not adjacentto anotherdisplay (e.g., theright edgeofMFD2), the cursorremainsat thatlimit. 1 Depressingandreleasingthe TDC designatesthe cursor position. 2.33.7.2 RIO Cursor Control. The RIO cursorcontrol is on the sensorhand control. It consistsof a fourposition select switch, a two-position (half-full action) trigger switch, anda handgrip.When the top,bottom, or right edgeof the selectswitch is pressed,the DD, TID, or MFD3, respectively, is selected for cursor display. Pressing the lett edge toggles sensorcontrol between radar and infrared. The cursor symbol becomesvisible when the trigger switch is pressedto the half-action position. Full trigger depressiondesignatesthe cursor position. Cursor symbol movement is controlled by handgrip movements. 2.33.7.3 Cursor Hooking Functions. Spot, symbol. and MFD pushbuttonhooks can be performed by the pilot on the HUD or MPD by activation ofthe TDC or on the TID or MFD by the RIO through use of the sensorhandcontrol. Normal symbol hooking is accomplishedby placing the ~XSW over the desiredsymbol using eithertheTDC or the SHC and activating the appropriatecursordesignate switch. The hooked symbol brightensand the pre-
ORIGINAL
viously hooked symbol returns to normal intensity. Symbol hooksamusedto display additionalinformation aboutthosesymbols or to designatetracks for functions that are format dependent.Only HUD, TID, TSD, and IRST normal format supportsymbol hooking. MFD pushbuttonhooks permit remote activation of MFD pushbutton functions through the TDC or SHC. They are accomplishedby positioning the cursor over the desiredMFD menu choiceandactivating thecursordesignateswitch. 2.33.6 Displays, Formats, and Symbology. The paragraphsthat follow describe the HUD and MFD displays. Sampleformats from format families areillustrated,symbols associatedwith thesefamilies are identified and defined,and format selectionis described. Many symbols are common to more thanone format family. Once a symbol has been defined for a format family, the detinition is not repeatedwhen describing otherformat families. Certain features,suchas changes in scalingbetweenformats, that areobviouswhen viewing the display are not covered. All symbolsavailable to a format areillustrated,however,they will rarely be displayedat thesametime. Not all formats areillustrated.Whereonly minor differences exist, they will be noted. Formats that contain only alphanumericsare describedbut are not illustrated. 2.33.8.1 Warning, Caution, Advisory Indicators. Warningsaredisplayedon the lower centerofthe HUD viewing area. These warnings are: L FIRE, R FIRE, L STALL, R STALL, andRDC SPD. The CLSN advisoryis also displayedon the HUD. Ifthere aremore thantwo warnings,then they will scroll up at the rateof one warning per second.
2-160
NAVAIR 01.F14AAD.1
I
RDR CMPTR
STBY
OFF
SENSOR
HAND
CONTROL
Figure 2-89. Cursor Controls
2-164
ORIGINAL
NAVAIR
QI-Fl4AAD-I
On the MFDs, warning/caution/advisoryindications are shown in a viewing window that appearson all formats exceptrepeats.This window is displayedin the upper left of the MFD and is referredto as the CAW window or CAW box. A similar window on the upper right of the MFD displays data-link legends.The messagewindow allows up to four CAWs to be displayed at onetime. Ifmore than four CAWs areto be displayed, they scroll up from the bottom of the window at a rate of one per second.Warning, caution, advisory legends are independentof format and may be directed to a specific crewmember.Figure 2-90 lists specific CAWs and the crewmemberto whom they aredirected. When warning, caution, or advisoriesare displayed, pressingthe pushbuttonabovethe CAW window (PB6) will remove the window and replace it with a boxed CAW legend.Pressingthe CAW pushbuttonwhen the legend is boxed returns the window and indications to the display and removesthe box from the legend. Note
If a repeat format is on MFDl, the CAW window is shifted to MFD2 in its current state, open or closed (acknowledged).New CAWs continue to be displayed on MFD2 until the repeat format is removed from MFDI. If a repeat format is displayed on both MFDI and MFD2 or on MFD3, receipt of CAW data removes the repeat format from MFDl and/or MFD3 and displays a new format with the CAW in theappropriate window. Receipt of a data-link advisory removes the repeatformat from MFDl (if appropriate)and MFD3 and displaysthe menu format with data-link advisories. (DD and TID displays are repeatson MFDl; HUD, DD, and TID displays are repeatson MFD2 and MFD3). Test Patterns. The test patterns (Figure 2-91) appearon the HUD and MFD when the display systemis turnedon with the MCs off during groundtests andare generatedby the DP.
2.33.8.2
Note
The large cross that appearson the HUD when the HUD PWR switch is set to TEST is generatedby the HUD, independentof the DP, and is usedto check HUD operation. The HUD and MFD test patternsalso momentarily appearduring IBIT and following a systemreset.Both test patternsare written in stroke and areusedto check stroke accuracy. ORIGINAL
The MFD/KROMA test pattern (a future-growth display) includes an MFD TEST legend,usedto selectthe MFD RASTER test pattern.
color
The MFD RASTER test patternallows for testingof individual pushbuttons. When a button is pressed,a solid-line box appearsaroundthe PRESS legend;pressing the button againremoves the box. The diamondand blinking breakawaysymbol areusedto checkRASTER accuracy.Numerics 0 through7 checkRASTER shades of grey. Selecting EXIT returns the display to MFDKROMA test pattern. HUD Formats. HUD format category (TLN, A/A, A/G) is normally selectedby useof MODE buttons on the PDCP. However, air-to-air formats are selectedautomatically ifthe pilot selectsaweaponusing the weaponselectswitch on the stick grip; selectsRDR PLM/pAL, IR PLM/PAL (all with gear up) with the sensor mode switch; IiAs the ACM guard; or if VSL HWSL LO is selectedwith the sensormode switch or DD. Air-to-ground formats are automatically selected when an air-to-groundweapon is selectedon the SMS format sincethe air-to-groundmastermode is automatically enteredin this case.The HUD default format is the TLN basic format (Figure 2-92). This format is displayed on power-up and if DPI experiencesa cold start (power outageof over 1 second). 2.33.8.3
The amount of information displayed on HUD formats is pilot selectableby means of the FORMAT and DECLUTTER switcheson the PDCP. Symbols arealso addedor deletedby the mission computerdependingon aircraft status, steering mode, and weapon selection. When the FORMAT switch is set to BOTH, airspeed and altitude information are displayed as boxed digital readoutswith analog dials. In the ANLG position, the boxes are removed from the digital readouts.In the DGTL position, only the boxed digital readoutis presentedand the analog dials are removed. The position of the HUDNDI ALT switch on the PDCP selectsthe type of altitude data that is to be displayed, either radar or barometric. If radar is selected anda valid radaraltitude exists (altitude ~5,000feetand AOB ~45”) radar altitude is displayed in the centerof the altitude dial. If the aircraft’s altitude exceeds5,000 feet or the radar altitude becomes invalid, the system automatically substitutesbarometric altitude and a “B” will flash to the right of the analogdial to indicateradar altitude is not being used.Switching HDD/VDI ALT to BAR0 removesthe flashing “B.”
2-I 62
NAVAIR
ACRONYM
DISPLAY
01.FMAAD-1
TYPE
AIRCREW
FUNCTION
L STALL
w
BOTH
HUD/MFD
Warns of left engine stall.
R STALL
w
BOTH
HUDIMFD
Warns of right engine stall.
L FIRE
W
BOTH
HUD/MFD
Warns of fire in left engine.
R FIRE
W
BOTH
HUD/MFD
Warns of fire in right engine.
RDC SPEED
W
PILOT
HUD/MFD
Safe Mach number exceeded for current position of flaps.
W/S
C
PILOT
MFD
Indicates failure of wingsweep
L N2 OSP
C
PILOT
MFD
Indicates overspeed
of left rotor N2.
R N2 OSP
C
PILOT
MFD
Indicates overspeed
of right rotor N2.
L Nl OSP
C
PILOT
MFD
Indicates overspeed
of left rotor Nl.
R Nl OSP
C
PILOT
MFD
Indicates overspeed
of right rotor Ni.
L TBT OT
C
PILOT
MFD
Indicates overtemp of left turbine blade.
R TBT OT
C
PILOT
MFD
Indicates overtemp of right turbine blade.
L FLMOUT
C
PILOT
MFD
Indicates left engine flameout.
R FLMOUT
C
PILOT
MFD
Indicates right engine flameout.
L IGV SD
C
PILOT
MFD
Indicates left inlet guide vane adjust schedule is not correct.
R IGV SD
C
PILOT
MFD
Indicates right inlet guide vane adjust schedule is not correct.
A/P REF
A
PILOT
MFD
Indicates autopilot mode is selected but not engaged.
CLSN
A
PILOT
HUD
Indicates collision course steering to target has been selected.
IFF ZERO
A
RIO
MFD
Indicates the identification friend or foe transponder is not operating correctly.
Figure 2-90. Warning, Caution,Advisory Functions(Sheet 1 of 3)
2-163
system.
NAVAIR
01-F14AAD-1
ACRONYM AAI ZERO
TYPE A
AIRCREW RIO
DISPLAY MFD
FUNCTION Indicates the air to air intercept interrogator is not operating correctly.
SDU ALM
C
RIO
MFD
Indicates the JTIDS Secure Data Unit is not operating properly or does not contain valid JTIDS crypt0 keys. Under certain conditions the display of this alarm is normal.
ASPJ HOT
C
RIO
MFD
Indicates an overtemp condition of the airborne self-protection jammer.
JTID HOT
C
RIO
MFD
Indicates an overtemp condition of the JTIDS R/T.
RWR
C
RIO
MFD
Indicates the radar warning receiver is not operating correctly.
FWD ASPJ
C
RIO
MFD
Indicates the forward ASPJ is not operating correctly.
AFT ASPJ
C
RIO
MFD
Indicates the aft ASPJ is not operating correctly.
AFT CG
C
BOTH
MFD
Indicates that stores station status has shifted center of gravity to preclude landing without correction.
MCI
C
RIO
MFD
Indicates mission computer operating correctly.
1 is not
MC2
C
RIO
MFD
Indicates mission computer operating correctly.
2 is not
CIU
C
RIO
MFD
Indicates the computer operating correctly.
MCI HOT
C
RIO
MFD
Indicates an overtemp condition mission computer #l.
MC2 HOT
C
RIO
MFD
Indicates an overtemp condition of the mission computer #2.
INS
A
RIO
MFD
Indicates the inertial navigation system is not operating correctly.
IMU
A
RIO
MFD
Indicates the inertial measurement not operating correctly.
CIU HOT
A
RIO
MFD
Indicates an overtemp condition of the CIU.
Figure 2-90. Warning, Caution,Advisory Functions (Sheet2 of 3)
ORIGINAL
2.164
interface unit is not
of the
unit is
NAVAIR
ACRONYM OPl HOT
TYPE A
AIRCREW
DP2 HOT
0%Fl4AAO-1
RIO
DISPLAY MFO
FUNCTION Indicates an overtemp condition of display processor 1.
A
RIO
MFO
Indicates an overtemp condition of display processor 2.
SMS HOT
A
RIO
MFD
Indicates an overtemp condition of the stores management system.
RDR HOT
A
RIO
MFO
Indicates an overtemp radar system.
HUD HOT
A
PILOT
MFO
Indicates an overtemp condition of the HUD.
3WR HOT
A
RIO
MFD
Indicates an overtemp condition of the radar warning receiver.
XS HOT
A
RIO
MFO
Indicates an overtemp condition data storage system.
of the
3EU HOT
A
RIO
MFO
Indicates an overtemp condition data entry unit.
of the
‘/lPS HOT
A
RIO
MFO
indicates an overtemp condition missile power supply.
of the
RSTS HOT
A
RIO
MFO
Indicates an overtemp condition of the infrared search and track system.
rARPS
A
RIO
MFO
Indicates the tactical air reconnaissance pod system is not operating correctly.
PF
A
RIO
MFO
Indicates a failure in the JTIDS R/F output detected by the JTIOS Interference Protection Feature.
IT10
A
RIO
MFO
Indicates the joint tactical information distribution system is not operating correctly.
R WIDE
A
ROTH
MFO
Indicates the TARPS IR must be switched to wide for adequate video resolution.
;AHR HOT
A
RIO
MFD
Indicates an overtemp condition of the standard attitude heading reference set.
condition of the
Figure 2-90. Warning, Caution, Advisory Functions(Sheet3 of 3)
2-165
ORIGINAL
NAVAIR
0%Fl4AAD-1
HUD TEST PATTERN
0
MFD/KROMA
0 A MFD
RASTER TEST PATTERN
Figure 2-91. Test Patterns ORIGINAL
2-166
STROKE
TEST PATTERN
NAVAIR Ol-Fl4AAD-1
GEAR DOWN - ANALOG
GEAR UP - ANALOG
5’
-5 5WOR
. -. :14\0:
--
Figure 2-92. HUD TLN Basic Format (Sheet 1 of 4)
2-167
ORIGINAL
NAVAIR
01-Fl4AAD-1
SYMBOL a
0
FUNCTION
Water line
Indicates fuselage reference line (FRL). Displayed when attitude information is not valid. Also displayed when gear down or the flightpath marker is at, or beyond the HUD’s full field of view.
Heading pointer
Actual aircraft heading is displayed below the stationary heading pointer.
~@
PitchMightpath
!@
Ghost flightpath
ladder
Ladder displays aircraft climb/dive angle and roll angle. Aircraft vertical flightpath angle is indicated by the position of the flightpath marker on the pitchfflightpath ladder. Positive pitch lines are solid and negative ptch lines are dashed. To aid in determining flightpath angle when it is changing rapidly, the pitch lines are angled toward the horizon at an angle half that of the flightpath angle. For example, in a 40” climb, the pitch lines are angled 20” toward the horizon. “Up” appears at +90” and “down” appears at -90”.
marker
Displayed at the true velocity vector position when the flightpath marker is caged and the true velocity vector position differs from the caged position in azimuth. When the true flightpath marker position is actually outside the HUD total field of view, the symbol will be pegged at the edge of the total FOV and flash.
0
Radar altitude indicator
Displays radar altitude when the aircraft is below 5090 feet AGL and bank angle is less than 45’. If RDR is selected as the altimeter source and valid radar altitude exists, the radar altitude is displayed within the dial, replacing the barometric altitude. An R is displayed to the right of dial to indicate radar altitude. If BAR0 is selected and a valid radar altitude exists, radar altitude is displayed above the attitude dial or box.
c9
Altitude analog dial
The HUD analog altimeter consists of ten dots encircling the altitude readout. Each dot indicates altitude in hundreds of feet with the zero mark located at the top center of the dial.
@
Altitude pointer
An analog pointer indicating altitude moves uniformly around the inside of the altitude dial based on indicated altitude. Increasing altitude is indicated by clockwise rotation of this pointer.
Digital altitude readout
Digital barometric or radar altitude is displayed depending on the source of the data. When the ALT switch is in the BAR0 position, barometric altitude is displayed. When the ALT switch in the RDR position and if aircraft altitude is 5000 feet or lower, radar altitude is displayed within the dial and is identified by an R to the right of the least significant digit. If the radar altitude becomes invalid by exceeding 5000 feet or 45’ AOB, barometric altitude is substituted and a B will flash to indicate that barometric altitude is being displayed rather than radar altitude.
Vertical velocity readout
The vertical velocity readout consists of a maximum of five digits for a positive vertical velocity indication and a maximum of four digits with a leading minus sign for a negative vertical velocity indication. If the limit 32,999 or -9,999 is exceeded, a minus sign with four x’s (-xXxX) is It is displayed below the six o’clock dot of the altitude dial.
Figure 2-92. HUD TLN Basic Format (Sheet2 of 4)
ORIGINAL
2-l 68
SYMBOL
FUNCTION
63
Negative three degree marks
Indicates the negative 3 degree position on the pitch ladder.
0
Barometric setting
The barometric pressure setting used by the dlsplay system and the weapon system is the value set on the pilot’s barometric altimeter. The setting will be displayed for up to 5 seconds on the HUD and VDI in the TLN mode when the setting is changed. At 18,000 feet, tf it Is off, the symbol comes on and blinks for 5 seconds.
0
pressure
Bank scale
Provides indication of bank angle to f45’. Tick marks are provided at O”, *IO”, f20”, .f30” (slightly larger) and f45”. The warnings L STALL, R STALL, L FIRE, R FIRE, and RDC SPEED and the CLSN advisory will appear on the HUD in the steady condition. Up to two indications may be displayed at any one time. When more than two indications are present, they scroll up from the bottom at the rate of one per second.
63
0
@
0 63
Bank angle pointer
Moving pointer provides indication of aircraft bank angle. At bank angles in excess of f45O, the pointer will be pegged at f50” and will flash.
Peak aircraft g
Peak Aircraft g is displayed on the HUD as follows: TLN Gear Down: If aircraft g falls below +O.O or exceeds +2.0. TLN Gear Up, A/A, A/G: If aircraft g falls below -2.0 or exceeds +4.5. Peak g indication is displayed until a declutter mode is cycled.
Aircraftg
Aircraft g is displayed on the HUD as follows; TLN Gear Down: If aircraft g falls below +0.5 or exceeds +I .5. TLN Gear Up, A/A, A/G: If aircraft g falls below -2.0 or exceeds +4.5.
Mach number
Indicates speed of the aircraft in math.
Angle-of-attack
Indicates angle-of-attack
in units. Note
When’the TLN gear down format is displayed, the AOA readout is removed when AOA is between 14 and 16 units. If AOA is greater than 14 units and decreasing, the readout remains off until AOA decreases below 13 units. If AOA is less than 16 units and increasing, the readout remains off until AOA increases above 17 units. @
Airspeed dial
The HUD analog airspeed dial consists of ten dots encircling the airspeed readout. Each dot indicates airspeed in tens of knots with the zero mark located at the top center of the dial.
@
Airspeed pointer
An analog pointer indicating airspeed moves uniformly around the inside of the airspeed dial based on indicated airspeed. Increasing airspeed is indicated by clockwise rotation of the pointer.
Extended horizon line
Represents the horizon with respect to the aircraft and changes orientation with any change in aircraft pitch or roll.
0
Figure Z-92. HUD TLN Basic Format (Sheet3 of 4) 2-169
ORIGINAL
I
SYMBOL
FUNCTION
@
Digital airspeed readout
Provides digital readout of calibrated airspeed.
@
Flight path marker
The flight path marker is displaced in azimuth and elevation to present computed flight path. Aircraft vertical flight path angle is indicated by the position of the flight path marker on the pitch/flight path ladder. In the caged mode, the flight path marker is caged in azimuth and the true flight path marker position is indicated by the display of the ghost flight path marker when the true position is more than 2” from the caged position. The flight path marker can be caged or uncaged by alternately pressing the CAGE/SEAM switch. On selection of TLN or A/A, the flight path marker IS mittally caged: selection of AIG presents the uncaged mode initially.
024
Heading Scale
Aircraft magnetic heading is indicated by the moving 360” heading scale. In TLN, the major divisions are numbered every 10 degrees. In A/A, the major divisions are numbered every 20 degrees.
Note When the aircraft is in the TLN mode with the gear handle down, the heading scale remains 2 degrees above the position of the flight path marker. The lowest point of the heading scale, including the numbers, will never rise above the normal (gear up) position. The heading scale is occluded by the altitude and airspeed dials and readouts. 3
@
Angle-of-attack bracket
Potential flight path marker
The AOA bracket is a pitch related variable that indicates the deviation of the current AOA from a desired value and is vertically referenced to the left wing of the flight path marker symbol. The center of the bracket represents the optimum AOA. The bracket moves lower with respect to the flight path marker as AOA increases and it moves higher as AOA decreases. Indicates the acceleration along the flight path marker. Provides a graphical representation of the ability to change the flight path angle by varying the thrust acceleration and/or angle of attack. Deceleration is indicated by the PFPM below the flight path marker and acceleration by the PFPM above the flight path marker.
Figure 2-92. HUD TLN Basic Format (Sheet4 of 4) The symbols removed by the DECLUTTER switch vary with formats and are discussedin the applicable paragraphs.Refer to Figure 2-93 for declutter information in TLN-GD, TLN-GU, A/A, and A/G modes. 2.33.8.3.1 Takeoff/Landing/Navigation Formats. TLN formats are categorized by the selected steeringmode andlanding gearposition. TLN basic, the HUD default format, doesnot display steeringinformation. Refer to Figure 2-92 for the location and description of TLN basic symbology. ORIGINAL
Steeringmode selection is madethroughMFD pushbutton or cursor designateaction on the VDI AWL formats. TCN and DEST steeringmode selectionsarealso availableon the HSD by boxing the tacandatabuffer or waypoint data butter, respectively. Making a steering modeselectionchangesTLN basicto TLN TCN (tacan), MAN (manual), DEST (destination),D/L (datalink), or AWL (all-weatherlanding). Steeringmode is identified on the HUD by a legendin the datareadoutdisplay area. Steeringmodesaredescribedin Chapter20.
2-170
NAVAIR
Ol-Fl4AAD-1
HUD MODES
I
RADAR ALTITUDE READOUT
TARGET POINTER/AON
cl
Not Present Present As Required
I
* Pitch ladder replaced on Spin
Figure 2-93. HUD Declutter Levels
ORIGINAL
NAVAIR 01.FI4AAD1
1. TCN selection adds a course-steeringarrow and course-deviationdots.Distanceto thetacanstation is displayedto the right of the TCN legend. 2. MAN steeringselectionaddsa commandedheading marker to the headingscale.The commanded headingmarker also appearson destination,datalink, and AWL formats. 3. DEST steeringselectionaddsthe waypoint destination rangeto TLN basic format. 4. D/L selection displays the range to the data-link destination.A largeflashing‘X” will appearin the center of the display when a data-link waveoff command is received. 5. AWL steeringselectionprovidesfor thedisplay of ACL and ILS, ACL only, ILS only, or no ACL and ILS glidepathsituationdisplays.The displayofthe HUD flight director glideslope and centerline steeringcan also be independentlycontrolled. Selections aremade via MFD pushbuttonactivation on the VDI AWL format. A large, flashing “X” will appearin the center of the display when a waveoff command is received. Distance to the tacan stationis displayedas is the TCN legend. When the landing gearhandle is placedin the down position, the HUD cage/uncagefunction is enabledon the CAGE/SEAM switch locatedon theinboardthrottle, the systemtransitionsto TLN-GD mode,andall weapon selections are cleared. In TLN-GD mode, the Mach number is removedand aircraft g is displayedif the g’s fall below +0.5 or exceed+1.5; peak g is displayedin normal declutter mode if aircraft g falls below 0.0 or exceeds+2.0; the horizon line is extendedacrossthe HUD field of view anda flying “W” (waterline)symbol is addedat the fuselagereferenceline. Note The waterline symbol is also addedin other HUD formats when the flightpath marker is at or beyondthe HUD field of view or when altitude datais lost.
Refer to NAVAIR Ol-F14AAD-IA for a description of air-to-air attack. 2.33.8.3.3 Sensor Mode Indications. Radar modes are indicatedon the HUD via alphanumerics.The radar mode alphanumericsareremovedwhen the radaris off or in the computer mode. An “X” overlays the mode indication if the IRST is failed (Figure 2-96).The radar mode alphanumericsareas follows: 1. Hot rangewhile search(HRWS) 2. Manual rapid lock-on (MRL) 3. Pilot automatic lock-on (PAL) 4. Pilot lock-on mode (PLM) 5. Pulse Doppler search(PDS) 6. Pulse Doppler single-targettrack (PDSTT) 7. Pulse search(PS) 8. Pulse single-targettrack (PSTlJ 9. Rangewhile search(RWS) 10. Rangewhile searchvelocity (RWS) 11. Sniff (SNIFF) 12. Standby(STBY)
Figure 2-94 showsthe symbols that areaddedduring tacanand AWL flight director steeringmodes,landing geardown, with digital or analogdisplay selection. Refer to Figure 2-95 for a description of the symbols that are available for TLN formats. 2.33.8.3.2 Air-to-Air Formats. A/A formats (Figures 2-96 and2-97) are presentedwhen the pilot selects
ORIGINAL
the A/A pushbutton on the pilot DISPLAYS control panel,when a weapon is selected,the radarhot modes areselected,or when the ACM guardis lifted. The A/A formats provide target acquisition, weapon status,and shoot prompts as well as primary flight information. Targetdataand the selectionlegendsA/A, PH, SP,SW, and G are displayed.Quantity of the selectedweapons is also shown. When GUN is selected, the quantity numberindicatesroundsremaining in hundreds.A large “X” through a weapon selection legend indicates that the masterarm switch is SAFE.
2.172
13. Track while scanautomatic (TWSA) 14. Track while scanmanual (TWSM) 15. Vertical scanlock-on high (VSLHI) 16. Vertical scanlock-on low (VSLLO).
NAVAIR 01.F14AAD-1
AWL/FLIGHT
DIRECTOR
TACAN
W 5-
15
1BOOR
/
TCN
12.5
\
(AT,I-F5OD-332-O
Figure Z-94. HUD Added Symbology (Sheet1 of 2)
2-173
ORIGINAL
NAVAIR Ol-FlUAD* 1 I.I~“L 0
0
0 @
0 @
0
Command marker
l-VI.&.
heading
I IVI.
This symbol indicates the heading required to achieve the selected course. Course selection may be manual, data link commanded, or waypoint destination. Where commanded heading is beyond display scale limits, the symbol will be pegged at the nearest edge to the commanded heading. This symbol does not appear on the basic or tacan formats.
Waterline
Indicates fuselage reference line (FRL). Displayed when attitude information is not valid. Also displayed when gear down or TLN Gear Up or, the flight path marker is at or beyond the HUD’s full field of view.
Breakaway, waveoff
A large flashing X will appear in both D/L and AWL steering modes if a WAVEOFF command has been received.
ILS precision course vectors
Consists of two independent vectors (vertical and horizontal) which form a cross pointer. The horizontal vector responds to ILS glide slope error and the vertical vector responds to ILS localizer error. Null/center indications are provided to enable the pilot to null the error and keep the vertical and horizontal needles centered. This message indicates that the all weather landing steering mode has been selected.
AWL legend Range
Extended horizon line
Depending on the format, this message will indicate either the range to the tacan station, data link destination or distance to waypoint destination. The legends TCN, D/L, or WPT, may also appear. When in the manual steering mode no range appears but the MAN legend is displayed. Indicates the horizon with respect to the aircraft with landing gear down. Changes orientation with any change in aircraft pitch and roll. The course arrow represents the selected course to the tacan station. Two dots will appear on the side of the flight path marker toward the course arrow and perpendicular to the arrow. The dot closest to the flight path marker represents a half scale deflection of 4” off course, while the outermost dot represents full scale deflection of 6” off course. When the aircraft crosses the selected course, the arrow moves to the opposite side of the flight path marker and the dots would appear on that side. For deviations of more than 9”, the arrow pegs. If the arrow is centered on course, the dots disappear. Flight path marker centered over the course arrow indicates being on course. For tacan bearings aft of f90”. the arrow will be dashed. The AOA bracket is a pitch related variable that indicates the deviation of the current AOAfrom a desired value and is vertically referenced to the left wing of the flight path marker symbol. The center of the bracket represents the optimum AOA. The bracket moves lower with respect to the flight path marker as AOA increases and it moves higher as AOA decreases.
@
gg;gyd
@
Angle-of-attack bracket
@
Flight director
The flight director symbol provides glide slope and centerline steering information computed by the mission computer using navigation system parameters and Data Link information from the SPN-42/46 ACLS system. The box with the three dots will provide the pilot with optimal glide path intercept and following when the flight path marker is inside the flight director box and the three dots are aligned with the wings and the tail of the flight path marker. The same procedures are used whether the flight path marker is caged or uncaged. The flight director symbol is removed from the HUD when the FLT DIR pushbutton on the VDI is unboxed.
ACL steering indicator
Provides ACL steering commands
0
driven by the ASW-27C
Figure 2-94. HUD Added Symbology (Sheet2 of 2)
ORIGINAL
2-174
data link.
NAVAIR
0%F14AAD-1
FORMAT SYMBOL
BASIC
DATA LINK
AWL
DESTINATION
Aircraft G’s Readout
(On all formats except GEAR DOWN & DECLUTTER-2)
Airspeed Dial
(On all formats except DIGITAL)
Airspeed Readout Box
I (On all formats except ANALOG or DECLUTTER-2)
Airspeed Readout
(On all formats)
Altitude Dial
(On all formats except DIGITAL)
Akiiude Readout Box
(On all formats except ANALOG or DECLUTTER)
Aititude Readout
(On all formats)
MANUAL
TACAN
I
I Angle-of-Attack
Readout
Bank Scale
(On all formats except DECLUTTER-2) (On all formats except DECLUTTER-
1 and 2)
Saro Setting Readout (5 set)
+
+
+
+
+
+
Ghost flight path marker
+
+
+
+
+
+
+l+l+ (Onall formats when GEAR UP)
+
+
+
+
+
+
Extended Horizon Line
(On all formats when GEAR DOWN)
HeadingScale Horizon Reference Markers
+l+l+
Mach Readout
(On all formats except GEAR DOWN and GEAR UP DECLUTTER-2)
Peak AJC G’s Readout
(On all formats except DECLUlTER-1
Pitch Ladder-TLN
and 2)
+l+l+l+
Radar Attitude Readout
Flight Path Marker Vertical Velocity Readout
+
(On all formats except GEAR DOWN DECLUlTER-1 DECLUTTER-2)
+l+l+l
(On all formats except DECLUTTERin GEAR DOWN)
+
& 2 and GEAR UP
+ l+l+
1 8 2 in GEAR UP and DECLUTTER-2
Figure2-95. HUD Symbology AvailableonTLN Formats(Sheet1of 2) 2-175
ORIGINAL
NAVAIR 6%FlUAD-
FORMAT SYMBOL
BASIC
AWL
DATA LINK
DESTINATION
:On all formats or when flight path marker pegged
Waterline Altitude Source-8
or R
HUD Cursor
MANUAL
TACAN
or attitude data invalid)
+
+
.+
+
+
+
+
+
+
+
+
+
Potential Flight Path Marker
;On all formats except DECLUTTER-2)
Angle of Attack Bracket
‘On GEAR DOWN only. All formats)
IRST Pointer
+
+
+
+
+
+
TCS Pointer
+
+
+
+
+
+
Caution/Advisory/Warning
+
+
+
+
+
+
Breakaway Symbol
0
+
+
0
0
0
Command
0
+
+
+
+
0
HUD Steering Legend-AWL
0
+
0
0
0
0
HUD Steering Legend-TCN
0
+
0
0
0
+
HUD Steering Legend-D/L
0
0
+
0
0
0
HUD Steering Legend-MAN
0
0
0
0
+
0
0
0
0
c
0
0
0
+
0
0
0
0
Sange Readout
0
+
+
+
0
+
4CL Steering Indicator Tadpole
0
+
0
0
0
0
-light Director
0
+
0
0
0
0
0
0
0
0
0
+
Heading Marker
HUD Steering Legend -
WPT
ILS Preotsfon CoureeVectore
?ourse Arrow 8 Deviation Dots L
Uotes: + indicates that the symbol is available for display on the selected format. o indicates that the symbol is not available for display on the selected format.
Figure 2-95. HUD Symbology Available on TL.N Formats (Sheet2 of 2) ORIGINAL
2-176
NAVAIR 0%Fl4AAD1
A/A BASIC, STT FORMAT - ANALOG, NO DECLUlTER
HUD TWS, IRST SEARCH-ANALOG, DCL LVL 1
/ D’ 34 I ’
a-
5’
: 370
* . -
.
I
-I- :;,i,,,. -
VQ
ov v
t “E 4.5
I
02 -5
nY
-
TO&
PI
36
..:
v
5L-
--J5
RNG ALT vc ID
94
TWSA IOI-
- -
-IWSM -
-
110
30.t 21.C 500 xx>
WPT 12 27.
(Al-)l-F5OD-333-l
Figure 2-96. HUD A/A SearchFormats (Sheet1 of 2)
2-177
ORIGINAL
NAVAIR
01-Fl4AAD-1
a
Radar target designator and target aspect
Indicates the radar line of sight (LOS) to the target. Symbol is displayed on all A/A weapon modes when radar is tracking a target. The position is computed from the radar LOS. The symbol is poskionable over the total HUD field of view (FOV). The symbol will be pegged at the FOV limits and flash. In Sm, target aspect is represented by a pointer which points in the direction of the aspect angle. Zero target aspect is straight down.
0
Target pointer
Indicates the direction of the target designator (TO) box position on the HUD. The target pointer is present when pointing to a TD box under the following conditions: 1) FONO 1 track is outside the IFOV (Instantaneous Field of View). 2) TID hooked track is outside the IFOV with no FONO 1 present. 3) Closest TMA is outside the IFOV and there is no FONO 1 TID hooked track.
@
$glele;ff-the-nose
The angle-off-the-nose (AON) indicator defines the angle between the FRL and the target line of sight that the target pointer is pointing to, in the plane described by the FRL and the target pointer. When the target designator is being pointed to by the target pointer, a three digit readout is displayed indicating the AON of that target. The AON indicator is not earth stabilized. The AON readout is centered below the origin of the target pointer and is given in degrees
Steering tee
Provides azimuth steering only, in search mode. Provides elevation and azimuth steering in track mode.
IRST symbol
Indicates location of sensed target.
Target range
Range of closest radar target in nautical miles and tenths. Numeric is displayed only when range is valid.
Target altitude
Attitude of closest radar target in thousands information is valid.
Target closing velocity
Displays closing rate to radar target. A minus sign indicates an opening velocity.
Target ID
Target ID display
Time of flight
TTG or lTA, refer to NAVAIR 01 -F14AAD-IA.
Navigation
Display mode of steering or steering mode, waypoint (DEST or D/L).
@
0 @ 0 @ @ 63 0 0 0 63 0 63 0
Data
Up to four displayed.
of feet. Displayed only when
selected or range
IRST mode indicator
Displays current IRST mode.
Radar mode indicator
Displays current radar mode.
Weapon select legend
Displays missile type and quantity, if selected, or gun and rounds remaining, in hundreds. If no weapon is selected, displays A/A.
Master arm safe cue
A large X through the A/A or weapon select legend indicates the Master Arm Switch is in SAFE.
TCS pointer
Indicates the direction of the TCS track.
NCTR
Indicates non-cooperative Oi-F14AAD-1A. I
target recognition
is available.
Figure 2-96. HUJI A/A SearchFormats (Sheet2 of 2) ORIGINAL
2-178
Refer to NAVAIR
FORMAT PHOENIX SYMBOL
-
SPARROW
SIDEWINDER SEARCH 1IlACK
Aircraft G’s Readout
3ASIC SEARCH 1 TRACK + + +
SEARCH 1 TRACK
Airspeed Dial
‘On all formats except DIGITAL)
Airspeed Readout Box
‘On all formats except ANALOG & DECLUlTER-2)
Airspeed Readout
On all formats)
Altitude Dial
On all formats except DIGITAL)
Altiiude Readout Box
On all formats except ANALOG & DECLUTTER-2)
Altitude Readout
On all formats)
Angle of Attack Readout
On all formats except DECLUTTER)
+
+
+
+l+l+l+l+l+
Baro Setting Readout Ghost Flight Path Marker
On all formats except DECLUTTER-2)
Heading Scale
On all formats excepl DECLUTTER 1 & 2)
+
GUN YIMG! 3 EIACKUF ,
+
T
+
+
+
Horizon
+
+
t
+
+
+
+
+
+
Reference Markers
+
+
t
+
+
+
+
+
+
+
+
+
+
+
+
Mach Readout
On all formats except DECLUTTER-2)
Peak AK G’s Readout
On all formats except DECLUTTER-2)
Pitch Ladder
On all formats except DECLUTTER-
Radar Altitude Readout
On all formats except DECLUTTER-1
& 2)
+l+l+l+l+l+
Flight Path Marker Waterline Altitude Source-B
1 & 2) 1
Dn all formats when flight path marker pegged, iriformation is invalid.) or R
gear isi dc rwn, or alt itude ,
+
+
+
+
+
+
HUD Cursor
+
+
+
+
+
+
IRST Pointer
+
+
+
+
+
+
TCS Pointer
+
+
+
+
+
+
SautiorVAdvisoryiWarning
+
+
+
+
+
+
3reakaway Symbol
+
+
+
+
+
+
pa;rrand Heading
+
+
+
+
+
+
A/A
PH#
SP#
SP#
SW#
SW#
3elect Legends, rrVeapon-Qty
1
PH#
G#
G#
-
Figure 2-97. HUD Symbology Available on A/A Formats (Sheet 1 of 2) 2-179
ORIGINAL
NAVAIR 01.fl4AAD1
I SYMBOL Master Arm Switch Safe 3Je
IASIC +
PHC EARCH +
iii!SPAI rRACK EARCH + +
SIDEV iEARCk
DER RACK
+
f
IIMGE +
0
0
+
0
+
0
0
+
0
0
GUN IACKUP +
+
0
Target Range Indicator
+
0
+ +
Naypoint
0
+
0
+
+
0
0
0
Steering Tee
+
0
+
0
0
+
0
0
Target Designator
+
0
+
0
0
+
+
0
Target Closing Velocity
+
0
+
0
0
+
0
0
Target Altitude
+
0
+
0
0
+
0
0
Target ID
+
0
+
0
0
+
0
0
TACAN Digital Readout
0
+
0
+
+
0
0
0
Flood Illumination
Pattern
0
0
0
+
0
0
0
0
Sidewinder Seeker Circle
0
0
0
0
+
+
0
0
SHOOT Cue
0
0
+
0
0
+
0
0
Reticle
0
0
0
0
0
0
+
0
Reticle A
0
0
0
0
0
0
+
0
Reticle B
0
0
0
0
0
0
+
0
Target Range Tape
0
0
0
0
0
0
+
0
Target Lead Cue
0
0
0
0
0
0
+
0
BATR Symbol
0
0
0
0
0
0
+
0
Bun Mode indication-MAN
0
0
0
0
0
0
0
+
Reticle Depression-#
0
0
0
0
0
0
0
+
4/A Gun/Backup 3eticle
0
0
0
0
0
0
0
+
Target Range-RNG,
#
Select
Mode
Votes: t indicates that the symbol is available for display on the selected format. J indicates that the symbol is not available for display on the selected format.
Figure 2-97. HUD Symbology Available on A/A Formats (Sheet2 of 2)
ORIGINAL
2-180
NAVAIR 01.F14AAD-1
IRST modes are indicated on the HUD via alphanumerics. The IRST mode alphanumericsare removed when the IRST is failed. The IRST alphanumericsare as follows:
allowing gunaiming by displaying the A/A gun/backup mode reticle. The reticle depressionangle, adjustedby the ELEV LEAD knob on the PDCP, is shown in the lower right corner of the HUD along with the MAN gun-modeindication.
1. Cooldown (COOL) 2.33.9 MFD Formats. Initial turn on or a cold start (definedasa systemresetor a power outageto the MCS ofat least300milliseconds) causesthe following default formats to be displayed: VDI TLN basic on MFDI, OBC basic on MFD2, and OWN A/C basic on MFD3. The actual format displayed on MFD3 dependson the navigationmode selectedand the conditionsexisting at the time. If theNAV MODE switch is at OFF, the OWN A/C basic format is displayed.
2. Hot IR (HOTIR) 3. Pilot automatic lock-on (PAL) 4. Pilot lock-on mode (PLM) 5. Single-targettrack (STT) 6. Standby(STBY)
MFD3 may also actasa controller of theDEU in that, when certainformats arebeing displayedon MFD3, the DEU is commanded to display correspondingslaved formats. Refer to Figure 2-102 for a listing of MFD3/DEU slavedcontrol conditions.
7. Track while scanautomatic (TWSA) 8. Track while scanmanual (TWSM). 2.33.8.3.4 Air-to-Ground Formats. Pushbutton selectionon the PDCP or selection of an air-to-ground I weaponplacesthe A/G basic format on the HUD (Figures2-98 and 2-99). The A/G basic format can display waypoint and tacan information. A/G DECLUTTER and ANLG and DGTL displays are similar to A/A formats.Refer to NAVAIR 01-FI4AAD-IA. 2.33.8.4 Overlay Symbology. Symbology (Figure 2-100)may be overlaid on displayedHUD formatswhen additional information is required. These include RECON, TWS, and IRST TWS.
With the exception of high-priority formats (ECM andspin), which appearwhen required,most MFD formats are selectableby means of MFD pushbuttonor cursor designation.The actual format that will appear may dependon other factors,however, suchas aircraft state(TLN, A/A, or A/G), steeringmode selection,and the alignment condition.
RECON, usedwith the TARPS pod, is selectedasan overlay from the MFD RECON formats. This overlay addsthe RECON command headingmarker, command ground-trackline, RECON steeringsymbol, targetdesignatorhexagon,and cameraselectionlegend.
The MENU legend appearson every MFD format except for HUD, DD, and TID repeats.These repeat formatsdo not display selections;pressingany pushbutton when in a repeatmode will place MENU1 on the MFD. The MENU legend is located above the center pushbuttononthe 1oweredgeoftheMFDs. Alsoappearing on every MFD format for easeof immediate selection, arethe SMS and ECM pushbuttonlegends(Figure 2-103).
Radar track while scan addsup to four radar target diamondsthat indicate the four closesttargets.Size of the symbolsindicatesrelativeproximity (i.e., thelargest is the closest).The four symbols are of presetsizes,not scaledto reflect actualdistances.
Repeateddepressionsof the ECM or SMS pushbuttons toggle between these formats and the previously selecteddisplay. This permits the crew to quickly check ECM or SMS conditions without having to reselectprevious formats.
The infrared searchand tracking system TWS adds up to four triangular IRST symbols to existing formats. Unlike TWS, thesesymbols areall the same size. Both IRST and TWS symbols are addedautomatically when a targetis being tracked.
SelectingMENU placesmenu 1 on the display. The legendreadsMENU1 and is enclosedby a rectangular box. SelectingMENU1 when it is boxed placesmenu 2 on the display with the legendMENU2 displayedin the box. The MENU pushbuttontogglesbetweenMENU1 and MENU2. Menu selection changesthe pushbutton legendbut doesnot alter the display being presented.
2.33.8.5 Manual Reticle. If the mission computer losescommunicationwith both DPs, theDP driving the HUD provides a manual reticle format (Figure 2-101)
2-181
ORIGINAL
NAVAIR Ol-F14AAD-1
HUD A/G FORMAT - ANALOG,
.-. -360 ‘./*
NO DECLUTTER
.*.
& :5L--
--
15
.
* 2000: - . -
.
< a M G
7.0 0.62 1.8
,OL--
-I10 A/G
-WPT
/ 12
/”
1
24.5_
(AT)%F50D-33%
SYMBOL a 0
0
FUNCTION
Waypoint select
displays destination
waypoint selection.
Range to waypoint readout
Iisplays range to selected waypoint.
Select legend
displays mode/weapon ielected.
selected. Will display fVG if no weapon has been
Figure 2-98. HUD A/G Basic Format
2-182
NAVAIR
SYMBOL
BASIC
FORMAT CCIP
I
01.F14AAD-1
MANUAL
Aircraft G’s Readout Airspeed Dial
(On all formats except DIGITAL)
4irspeed Readout Box
(On all formats except ANALOG & DECLUlTER
Airspeed Readout
(On all formats)
Altitude Dial
(On all formats except DIGITAL)
Altitude Readout Box
(On all formats except ANALOG & DECLUTTER
Ntitude Readout
(On all formats)
Angle of Attack Readout
(On all formats except DECLUTTER
Baro Setting Readout
- 2)
- 2)
- 1 & 2)
+ I + I
Shost flight path marker
(On all formats except DECLUTTER
- 2)
Heading Scale
(On all formats except DECLUTTER
- 2)
+
Horizon
+
+
+
Reference Markers
+
+
+
Mach Readouts
(On all formats except DECLUTTER
- 2)
Peak AK G’s Readout
(On all formats except DECLUTTER
- 2)
Pitch Ladder
(On all formats)
Radar Altitude Indicator
(On all formats except DECLUTTER
Flight Path Marker Altitude Source-B HUD Cursor
or R
- 2)
+
+
+
+
+
+
+
+
+
Figure Z-99. HUD Symbology Available on A/G Formats (Sheet 1 of 2)
2-183
ORIGINAL
NAVAIR
Ql-Fl4AAD-1
SYMBOL
BASIC
FORMAT CCIP
MANUAL
IRST Pointer
+
+
+
TCS Pointer
+
+
+
Caution/Advisory/Warning
+
+
-I-
Breakaway Symbol
0
+
0
Command
+
+
+
Select Legends, Weapon-Qty
A/G
G
G
Master Arm Switch Safe Cue
+
+
+
Pull Up Cue
0
-I-
O
Waypoint Select
+
+
+
Steering Tee
+
+
+
TACAN Digital Readout
+
+
+
Gun Mode indication
0
CCIP
MAN
0
+
+
Max. Gun Firing Range
0
-I-
O
Reticle
0
+
+
Target Range Tape
0
+
0
0
0
+
Heading Marker
Gun Rounds Remaining
Reticle Depression
(100’s)
Numerics
Notes: + indicates the symbol is available for display on the selected format. o
indicates that the symbol is not available for display on the selected format.
Figure 2-99. HUD Symbology Available on A/G Formats (Sheet2 of 2)
ORIGINAL
2-I 84
NAVAIR
Of-F14AAD-‘f
HUD RECON STEERING A/G
4 - VCN
(AT)*-F5OD-3374
SYMBOL
FUNCTION Indicates the magnetic heading to the dynamic steering point or commanded in the SO deg-270 deg maneuver during map steering.
0
Target designator, hexagon
Displays target position. Positioned by on-board
@
K;mand
Displays the path of the command
@
Camera selection legend
Displays the camera operational mode. First letter indicates frame position: V = vertical, F = forward, or blank. Second letter indicates pan position: C = center, R = right, L = left, or blank. Third letter indicates IRLS position: N = narrow field of view, W = wide field of view, S = standby, or blank.
Recon steering symbol
Provides elevation and ezimuth steering information reconnaissance mode.
0
ground track
sensors or data link.
ground track.
when in
Figure 2-100. HUD Overlay Formats
2-105
ORIGINAL
MMGQBACKUPMODE
GUN MODE INDICATION
(Al-II--
Figure 2-l 01. BUD Manual Reticle Format With a MEND display selected,format legends(Figure 2-103) are displayed aroundthe edgesof the CRT. A format is selectedbycursordesignationor by pressing the pushbuttonadjacentto the legend.When a format is selected,its legend is highlighted on the display by endosing it in a rectangularbox. When a display processoracknowledgesa pushbutton being depressed,the legendis boxedwith a dashed lime. When the MC acknowledgesthe pushbuttonrequest,the line becomes solid. If the MC does not acknowledge the request,the dashedbox disappears.This system is usedto show the crew that the display system hasreceivedthe request.SelectingMEND only changes the pushbutton legends. The current display remains until a selectionis made from MENU. For conveniencein describingformat selection,numbers are assignedto the pushbuttonsstarting from the lower left sideand counting clockwise. On the MENU1 display, PBl is the pushbutton correspondingto the DATA legend. From MENU1 the following formatsmay be selected: 1. PBl DATA - This selection presents one of four OWN AK formats. The format to be disORIGINAL
2-166
playeddependsonthepos.itionoftheNAVMODE switchintheRIOcock$t. EitherOWNA/Cbasic, groundalign, CVA (carrieralign), or IFA (in-flight align) formats will be displayed. 2. PB2 NAV - Selecting NAV presentsone of 8 number of NAVAID or SAHRS ALIGN formats, depending on alignment mode conditions. Formats that may be displayed include NAV AID options, NAV AID corrections, NAV AID enabled, SAHRS ALIGN (NORM, MAG, SHDG), or SAHRS ALIGN (CV). 3. PB3 -
No selection.
4. PB4 TSD - This selection places thy tactical situation display format on the display. Switching logic prevents TSD formats from appearing on more than one of the pilot MFDs. Therefore, if TSD has been established on MFD2 and it is selectedfor MFDl, it will appearon MFDl, and be replacedon MFD2 with MENUl. Refer to the Supplemental NATOPS Flight Manual, NAVAIR 01-F14AAD-IA, for a description of TSD formats.
NAVAIR
5. PB5 VDI - This selectionplacesone ofseveral VDI formatson thedisplay. VDI formatsare headdown attitude displays presentingbasic flight information aswell as steeringandweapondelivery cues.Format selection dependson PDCP MODE pushbuttonselection, steering selection, weapon selection,and track or searchmodes.
SLAVED DEU FORMAT
MFD3 FORMAT
Ol-F14AAD-1
OWN A/C BASIC
OWN A/C
OWN A/C GROUND
OWN A/C
OWN AK CVA
OWN A/C
OWN AIC IFA
OWN AIC
HSD TACAN
OWN A/C
6. PB6 -
HSD WAYPOINT
WAYPOINT PLOT
WAYPOINT DATA 1 (Note 1)
WAYPOINT
WAYPOINT DATA 2 (Note 2)
WAYPOINT
RECON WPT DATA 1 (Note 6)
WAYPOINT
7. PB7 CTVS - This selection displays video from the HUD cockpit television sensoron the MFD. The video consistsofa real-world view plus the symbology appearingon the HUD.
RECON WPT DATA 2 (Note 7)
WAYPOINT
CV MAN DATA (Note 3)
CV ALIGN
CV SINS DATA (Note 4)
CV ALIGN
css
css
SMS
SMS
SAHRS ALIGN (NORM, MAG, SHDG)
OWN A/C
SAHRS ALIGN (CV)
CV ALIGN
NAVAID OPTIONS
NAV AID
NAV AID ENABLED (Note 5)
NAV AID
TSD
NAV GRID
8. PBS OBC - Selecting OBC places the ON BOARD CHECKOUT basic format on the display. From the basic format, other OBC formats can be selected,allowing BITS to be commanded andtestresultsto be displayed.There are 10 OBC formats. Refer to Chapter38 for a description of theseformats and their use. 9. PB9 CHKLST - This selection initially places the TAKEOFF checklist on the MFD. From the TAKEOFF format, the LANDING checklist may be selected.PB9 togglesbetweenTAKEOFF and LANDING when CHKLST hasbeenselected. 10. PBlO -
Votes:
No selection.
11. PB 11HUD - This selectiondisplaysa repeatof the current HUD symbology on the MFD.
[l) No slaved DEU format shall be established if MFD 3’s previous format was WAYPOINT DATA 2 or RECON WPT DATA 1.
12. PB12 TID - This selectiondisplays a repeatof the tactical information displaypresentationonthe MFD.
:2) No slaved DEU format shall be established if MFD 3’s previous format was WAYPOINT DATA 1 or RECON WPT DATA 2.
13. PB13 DD - This selection displays a repeatof the digital display presentationon the MFD.
13) No slaved DEU format shall be established if MFD 3’s previous format was CV SINS DATA.
14. PB14 TCS - This selection displays the video from the television cameraset on the MFD.
4) No slaved DEU format shall be established if MFD 3’s previous format was CV MAN DATA. 5) No slaved DEU format shall be established MFD 3’s previous format was NAV AID CORRECTIONS.
No selection.
if
15. PBl5 IRST - This selection displaysthe infmred search and track systemnormal format on the MFD.
6) No slaved DEU format shall be established if MFD 3’s previous format was RECON WPT DATA 2.
16. PB16 HSD - This selection displays one of three horizontal situation display formats on the MFD. The format displayed will be the last previously displayed.If no HSD format hasbeenselected after a cold start or system reset,then the HSD waypoint format will be presented.
7) No slaved DEU format shall be established if MFD 3’s previous format was RECON WPT DATA 1.
Figure 2-102. SlavedDEU PageControl 2-107
ORIGINAL.
NAVAIR 01.Fl4AAD-1
Figure 2-103. MFD MENU Displays
ORIGINAL
2-188
NAVAIR 01.F14AAD-1
17. PB17 ECM - This selection places the ECM format on the MFD. A secondselection of ECM while viewing the ECM format returns the previous format to the MFD, providing that ECM ORIDE has been selected and throat is being reported. 18. PB18 MENU1 - This legendwill be boxed.Selectionof MENU1 whenboxedpresentsMENUZ. 19. PB19 SMS - This selection places the stores managementsystem format on the MFD. In addition to weapontest andselectvia the SMS format, TACTS and SIM modes are enabled. Refer to NAVAIROI-F14AAD-IAforacompletedescription of TACTS and SIM modes.A secondselection of SMS while viewing the SMS format returns the previous format to the MFD. 20. PB20 -
No selection.
MENU2 (Figure 2-103) allows selection of the RECON andJTIDS formats on the MFD. 21. PB21 JTID - This selectiondisplaysthe JTIDS OWN A/C DATA format. From the JTIDS OWN A/C DATA format, the TSD MENU (TMENU) or JTIDS Hook - TSD or TID format can be selected. 2.33.9.1 High-Priority Formats. High-priority formats include spin indicator, ECM, warning/caution/ advisory and systemmessagedisplays. 2.33.9.1.1 Spin Indicator. If a spin condition is detected,that is, if body yaw rate exceeds30” per second, a spin indicator format (Figure 2-104) is displayed on MFD 1 andthe TID, MFDs 2 and 3 display the VDI. If MFD 1 is not on, the spin display will appearon MFD 2. When the spin condition is no longer valid (yaw rate of 27” per secondor less), the spin indicator format is removedandthe previous format is restoredto the display exceptas follows: 1. If conditions for the display of the ECM format exist, the ECM format will appearon the display instead. 2. If the previous format was a HUD, DD, or TID repeat, MENU1 with a display of warning/ caution/advisory and/or data link (D/L) advisory messageswill be displayed. 3. If INS and SAHRS failures occur while the spin arrow format is displayed,the pointer on the yaw
rate scale is removed from the MFD, the spin arrow is frozen, and an X is superimposedover the spin arrow. The airspeed, AOA, and altimeter scalesare not obscured(referto Chapter 11). 2.33.9.1.2 ECM Format. If the pilot and/or RIO ECM switches (Figure 2-83) are set to ORIDE and a threat is reported,the ECM format will override the presentformatson MFD 2 and/orMFD 3. ECM override is enabledindependentlyby pilot and RIO and may be deselectedindependently.When the threatis no longer being repotted,the ECM format is replacedby the previous format. If MFD 2 is not on, the ECM format is establishedon MFD 1. Only the spin indicator format can override the ECM format. The ECM format can also be selectedmanually by pushbuttonselection.The ECM legendappearson all MFD formats above PB 17. When selected,the legend is boxed. PressingPB17 with ECM boxed returns the previous format to the display. For further information, refer toNAVAIR Ol-F14AAD-IA. 2.33.9.2 Warning/Caution/Advisory, System Message, and Advisory Formats. Warning/ caution/advisory indications and data-link advisory readouts appearas overlays on displays as required. Figure 2-105showsthe locations of theseoverlaysand describestheir control laws. Waming/caution/advisoty indications are displayed on the MFD in the upper left readout, and data-link JTIDS advisoriesaredisplayed in the upper right readout, The readoutshave the capability to presentup to four indicationsat a time with eachindication consisting ofup to eight charactersin length. When more thanfour indications aredesignatedfor display within a readout, the indicationswill cyclically scroll up from the bottom at a rate of one indication per second.The warning/ caution/advisory indications are capable of being acknowledgedand removedfrom the display whereasthe data-IinkLITIDS advisories are not acknowledgeable. When a warning/caution is displayed, the MASTER CAUTION light flashes and the READ MFD caution lights come on. Systemsmessagesaregeneratedby the mission computer to alert the crew of system conditions. Two categories of system messagesare displayed: computer messages(thosethat can appearon any MFD format), and OBC messages(those that can only appearon the OBC andmaintenancecurrent-failuredisplay formats), The OBC and maintenance current-failure display formats are capable of supporting both categoriesof system messagessimultaneously. The messagesare
2-189
ORIGINAL
NAVAIR Ql-FlUAD-1
FUNCTION
SYMBOL 0
0 @
@
0
@
Airspeed scale
Presents indicated airspeed in knots on a vertical tape.
AOA scale
Presents angle-of-attack
Altitude scale
Presents altitude in thousands of feet on a vertical tape. The display flashes when altitude is below 10,000 feet MSL.
Engine stall indicator
Displays either R STALL on right side of MFD or L STALL on left side of MFD to indicate a stalled engine.
Spin arrow
Displays an arrow pointing either left or right indicating
Yaw rate scale
Moving carat indicates yaw rate in degrees per second against a stationaty scale.
in units on a vertical tape.
Figure 2-104. MFD Spin Indicator Display
ORIGINAL
2490
direction of spin.
SYMBOL
FUNCTION The warning/caution/advisory readout is referred to as the CAW box. The CAW box is selected on and off via PB6. When the CAW box is not displayed, the CAW select legend is displayed and boxed (CAW). The CAW box displays warning messages steady and bright, cautions at normal intensity flashing at a 3 Hz rate, and advisories at normal intensity and steady. If the caution is displayable in the pilot cockpit, pressing the MASTER CAUTION light causes the caution message to become steady.
0
0
Computer
Data IinwJTlDS readout
message
advisory
The first row of ASCII characters is used to display the computer messages for all display formats. See figure 2-61.24 for a listing of these messages. Provides display of data link/JTlDS advisories. The data link JTIDS advisory indications are not acknowledgeable. Indications that will be presented on the HUD and MFD and their logic are described in NAVAIR Ol-F14AAD-1A.
Figure 2-105. MFD WamingKaution/AdvisoIy and MessageOverlays (Sheet1 of 2)
2-191
ORIGINAL
NAVAIR 0%F14AAD-I
SYMBOL _....--@
0
The second row of ASCII characters is used to display the OBC messages on the OBC and maintenance current failure formats. See figure 2-81.24 for a listing of these messages.
OBC messages
Acknowledge pushbutton
FUNCTION
I
(ACK)
The ACK pushbutton legend appears whenever a system message is displayed. When the ACK pushbutton is pressed the message will be removed from the MFD. System messages must be acknowledged before new messages can be displayed.
Figure Z-105. MFD Warning/Caution/Advisory and MessageOverlays (Sheet2 of 2) displayedon the upper center portion of the MFD and consist of two rows of 19 ASCII characters,each row displaying a categoryof systemmessages.Systemmessages (Figure 2-106) appear as required on the MFDs.They may be computeror OBC messages.When a system messageis displayed an ACK (acknowledge) legend appearsabovePB20. System messagesremain displayed until tbe ACK button is pressed.Should a subsequentmessagebe sentwhile one is alreadybeing displayed, the first must be acknowledgedbefore the next will be displayed. 2.33.9.3 Alphanumeric (Data) Formats. Many MFD formatshaveno symbols,but ratherdisplaynavigation, alignment, weapon,avionics, and diagnosticdata. Takeoff andlanding checklii may alsnbe selected.Use of such formats is explainedin the chapterwhere it pertains.Data formats m identified by titles displayedjust below the upperpushbuttonlegends.When a format is selected,its pushbuttonlegendis boxed. The following paragraphshi theseformats and how they anzse lected.Figure 2-107showsa typical finmat 1. RECON DATA - This format pe.rmitaselection of reconnaissancewaypoint and steering mode (point--point, commandedcourse,map) to waypoint; displays selectedwaypoint and mission data;and displays camerastatus.It is selectedvia PBS~mformatsMENU2,RECONWPTDATA 1 and RECON WPT DATA 2. 2. RFCON WPT DATA 1 - This format displays waypoint information for waypoints 1 through 10 aswell as latitude,longitude,andaltitude information for theselectedwaypoint.It is selectedvia PB7 (R-l) from formats RECON DATA and RECON WPT DATA 2.
2-192
3. RECON WPT DATA 2 - This format displays waypoint information for waypoints 11through20 as well as latitude, longitude, altitude information for the selectedwaypoint It is selectedvia PB9 (R-2) from formats RECON DATA and RECON WPTDATA 1. Note See Chapter 22 for more information on recommissanceformats. 4. TAKEOFF CHECKLIST - This format lists the items to be checked before takeoff it is selected via PB9 (CHKLST) and PB7 (T/O) on the LANDING CHECKLIST format. 5. LANDING CHECKLIST - This format lists the items to be checked before landing; it is selectedviaPB7 (LDG) ontheTAKEOFP CHECKLIST format. 6. OWN A/C formata - These formats consist of basic, ground, CVA (carrier align), and IFA (inflight align). OWN A/C basic displays own-ship data such as latitude, longitude, altitude, groundspeed,magnetic variation, true airspeed,navigation quality, wind speedand direction, barometer (altimeter) setting, and true heading. The other OWN A/C formats are alignment related and add alignment information to the basic format, including an alignment quality indicator scale. These formatsareselectedviaPBl(DATA)onMENUI, VDI, HSD, NAV AID, and SAHRS ALIGN formats. The format displayed dependson the alignment mode. As transitions occur between alignment modes,the formatswill automaticallychange. On MFD 3, an alignment or INS mode transition will causethe current format to be replacedby an OWN A/C, CV DATA, or IFA format.
NAVAIR 01.Fl4AAQ-1
COMPUTER
MESSAGE
PRIMARY MFD
SECONDARY -
NOT OPERATIONAL
(Note 7)
WAYPOINT INVALID
(Note 7)
TCN STEER INVALID
(Note 9)
SEL TACAN STEERING
(Note 7)
-
(Note 7)
-
TEST COMPLETE-GGGGG
(Note
1)
PREFLT OBC COMPLETE
I,3
2 (Note 8)
INFLT OBC COMPLETE
183
2 (Note 8)
ALIGN SUSPENDED
183
2 (Note 8)
RETEST COMPLETE
I,3
2 (Note 8)
OBC SEQ ABORTED
I,3
2 (Note 8)
RETEST ABORTED
183
2
OBC FAIL DETECTED
I,3
2 (Note 8)
INVALID ‘A’WWWW LOAD (Note 2)
I,3
2 (Note 8)
MC1 ERROR CODE XX
I,3
2 (Note 8)
I,3
2
(Note 3)
MC2 ERROR CODE XXX E BLOCK ADD SSSS (Note 4)
3
E FLYCH ADD SSSS
3
FLYCH EXISTS SSSS
3
E TRAP ADD SSSS NN (Note 5)
3
E 4 TRAPS SSSS NN
3
E TRAP VAR SSSS NN
3
E TRAP ALGO SSSS NN
3
E FLYCH INC SSSS
3
N FLYCH IN SSSS
3
E FLYCH DEC SSSS
3
NO TRAP NO. SSSS NN
3
TRAP TRU INB SSSS NN
3
ILS STEER INVALID
(Note 9)
ACL STEER INVALID
(Note 9)
D/L STEER INVALID
(Note 9)
TACAN NOT AVAIL
(Note 7)
SET PARKING BRAKE
I,3 3
NO IFA/NO VEL
(Note 8)
(Note 8) -
2 (Note 8) -
32 PLOTLINE DEFINED
3
-
E NOT AVAIL SSSS
3
-
DEST STEER INVALID
(Note 9)
-
MAN STEER INVALID
(Note 9)
-
DATA REQUIRED PILOT OBC DISABLE
MFD
13
2
1
2
Figure 2-106. Computer andOBC Messages(Sheet 1 of 4) Z-193
ORIGINAL
NAVAIR Ol-F14AAD-1 COMPUTER
MESSAGE
I
PRIMARY MFD
1
SECONDARY
t,3 3
2 (Note 8)
3
2
INVALID PLOT WPT VIDEO REC NOT AVAIL
3 3
2 -
VlDEO SWITCH ERROR
3
-
VIDEO REC LOST
3
-
(Note 9)
-
INTERLOCK ABORT RDR ALLOTMENT GFL CHALLENGE
IFF
ECM DATA INVALID
2
1,3 (Note 9) 3
2 (Note 8) -
ASPJ CFL GO TO SA ASPJ CFL GO TO PH
3 3
-
ASPJ CFL GO TO SD
3
-
ASPJ CFL
3
-
BAD RWR LOAD RDR CFL
3,t 3
AAAAA ALGN COMPL (Note 6) GB-NORM GB-INIT
ALIGN
GB-SLEW GB-CARD
ALIGN
MFD
2 (Note 8) -
3
-
3
-
3
-
GB-GND
CAL COMPL
3
-
GB-SEA
CAL COMPL
3
-
NO AIC - DSS LOAD
3
2 (Note 8)
NO AIC - NET ENTRY
3
2 (Note 8)
NO AIC - XMIT MODE
3
2 (Note 8)
NO AIC - NO RESPONSE
3
2 (Note 8)
NO AIC - REQ DENIED
3
2 (Note 8)
JTIDS NOT AVAIL
3
2 (Note 8)
NO LOAD - NEED DSS
3
2 (Note 8)
NO LOAD - DSS FAIL
3
2 (Note 8)
LOAD ERROR - JTiDS
3
2 (Note 8)
JTIDS FAIL DETECTED
3
2 (Note 8)
MCS FULLUP ENTERED
3,t
2 (Note 8)
MCS FULLUP AVAIL MCS COLD START
3,l 3,1
2 (Note 8)
NO CHNG RECON WPTS
I,3
2 (Note 8)
Figure 2-106. Computerand OBC Messages(Sheet2 of 4)
ORIGINAL
2.194
2 (Note 8)
NAVAIR 9%Fl4AAD-l
COMPUTER
MESSAGE
1
PRIMARY MFD
I
SECONDARY
MFD
dotes: 1) through (6) indicates the range of the ADVISORY DATA from the application :orresponding ASCII strings:
(1)
GGGGG 1 2 3 4 5 6 7 6
(2)
AUX CD CNI FLT NAV Ew TAC IRST
:3)
xxx
;4)
ssss
wkvwvw
1 MC1 2 MC2 4 DEU 5 MDSl 6 MDS2 7 RDR 6 au 9 SAHR IO SMS 11 ADAC 12 DSS 13 ASPJ I4 PWR 15 IRST 16 SDIS 7) The MFD these messages are presented on is the MF is received or on other MFDs when unique display co, 6) MFD 2 is secondary
5)
NN
6)
-
function and the o-999
6 8 9 10 11 12 13 15 16 17 18 o-99
MDSI CIU DEU MC1 MDS2 ADAS SMS MC2 IRST
1 2
INS SAHRS
from which the pushbutton itions exist.
SDIS JTIDS
causing the message
only when MFD 1 fails.
9) These computer messages are displayed on all MFDs displaying a VDI format. If no VDI format is displayed on MFD 1 and MFD 2, this computer message is displayed on MFD 1 (provided no repeat format is displayed) with MFD 2 as a secondary when MFD 1 fails.
Figure Z-106. Computer and OBC Messages(Sheet3 of 4)
2195
NAVAIR 01-Fl4AAD-1 COMPUTER
OBC/CSS
Messages
PRIMARY
MESSAGE
Removed
MFD
SECONDARY
MFD
After 3 Seconds
WOW NOT SATISFIED TAS NOT SATISFIED MULTI INTLK NOT MET EQUIPMENT CONFLICT NO COMMAND BIT OBC SEQ IN PROGRESS RETEST IN PROGRESS
OBC/CSS
Messages
Removed
When Condltlon
Change
MASTER TEST NOT SET HANDBRAKE NOT SET
Figure 2-106. Computerand OBC Messages(Sheet4 of 4) 7. CV DATA formats - These formats consist of CV MAN DATA andCV SINS DATA. Data presentedis similar to OWN A/C except that it includes additional information from manual entry or the ship’s SINS. Theseformats areselectedvia PB3 (CV) on OWN A/C CVA and SAHRS ALIGN formats.The format displayeddependson whether or not data link is providing SINS data. PB5 (MAN) on the CV DATA format togglesbetween MAN and SINS. 8. IFA --ZcThis format presents similar data to OWN AK! and also provides for selection of inflight alignment. It is selectedvia PB4 (IFA) on the OWN A/C IFA format. 9. WPT DATA - This format displayslatitude,longitude, and altitude data for the 100 systemwaypointsaswellasown-sircraftandCVAINS/SAHRS data.It is selectedvia theWPTS PB (PB6) on anyof the own-aircraftformats.It is alsoautomaticallydisplayeduponselectingENT on the surfacewaypoint format.The format consistsof 10pagesthatpresent 10 waypointseach.The pagesare selectedvia the “<-” and“ ->” PBS(PB9 andPB 10). 10. INS UPDATE - This format is used to update and correct INS information. Update datamay be selectedvia radar, tacan, visual sighting, JTIDS, or HUD hooking. The format is selectedvia PB13 (LJFDT) on the HSD founats as well as PB15 (SWP) on the SURFACE WPT format. ORIGINAL
2-196
11. SURFACE WPT - This format permits the creationofnew waypointsortheupdateofexisting waypoints. It is selectedvia PBl5 (SWP) on the INS UPDATE format. 12. NAV AID formats - The NAV AID formats, which consistofNAV AID OPTIONS, NAV AID CORRECTIONS, and NAV AID ENABLE, permit updating of navigational information for greateraccuracy.The formatsareselectedvia PB2 (NAV) on the HSD, OWN A/C, CV DATA, or IFA formats.The format displayeddependson the selection or deselectionof alignment mode, continuous data source,and whether ENABLE (PB8 on NAV AID CORRECTIONS) was previously selected.PB7 (GEO/REL) is usedto selectwhich JTIDS navigation datais usedfor track corrections and continuousposition updates. 13. SAHRS ALIGN formats - These formats WI-IRS ALIGN (NORM, h4AG, and SHDG) and SAHRS ALIGN (CV), permit selectionof datato be used in SAHRS alignment. They are selected via PB2 (NAV) on the HSD, OWN A/C, CV DATA, or IFA formats. The format presenteddepends on alignment mode selection and SAHRS test status.Also, the display automatically transitions to a SAHRS ALIGN format from a NAV AID format when align mode changesfrom none or IFA to an alignment mode.
NAVAIR Of-F14AAD-1
Figure Z- 107. Typical MFD Alphanumeric Format
on all OBC formats to inform the crew of the progressof the alignment while tests are being performed.
Note
Referto Chapter20, for more infommtion on navigationrelated formats. 14. MISSILE SUBSYSTEM formats - Two formats display the status of the missiles; refer to NAVAIROl-F14AAD-1A. 15. OBC formats - There are 10 OBC formats. They areusedto initiate BIT of the avionics equipment and to display test results. OBC basic presentsan overall view of subsystemtest resultsand allows for selectionof the other OBC formats. It is selectedvia PB8 on the MENU1 format. It may also be selectedTom the other OBC formats by pressingthe pushbuttonfor the boxed legend (the format being displayed).The legendson OBC basic show which groupsof subsystemsmay be selected. The OBC subsystem formats display failures to the WRA level. A WRA legend is brightly displayedwhen awaiting test, is flashing during test, and is displayed at normal brightness after test. An alignment quality indicator appears
2-197
16. MAINTENANCE - Displays a list of current WRA failures. It is selected via PB9 (FAULT) on the OBC formats. It is also selectedvia PB3 (FHF) on the FAILURE HISTORY FILE andPB4 (CSS) on the COOPERATIVE SOFTWARE SUPPORT format. These legends appearboxed before selection. 17. FAILURE HISTORY FILE - The FHF format lists the WRA failures, the type of failure, if this information is available to the MCS, and the time of up to 10 failure occurrencessince the file was cleared.This format is available via PB3 @-IF) on the MAINTENANCE and CSS formats. 18. COOPERATIVE SOFTWARE SUPPORT The CSS format is a diagnostic tool that can be used by maintenancepersonnel to troubleshoot systemandWRA anomalies.It is selectedvia PB4 (CSS) on the MAINTENANCE andFIG formats.
ORIGINAL
NAVAIR 0%F14AAD-1
Not6 Chapter38 includes a complete description of the OBC, MAINTENANCE, FHF, and CSS formats with a discussion of their use and interpretation.
barometricpressuresetting, etc. Figure 2-108 identifies anddescribesTLN symbol functionsin varioussteering and tracking modes. The last example in Figure 2-108 illustrates VDI declutter. Refer to Figure 2-108 for a listing of symbols available on VDI TLN formats in normal anddeclutter modes.
19. IRSTS SUMMARY - This format, which is used in conjunction with other IRSTS formats, provides information on the hookedIRSTS target. It can be selectedvia PB13 (SMY) on the IRSTS NORMAL and IRSTS CSCAN formats. 20. JTIDS DATA formats - There are four alphanumeric JTlDS data formats. They are the OWN A/C DATA, F-14D PPLI, Non-F-14D PPLI, and TARGET formats.The OWN A/C format displays own-ship PPLI data and JTIDS status.The PPLI formats display the data received for the hooked PPLI. The TARGET format displays dataassociatedwith a hookedtarget(radar,IRST, or ITIDS). The PPLI andTARGET formats areavailablefor a hooked symbol on either the TSD or TID. 2.33.9.4 VDI Formats. The VDI presentation on the MFD provides essentially the same information as that displayed on the HUD. However, in order to more easily distinguish between ground, horizon, and sky, shadingsimulation is used.The format is generatedby internal raster scanning with the sky being presented lighter than the ground. VDI formats consistof TLN basic,TLN AWL, TLN data link, TLN destination, TLN manual, TLN tacan, A/A basic, A/A Phoenix search,A/A Phoenix track, A/A Sparrow search, A/A Sparrow track, A/A Sidewinder search,A/A Sidewinder track, A/A gun, A/G, and TWS and recon overlays. 2.33.9.4.1 VDI TLN Formats. With TLN selected onthe PDCP (TLN MODE button depressed),selecting VDI via PBS on theMENU1 or RECON DATA formats presentsone of a number of TLN formats on the MFD 6om which the selection was made. The format displayedwill dependon whethera steeringmodehasbeen previously selected. Initially TLN basic, the MFD 1 default format, is usedto selectthesteeringmode.When any steeringmode (all weatherlanding, tacan,destination, data link, or manual) is selected,formats on both the HUD and MFD changeto accommodatethe selection. These other VDI TLN formats have pushbutton selectionsto changethe steeringmode. When steering is selected,a heading command scale is addedas well as steering aids such as steering vectors, indicators, range,and breakaway symbols. There is one level of declutteron VDI formats that addsa waterline symbol and removes information such as airspeed, altitude, ORIGINAL
2.33.9.42 VDI Air-to-Air (WA) Formats. With A/A selectedonthePDCP (A/A MODE buttondepressed), one of a numberof VDI A/A formatswill appearwhenVDI is selectedon au MFD Tim theMENU1 or RECON DATA format The actual format that is presenteddependson which weaponhas been selected.With no weapon selected,the A/A basic format is presented.Most symbols arecommon betweenVDI formatsandhavebeenshown in Figure 2-109.Figure 2-110describesadditionaltatget symbologyanddatathat is providedin VDI A/A formats. Unlike HUD A/A formats that have unique search symbols dependingon weapon selection,all VDI A/A searchformatsareidentical exceptfor theweaponselect legends.VDI basic, gun, and missile track formats add a steering“T,” rangebar, and target aspectsymbols as well as target range, altitude, and closing velocity and DD selected range digital information. The missile tracking formats also add maximum, optimum, and minimum rangesymbols to the rangebar and an allowable steeringerrorcircle. Figure 2-111 lists the symbols available on VDI A/A formats. 2.33.9.4.3 VDI Air-to-Ground (A/G) Formats. When MI is selected from the MENU1 or RECON DATA format with the A/G MODE buttonon thePDCP selected,that MFD displaysthe VDI A/G format.Unliie HUD A/G formats, the VDI A/G format doesnot have target, aiming, gun, or pulhtp information, nor doesit haveany uniqueVDI symbols otherthanthe A/G select legend. Figure 2-111 shows the A/G symbol set and Figure 2-112 showsthe format. Note In A/G mode the basic VDI symbology and format will generally be the same as TLN with the following differences: (1) selection of manual, tacan, and all-weather landing steeringmodes will not be provided; (2) the waterline referencedot and the headingand course select settingswill not be displayed; and (3) the pitch/flightpath ladder will be compressedand modified. 2.33.9.4.4 VDI Overlay Formats. The MFD VDI overlay formats are track while scan (TWS), infrared searchand tracking system-TWS (IRSTS-TWS), and reconnaissance.
2-199
NAVAIR Ql-F14AAD.1
TLN BASIC
Figure Z-108. MFD Ml Farmats -
‘kk&f,
2-199
Ladng,g,Navigstion (Sheet 1 of 9)
ORIGINAL
NAVAIR 0%F14AAD-I SYMBOL 0
0 @
FUNCTION
Heading scale
Aircraft magnetic heading is indicated by the moving 360” heading scale. In TLN, the major divisions are numbered every 10 degrees.
Heading
Actual aircraft heading is displayed
Pitch/flight
pointer path ladder
below the stationary heading pointer.
Ladder displays aircraft climb/dive angle and roll angle. Aircraft vertical flight path angle is indicated by the position of the flight path marker on the pitch/flight path ladder. Positive pitch lines are solid and negative pitch lines are dashed. To aid in determining flight path angle when it is changing rapidly, the pitch lines are angled toward the horizon at an angle half that of the flight path angle. For example, in a 40” climb, the pitch lines are angled 20” toward the horizon. UP appears at +90” and DOWN appears at -90”.
Radar altitude indicator
Displays radar altitude when the aircraft is below 5,000 ft AGL. When radar altitude is selected for display on the HUD and MFD (via the switch located on the pilot display control panel) the radar altitude indicator will be decluttered from the display.
Vertical velocity
Displays aircraft rate of climb/descent. negative (-) sign.
@)
Altitude
Barometric or radar altitude may be displayed depending on the source of data. When the ALTITUDE switch is in BARO, barometric altitude is displayed. When the ALTITUDE switch is in RDR, radar altitude is displayed and is identified by an R next to the altitude. If the radar altitude is invalid, barometric altitude will be displayed and a B next to the altitude will be flashed to indicate that barometric altitude is being displayed rather than radar altitude. The bottom of the altitude box is positioned at the waterline reference position.
0
BAR0 pressure setting pushbutton
Enables display of the barometric pressure setting used by the display system and the weapon system. Successive depression of the pushbutton will cause the setting to alternately appear and disappear.
@
Barometric setting
The barometric pressure setting used by the display system and the weapon system is the value set via pilots barometric altimeter. When the BAR0 setting is changed, the BAR0 setting will be momentarily displayed for 5 seconds after the change is made.
69
DEST steering pushbutton
Enables selection of the destination
D/L steering pushbutton
Enables selection
Course select setting
Indicates the magnetic course selected by the pilot via the COURSE knob.
DCL pushbutton
In TLN, selection of the declutter button removes the airspeed Mach number, altitude, vertical velocity and heading and course line settings, and adds waterline reference indicators. Selection of the declutter option is indicated by a box around the pushbutton.
@
0
63 0 0
pressure
Figure 2-108. MFD VDI Formats ORIGINAL
Of
Descent will be indicated by a
steering mode.
the data link steering mode.
Takeoff, Landing, Navigation (Sheet2 of 9) 2-200
NAVAIR 0%FI4AAD-I SYMBOL
FUNCTION
Bank scale
Provides indication of bank angle to 60”. Marks are provided at O”, 9, lo”, 20”, 30°, 45” and 60”.
@
ECM display pushbutton
Enables the presentation of the threat display. Once depressed, subsequent depression of the ECM pushbutton will return the display to the VOI display. This will permit a quick look at the threat display and provide a quick return to the VDI display.
0
MENU display pushbutton
Depression of menu will result in the MENU list to appear in the border area of the VDI display for subsequent selection.
Bank angle pointer
Moving pointer provides indication on aircraft bank angle. At bank angles in excess of 65” the pointer will be removed from the display.
SMS display pushbutton
Enables the presentation of the SMS display. Once depressed, subsequent depressing of the SMS pushbutton will return the display to the VDI display. This will permit a quick look at the SMS display and provide a quick return to the VDI display.
Heading select setting
Indicates the magnetic heading selected by the pilot.
TCN steering pushbutton
Enables selection of the tacan steering mode.
Ground plane
The dark shaded ground plane.
MAN pushbutton
Enables selection of the manual steering mode.
Waterline reference dot
In TLN, fixed dot appears at the optical center to denote the waterline reference position.
Horizon
Denotes demarcation between the ground and the sky. It represents the horizon with respect to the aircraft and changes orientation with any change in aircraft pitch or roll.
Airspeed
Provides display of indicated airspeed. The bottom of the airspeed box is positioned at the waterline reference position.
Mach number
Provides display of aircrafl speed in math to the nearest hundredth.
AWL steering pushbutton
Enables selection of the all weather landing (AWL) steering mode. Selection permits option to display either ACL, ILS, both or no steering information on the VDI and/or HUD.
0
63
0
53 53
53 53 @
23
@
@ 26 3
Note With VDI on MFD 3, AWL selection is possible, but deselection is inhibited.
Figure Z-108. MFD VDI Formats -
Takeoff, Landing, Navigation (Sheet3 of 9) 2-201
ORIGINAL
NAVAIR 01.F14AAD-1
@
a
SYMBOL
FUNCTION
Flight path marker
The vertical position of the flight path marker with respect to the flight path ladder indicates the vertical flight path angle of the aircraft.
Sky plane
The shaded area represents the sky.
TLN TACAN STEERING
Note The following changes or additions steering is selected.
0
0 0
Command marker
heading
Command heading marker is positioned relative to the magnetic heading scale. Where commanded heading is beyond display scale limits, the marker will be pegged at the edge nearest to the commanded heading.
Tacan range
Indicates distance to the selected tacan station.
Course arrow
The course arrow represents the pilot selected course to the tacan station. Two dots will appear on the side of the flight path marker toward the course arrow and perpendicular to the arrow. The dot closest to the flight path marker represents a deftection of 4” off course, while the outermost dot represents a deflection of 9” off course. When the aircraft crosses the selected course, the arrow moves to the opposite side of the flight path marker and the dots would appear on that side. For deviations of more than 9”, the arrow pegs. If the arrow is centered on course, the dots disappear. flight path marker centered over the course arrow indicates being on course. For tacan bearings aft of +90”, the arrow will be dashed. Box around TCN pushbutton been selected.
TLN DEST STEERING
legend indicates the tacan steering mode has
Note The following changes or additions destination steering is selected.
0
0 @
occur when tacan
occur when
Command marker
heading
Indicates the heading required to steer to the waypoint destination selected by the RIO. Where commanded heading is beyond display limits, the marker will be pegged at the edge nearest to the commanded heading.
Destination
range
Indicates distance to the selected waypoint.
iifJitFing
mode
Box around dest pushbutton mode has been selected.
Figure 2-108. h@D VDI Formats -
ORIGINAL
legend indicates the destination
steering
Takeoff, Landing, Navigation (Sheet4 of 9)
2-202
NAVAIR WF14AADI
TLN TACAN STEERING
35
-3
---
36
01
-
---
TLN DESTINATION
STEERING
(AT&F5OD-342-Z
Figure 2-108. MFD VDI Fomats -
Takeoff, Landing, Navigation (Sheet5 of 9)
2-203
ORIGINAL
TLN DATA
LINK STEERING
TLN AWL
Figure2-108.MFD VDI Formats-
ORIGINAL
STEERING
Takeoff,Landing,Navigation(Sheet6 of 9)
2-204
SYMBOL
TLN DATA LINK STEERING
FUNCTION NOW The following changes or additions occur when data link steering is selected.
0
Ezi;d
Mach
Indicates data link commanded
0
Command marker
heading
Command heading marker is positioned relative to the magnetic heading scale to indicate data link command heading. Where commanded heading is beyond display scale limits, the marker will be pegged at the edge nearest to the commanded heading.
0 @
0
@
math number.
Data link range
Indicates data link commanded
range.
;$i;d
Indicates data link commanded thousands of feet.
altitude. The two digits displayed
altitude
represent
Breakaway
Appears as a f\asb+i’~ %yr&3 in the cemel ot the display. Symbol is commanded by data link to indicate an immediate change in flight path is warranted.
D/L steering mode selection
0ti around DjLpus’nbuIton has been selected.
2-205
legend indicates the data link steering mode
ORIGINAL
NAVAIR Ql-FlUAD-1
Note
TLN AWL STEERING
The following changes or additions steering is selected. 0
0
@
c9 0
69
0
Command marker
occur when AWL
Positioned relative to the magnetic heading scale to indicate ACL data link command heading. Where commanded heading is beyond display scale limits, the marker will be pegged at the edge nearest to the commanded heading.
heading
Precision course vectors
Consist of two independent vectors (vertical and horizontal) which form a cross pointer. The horizontal vector responds to ILS glide slope error and the vertical vector responds to ILS localizer error. Null/center indications are provided to enable the pilot to null the error and keep the vertical and horizontal needles centered.
Flight Director select
The pilot’s FLT DIR pushbutton controls the display of the flight director on the HUD. The FLT DIR pushbutton legend is displayed on the AWL VDI format when valid navigation data is available and a/c vector or ACL data link mode is selected. The pushbutton will toggle between boxed and unboxed upon selection if the data link mode is ACL. The HUD flight director is displayed when the FLT DIR pushbutton is boxed if the autopilot is not engaged and MODE I control commands are being sent to the aircraft. Boxing the FLT DIR legend enables display of the flight director.
ACL steering indicator
Provides ACL steering commands
Waveoff
During carrier landings, a large X will appear flashing in the center of the display to indicate a waveofl command.
MFD AWL
display
select
driven by the ASW-27C
data link.
Permits option to display AWL (both ACL and ILS), ACL, ILS or no steering on the MFD. Initial selection of the AWL steering mode on the basic VDI format displays both ACL and ILS steering information on the MFD. This will be indicated by AWL in the box adjacent to the MFD legend. Successive depression of the pushbutton cycles AWL, ACL, ILS and no steering information on the MFD in that order. information
HUD AWL
display
select
Permits option to display AWL (both ACL and ILS), ACL, ILS, or no steering information on the HUD. Initial selection of the AWL steering mode on the basic VDI format displays both ACL and ILS steering information on the HUD. The HUD flight director is displayed when the FLT DIR pushbutton is boxed (only available when the autopilot is not engaged) and flight director commands are being sent to the aircraft. Boxing the FLT DIR legend enables display of the flight director. If the pilot intends to make a MODE I approach, he must advise the ground controller of his intentions. The ground controller will then disable the flight director commands and enable the autopilot commands, Until this is done, the pilot will not have the capability to couple the autopilot to the ACLS commands. The only information that is displayed on the HUD during MODE I approaches is the ACLS tadpole situation information and the ILS needles situation information.
Figure Z-108. h4FD VDI Fonnat~ -
ORIGINAL
Takeoff, Landing, Navigation (Sheet8 of 9)
2.206
TLN AWL DECLUlTER
,I”I.v.
. .
. .
KER
OPTION IN THE TLN AWL STEERING MODE REMOVES THE AIRSPEED. in.Y.2” ““-’ ’ ‘IUMBER, I’ ALTITUDE. VERTIC AL VELOCIN AND HEADI :NG AND COURSE LINE SElTI NGS, AND ADDS THE WATERLINE REFERENCE BARS.
-/
-_--
----
_--
---~
(AT)2-F50&342-4
FUNCTION
SYMBOL
TLN AWL DECLUlTER The waterline reference indicators are displayed indicate the fuselage reference line.
Figure 2-108. MFD VDI Fomats -
when DCL is selected and
Take&, Landing,Navigation (Sheet9 of 9)
2-207
NAVAIR
@I-F14AAD-I
FORMAT
Aircraft Readout & Box
DATA BASIC AWL LINK DESTINATION (On all formats except when DECLUTTER)
Altitude Readout and Box
(On all formats except when DECLUTTER)
SYMBOL
+l+l+
Bank Scale Baro Setting Readout #
+
+
(On all formats except when DECLUTTER)
Heading Select Point SettingHSEL, #
(On all formats except when DECLUTTER)
Heading Scale
Ground/Sky
TACAN
(On all formats except when DECLUTTER)
Course Line Setting-CSEL,
Horizon/Ground
I +
MANUAL
Plane
Texture
Ground Perspective Lines Mach Readout
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+
(On all formats except when DECLUTTER)
Pitch Ladder-VDI
+
+
+
+
Radar Altitude Readout
+
+
+
+
Flight Path Marker.
+
+
+
+
vertical Velocity Readout
(On all formats except when DECLUTTER)
Ntitude Source-S’
(On all formats except when DECLUTTER)
or ‘R
MFD Cursor
+
+
JDI Center
+
+
Caution/Advisory/Warning
+
+
Breakaway Symbol
+
0
Command
Heading marker
+
+
Command
Alt Data Link-CMD,
+
0
#
Figure 2-109. h@D VDI Symbology Available on TLN Formats (Sheet 1 of 2)
ORIGINAL
2.208
NAVAIR
0%Fl4AAD-1
FORMAT BASIC
AWL
0
0
DATA LINK +
MFD Steering Legend-AWL
+
0
MFD Steering Legend-TCN
t
MFD Steering Legend-D/L
SYMBOL Command
Mach-CMD,
#
DESTINATION
MANUAL
TACAN
0
0
0
t
+
+
+
t
t
+
t
t
t
t
t
t
t
+
MFD Steering Legend-MAN
t
t
+
t
t
t
MFD Steering Legend-DEST
t
+
t
t
t
t
MFD Steering Legend-AWUHUD
o
t
0
0
0
0
MFD Steering Legend-AWUMFD
o
t
0
0
0
0
HUD FLT DIR Legend-FLT
0
t
0
0
0
0
VDI DECLUTTER Legend-DCL
t
t
+
t
t
t
Format Select Legend-SMS
t
t
t
t
t
t
Format Select Legend-MENU
t
+
+
t
t
t
Format Select Legend-ECM
t
t
t
t
t
t
Sara PB Legend-S
+
+
t
t
t
t
PR Legend Crossouts
t
t
t
t
t
t
DIR
Waterline
(Added to all formats during DECLUITER)
ILS Precision Course Vectors
0
+
0
0
0
0
Range Readout-RNG,
0
0
t
t
0
t
ACL Steering Indicator Tadpole
0
t
0
0
0
0
Course Arrow & Deviation Dots
0
0
0
0
0
t
#
Note: ‘t’ indicates that the symbol is available for display on the selected format. ‘0’ indicates
that the symbol is not available for display on the selected format.
Figure Z-109. MFD VDI Symbology AvailaWe on TLN Formats (Sheet2 of 2)
2-209
ORIGINAL
NAVAIR Ol-F14AAD-1
A/A
SYMBOL VA Basic - Search
BASlC -
SEARCH MODE
F
FUNCTION Note In A/A search mode and no weapon selected, the ba.sicVDI symbology and format will generally be the same as TLN with the following differences: (1) selection of manual, tacan and all weather landing steering modes will not be provided; (2) the waterline reference dot and the heading and course select settings will not be displayed; (3) the heading scale numerics will be provided at 20 degree intervals, and (4) the pitch/ flight path ladder will be compressed and modified.
0 0 0
Heading scale
Aircraft magnetic heading is indicated by the moving 360” heading scale in A/A. The major divisions are numbered every 20 degrees.
Heading pointer
Actual aircraft heading is displayed
Command marker
Positioned heading.
heading
Figure 2-110.
ORIGINAL
below the stationary pointer.
along the heading scale to correspond
with the command
;I> VDI Air-to-Air and Air-to-Ground Formats (Sheet1 of 6)
2-210
NAVAIR 0%Fl4AAD-1 SYMBOL
FUNCTION
Pitch/flight path ladder
Ladder displays aircraft climb/dive angle and roll angle. Aircraft vertical flight path angle is indicated by the position of the flight path marker on the pitch/flight path ladder. Positiie pitch lines are solid and negatlle pitch lines are dashed. To aid in determining flight path angle when it is changing rapidly, the pitch lines are angled toward the horizon at an angle half that of the flight path angle. For example, in a 40” climb the pitch lines are angled 20” toward the horizon. UP appears at +90 and DOWN appears at -90. The VDI, pitch ladder will always be caged.
Radar akiiude indicator
Displays radar altitude when the aircraft is below 5,000 ft AGL. When radar aftitude is selected for display on the HUD and MFD (via the swkch located on the pilot display control panel), the radar altitude indicator will not be displayed.
Vertical velocity
Displays aircraft rate of climb/descent in feet per minute. Descent will be indicated by a negative (-) sign. Absence of the negative sign indicates a positive value.
Attitude
Barometric or radar altttude will be displayed depending on the source of data. When the ALTITUDE switch is in RDR, radar altitude will be displayed and will be identified by an R next to the altitude. If the radar altitude is invalid, barometric altllude will be displayed and a Bnext to the altitude will be flashed to indicate that barometric altitude is being displayed rather than radar altitude. The bottom of the altitude box will be positioned at the waterline reference position.
Altffude source
Indicates source of altitude data.
@
B=o;;;;;~;r
In A/A and A/G, pushbutton enables momentary display of the barometric pressure setting on the pilot’s altimeter. The setting will appear for 5 seconds each time the pushbutton is depressed. However, in TLN the barometric pressure setting will be displayed continuously on the HUD and VDI.
10 3
Barometric setting
@
0
69
0
@
53
pressure
DEST steering button
The barometric pressure setting used by the display system and weapon system is the value entered. When the baro setting is changed on the DEU in the A/A and A/G mode, the baro setting will be momentarily displayed for 5 seconds after the change is made or will appear for 5 seconds when the barometric pressure setting pushbutton is depressed. It will also appear and flash for 5 seconds when the aircraft drops below 10,000 feet, 300 knots. Enables selection of the destination
steering mode.
Figure 2-110. MFD VDI Air-to-Air and Air-toGround Formats (Sheet2 of 6)
2-211
NAVAIR 01.F14AAD1
FUNCTION
SYMBOL D/L steering pushbutton
Enables selection of the data link steering mode.
013
A/A mode selection legend
Indicates selection of the A/A mode.
@
Declutter (DCL) pushbutton
In A/A, selection of the declutter option removes the indication of airspeed, Mach number, altitude and vertical velocity from the display, and adds waterline reference indicators. Selection of the declutter option is indicated by a box around the pushbutton legend.
Bank scale
Provides indication of bank angle to *60”. ilO”, f20”, f30”, f45” and f60”.
ECM pushbutton
Enables the presentation of the threat display once depressed. Subsequent depression of the ECM pushbutton will return the display to the previous format. This will permit a quick look at the threat display and provide a quick return to the previous format.
MENU pushbutton
Depression of MENU will result in the MENU list to appear in the border area of the display. Subsequent depression of the pushbuttion will result in the alternate presentation of the MENU1 and MENU2 list in the border area of the display.
Bank angle pointer
Moving pointer provides indication of aircraft bank angle. At bank angles in excess of 65” the pointer will be removed from the VDI display.
SMS pushbutton
Enables the presentation of the SMS display once depressed. Subsequent depression of the SMS pushbutton will return the display to the previous format. This will permit a quick look at the SMS display and provide a quick return to the previous format.
0
0
63
0
63
@
Marks are provided at O”, f5”.
An X through the A/A mode selection legend indicates that the master arm switch is in the safe position.
0
0
Ground plane
The dark shaded ground plane.
Horizon
Denotes demarcation between the ground and the sky. It represents the horizon with respect to the aircraft and changes orientation with any change in aircraft pitch and roll.
Figure 2-110. MFD MI Air-to-Au andAir-to-Ground Formats (Sheet3 of 6)
ORIGINAL
2-212
SYMBOL @
@ @
G3
FUNCTION
Airspeed
Provides display of indicated airspeed. The bottom of the airspeed box is positioned at the waterline reference position.
Mach number
Provides display of aircraft speed in Mach to the nearest hundredth.
Flight path marker
The vertical position of the flight path marker with respect to the pitch ladder indicates the vertical flight path angle of the aircraft.
Sky plane
The light shaded area represents the sky.
VA Weapon
- Search
Note When a weapon has been selected for launch in the A/A search mode the basic VDI symbology and format will generally be the same as A/A search mode with no weapon selected. The selection of the missile type and quantity of ready missiles will replace the A/A mode selection legend and the master arm switch safe indication will appear as appropriate.
0
Selected weapon type and quantity indication
Indicates which missile has been selected for launch via the weapon select switch, the type and the quantity available for launch are displayed. Selections are PH (Phoenix), SP (Sparrow), SW (Sidewinder), and G (gun).
@
[zg;i:;m
An X through the weapon type and quantity indicates that the master arm switch is in the safe position.
dA Weapon
switch safe
- Radar STT
Note When a weapon has been selected for launch in the AJA radar single target track (STT) mode and the radar target is FONO 1, the basic VDI symbology and format will generally be the same as the A/A radar SlT mode with no weapon selected. Selection of a missile in radar STT will enable the display of an allowable steering error (ASE) circle, range bar and DD range scale selection.
a
Range bar
The range bar is a fixed length vertical bar range scale against which maximum, minimum and present range of the radar STT FONO 1 target may be displayed. Scaling changes are determined by DD selection. Scaling is for 200,100,50,20,10, and 5 miles. The range bar moves sideways as a function of target azimuth. The upper tic represents maximum range. The middle tic represents optimum range and the lower tic represents minimum range. The circle represents the target and moves vertically as a function of range. Target aspect is represented by a pointer which points in the direction of the aspect angle. Zero target aspect is straight down.
Figure 2-110. MFD VDI Air-to-Air and Air-to-Ground Formats (Sheet4 of 6)
2-213
ORIGINAL
NAVAIR
Ol-F14AAD-1
A/A
A/A
WEAPON
WEAPON
-
-
SEARCH
RADAR
MODE
STT MODE
Figure2-l 10. h4FDVDI Air-to-Air andAir-to-GroundFormats(Sheet5 of 6)
ORIGINAL
2-214
NAVAIR Ol-F14AAD-1
SYMBOL
FUNCTION
0
Radar SlT FONO 1 target data
Range, altitude and closing velocity of the radar Sll presented.
@
;Apble
ASE circle indicates the steering error allowed for launching a missile. Size of the circle is variable and is determined by the magnitude of the allowable error.
@
Selected weapon type and quantity indication
When missiles are selected for launch via the weapon select switch, the type and the quantity available for launch are displayed. An X through the indication will signify that the master arm switch is in the safe position.
0
~i~gs~‘e
Readout provides indication of RIO’s DD range scale selection of 5, 10,20, 50, 100, or 200 miles.
steering error
FONO 1 target will be
Figure 2-110. MFD VDI Air-to-Air andAir-to-Ground Formats (Sheet6 of 6)
SYMBOL
FORMAT PHOENIX SPARROW I BASIC SBARCH 1 TRACK 1SBARCH 1 TRACK
Aircraft Readout 8 Box
(On all formats except when DECLUTTER)
Altftude Readout and Box
(On all formats except when DECLUTTER)
Bank Scale
+l+(+l+l+
Bar0 Setting Readout
SIDEWINDER SEARCH TRACK
GUN
+
+
+
(On all formats except when DECLUlTER)
Heading Scale
+
+
+
+
+
+
+
+
Horizon Line, Ground Plane
+
+
+
+
+
+
+
+
Command
Aftllude D/L
+
+
+
+
+
+
+
+
Command
Mach
+
+
+
+
+
+
+
+
Pitch Ladder
+
+
+
+
+
+
+
+
Radar Altllude Readout
+
+
+
+
-I-
+
+
+
Flight Path Marker
+
+
+
+
+
+
+
+
Vertical Velocity Readout
(On aft formats except when DECLUlTER)
Altitude Source-B
(On all formats except when DECLUlTER)
or ‘R’
Figure 2-111. h4FD VDI Symbology Available on Air-to-Air and Air-to-Ground Formats (Sheet 1 of 2)
2-215
ORIGINAL
NAVAIR 61.Fl4AAD-1
FORMAT PHOENIX SPARROW 1 SIDEWINDER I BASIC SEARCH 1 TF~ACK 1SEARCH 1 TRACK 1SEARCH 1 TRACK (On a formats except when DECLUTTER)
SYMBOL
Mach Readout
GUN
MFD Cursor
+
+
+
+
+
+
+
+
Warning/Caution/Advisory
+
+
+
+
+
+
+
+
Breakaway Symbol
+
+
+
+
+
+
+
+
Command
+
+
+
+
+
+
+
+
NA
PH#
PH#
SP#
SP#
SW#
SW#
G#
Sky Texture
+
+
+
+
+
+
+
+
Push Button Legend-SMS
+
+
+
+
+
+
+
+
Push Button Legend-MENU
+
+
+
+
+
+
+
+
Push Button Legend-ECM
+
+
+
+
+
+
+
+
Push Button Legend-D/L
+
+
+
+
+
+
+
+
Push Button Legend-DEST
+
+
+
+
+
+
+
+
Push Button Legend-DCL
+
+
+
+
+
+
+
+
BAR0 PB Legend - B
+
+
+
+
+
+
+
+
PB Legend Crossout
+
+
+
+
+
+
+
+
Master Arm Safe Cue
+
+
+
+
+
+
+
+
Heading Marker
Select Legends, Weapon-City
Waterline
to all formats during DECLUTTER)
Steering Range-RNG,
#
0
+
+
+
+
+
+
+
+
0
+
0
+
0
+
+
0
+
0
+
0
+
+
0
-I-
O
+
0
+
0
Target Range Heading
0
+
0
+
0
+
+
Target Range Numeric
0
+
0
+
0
+
+
Target Closing Velocity
0
+
0
+
0
+
+
4/A Target Altitude
0
+
0
+
d
+
+
DD Selected Range
0
+
0
+
0
+
+
4SE Circle
0
+
0
+
0
+
0
Steering Tee Range Bar Max/Min/Opt*
Range
Note ‘+’ indicates that the symbol is available for display on the selected format. ‘0’ indicates that the symbol
* Sidewinder
is not available for display on the selected format.
does not display opt range.
Figure 2-111. h4FD VDI Symbology Available on Air-to-Air and Air-to-Ground Fomats (Sheet2 of 2) ORIGINAL
2-216
NAVAIR 01.Fl4AAD-1
(AT)Z-F50D-353-0
Figure 2-112. MPD VDX Air-to-Air (AIG) Format When FECON is selectedfrom the RECON DATA formats, reconnaissancesymbols are overlaid on the HUD and any MFD (Pigure 2-113) that is displaying a VDI format. An exception is when a weaponhas been selected,then only the MPD displays the overlay. When radar detects a valid target, a priority target diamond is overlaid on VDI formats. The diamond’s lateral position indicates the target’s position relative to own aircraft and the angular scaling is the same as the VDI A/A pitch ladder. The diamond vertical position indicates target altitude relative to own aircraft and the scaling is 10,000 feet/O.8inch. (The distance betweenpushbuttons is 0.8 inch.) A target at the horizon line would be at the same altitude as own aircraft. Up to four target diamonds may be displayed at one time. Unlike the HUD diamonds, which are sized to indicate target proximity, VDI target diamonds are the samesize. Target range in nautical miles is shown by the numbers appearing directly abovethe symbol. The radar target overlay example in Figure 2-114 shows the radar TWS mode and is overlaid on an A/A basic format.
Both target diamonds and IRSTS triangles may be overlaid at the same time on VDI A/A or A/G formats. 2.33.9.5 HSD Formats. The HSD formats provide systemnavigation information such.asmagneticheading, magnetic course, wind direction and speed,true airspeed,gro~dspeed, waypoint data,and tacandata. The HSD format family consistsof HSD waypoint, tacan, and tacan CDL Selection of PB16 from the MENU, OWN A/C, CV, IFA, WPT DATA, RECON DATA, INS UPDATE, NAV AID, SURFACE WPT, or SAHRS ALIGN formats will place the previously selectedHSD format on the MFD. After a cold start,the HSD waypoint format is shown. Figure 2-l 15describes HSD symbols.Figure 2-116 illustratesthe activation of the plot line display and showsthe selectedcourseline that appearswhen a steeringmode (m this case,destination steering)hasbeenselected
The HSD tacanformat is selectedby PB16 (HSD) if thepreviously selectedHSD format was tacan,or PBl 1 (X/Y) on HSD waypoint, or PB14 (boxedCDI) on HSD tacanCDI. Figure 2-l 17 shows HSD tacanwhen tacan When the IRSTS detectsvalid targets,JRSTS triansteeringhas not been selectedand also illustrates the gles areoverlaid on VDI formats. Position scaling is the selectedcourse line that appearsafter tacan steering selection.Tbis format allows for the selectionof tacan sameasthat of radarpriority targetdiamonds.However, sincerangecamrotbeaccumtelydeWrminedbytheIRSTS, CD1 (Figure 2-l 18) via PB14 (CDI). no rangeinformation is presentedon this overlay. Chapter20 descrii the use of the HSD formats. 2-217
ORIGINAL
NAVAIR 01.Fl4AAD-l
I
SYMBOL
FUNCTION Indicates the magnetic heading for Recon steering.
Recon Steering Symbol
Provides elevation and azimuth steering information when in reconnaissance mode. When steering symbol is coincident with flight path marker, the aircraft is flying the bank command to the dynamic steering point.
0
Target Designator, Hexagon
Displays target position. Positioned by on-board sensors or data link. When displayed on VDI formats, the degrees per inch scaling of the symbol corresponds to the scaling of the rungs of the pitch ladder of the format being overlaid (TLN. A/G, or A/A).
@
Command Ground Track Line
Displays the path of the command ground track. When displayed on VDI formats the degree scaling of rotation corresponds to the scaling of the rungs of the pitch ladder for the format being overlaid (TLN, A/G, A/A).
0
Figure 2-113. MFD VDI Recon Overlay Format
ORIGINAL
2-218
NAVAIR 0%Fl4AAP1
RADAR TARGET OVERLAY
IRSTS TARGET OVERLAY
(AT&F50D-354-O
Figure 2-l 14. MFD VDI Radarand IRSTS Overlay Formats (Sheet1 of 2)
2-219
ORIGINAL
NAVAIR
OI-WWAD-1
SYMBOL
FUNCTION
ladar Target Overlay
Note In the A/A radar track while scan (TWS) mode and no weapon selected the basic VDI symbology and format will generally be the same as A/A radar single target track except that up to 4 target priority diamonds may be displayed to show direction and relative altitude of the 4 closest radar targets. FIST TWS targets may be displayed simultaneously with radar TWS targets. When this situation occurs, the target data will pertain to the closest radar TWS targets.
a
Radar target data
Range, altitude, and closing velocity of the closest radar TWS target will be presented. Up to 4 target priority diamonds may be displayed to show direction and relative altitude of the 4 closest radar targets. The numerics above the diamonds indicate the target range to the nearest nautical mile.
RSTS Target Overlay
Note In the A/A IRST track while scan (TWS) mode and no weapon selected the basic VDI symbology and format will generally be the same as A/A radar track while scan except that up to 4 target priority triangles may be displayed to show direction and relative altitude of the 4 closest IRST targets. IRST TWS targets may be displayed simultaneously with radar TWS targets. When this situation occurs, the target data will pertain to the closest radar TWS targets.
a
@
Range, altitude, and closing velocity of the closest IRST TWS target will be presented.
Target data
::flgr
target priority
Up to 4 TWS target priority triangles may be displayed and relative altitude of the 4 closest IRST targets.
to show direction
Figure2-114.MFD MI RadarandIRSTSOverlayFormats(Sheet2 of 2)
2-220
NAVAIR
WAYPOINT. ._._.. - ____,
NON-STEEERING ._-._ -.--._..__
SYMBOL 0
@
0 @ 0
@
0
Compass
rose
Ol-Fl4AAD1
FUNCTION The compass rose is a circular magnetic scale that consists of major divisions at IO degree intervals, minor divisions at 5 degree intervals, numerics at 30 degree increments and cardinal points at 90 degree increments.
Wind
Displays wind direction in degrees and wind speed in knots.
True airspeed
Displays true air speed in knots.
Ground speed
Displays ground speed in knots.
Lubber line
The lubber line indication (diamond) is fixed at the top of the compass rose and indicates aircraft magnetic heading.
Ground track line
The ground track line rotates inside the compass rose to represent the ground track.
ADF pointer
The ADF symbol shows the direction of the nearest automatic direction finder station.
Figure 2-l 15. MFD HSD Format (Sheet1 of 3)
2-221
ORIGINAL
NAVAIR
0%FI4AAD-1
SYMBOL
FUNCTION
Heading select pointer
Displays selected or commanded heading. The symbol rotates outside the compass rose when manually controlled by the heading potentiometer knob located in the pilot’s crew station.
Tacan data
Displays the range, bearing, and time-to-go to the tacan station selected by the aircrew. This information is displayed in the readout as well as the corresponding tacan station channel number. X or Y channel may be displayed.
Tacan display option pushbutton
This pushbutton enables the presentation and activation of tacan related symbology and display options. Selection of this option enables the presentation of the tacan situation symbol, selects tacan steering mode, results in the appearance of the tacan, course deviation indication (CDI) pushbutton selection, and AWL pushbutton selection. Selection of this option will be indicated by a box around the tacan data.
Waypoint symbol
The numbers (1 to 100) adjacent to the symbol identify the waypoint and ara located on the display to provide an indkatior.of relative range and bearing from own AK.
Set pushbutton
Depression of the SET pushbutton will enable the establishment waypoint at the designated cursor position on the HSD.
@
Aircraft symbol
The stationary aircraft symbol is positioned in the center of the compass rose. The symbol in conjunction with the compass rose indicates magnetic heading.
@
Update (UPDT) pushbutton
Depression of the UPDT pushbutton format on the MFD.
Plot pushbutton
The PLOT pushbutton enables/disables the display of plotted lines between waypoints on the HSD waypoint format.
Enter (ENT) pushbutton
Depression of the ENT pushbutton enters selection of a new waypoint for destination steering. The waypoint number is selected via the waypoint number increment/decrement pushbuttons on the HSD format.
Course line setting
Indicates selected course in degrees.
Scale (SCL XXX) pushbutton
Enables range scale selection (ZOO, 100, 50, 25, and 10 nautical miles). The scale is the distance from the aircraft symbol to the inside edge of the compass rose. Successive depressions of the pushbutton causes the range scale to decrement and then start again at 200 miles.
ECM pushbutton
Enables the presentation of the threat display. Once depressed, subsequent depression of the ECM pushbutton will return the display to the previous format. This will permit a quick look at the threat display and provide a quick return to the previous format.
@
@
63
0
0
0
63
0 c3
53
enables the display of the INS update
Figure 2-115. MFD HSD Format (Sheet2 of 3) ORIGINAL
2-222
of a
SYMBOL @
0
022 0 @
0
0 26
FUNCTION
MENU pushbutton
Enables the result in the Subsequent presentation display.
presentation of the MENU displays. Depression of MENU will MENU1 list to appear in the border area of the display. depression of the pushbutton will result in the alternate of the MENU2 and MENU1 list in the border area of the
SMS pushbutton
Enables the presentation of the SMS display. Once depressed, subsequent depression of the SMS pushbutton will return the display to the previous format. This will permft a quick look at the SMS display and provide a quick return to the previous format.
Heading select setting
Indicates the magnetic heading selected.
DATA pushbutton
Enables the display of the own /VC data fonat.
Attllude source
Indicates the source (INS or SAHRS) of ownship pitch and roll angles.
NAV pushbutton
Enables the display of the appropriate determined by the mission computer.
Waypoint decrement (down arrow) pushbutton
Enables the decrement of the waypoint number of the associated waypoint data display and Is used for the selection of the waypoint for destination steering.
NAV AID or SAHRS ALIGN format as
027
WaypOint
@
Waypoint increment arrow) pushbutton
@
z:lnt
@
~~;;;~~Ww
This pushbutton enables the presentation and activation of waypoint related symbology and display options. Selection of this option enables the destination steering and results in the appearance of the plot line display selection. Selection of this option is indicated by a box around the waypolnt data.
Waypoint data
Displays the range, bearing and time-to-go to the waypoin: selected by the aircrew via the Increment/decrement pushbuttons. This information is displayed in the readout.
0
032 033
Waypoint
Indicates the selected waypoint number (via the increment/decrement pushbuttons) of the associated waypoint data display and the desired waypoint for destination steering.
number
(up
Provides bearing indication of the waypoint entered by the aircrew for destination steering.
bearing
DEST
Enables the increment of the waypoint number of the associated waypoint data display and is used for the selection of the waypoint for destination steering.
readout
Tacan bearing pointer head and tail
Provides an Indication of the waypoint number entered for destination steering. Provides bearing indication to and from the selected tacan station.
Figure 2-115.
MFD HSD Format (Sheet 3 of 3) 2.223
ORIGINAL
NAVAIR Q1-F1MAD-1
. --.
-.._--
SELECTED COURSE LINE
Figure 2-l 16. Plot Lie and CourseLine Displays (Sheet 1 of 2)
ORIGINAL
2-224
NAVAIR 0%F14WD-1 SYMBOL
a 0
0
I
FUNCTION
Plot lines
Dashed plot lines are drawn between waypoints to aid in navigation. waypoints for plotting are selected via the DEU.
The
PLOT pushbutton
Box around the PLOT pushbutton legend indicates the display of plotted lines between waypoints has been enabled.
Selected course line
The course line rotates within the compass circle and depicts the aircraft commanded course during the destination steering mode.
Figure 2-l 16. Plot Line and CourseLine Displays (Sheet2 of 2) 2.33.9.6 SMS Formats. Selection of the SMS formats may be made from any format via PB19 (SMS). DepressingPB19 a secondtime returnsthe previously selecteddisplay. This toggle action permits the crewmember to check the weapon statusquickly. The MC determinesthe wingfonn contiguration that will be displayed. The CAP/attack and fighter configurationsare shown in Figure 2-119. For SMS symbols, configurations, and phasesof launch,including an explanationof theAIM-54 MOAT and DMA results,refer to NAVAIR Ol-F14AAD-1A. 2.33.9.7 Engine Monitor Format. The engine monitor format (Figure 2-120) is selected via PB15 (ENG) on the OWN A/C formats. This format includes a representationof the aircraft engineinstruments,displaying instrument readingsfor left and right engines, fuel endurance(basedon existing conditions), and any engineexceedanceconditions. Rpm is provided asNl andtemperatureasturbine bladetemperature(TBT not EGT). Fuel flow is shown as either main (M) or total (T), dependingon power setting (either nonafterburner or afterburnerrange).This information is provided by theFEMS. Engine monitor format is not providedwhile in SEC mode. Refer to FEMS in this chapterfor additional information. 2.33.9.6 IRSTS Formats. There are three dedicatedIRSTS formats in the IRSTS format family. They are IRSTS normal, IRSTS CSCAN, and IRSTS summary (refer to NAVAIR 01-F14AAD-IA). Other IRST information and symbols appearon the HUD, VDI, and TSD formats. 2.33.9.9 TSD Format. The TSD format is chosen via the TSD legendon MENUl. The format consistsof five distinct legend setathat appearin responseto crew
MFD inputs Refer to NAVAIR 01-F14AAD-IA for a descriptionof the TSD format andassociatedsymbols. 2.33.9.10 JTIDS Data Readout Formats. Referto NAVAIROI-F14AAD-IA. 2.34 DATA ENTRY UNIT The DEU (Figure 2-121) on the RIO tight vertical consoleprovides manual dataentry and control of certain mission functions. The DEU is a remote terminal that communicateswith the mission computersvia the multiplex buses.The DEU is powered by the 28-Vdc main bus. The DEU consists of a DEU control knob, data entry display, 20 option keys, and four option display legends.The DEU control knob controls power, brightness, and the test function. The option display legendsdisplay the optionsfor the function or parameter selected.The option keys enableselectionofthe desired menu functions and entry of requiredmission parame ters.The dataentrydisplay is atwo-line display.The top line indicatesthe currently selectedparameterwhile the bottom line (scratchpad) is used to enter data. The scratchpadconsistsof a 14-characterdisplay. The characterlocations are often denotedby underlinesthat, as data is keyed in, disappear. 2.34.1 Data Entry Unit Operating Modes. As selectedby the RIO, the DEU operatesin one of two modes:slavedto the RIO muhifbnction display(MFD3) or independentof MFD3. Initially, whenthe DEU is poweredon, it defaultsto the slavemode.The slaveandindependentmodes are toggled by pressingthe SLWINDP option key. When operatingin the slavemode, the data entry displayon the main menupagemadsMENU-DEU SLV (Figure2-121).When theMFD displaysa formatto which the DEU is slaved the DEU contiguresthe cormspendingpage(Figure 2-102).However,when the MFD
2-225
ORIGINAL
TACAN, NON-STEERING
TACAN -
STEERING
Figure 2-l 17. MFD HSD TacanDisplays (Sheet 1 of 2)
2-220
SYMBOL 0
0
0
@
0
G3
3
23
FUNCTION
Tacan situation symbol
Provides indication of relative range and bearing to the tacan station from ownship.
Tacan display option pushbutton
The box around the tacan data indicates that the tacan steering option has been selected.
SET pushbunon
Pressing the SET pushbutton enables the establishment the designated cursor position on the HSD.
PLOT pushbutton
Pressing the PLOT pushbutton enables/disables the display of plotted lines between waypoints on the HSD waypoint format.
Selected course line
Moves within the compass rose to depict the selected tacan course during tacan steering.
AWL pushbutton
The AWL display is enabled by this pushbutton.
CDI pushbutton
The course deviation indicator (CDI) display is enabled by this pushbutton.
Course line setting
With the command pointer set, the CSEL readout indicates the magnetic course setting in degrees.
of a waypoint at
Figure 2-l 17. MFD HSD Tacan Displays (Sheet2 of 2) displays a format to which the DEU cannot slave, the DEU remainson whateverformat it is displaying. Gpcrating in the independentmode enablesaccessto all menu options without being a&ted by changesto the h4FD3 display.When the MENU option key is pressed, tbe main MENU pageis displayedwith the presentDEU mode displayedon the scratchpad. 2.34.2 DEU Menu Pages. TheDEUconsistsofthe following menu pages.
5. NAV AID 6. NAV GRID 7. JMD RNAV -
JTIDS relative navigation.
8. JTID COMh4 -
JTIDS communications.
10. JTIDS MODE -
JTIDS mode.
11. DOWN LOAD -
JTJDS initialization.
12. IFT -
Nontimctional.
Storesmanagementsystem. 13. PLOT -
2. OWN A/C 3. WPT -
Navigation grid.
9. JTID PPLI - JTIDS preciseparticipantlocation identification.
2.34.2.1 Main Menu Page. The main menu page (Figure 2-121) enablesaccessto the various subpages. Pressingthe desiredoption key on the main menu displays the desiredsubpage.The subpagesare asfollows: 1. SMS -
Navigation aid.
Plot.
Own aircraft. 14.
Waypoint.
CSS -
Cooperativesupportsoftware.
15. SLViINDP 4. CV ALGN -
Slave/independent.
Carrier align. 16. ALT MENU 2-227
When available. ORIGINAL
NAVAIR 01.F14AAD-1
SYMBOL
FUNCTION
a
Tacan Course indication
ndicates tacan course and deviation from tacan track.
0
Course deviation scale
Xsplays deviation from selected course. Each dot represents 4 degrees.
0
CDI pushbutton
3oxed CDI legend indicates that tacan CDI display has been selected.
Xsplays deviation from selected course against deviation scale.
Figure 2-118. HSD Tacan CD1 Format
ORIGINAL
2.228
NAVAIR Of-FI4AAD-1 CAP/ATTACK
CONFIGURATION
FIGHTER CONFIGURATION
Figure 2-119. MFD SMS Format -
WINGFORM
WINGFORM
CAP/Attack, Fighter Wingform (Sheet 1 of 2)
2-229
ORIGINAL
NAVAIR OW14AAD-I SYMBOL 0
0
03 @
0
@
0
@
@
@
;yEF
status
FUNCTION SAFE or ABM is displayed to indicate the status of the master arm switch.
Rounds remaining
Rounds remaining is indicated in hundreds (6,5, 4,3. 2, 1 and 0) by a single digit. An X will appear when the gun is empty. HI or LO indicates the rate at which the rounds are fired.
HI/LO gun rate pushbutton
Enables the selection of the HI or LO rate of gun fire. HI rate is default mode. Pressing the pushbutton will toggle rate of fire between HI and LO.
PGUlM56
Enables selection of PGU or M56 round. Pressing the pushbutton toggle between PGU and M56.
Store station numbers (lA,lB.2.3.45,6,7, 6A, and 6B)
Indicate the location of the stores (weapons aircraft.
Manual (MAN) gun mode pushbutton (A/G only)
Enables manual selection of the manual option during air-to-ground operations. CCIP mode is the primary gun mode and is obtained immediately upon gun selection. A box will appear around the pushbutton legend to indicate the manual option has been selected. Refer to NAVAIR 01-F14AAD-IA.
Missile status (MS) pushbutton
Enables the presentation
CAP/attack wingform
Wingform provides a plan view of the stores carried on an aircraft configured for the CAP/attack role.
SMS pushbutton
Box around the SMS pushbutton legend indicates the SMS display is selected. Once selected, a subsequent depression of the SMS pushbutton will enable the return to the previous display.
Fighter wingform
Wingform provides a plan view of the stores carried on an aircraft configured for the fighter role.
Figure 2-l 19. MFD SMS Format -
ORIGINAL
and fuel tanks) carried on the
of the missile status display.
CAP/Attack, Fighter Wingforms (Sheet2 of 2)
2-230
will
Figure 2-120. MFD Engine Monitor Format (Sheet1 of 2)
ORIGINAL
NAVAIR
Q1-F14AAD-I
SYMBOL
3~
I
FUNCTION
(
Rotor speed
Left and right rotor speeds (Nl) are displayed format in percent RPM. The digital indications below the corresponding analog scale.
I
3
Turbine blade temperature
Left and right engine turbine blade temperature (TBT) are displayed both in an analog and digital format. The analog scale ranges from 500 to 1200 degrees Fahrenheit. The digital indications are located immediately below the corresponding analog scale.
0
Main fuel flow
Left and right main fuel flow (FF/M) are displayed in an analog format in thousands of pounds per hour (PPH). The analog scale ranges from 0 to 17,000 PPH.
c9 Fuel endurance
Readout provides an indication of the flight time remaining in hours and minutes. The readout is based on the existing fuel supply for the selected engine condition (normal or afterburner).
I
(
both in an analog and digital are located immediately
Up to three engine exceedance conditions are capable of being displayed at a time. The indications will scroll upward at a 1 rate when more than three exceedance conditions exist. The indications may be: L/R MACH #, UR LO THR, UR A/ICE, L./R OIL LO, or UR AUG. I@
Nozzle position
0
Data pushbutton
/
Left and right engine nozzle positions (NP) are displayed in an analog format between 0 and 100 percent to indicate relative position from fully closed to fully open, respectively.
I
Enables the presentation
of the OWN A/C DATA display. Note
When afterburner condition is selected, the total fuel flow consists of main and augmented fuel. This format illustrates the afterburner condition where total fuel flow are displayed. @
Total fuel flow
Left and right engine total fuel flow (FF/T) are displayed in an analog format in thousands of pounds per hour (PPH). The analog scale ranges from 0 to 100,000 PPH.
Note Engine data is not provided while in SEC mode.
Figure 2-120. MFD Engine Monitor Format (Sheet2 of 2)
ORIGINAL
2-232
NAVAIR 0%F14AAD-1
0, I
0
MENU - DEU INDP I
--------d--m----,
I8 I
OWN Aic
JTID RNAV
SW3
JTID COMM
WPT
0
0
c9
/
@
NOMENCIATURE 0
I t
FUNCTION
Data Entry Display
Displays the name of the page selected and provides a scratchpad enter and change data as required.
DEU control knob
Initial clockwise rotation past the detent turns system power on; continued rotation increases brightness of scratchpad display and option legend placarding. When depressed, a self-test of the panel is completed.
Option keys (twenty)
Enables selection of desired menu options and entry of required mission data,
Option legend
Displays the various menu options for the function or parameter Option legends vary with page selection.
Figure 2- 121. Data Entry Unit/Main Menu Page
2-233
used to
selected.
NAVAIR Ol-Fl4AAD-1
2.34.2.2 Subpages. The operating characteristics of the subpagesare as follows: Parametersrequiring input often have associatedlimits and qualifiers. Data entry parametersam shown in Figure 2-122. All data input left to right is validated characterby character. This includes the parameterof latitude, longitude, and time. Data input from right to left is validated upon depressionof the ENT option key. When latitude and longitude are input t?om left to right, leading zeroes must be entered but trailing zeroes for minutes and minute tractions arenot required.Keying additional numerics after the dedicatedcharacterlocations are tilled will not changethe initial keyed-in data.The applicable east,west, north, or south (E, W, N, S) can be keyed in before, during, or after numerical dataentry The backspaceoption key (BKSP) is used to deletedata in the reverseorder of entry.The return option key (RTN) is usedto display the next higher level pagein the branch category.
needlesandtheturn-and-slippointer deflectsto theright and lines up with the fucedmarker.
2.35 FLIGHT INSTRUMENTS
2.35.3 Standby Altimeter. Both the pilot and RIO standbyaltimeters display altitude up to 99,000 feet on the five-digit counter,but only the left two digits are moveable. The pointer moves about a dial calibrated from 0 to 1,000feet in 50-foot increments.
2.35.1 Standby Attitude indicator. A3-inchstandby gyro horizon indicator on the left sideofthe pilot instrument panel and anotheron the left side of the RIO instrumentpanelare for emergencyuseshouldthe system (INS or SAT-IRS)attitude information become unreliable. It is a self-contained,independentgyro that displays aircraft roll and pitch from the horizontal and includes a standardturn-and-slipindicator. The presentation consists of a miniature aircraft viewed against a rotating gray and black background, which represent sky and ground conditions, respectively. Caging should be accomplished at least 3 to 4 minutes beforetakeoff to allow the spin axis to orient to true vertical. After the gyro has erectedto vertical, the miniature aircraft referencemay be raised or lowered +5O,-10” to compensatefor pitch trim by turning the adjustmentknob in the lower right comer of the instrument. Electrical power should be applied for at leaat 1 minute beforecaging.The unit shouldbe cagedprior to enginestart during cockpit interior inspection.In flight, recagingshouldbeinitiated only when errorexceeds1O0 and only when the aircrafi is in a wings-level normal cruise attitude.Errors ofless than 10”will automatically erectout at a rate of 2.Y per minute. Electrical power is suppliedby the essentialac buses. An OFF flag appearson the right side of the instrument facewhen power is removedor when the gyro is caged, but the gyro is capable of providing reliable attitude information (within 9’) for up to 3 minutesafter a complete loss of power. The gyro canbe manually cagedby pulling the pitch trim knob on the lower right comer of the instrument. DepressingTEST centersthe ARA-63 ORIGINAL
2.35.1.1 Turn-and-Slip indicator. The standby attitude indicator includes a standardneedle and ball turn-and-slip indicator. The pointer is testedwhen the TEST button is pressedand it deflects to the right and lines up with the fixed marker. 2.35.2 Standby Airspeed indicator. The standby airspeedindicator on the pilot andRIO instrumentpanels is a pitot-static instrument that displays indicated airspeedfrom 0 to 800knots. The indicator is graduated in IO-knot incrementsup to 200 knots, then in 50-knot increments. Note The indicated airspeeddisplayed is not correctedfor position error.
A BAR0 settingknob, on the bottom left, is usedto set in the local atmospherepressure(TNCHES HG) between 28.10 to 30.99 inclusive. The four-digit counter displaysthe BAR0 setting.The BAR0 settingfrom the pilot standbyaltimeter is provided to the mission computers via the converter interface unit and can be displayed on the HUD and the MFDs. 2.35.4 ANIAPN-194(V) Radar Altimeter System. The radar altimeter is a low-altitude (0 to 5,000 feet), pulsed, range-trackingradar that measuresthe surface or terrainclearancebelow the aircraft.Altitude information is developed by radiating a short-durationradio frequencypulse from the transmitantennato the Earth’s surface and measuring elapsedtime until radio frequencyenergyreturnsthroughthe receiverantenna.The altitude information is continuously presentedto the pilot, in feet of altitude, on an indicator dial. The system also outputsa digital signal for display of radar altitude on the HUD from 0 to 5,000 feet during takeoff and landings. The radar altimeter has two modes of operation.In the searchmode, the system successivelyexaminesincrements of range until the complete altitude range is searchedfor a return signal. When a return signal is detected,the system switches to the track mode and tracks the return signal to provide continuous altitude information.
2-234
INPUT NAME
UNITS
LIMITS
SIGN
FIELD/PROMPT
DIR OF ENTR!
*(I)
QXXXXXX
(2) RT to LT (5)
ALTITUDE
FT
-5000 to +131071
Baro pressure
IN HG
25 to 35
NONE
xX.xX
RT to LT
Bearing
DEG
1 to 360
NONE
XXX
RT to LT
Channelnumber
1 -
lot0
127
NONE
1 XX
1 RTtoLT
Coverage
DEG
oto180
NONE
x)(x
RT to LT
Direction
DEG
1 to 360
NONE
XXX
RT to LT
Heading
DEG
1 to 360
NONE
XXX
RT to LT
Latitude
DEG. MIN
-90 to +90
S, N (3)
QbXXbXXXX
(4) LT to RT
Longitude
DEG, MIN
-180 to +1eo
W E (3)
QbXXXbXXXX
(5) LT to RT
Magnetic variation
-1eoto
W, E (3)
XXX.XbQ
RT to LT
IFT number
DEG -
0 to 31
NONE
XX
RT to LT
Waypoint number
-
1 to20
NONE
XX
RT to LT
Weapon option
-
0 to 6
NONE
X
RT to LT
Range
NMI -
0 to 500
NONE
)-00(.X -
RT to LT
1 to 6
NONE
X
1 RTtoLT
NONE
I XX
I RTtoLT
Sector Carrier speed
1 KNOTS
+I80
IOto64
IFT TGT speed
KNOTS
0 to 2047
NONE
XxXx
RT to LT
Wind speed
KNOTS
0 to 200
NONE
XXX
RT to LT
Time
HRS MIN, SEC
oto23 oto59
NONE
XXXXbXX
(4) LT to RT (5)
Vertical lever arm Map lines
FT -
Map offset
Fr
*131071
k(l)
Target length
NMI
O-2048
NONE
Command
course
1 DEG
lOto
1
oto99
I l-360
1
NONE
I XXX
NONE
Xx
RT to LT
QXXXXXX
RT to LT
xX)(x.X
RT to LT
NONE
I XXX
1 RTtoLT
I RTtoLT
Notes: (1) If a sign is not input, the number is assumed positive, (2) Prompt underscores disappear as numerics are input. Pressing ‘BKSP’ will delete a keyed-in numeric and the underscore will reappear. Continued backspacing will delete inputs in the reverse order in which they were input. If the prompt is a single underscore, it disappears upon the first keyed entry. When backspacing, it will reappear when the first keyed entry has been deleted. (3) Qualifiers ‘s’. ‘N’, ‘E’. ‘w’, ‘+’ and ‘-’ can be keyed in before, after or during keying of numeric data. ‘BKSP’ will not delete these symbols; however, they can be overwritten. The last keyed symbol will be implemented. Depression of ‘CLR’ will also reset the total scratchpad. (4) Trailing zeroes for minutes and seconds will be assumed if not entered from keypad. (5) ‘b’ implies blank or space: ‘Q’ implies qualifier (S, N, E, W, +, -).
Figure 2-122. Data Entry Parameters 2-235
ORIGINAL
NAVAIR Ol-F14AAD-1
Whenthe radaraltimeter dropsout of the trackmode, anOFF flag appearsandthepointer is hiddenby a mask. The altimeter remainsinoperativeuntil a return signalis received,at which time the altimeter will againindicate actual altitude aboveterrain. Reliable system operationin the altitude rangeof 0 to 5,000 feet permits close altitude control at minimum altitudes. The system will operate normally in bank anglesup to 45Oand in climb or dives exceptwhen the reflected signal is too weak. The system includesa height indicator (altimeter),a test light on the indicator, a low-altitude warning tone, a radar receiver-transmitterunder the forward cockpit, andtwo antennas(transmitandreceive)oneoneachside of the IR fairing, in the aircraft skin. During descent,the warning tone is heard momentarily when the aircraft passesthroughthe altitude seton the limit index. When the aircraft is below this altitude, the red low-altitude warning light on the indicator stayson. Note If radar altitude is unreliable, only the OFF flag is present. The radaraltimeterreceivespower from theac essential bus No. 1 through the RADAR ALTM circuit breaker(4B3) and from dc essentialbus No. 1 through the ALT LOW WARN circuit breaker(7B6). The radar altimeter has a minimum warmup time of 3 minutes. During this time, failure indications and erroneousreadoutsshould be disregarded. 2.35.4.1 Radar Altimeter. The radaraltimeter (FO12) on the pilot instrumentpanel has the only controls for the system. The indicator displays radar altitude above the Earth’s surface on a single-turn dial that is calibrated from 0 to 5,000 feet in decreasingscale to provide greaterdefinition at lower altitudes.The control lmob in the lower right comer of the indicator is a combination power switch, self-testswitch, and positioning control for the low-altitude limit bug. 2.35.4.2 Altimeter BIT. Depressing and holding the control knob energizesthe self-test circuitry; the green test light illuminates, the indicator reads 100 +lO feet, and the HUD altitude scale reads approximately 100 feet. If the indicator passesbelow the altimeter limit bug setting, the aural andvisual warnings are triggered. Normal operation is resumedby releasing the control knob. 2.35.4.3 Low-Altitude Aural Warning. A lowaltitude aural warning alarm provides a 1000Ha tone, ORIGINAL
modulated at two pulses per second,lasting for 5 seconds.The tone is available to both crewmemberswhen the airwail descendsbelow the altitude set on the lowaltitude limit bug. 2.35.5 Vertical Velocity indicator. The wrtical velocity indicator on the left side of the pilot and RIO instmment panel is a sealedcaseconnectedto a static pressureline through a calibrated leak. It’indicates rate ofclimb or descent.Suddenor abruptchangesin attitude may causeerroneousindicationsbecauseof the sudden changeof airflow over the static probe. 2.35.6 Standby Compass. A conventionalstandby compassis abovethepilot instrumentpanel.It is a semifloat-type compasssuspendedin compassfluid. 2.35.7 Clock. A mechanical 8&y clock is on the instrumentpanel in eachcockpit. It incorporatesa l-hour elapsed-timecapability. A winding and settingselector is in the lower left comer of the instrument face. The knob is turnedin a clockwise direction to wind the clock and pulled out to set the hour and minute hands.An elapsedtime selector in the upper right comer controls the elapsedtime mechanism. This mechanism starts, stops, and resetsthe sweep second and elapsedtime hands. 2.36 ANGLE-OF-ATTACK
SYSTEM
The AOA system measuresthe angle betweenthe longitudinal axis of the aircrat?and the relative wind. This is usedfor approachmonitoring andto warn of an approaching stall. Optimum approach AOA is not affected by gross weight, bank angle, density altitude, or load configuration (see Figure 2-123 for AOA conversions). The system includes a probe-type transmitter, approachlights, an indicator, and an indexer.The indexer and approach lights are controlled by the indicator, which is electrically slavedto the sensorprobetransmitter. In flight, the probe, which is on the left side of the fuselage, aligns itself with the relative airtlow like a weathervane. Probe anti-icing is provided by meansof a 115-Vat heatingelementalong theprobeandprobehousing.The heating element is controlled by the ANTI-ICE switch on the pilot right console. During ground operation, probeheat is on with the landing gearhandledown and the switch in ORIDE/ON. With weight on wheels,the position OFF/OFF andAUTO/OFF deactivatetheprobe heatingelement.
NAVAIR Ol-F14AAG-1
SEA LEVEL
10
0
Figure2-123.Angle-of-AttackConversion (Sheet1 of 2)
2-237
ORIGINAL
NAVAIR QI-FUAAD-I
DATE JAN”ARY 1974 DATA BASIS: FUGHT TEST
SEA LEVEL INDICATED PRESSURE ALTITUDE 35,000 FEET
AlRCRAFT CONFIO”RATION: FLAPS,?.LATS UP,OEAR UP.SPEED BRAKES RETRACTED - cmc OPERATIONAL 14, AIM-7F
Figure 2-123. Angle-of-Attack Conversion(Sheet2 of 2)
ORIGINAL
2.238
NAVAIR Ql-Fl4AAD-l
2.36.1 AOA Test. A safety of flight check of the AOA indicator and other aircratt instruments can be performedwhile in flight or on the deck when INST is selectedon the pilot’s MASTER TEST switch, the referencebar on the AOA indicator should indicate 18.0 33.5 tits. A check of the indexer can be made by selectingLTS on the MASTER TEST switch.
illuminated by coloredlamps to provide approachinformation. The relay-operatedcontactsin the AOA indicator alsocontrol theAOA indexer.The upperarrow is for high AOA (green),the lower arrow is for low AOA (red),andthecircle is for optimum AOA (amber).When both an arrow and a circle appear,an intermediateposition is indicated.
2.36.2 AOA Indicator. This indicator (Figure 2124) displays the aircraft AOA and provides a stall warning referencemarker,a cliib bug, cruise bug, and an AOA approachreferencebar for landing approach.
2.36.3.1 Indexer Lights. The indexer lights function only when the landing gear ham-lieis down. A flashertit causesthe indexerlights to pulsatewhen the arrestinghook is up andthe HOOK BY-PASS switch is in CARRIER. The intensity of the indexerlights is controlled by the INDEXER thumbwheel control on the pilot MASTER LIGHT panel.
AOA is displayedby a vertical tape on a calibrated scalefrom 0 to 30 units, equivalentto a rangeof -10’ to +40° of rotation of the probe. The approachreference bar is providedfor approach(on speed)AOA at 15units. The AOA indexer and approach lights will automatically follow the indicator. Theclimbreferencemarkerissetat5.0unim,thecmise markerat8.5uoits,andtbestallwamingmarkerat29unitp. Thesereferencemarkersam presetto the optimum AOA valuesandcannot be changedby thepilot. 2.36.3 AOA Indexer. The AOA indexeron the pilot glareshield(Figure 2-124) has two arrows and a circle
2.36.4 Approach Lights. The approachlights consist of red, amber,and greenindicator lights abovethe nosegearstrut. The lights are actuatedby the AOA indicator andprovide qualitative AOA information to the landing signal officer during landing approaches.A flasherunit in the AOA system will causethe approach lights to pulsatewhen the arrestinghook is up with the landmg geardown and the HOOK BY-PASS switch is in the CARRIER position. When the FIELD position of the HOOK BY-PASS switch is selected,the flasherunit is disabled.
ANGLE-OF-ATTACK INDICATOR
Figure 2-124. Angle-of-Attack Displays 2-239
ORIGINAL
NAVAIR Ol-Fl4AAD-l
A green approachlight indicates a high AOA, slow airspeed,an amber light indicatesoptimum AOA; and a red approachlight indicatesa low AOA, fast airspeed. 2.37 CANOPY SYSTEM The cockpit is enclosed by a one-piece,clamshell, rea&nged canopy. Provisions are included to protect the pilot and RIO Born lightning strikesby the installation of aluminum tapeon the canopyabovethe headsof the crew. Normal opening and closing of the canopyis by a pneumatic and hydraulic actuatorwith a separste pneumaticactuatorfor locking and unlocking. The csnopy can be openedto approximately 25” for ingressand egressin approximately 8 to 10 seconds.In emergencies, the canopy can be jettisoned t?om either crew position or externally from either side of the forward fuselage.For rescueprocedures,seeparagraph12.1.6.
The maximum permitted taxi speed and headwind component with the canopyopen is 60 knots. Note An occasionalhowl inside the canopy may occur in some aircraft when subjectedto an approximate 4g maneuver. The howl has beenattriiuted to thecanopyrain seals;when they are removed the howl disappears.A canopy howl in aircraft with rain seals installed doesnot limit aircraft operation.
pressuregaugein the nosewheelwell shouldbe checked during preflight. A fully chargednitrogen bottle pmvides approximately 10 complete cycles (open and close) of the canopy before the system is reducedto a minimum operatingpressureof 225 psi. If pneumatic pressuredropsbelow 225psi, the canopyconnol module automaticallypreventsiiuther depletionof themainreservoirandthecanopymustbe.openedbytheauxiharymoda. 2.37.1 Canopy Operation 2.37.1.1 External Canopy Controls. Access to theexternalcanopycontrol is obtainedthroughau access dooron the left titselagedirectly below theboardingladder.Pullingthehandleoutandroratingitcounterclockwise to NORM CL closesthe canopy.Rotatinghuthercounterclockwise to the BOOST close position will allow the canopy to be closed under a high headwind or coldweatherconditions.If BOOST is usedto closethecanopy, the handleshould be returnedto NORM CL. Rotatingit clockwiseto . NORM OPEN opensthecanopyundernormal opemtmg conditionsand rotating it furtherto AUX OPEN allows the canopyto be openedmanually. Note NORM OPEN is not detenti, therefore,do not rotate.thehandlefurtherclockwise unless the AUX OPEN position is desired. Using AUX OPEN unnecessatilywill depletethe auxiliary uplock nitrogen bottle.
The canopy system is controlled with the canopy control handle under the right forward canopy sill at eachcrew position. An external canopycontrol handle is on the leg side of the fuselage directly below the boarding ladder. A CANOPY caution light on the RIO CAUTION ADVISORY panel illuminates when the canopyis not locked.A LADKNPY cautionlight onthe pilot CAUTION ADVISORY panel illuminates when the canopy is not locked or the ladder is not stowed. Electrical power for the caution lights is suppliedfrom the essential dc bus No. 2, through the CAN/LAD/ CAUTION/EJECT CMD IND circuit breaker(8C5).A l-inch by 2-inch white stripe is painted on the canopy hame and sill above the canopy control handle panel. Alignment of this stripe provides an additional visual guide that the canopyis in a closed-and-lockedposition.
2.37.1.2. Cockpit Canopy Controls. The canopy pneumaticandhydraulic systemis operatedby actuation of either of the cockpit control handles(Figure 2-125), or the external control handle, which positions valves within the pneumatic control module to open or close the canopy.The canopypneumaticandpyrotechnicsystems areshown on FO-15. Modes of operationavailable are:OPEN, AUX OPEN, HOLD, CLOSE, andBOOST.
Pmmatic pressurefor normal canopy operationis storedin ah&h-pressure,dry-nitrogenXW-VO~sticing is accomplishedexternally throughthe nosewheelwell. Normal pressure should be serviced to 3,000 psi. A ORIGINAL
2-240
Flightcrews shall ensurethat handsand foreign objects are clear of front cockpit handholds, top and sides of ejection seat headboxes, and canopy sills to prevent personal injury and/or structural damageduring canopy opening or closing sequence.Foreign objects can catch ejection system initiators on the right aft side of the ejection seatheadboxescausinginadvertentejectionevenwith seat locking handles safe. Only minimum clearanceis affordedwhen canopyis trausiting fore or aft.
NAVAIR Ol-Fl4AAD-1
NOMENCLATURE
FUNCTION
a
CANOPY caution light (RIO)
Advises RIO canopy is not in a down and locked position.
0
$gyy
Advises pilot boarding ladder is not in the up and locked position or that the canopy is not in the down and locked position.
0
0 @ 0 c9
0
caution
BOOST
Used to close the canopy in cold or hot weather or when headwinds greater than 30 to 60 knots.
CLOSE
Used under all flight conditions.
HOLD
Used to hold canopy in any position other than closed.
OPEN
Used to open the canopy under normal conditions,
AUX OPEN
Used to open canopy manually, which is required when nitrogen bottle pressure drops below 225 psi.
CANOPY JETTISON handle
Used to jettison canopy.
Figure Z-125. Cockpit CanopyControl Handle andIndicator Lights
2.241
are
NAVAIR Ol-F14AAD-1
2.37.1.2.1 Open. When OPEN is selected,nitrogen is ported to the locking actuator through the Contml module and the canopy is moved aft disengagingthe canopy hooks from the sill hooks. Pneumaticpressure is thenportedto the canopyactuatorto raisethe canopy. 2.37.1.2.2 Hold. SelectionofCANOPY HOLDduring transition of the canopy stops the canopy in any intermediateposition betweenclosedandopenby pmssurizing the lock valves in the canopy actuator.These lock valves stop the transferof hydraulic fluid. With the canopy in any intermediate (CANOPY HOLD) position, moving the handle slowly toward OPEN will allow the canopyto begin to close until the handleis Enally in OPEN. This occursbecausethe fast motion of the handle moves the selector valve cam, which vents preasmefrom the lock valves and allows the canopyweight to transferhydraulic fluid. Once the selector valve cam is completely moved to OPEN, pressureis then applied to the open side of the canopy actuator.
If the canopyhandleis left in an intemmdiate position for an extendedperiod, the canopy will slowly close. 2.37.1.2.3 Close. In CLOSE it allows the canopyto close under normal conditions (30~knotheadwind)using its own weight without an expenditureof stored nitrogen.When thecontrol handleis setto CLOSE, both sides of the canopy actuator are vented to the atmosphere, allowing the canopy to lower itself. The fti closing motion actuatesa pneumatic timer, which directs pressurefrom the control module to the locking actuatorandthe canopyis moved forward to engagethe canopyhooks in the sill hooks. To closethe canopyunderhigh headwindconditions (30 to 60 knots) or when difficulty is experiencedbecauseof hot or cold temperatums,BOOST is used.The BOOST mode is activatedby rotating the canopycontrol handle outboardpast the CLOSE stop and pushing the handle forward. With the control handle in this position, the control module ports additional regulated pneumatic pressure to the closed side of the canopy actuator. If BOOST is used to close the canopy, the handleshould be retumed to CLOSE. 2.37.1.3 Auxiliary Canopy Opening. When the main pneumaticreservoirpressureis reducedto 225psi, the canopy control module automatically prevents furORIGINAL
ther depletionof reservoirpressureandthe canopymust be openedmanually. Actuation of the auxihary mode can be at&ted Born either the pilot or RIO canopy control handleor from the ground externalcanopycontrol. To openthe canopy from the cockpit in tbis mode, the canopycontrol handle in the cockpit must be rotated outboard to move the handle past the OPEN stop and then pulled aft to AUX OPEN. This activatesa pneumatic valve, which admits regulatedpneumaticpressure Born an auxiliary nitrogenbottle to the locking actuator andmoves the canopyaft out of the sill locks. When the canopy isunlocked, pneumatic pressuret+om the main reservoirisportedtotheopensideofthecanopyactuator to counterbalancetheweight of the canopy,allowing the canopy to be manually openedor closedby the flightCrew.
Before leaving the cockpit, the control handleshould be returnedto HOLD. If left in AUX OPEN, the canopy’s own weight or a tailwind could force the canopy down with low pressurein the main reservoir.Oncethe auxiliary canopyunlock bottle is used,the canopywill not return to the normal mode of operationand cannot be locked closed until the auxiliary pneumaticselector valve on the aft canopy deck is manually reset(lever in vertical position). The auxiliary canopyunlock nitrogenbottle is on the turtlebackbehmdthecanopyhingelme(refertoFO-15). Servicing of the auxiliary bottle is thnmgh the small accesspanel immediately behind the canopy on this turtleback.A tidly chargedbottle will provide approximately 20 canopy cycling operationsin the auxiliary openmode. 2.37.1.4 Canopy Jettison. Tbecanopy canbejettisonedfioin either cockpit or tium external controls on eachside of the foselage.An internal control handlein eachcockpit (Figure 2-125) is on the forward right side of eachflightcmw instrument panel and is paintedyeilow and black for easeof identification. To activatethe jettison control handle, squeezethe bmer face of the handle andthen pull. The length ofpull is approximatelyone-halfto threequarterinch, and the handle comes tkee of the aircraft when actuated. Pulling either CANOPY JBTTISON handleactuatesan initiator that ignitesthe canopyseparationchargeandactuatesthe canopygasgenerator.The canopy separation charge ignites the expanding, shielded,mild-detonatingcord lines, routedthroughthe canopysill hooks, breaking the sill hook tinngiile bolt. This allows the hooks to rotate upward, releasingthe canopy. The canopy gas generator produces highpressuregas that forces the canopy hydraulic actuator shaftupward, ballistically removing the canopy.
NAVAlR 0%F14AAD1
Ejection through the canopycan result in injury and is provided only as a backup method, therefore,the canopy is jettisoned as part of the normal ejection soquence.An upward pull on the ejection seatfiring handle jettisons the canopyprior to ejection. 2.37.1.4.1 External Canopy Jettison Handles. There are two external emergencyjettison handles located on the lower left and right t%selagebelow the pilot cockpit, appropriately marked for rescue. Opening either accessdoor and pulling the T-handle tires an initiator that detonatesthe canopy separation chargeand actuatesthe canopy gas generator.The sequence is the same as when the cockpit handles are pulled. The jettison control handlesrequire squeezing the inner face of the handle and then pulling for actuation. The length of pull is approximately one-half to three-quarterinch and the T-handle comes Bee on the aircraftwhen actuated.Refer to Chapter 12 for canopy externaljettisoning procedures. 2.38 EJECTION SYSTEM The aircraft is equippedwith an automatic electronically sequencedcommandescapesystemincorporating two Navy aircrew common ejection seat (SJU-17(V) 3/A (pilot) and SJU-17(V) 4/A (RIO)) rocket-assisted ejection seats.Both seatsare identical in operationand differ only in nozzle direction of their lateral thrustmotors,which provide a divergentejectiontrajectory away from the aircratt path. When either crewmemberinitiatesthecommand escapesystem,the canopyis ballistically jettisoned and each cmwmember is ejectedin a preset-timesequence.Tbe RIO is ejectedto the left and the pilot to the right. Safe escapeis provided for most combinations of aim&I altitude, speed,attitude,and flightpatb within an envelopefrom zero airspeed,zero altitude in a substantially level attitude to a maximum speedof 600 KCAS betweenzero altitude and 50,000 feet. Preflight proceduresare shown in Chapter 7 of this manual; ejection proceduresare discussedin Chapter 16. Ejection sequenceis illustrated in FO-16 and FO-17.
Loose gearin the cockpit is a FOD and missile hazard, especially during carrier operations, maneuvering flight, or ejection sequellces.Crariageofgearthatcannotbecontainedin thewckpit stomgewmparmledltshall bekept to a minimum consistentwith mission requirements and the mission environment
2.38.1 Ejection Seat. The NACES seat (Figure 2-126) is provided with a rocket-deployed6.5 meter (20-foot), aeroconical, steerable parachute that is packed with a ribbon extraction drogue in a container behind the seatoccupant’shead.The seatbucket holds the smvival kit and also has the seat tiring handle and otheroperatingcontrols. The parachuterisers attachto the crewmember’storso harnessby meansof seawateractivated release switches. Normal ejection includes canopyjettison beforethe seatsarecatapultedout of the cockpit; however,the parachutecontaineris fitted with canopy penetratora.This permits a backup ejection through the canopy after a time delay in the event of safe-and-armunit failure or failure of the canopy to separatet?omthe aircraft. After ejection has been initiated, two pitot heads mounted next to the parachutecontainerare deployed. Airspeed and altitude are provided to the batteryoperatedelectronicsequencermounted underthe parachute container. The sequencer,which also receives static pressure,uses the information to determine the propersequencingof deploymentof the seatdmgueand parachuteand releaseof the harnesslocks. Depending on seataltitude and airspeed,the seatdrogue,which is catapult-deployedt?om a canisteron the backof the seat and has a three-pointattachmentbridle, can be usedto stabilixetheseat,slow its descent,orbejettisonedbefore the parachute deployment rocket is tit& To ensure parachutedeploymentand man-seatseparation,a bar+ static releaseoperatesto tire the parachutedeployment rocket and releasethe hamess locks in the event of complete or partial sequencer failure. As a further backup,operatingthe manual releasehandleon the seat bucket will also fire the parachutedeployment rocket and releasethe harnesslocks. 2.38.1.1 Seat Firing Handle. Ejection is initiated by pulling up on the seatfiring handleon the tiont of the seatbucketbetweenthe crewmember’sthighs. This action operateslinkage that withdraws the searst?om the two seat initiator cartridges,commencing the ejection sequence. 238.12 SAWARMED Handle. ?be SNARMED handleon theright side of the seatbucket forwardof the manual override handle is the only control for arming andsaSngthe seat.(On the ground, a safetypin is also installed in the seatftig handle.)The handlelocks in the selectedposition. It is operatedby releasinga catch to remove the locking plunger.When the handle is IX+ tated forward (up) to safe the seat,the SAFE legendis displayedon a white backgroundand a safetyplungeris inse-ttedinto the firing handlelinkage sothat thehandle cannot be pulled up, rendering the seat inoperative. Rotating the handle aft (down) displays the ARMED
2.243
ORIGINAL
NAVAIR 01-Fl4AAD-1
CATAPULT
CANOPY
PENETRATOR
(2) \
MANIFOLD
VALVE
-I
LH PITOT (STOWED)
PARACHUTE DEPLOYMENT
SEAWARS
(2) \
LH BALLISTIC
STICKER
MANUAL
STRAP
(2)
OVERRIDE HANDLE \ HARNESS LAP BELT
(2)
SAFE/ARM HANDLE PERSONNEL DISCONNECT
LEG RESTRAINT LINE SNUBBER
HARNESS CONTROL
(2)
EJECTION HANDLE
/
CONTROL SAFETY PIN
LEG
RESTRAINT
“I4 \\
\
LATERAL ’ THRUST MOTOR (FORWARD SEAT - LH SIDE; AFT SEAT - RH SIDE)
LINES
Figure 2-126. Ejection Seat(Shed 1 of 2)
ORIGINAL
2.244
SERVICES BLOCK
LOCK LEVER
NAVAIR Ql-FUAAD-I
I Figure 2-126. Ejection Seat(Sheet2 of 2)
2-245
ORIGINAL
NAVAIR Ql-FlUAD-1
legendon a yellow-black stripedbackground.This pulls the safetyplungerfrom the tiring handlelinkage,being the handle and allowing the seat to be fmd. With the canopy closed,the SEAT UNARMED caution light in the RIO cockpit is illuminated if the SAFE/ARMED handle on either seatis in the SAFE position. 2.38.1.3 Manual Override Handle. The manual override handle on the right side of seatbucket behind the SAFE/ARMED handle is connectedby linkage tc the lower harnesslock releasemechanism and to an initiator in the seatbucket. The handle is locked in the down position by a catchoperatedby a thumb button at the forward end of the handle. Depressingthe thumb button allows the handleto be rotatedaft. Operatingthe handle also rotates the SAFE/ARMED handle to the SAFE position. A catch in the lower part of the manual releasehandle must be reset before the handle can be returnedto the down position. With the seatin the aircraft, operationof the handlelinkage is restrictedby the pin puller andreleasesonly the lower locks, negative-g strap, and the leg restraint line locks to permit emergency groundegresswith the survival kit attached. Note The parachuterisers andpersoMe services must be disconnectedmanually.
2.38.1.8 Leg Restraints. Theleggartersandrestmint cordskeepthe occupant’sleg firmly againstthe leg rests during ejection. The garters are placed around the leg below the calf and above the knee. The leg-restraint cords are attached to the aircraft deck androutedthrough the seatsnubberbox structure. They are then passedthrough garterrings and snapped into the leg-line locks. The garterrings are snappedinto the bayonet fitting when strappingin. Leg-line release is accomplishedby pulling the manual overridehandle. Leg restraintsmay be adjustedby pulling the tab on the inner side of eachleg-line snubberbox. 2.38.1.7 Negative-G Strap. The negative-gstrapis not incorporatedin the F-14D NACES ejectionseat
After ejection, the pin puller disengagespermitting liuther movement of the linkage so that operating the handle releasesthe lower harnesslocks and fires the manual override initiator that provides gas pressureto releasethe upper torso harnesslo&s and fue the parachute deployment rocket in the event of automatic sequencing failure. 2.38.1.4 Torso Harness. The torso harnessis worn by the crewmember and takes the place of a separate lapbelt and shoulderharness.The uppertorsoharnessis connectedby releasefittings (Koch fittings) to the inertial reel via strapspassedthrough roller yokes attached to the parachuterisers.The releasefittings incorporate SEWARS to allow automaticreleaseon saltwaterentry. A fitting on the lower part of the torso harnessconnects to the negative-gstrap, and two buckles connectto the seat lapbelt fittings. Lapbelt girth can be adjusted to accommodatethe individual crewmemberby adjusting eachbelt strap. 2.38.1.5 Harness Lock Control Lever. The barnesslock control lever on the left side of the seatbucket hastwo detentedpositions. In the forward (locked) position, forward movement of the occupantis restricted and any slack createdby rearwardmovement is taken up by the inertial reel. The control is locked in this ORIGINAL
position by a detent.In the aft position, the occupantcan move forward freely, unless the reel locks owing to excessiveforward velocity. When the forward velocity decreasessuft%iently, the inertia straps are released without the necessityof repositioningthe manual control. Both straps feed from the same shaft, and it is impossible for one to lock without the other.If the reel is lockedmanually the control must be positionedaft to the unlockedposition to releasethe straps.
2.38.1.8 Seat Height Adjustment Switch. Seat heightisadjustedbyanactuatordrivenbyasingle-phase 1IS-Vat electric motor. Operationof theactuatoris controlled by a three-positionswitch on the right aft sideof the seatbucketmarkedRAISE, OFF, andLOWER. The switch is spring loaded to the center OFF position; RAISE is aft and LOWER is forward. Electric power is suppliedfrom phaseB of the right main ac bus through the ACM LT/SEAT ADJ/STEADY POS LT circuit breaker(214).
The seatheight actuatormotor has a maximum duty cycle of 1 minute on in any 8-minute period. 2.38.1.9 Survival Kit. The survival kit (Figure2-127) forma the sitting platform for the crewmemberandconsists of a fabric survival-aids container covered by a contoured,rigid platform with a cushionon top to provide a firm seat and additional comfort for the crewmember.The kit is retainedin position by pivot fittings at the front and lugs attachedto the lower harnesslocks at the rear.Attached to the lower harnesslock lugs are two adjustableharnesslap strapswith integral lapbelt releaset3ting.9.
2-248
Figure 2-127. Survival Kit
ORIGINAL
NAVAIR 01.FI4AADI
The wvival kit accommodatesa liferaft, an emergencyoxygencylinder, andthe survival aids.The emergency oxygen cylinder is mounted to the undersideof the platform, a pressuregaugeis on the left thigh support, and a greenmanual operatinghandleis on the left side of the platform. The emergency oxygen is also automatically activated during ejection by a static line coMected to the cockpit floor. Note Flow of oxygenfrom the emergencycylinder can be stopped by reseating the manual actuationhandle. A URT-33C radio locator beaconis in a cutout in the left thigh supportand is connectedto the cockpit floor by a static operatingcableso that it canbe automatically actuateddmingejection(ifdesired).Thefabricsurvivalaids containercan be deployedon a lowering line after ejection by pulling on either of the two yellow handles located on the back side. The liferaft is automatically inflated when the survival-aids container is deployed. Contents of the survival-aids container may vary depending on the areaof operation,but the following is a typical list: 1. Liferafl dye markers 2. Signal flares 3. Morse code and signal card 4. Spaceblanket
zero/zeroejection t?om a level attitude.The rocket motor nozzlesare inclined so that the thrustpassescloseto the cg of the seatandoccupant.The motor also includes a lateral thrust nozzlethat imparts a divergenttrajectory carrying the seataway from the aircraft flightpath. 2.38.2 Command Ejection Lever. A command ejection lever (Figure 2-128) above the RIO left outboard console allows the RIO to select either pilot or RIO control of the command ejection system.Each position has an internal locking detent.The handle is unlocked by lifting upward andmoved by a forward or aft motion. If the handleis releasedbefore reachingthe aft position, it is spring loaded to return forward. It will automatically lock in the forward position; however a downward motion is required to positively lock it into the aft position. To select MC0 command ejection position, raise the handle and pull aft. An EJECT CMD flip-flop-type indicator on the landing gearpanel indicatesthe command mode selected.The RIO may eject individually when the command ejection lever is in the pilot controlposition. When the commandejectionlever is in the MC0 command position, the RIO can initiate ejection of both seats.Regardlessof the position of the commandejectionlever, anejectioninitiatedbythepilot will always eject both crewmen. Command ejection by either crewmemberwill eject the RIO fust andthe pilot 0.4 secondlater. Depending on aircraft dynamics, the total time for command ejection.of both seats in the normal (safe and arm device) mode is from 0.4 to 0.9 second;in thebackupinitiator mode, thetotal time is 1.5 second. 2.38.3 Ejection Initiation. With the SAFWARMED handlein the ARMED (down) position, pulling the seat ftig handleupward to the extentof its travel beginsthe ejection by pulling the searson the seat initiators. The following eventsoccur:
5. Desalterkit or cannedwater 6. 50 feet of nylon cord 7. Bailing sponge
1. Canopyjettison is initiated.
8. SRU-31/P tlightcmw survival kit,
2. The poweredinertia reel retracts,pulling the crewmember back in the seat.
If over water, the survival-aids container should be deployedon its lowering line beforereachingthe surface to make the raft immediately available on landing. If over land, it should not be deployed. This will reduce the risk of entanglementand protect againstinjury. 2.38.1 .I 0 Rocket Motor. The rocket motor is on the bottom of the seat bucket. It is ignited by a lanyard attachedto the cockpit floor asthe catapultnearstheend of its stroke. The rocket thrust is approximately 4,800 pounds for .25 second and sustains the thrust of the catapultto carry the seatto a sufficient height for a safe
ORIGINAL
2-248
3. The delay initiators areactivated.Theseinitiators have built-in delaysof 1.Osecondfor the RIO seat and 1.5 secondsfor the pilot seat. 4. The restriction is removed from the manual override mechanism. 5. The 4.0~seconddelay cartridge for the barostatic releaseis initiated. 6. The safe and armed device is armed.
NAVAIR
NOMENCLATURE a
@
EJECT CMD lever (RIO cockpit)
pEJ:MD
W-flop)
Of-F14AAD-1
FUNCTION PILOT -
Ejection initiated by the pilot will eject himself and RIO (RIO first). Ejection initiated by the RIO will eject only the RIO. Pilot eject command indicator -PILOT.
MC0 -
Ejection initiated by the pilot will eject himself and RIO (RIO first). Ejection initiated by the RIO will eject himself and pilot (RIO first). Pilot eject command indicator -MCO.
PILOT -
Indicates command ejection lever is in PILOT. Only the pilot can eject himself and RIO -RIO-initiated ejection will eject only himself.
MC0
Indicates command ejection lever is in MCO. Both pilot and RIO can eject both flightcrew members -RIO will eject first.
-
Figure 2-128. Command Ejection Lever
2-249
ORIGINAL
NAVAIR 0%FlUAD1
when canopy jettisonis complete,alanyardattached to thecanopypullsasear,fbingthesafeandarmdevice. Thisinitiatesthe thermalbattoriesthatpowerthe seat electronicsequencer and fires the two-stagecatapult, ejectingthe seat.TheRIO seatis fired immediately on tiring ofthe safeandarmdevice,whilethepilotseatis delayed0.4second,TheIFJrswitchis actuated whenthe pilot seatis fired. If the canopyfails to se~mrate or the safeandarm devicedoesnot tire, thebackupinitiatorsoperateat the expirationof their&lays,firingtheRIO seat1.0second afterfbinghandleactuationandthepilotseat0.5second later,throughthecanopy.
mentrocketandreleasetheJmmess locksby usingthe mand ovemide handle. In all modes, followingstartswitchactuation,thepitot headsextend, environmental sensingfor modeselection commences, andtheseatdrogueis deployed onits tJrre+pointbridle to stabilizeandslow the seat.while this is occur&, the sequencer selectsoneof the five operatingmodes (FO-16andFO-17) from its lookuptablesbasedon sensed altitudeandairspeed.Themodesaredescribed asfollows:
2.38.4.1 Electronic Sequencing.
1. Mode1 - Thisisthelow-altitude,low-a&peed mode, Thedroguebridlereleases operateimme diatelx theparachutedeploymentrocket6resto extractanddeploytheparachute;andtheharness locksareraleased, Theoccupantisheldin thesoat momentarilyby thestickerclips.
As the seatascendsthe guiderails, the following eventsoccur: 1. The multipurposeinitiator lanyardsbegin to withdraw.
2. Modes2,3, and4 -
Thesemodesamfor low to medimnaltitudesat airspeedsin excessof 350 knots.Thedrogueis ratainedto slowandstabilize theseat.Then,theparachute deployment rocketis fired to extract and deploythe parachute,the dmguebridlereleases thadrogua;andtheJmrness locksarereleased. Theoccupantisheldin theseat momomarilyby thestickerclips.
2. Personnel servicesbetweenseatandaircratlare diSCOMCCtCd.
3. Theemergency oxygensupplyis initiated. 4. Theemergency locatorbeaconis activated. 5. Thelegrestraintlmesamdrawn&roughthesnub hersandrestrainthe crewmember’s legs to the
3. Mode5 -
f?ontofthesaatbucket.WhenthelegmstraintlJmes becometaut,the breakring in eachline failsand thelinesaretIeedfrom the r&craft.Thesnubbers preventforwardmovementof thelegs. At the endof the catapultstroke(approximately 35 inchesof seattravel),themultipurpose initiatorlanyards becometaut andwithdraw the firing unit sears.This routesgaspressureto the electronicsequencer start switches,beginningsequencer timing to the pitot doploymentmechanisms andto therocketmotor,firingit. Theelectronicsequencer determines thepropermodeof seatoperationbasedonaltitudeandairspeed
Thismodeiss&otedathighaltitude. Thelowerdroguebridlereleases operato,retainingthe drogueby the upper attachpoint only. Environmentalsensingrestarts,andthe seatis allowedto fall to 18,000feetbeforethe sequence continues. Thenthetqrperdroguerelease operates, freeingthe drogue,the parachutedeployment rocketis fuedto extractanddeploytheparachute, andthe harnessJocksarereleased. TJveoccupant ismomentarilyheldin theseatby the&i&r clips.
In all modes,parachutedeploymentlifts the crewmemberand survivel kit from the seat,pulling the stickerstrapsfrom theclips.
2.38.4 Seat Operation After Ejection. Postejection 2.38.4.2 Barostatlc
Release. To ensurethat the operation(FO-16andFO-17)b@ns at theendof cata- parachuteisdeployedandthehamesslocksarereleased. pult travel when the rocketmotor tires andthe start thebarostatic releasaunit,consisting of abarostatanda switchesactuate.br normaloperation, theelectronic secartridge,providasanindependent automaticbackupto quencerselectstJreoperatingmodedopendingonaJtitude the electronicsequencer.Thecartridgeis6mdonaof andammeed. A barostatic release unit urovides anauto- threeways: electricallyby the sequencer at a praset maticb&up for electronic. operation. Fourseconds after altitudeof 18,000feet (FO-16andFO-17),me&anithe seatftig handleis pulled,the barostaticunit is tally by thebamstaticreleaseunit between14,000and armedpermittingparachute deployment andJramess m16,000feet; or me&anicallyby gaspmssuretiom a Jesseas determind by the bamstatsettingif the so 4-second&laycartridgewhenthemamraJ ovarridehanquence~ hasnot functioned.As a fur&r backup,the dleispuJled.Afterthetimedelay,gaspressuroisapplied crmmembercanmanuallytire the pamchutedeploy- to the bamstatcartridgetiring mechanism. Abovethe ORIGINAL
2.250
barostat altitude setting, the mechanism is restricted from moving; at or below the altitude it is &se to move and fire the cartridge if it has not aheady been hind electrically. When fd the barostatcartridgeprovides gaspressureto tire theparachutedeploymentrocket and operatethe harnesslock release. 2.38.4.3 Manual Override. Afterejectioqthemanual overridehandleprovidesa furtherbackupto both the electronic sequencerand the barostaticrelease.Pulling the handlefires a cartridgethat provides gaspressureto tire the parachutedeployment rocket and operatethe harnesslock release. 2.39 LIGHTING SYSTEM 2.39.1 Exterior Lights. The exterior lights include position lights, formation lights, anticollision lights, a taxi light, approachlights, and an air refueling probe light. All exterior lighting controls, except for the air refuelingprobelight andapproachlights, arelocatedon the MASTER LIGHT panel on the pilot right console. The exterior lights masterswitch on the outboardthrottle must be on for any exterior light to l?mction (except for approachlighta). The pilot light control panel is shown in Figure 2-129. A two-channel flasher unit is usedfor flashing lights. Onechannelflashesthe anticollision andposition lights andhascircuit protection f?om the ANTICOLUXJPP POSiPOS LTS circuit breaker (211).The secondflasher channel flashesthe AOA indexer and approach lights and has circuit protection from the ANGLE OF ATTK IND AC circuit breaker (3F3). Note The anticollision, position, and supplementary position, formation, and taxi lights are inoperative when operating on emergency generator. 2.39.1.1 Position Lights. The position lights consist of a red light on the left wingtip, a greenlight on the right wingtip, and a white position light in the left fin cap assembly.Supplementalposition lights include.upper andlower red lights on the leg wing glove andupper and lower green lights on the right wing glove. When the wind-sweep angle is forward of 25”, the wingtip position lights areoperational;whenthewings areswept all of 25”, the wingtip position lights are disabled and the glove position lights are operational.When operating in steadymode with the nosegeardown and locked andthe wings forward of 25’, both the wingtip position lights and the glove position lights areoperational.The position lights arepowered tiom the right main ac bus throughthe exterior lights masterrelay.
Note When the anticollision lights are on, the flasherfor the position lights is disabledand the lights revert to steady. 2.39.1.2 Anticollislon Lights. There are three red, flashing anticollision lights. One anticollision light is installed in the bottom of the inframd pod on the lower forward fuselage.Another anticollision light is installed in the top forward part of the left vertical stabilizer.The third anticollision light is on the top aft part of the right vertical stabilizerand directsits anticollision beaconup and down. The lower fuselage forward anticollision light remainsoffduringtakeoffandlandingwiththenosewheel door open.With the nosewheeldoor closed,the lower tirselageforward anticollision light will operatewith the ANTI COLLISION light switch setto ON. The anticolliiionlights arepoweredthroughtheright mainbus with circuit protection on the RIO ac right main circuit breakerpanel TAXI/FORM LT (3A2). 2.39.1.3 Formation Lights. The formation lights consistof wingtip lights on eachwing, fuselagelights, andvertical fin tip lights on both sides of the aircraft. All formation lights are green.Intensity of the lights is controlled by the FORMATION thumbwheel on the MASTER LIGHT panel. Electrical power is supplied throughthe right main buswith circuit protectionon the RIO ac right main circuit breakerpanel TAXI/FORM LT (3A2). 2.39.1.4 Taxi Light. The taxi light installed on the nosewheelis a fixed-position light. A limit switch onthe nosegeardoor will turn the light off when the gearis retracted.A two-position, ON and OFF, switch is on the MASTER LIGHT panel. Electrical power is supplied throughtheright main bus with circuit protection on the RIO circuit breakerpanel TAXI/FORM LT (3A2). 2.39.2 Interior Lights. The interior lighting of the cockpit consists of red instrument panel and console panel lights, red and white floodlights for additional consoleand instrument panel lighting, and utility/map lights for eachflightcrew station.At thepilot station,the interior lights arecontrolled from the MASTER LIGHT panelon theright outboardconsole.The RIO cancontrol the interior lighting tirn the interior light panel on the RIO right outboardconsole. 2.39.2.1 Instrument and Console Panel Lights. All flight instrnme.ntsin the pilot and RIO instrument panel and consolepanel lights are lighti by white lighting. Individual thumbwheel controls are
2-251
ORIGINAL
NAVAIR 0%FlUAD-
Figure 2-129. Cockpit Light Chtrols (Sheet 1 of 3)
2.252
NAVAIR OI-F14AA~-~
NOMENCLATURE @
b.~;iOLLlSION
@
F’z’;fON
@
@
FUNCTION ON and OFF - Energizes or deenergizes the anticollision lights. When anticollision lights are on, the flasher unit for the position lights is disabled.
light
FLASH -
Causes the wing or supplementary tail and position lights to operate in a flashing mode with landing gear up. With gear down supplementary lights operate steady only.
STEADY -
With the wing and tail (or either) position lights on, lights are on steady.
BRT -
Bright tail light
OFF -
Deenergizes
DIM -
Dim tail light
BRT -
Bright wing lights
OFF -
Deenergizes
DIM -
Dim wing lights
oto1-
Dims pilot’s liquid crystal display brightness. backlighting on.
1to14-
Night variable intensity
INDEXER thumbwheel
oto14-
Variable increase in intensity of indexer lights.
TAXI light switch
ON -
Nose gear must be down and locked.and exterior light switch must be on.
OFF
Turns light off.
oto1-
Turns instrument
lights flasher
;\A;OSITION
WI&POSITION
light
light
LCD panel light thumbwheel
0
c9 0
@
INSTRUMENT lights thumbwheel
1to14
-
tail position light
wing lights
EIG white
the master
panel lights on.
Variable increase of intensity to a maximum brightness 14.
at
BRT -
Bright light.
Note
DIM -
Dim light.
Switch must be pulled out to be moved to BRT or DIM.
OFF -
Turns light off.
oto1-
Turns console lights and console white floodlights
1 to14-
Variable increase of console lights intensity to maximum brightness at 14.
BRT
Bright white instrument flood and console floodlights
MED
White console floodlights
DIM -
Dim white console floodlights
@
63
@
ST;f+t
FLOOD lights
CONSOLE lights thumbwheel
$JzFLOODlights
on,
only.
only. only.
Figure 2-129. Co&pit Light Controls (Sheet2 of 3) 2-253
ORIGINAL
NAVAIR 0%FI4AAD-1
FUNCTION
NOMENCLATURE
I
m @
FORMATION lights thumbwheel s?ri;r
lights master
oto1-
Turns formation
lights on.
1 to14-
Variable increase of light intensity to maximum of 14.
ON
Enables all exterior lights except approach approach lights to night intensity.
OFF
Permits pilot to turn off all exterior lights except approach lights. Sets daylight intensity on approach lights.
lights. Dims
Figure 2-129. Cockpit Light Controls (Sheet3 of 3) provided for the pilot and RIO instrument and console lighting. The thumbwheelshave 14 variable selections from 0 to 14. Initial rotation from 0 to 1 activates the circuitry and provides a low-intensity light. Further rotation up to a maximum intensity (14) increasesthe brightness.The INSTRUMENT thumbwheelalso controlstbeintensityoftbeCALJTIONADVISORYpanels, the left and right vertical consoles,and the digital data indicator lights, which consistofhigh- andlow-intensity lighting. The consolelights thumbwheelturnspower on for both the consolelights andthe floodlights. The pilot and RIO instrumentand consolelights areprotectedby circuit breakers on the RIO ac circuit breaker panels (2I2,3Al, 3A2, and 3A5). Lighting for the pilot tumand-slip indicator is controlled by the INSTRUMENT lighting thumbwheel. The engine indicator group uses integral white lighting for daylight operations, and liquid crystal display brightnessis controlled by the LCD thumbwheel. 2.39.2.2 Floodlights. The floodlights consist of 4.2-watt and 20-watt white lights that illuminate the instrument and console panels. When navigating aroundthunderstorms,the storm floodlights should be turnedon bright to assistin preventingtemporaryblindnessfrom lighting. The STORM FLOOD toggle switch on the pilot master light panel and anotheron the RIO light panel are safety interlock switches that must be pulled up to be positioned to BRT or DIM. In DIM, low-intensity floodlighting is provided. Note When the storm floodlights are on (BRT or DIM), the intensity of the CAUTION and ADVISORY panel lights is increasedto day (bright) illumination mode. Console and instrument panel floodlights are available in BRT. In the MED and DIM, only console floodlights areavailable. The panel floodlights areproORIGINAL
tected by a FLOOD LTS circuit breaker(4A6) on the RIO ac essentialNo. 1 circuit breakerpanel(4A6). The white floodlights am protectedby the STORM FLOOD LT circuit breaker(216)on the RIO ac right main circuit breakerpanel. 2.39.2.3 Utility and Map Lights. The piIot utility and map light is on a bracket abovethe right outboard console. The RIO utility and map light is in a bracket aboveandmidway along theright andleft console.Each light hasa rheostatcontrol including an ON andOFF on the rear of the lamp. A red filter may be selectedby rotatingthe faceofthe lamp. Pressingthelocking button on top of the lamp permits rotating the face of the lamp to reselecta white light with a flood or spot illumination option. An alligator clip and swivel mounting allow the light to be positionedon a clipboard or otherconvenient location. A flasherbutton on the heel of the lamp allows eithercrewmemberto usethe light asa signal lamp. The utility andmap lights are suppliedelectricalpower from the ac essentialNo. 2 bus andareprotectedby theUTILITY LTS circuit breaker(3A6). 2.39.3 Warning and Indicator Lights. Warning, caution, and advisory lights (Figures 2-130 and 2131) are provided in both cockpits to alert the pilot and RIO of aircraft equipment malfunctions, unsafe operating conditions, or that a particular system is in operation. Warning lights illuminate red with black letters to warn of hazardousconditions that require immediate corrective action. Caution lights show yellow letters on an opaque background to indicate an impending dangerouscondition. The lower halfofthe CAUTION ADVISORY panel consists of advisory lights that show green letters on opaquebackground. Advisory lights indicate degradedoperationsthat may require corrective action.
2.254
NAVAIR Ol-F14AAD-I
Figure Z-130. Pilot Indicator Lights (Sheet 1 of 5)
2-255
ORIGINAL
NAVAIR 0%F14AAD-1 NOMENCIATURE
0
0
I
FUNCTION
SAM (warning)
Steady illumination when a surface-to-air missile tracking radar is detected. Flashing when a missile has been launched.
AM (warning)
Steady illumination when an anti-aircraft tracking radar is detected. Flashing when an AAA radar firing signal is detected.
cw (warning)
Indicates continuous
wave emitter detected.
Al (warning)
Steady illumination
WHEELS (warning)
Flashes with flaps down more than IO”, either throftle below approximately 55%, and any landing gear not down and locked.
BRAKES (warning)
Indicates antiskid failure or failure of priority valve in the brake power module to switch to combined hydraulic system (operating in AUX brake mode). Illuminates when parking brake is pulled.
ACLSIAP (caution)
Auto pilot and automatic
NWS ENGA (caution)
Indicates nosewheel steering is engaged and will respond as a function of rudder pedal displacement. Automatically centers with hook down.
AUTO THROT (caution)
Indicates APC has been disengaged MODE switch.
indicates an airborne interceptor
tracking is detected.
carrier landing system mode disengaged.
by means other than the THROTTLE
Indicates radar locked on target. @
KiOry)
@
EEi)
0
HOT TRIG (warning)
Indicates that firing logic conditions are available. Pilot’s trigger or bomb button and RIO’s launch butfon will fire or release ordnance when actuated.
@
El;;
Flashes when any light on the pilot’s CAUTION ADVISORY panel illuminates.
@
zning)
@
EMERG STORES JEI-DACK (warning)
Indicates target meets specified fAR requirements.
CAU-mN
Fire/overheat
condition in engine nacelle.
Indicates EMERG STORES JETT pushbutton
is activated.
Note The following lights on the CAUTION ADVISORY panel are in alphabetical order
Figure 2-130. Pilot Indicator Lights (Sheet2 of 5)
ORIGINAL
2-256
NAVAIR OW14AAD-1 NOMENCLATURE @
FUNCTION
AUTO PILOT (caution)
Indicates failure of one or more pilot relief modes.
AUX FIRE
Indicates low pressure (approximately 90 psi below the nominal 600 psi) in the auxiliary fire extinguishing agent container.
Eisory) BINGO (caution)
Indicates total fuel quantity indicator is less than BINGO preset value.
BLEED DUCT (caution)
Indicates bleed air leak sensing elements detect temperatures greater than 575°F between engine and primary heat exchanger. Also indicates hot air leak detection (excess of 255” F) between primary heat exchanger and ECB turbine compressor.
B/U OXY LOW (caution)
Indicates backup oxygen system pressure is 200 psi or less.
CADC (caution)
Indicates failure associated
ENG FIRE Ex-r (advisory)
Indicates low pressure (approximately the fire extinguishing agent container.
L ENG SEC R ENG SEC (caution)
Indicates augmenter fan temperature controller @FTC) is in secondary mode. Afterburner is inoperative and thrust levels can vary from as rile as 65% to as much as 116% of primary mode MIL thrust.
FLAP (caution)
Indicates: Disagreement between main and/or auxiliary flap position, or asymmetry lockout. CADC failure. WG SWP DR NO. 2/MANUV FLAP (LEI) circuit breaker pulled. Landing flaps down and airspeed greater than 225 knots.
L FUEL LOW R FUEL LOW (caution)
Indicates fuel thermistors uncovered in aft and left or forward and right fuel feed group (approximately 1,000 pounds remaining in individual fuel feed ww).
L FUEL PRESS R FUEL PRESS (caution)
Indicates insufficient discharge turbine driven boost pump.
L GEN R GEN (caution)
Indicates that corresponding generator is inoperative because of fault in generator, control unit, or electrical distribution system.
HYD PRESS (caution) HZ TAIL AUTH (caution)
with air data computer. 90 psi below the nominal 600 psi) in
pressure (less than 9 psi) from respective
Indicates hydraulic pressure from either engine-driven
pump is less than
2,100 psi. Indicates failure of lateral tail authority actuator to follow schedule or CADC failure.
Figure 2-130. pilot Indicator Lights (Sheet3 of 5)
2-257
ORIGINAL
NOMENCLATURE
FUNCTION
R INLET L INLET (caution)
ndicates AICS programmer
INLET ICE (CautlOrl)
ndicates ice accumulated on ice detector in left inlet with ENG/PROBE/AICS ANTI-ICE switch in AUTO/OFF or OAIDE/ON selected.
INTEG TRIM (advisory)
ndicates a discrepancy between input command signal and actuator )osition, or an electrical power loss within the computer.
LAD/CANOPY (caution)
idvises that the boarding ladder is not in an up and locked position or that :anopy is not in down and locked position.
LAUNCH BAR (advisory)
weight-on-Wheels: l
and/or system failure.
Aircraft kneeled, either throttle less than MIL, launch bar not up and locked (normal indication until MRT checks).
Meeight-off-Wheels: l l l
Launch bar not up and locked. Launch bar not wlthin f 15” of center, cocked nosegear. Nose strut not fully extended.
MACH TRIM (advisory)
ndicates failure of Mach trim actuator to follow schedule.
OBOGS (caution)
ndicates a switchover to backup oxygen or OBOGS switch OFF
L OIL HOT R OIL HOT (caution)
ndicates oil temperature too high. May be an indication of the righ-scavenge oil temperature: continued engine operation will result in educed gearbox life and lubrication degradation.
OIL PRESS (caution)
ndicates left or right engine oil pressure is 11 psi or less.
READ MFD (caution)
ndicates any or all of the following warning/caution he upper left corner of the MFD. L N2 OSP R N2 OSP L Ni OSP R Nl OSP L TBT OT RTBTOT L FLMOUT R FLMOUT L IGV SD R IGV SD
W/S Figure 2-130. Pilot Indicator Lights (Sheet4 of 5)
ORIGINAL
2-258
legends that appear on
NAVAIR
NOMENCLATURE
Ql-Fl4AAD-1
FUNCTION
L RAMPS R RAMPS (caution)
Indicates ramps are neither positioned flight conditions. (See figure 2-5.)
in stow nor trail locks during critical
PITCH STAB 1 PITCH STAB 2 (caution)
Indicates inoperative pitch channel.
RATS (advisory)
RATS operation
ROLL STAB 1 ROLL STAB 2 (caution)
Indicates inoperative roll channel (roil SAS failure).
RUDDER AUTH (caution)
Indicates disagreement between position and command authority actuators to follow schedule, or CADC.
SAHRS (advisory)
Indicates attiiude or heading information
SPOILERS (caution)
Indicates spoiler failure causing a set of spoilers to be locked down.
START VALVE (caution)
Starter solenoid air valve open after start. Starter overspeed and/or destruction possible.
TRANSIRECT (advisory)
Indicates one operable transformer-rectifier or dual transformer-rectifier failure.
WING SWEEP (advisory)
Indicates failure of a single channel in the system.
WSHLD HO-f (advisory)
Indicates center windshield
YAW STAB OP (caution)
One yaw channel inoperative.
YAW STAB OUT (caution)
Two yaw channels inoperative
is enabled.
from SAHRS is unreliable.
is powertng
is overheated.
(yaw SAS failure).
Figure 2-130. Pilot Indicator Lights (Sheet5 of 5)
2-259
failure of rudder
the total dc load,
Figure.2-131.RIO IndicatorLights(Sheet1of 3)
ORIGINAL
2-260
NAVAIR
NOMENCLATURE a
@
0%FlrlAAD-1
FUNCTION
INS status indicators
Not operational.
Evis0t-y)
Indicates mode 4 interrogation generated reply.
was received, but system has not
RCV (advisory)
Indicates ALQ-165
is receiving a threat identification
XMIT (advisory)
Indicates ALQ-165
is transmitting.
SAM (warning)
Steady illumination when a suriacs-to-air missile tracking radar is detected. Flashing when a missile has been launched.
AAA (warning)
Steady illumination when an anti-aircraft tracking radar is detected. Flashing when an AAA radar firing signal is detected. Indicates a continuous
signal.
wave emitter is detected.
Krning) Al (warning)
Steady illumination
indicates an airborne interceptor tracking is detected.
Flashes when any caution light on the RID’s CAUTION ADVISORY panel illuminates. Indicates DD and/or TID controls and displays are overheating. @
g%y CABIN PRESS (caution)
Indicates aircraft cabin pressure has dropped below &psi differential or cockpit altitude is above 27,000 feet.
pressure
FUEL LOW (caution)
Indicates fuel thermistors uncovered in aft and left or forward and right fuel feed group (approximately 1,000 pounds) remaining in individual fuel feed group.
B/U OXY LOW (caution)
Indicates backup oxygen system pressure is 200 psi or less.
CANOPY (caution)
Indicates that canopy is not in down and locked position.
Figure 2-131. RIO Indicator Lights (Sheet2 of 3)
2-261
ORIGINAL
m Il.”
I I”..
Indicates either seat is in the SAFE position.
RDR ENABLED (caution)
Indicates that radar operation on the ground is possible or failure of right main landing gear safety switch or wiring.
READ MFD (caution)
Indicates any or all of the following warning, caution, or advisory legends that appear on the upper left corner of the MFD. SDU ALARM ASPJ HOT JTID HOT RWR FWD ASPJ AFT ASPJ MCI MC2 MC1 HOT MC2 HOT CIU INS
IMU CIU HOT DPl HOT DP2 HOT SMS HOT AFT CG HUD HOT RWR HOT DSS HOT DEKI HOT IRST HOT
BINGO (caution)
Indicates total fuel quantity indicator is less than BINGO preset value.
SENSOR COND (advisory)
Indicates coolant temperature exiting heat exchanger is 104”F, radar coolant pump output pressure is below 60 psi, or the overtemperature switch has shutdown the coolant pump.
COOLING AIR (advisory)
Indicates an overtemperature condition exists in the electronic forced air cooling system. With degraded cabin pressure or flow, indicates possible bleed duct failure forward of primary heat exchanger and 400” modulating valve.
OBOGS (caution)
Indicates a switchover to backup oxygen or OBOGS switch OFF
SAHRS (advisory)
Indicates attitude or heading information
from SAHRS is unreliable.
Figure 2-131. RIO Indicator Lights (Sheet3 of 3)
ORIGINAL
2-262
NAVAIR 01.F14AAD-1
2. Approachindexer 3. AUTO THROT Radiation hazard exists on deck when the RDR ENABLED caution light is illmninated. The light indicates that the RADAR TEST ENABLE switch (maintenance switch) is in the “A” (radiateand scan)position. This condition permits the weight-onwheelsinterlock to be bypassed,allowing the tmnsmitter to radiate out the antennawhen RADAR XMIT is selectedon the handcontrol unit. Illumination of the light does not indicate a weight-on-wheelsfailure.
4. BRAKES 5. EMER STORES 6. FIRE 7. GO/NO GO 8. HOOK light 9. HOT TRIG
2.39.3.1 MASTER CAUTION Light. The pilot MASTER CAUTION light is centrally located on the mastercaution/masterarm control panel, and,in the aft cockpit, the RIO MASTER CAUTION light is on the left instrumentpanel. When the lights are illuminated, yellow letters show on an opaquebackground.Individual MASTER CAUTION lights flash whenevera caution light on the respectivecaution and advisory panel illuminates. A MASTER CAUTION light may be turned off by depressingits lens. This will activate a reset switch that rearms the master circuit for a subsequentcaution light. A caution light lit on the caution andadvisorypanelwillnotbetumed offbyresettingthe MASTER CAUTION light. 2.39.3.2 Indicator Lights Test. Acheckofallindicator lights can be performed while airborneor during on-deck operations. The pilot caution and advisory lights,the MASTER CAUTION light, andall associated circuitry are testedthrough the MASTER TEST panel. The test is initiated by selecting LTS and pressingthe mastertest knob. Electrical power is routedthroughthe circuitry to provide simulatedfailure signalsto the caution and advisory lights. Illumination of eachwarning, caution,and advisorylight verifies propercontinuity of theindicator lights. A malfunction is indicatedby failure of a light to illuminate. Illumination of any caution light causesthe MASTER CAUTION light to flash. If the MASTER CAUTION light illuminates steadily during the LTS test, it indicates a failure of the MASTER CAUTION light, primary power failure, failure of the flasher module, or that failure has beendetectedby the BIT circuits. The following indicator lights arealsoilluminated by the LTS test throughthe MASTER TEST panel:
10. LDG GEAR transition light 11. LOCK 12. NWS ENGA 13. RATS 14. Err 15. Refuelingprobe transition light 16. SAM 17 SHOOT 18. WHEELS. Note The DATA LINK power switch must be on to check the DDI lights. The RIO caution and advisory lights aretestedin the samemanneron the TEST panel on the right console. 2.40 STORES MANAGEMENT SYSTEM/ JETTISON The SMS is the interfacebetweenaircrafi storesand the mission computer system. It provides signal processingandlogic control requiredfor inventory andidentification of all stores;preparationand test of missiles; and weapon select, arm, and launch functions. The emergencygenerator(1 kVA mode) provides backup power (28 Vdc essential)for emergencyjettison. The SMS has extensiveself-testcapabilitiesandreportsfailures to the MCS for display to the crew.
1. ACLSIAP
2-263
ORIGINAL
NAVAIR QI-Fl4AAD.1
ARMBUS. The SMP also controlsweaponselect,SMS andweaponBIT, monitors aircraft safetyinterlocks,and controlsthe launch-to-ejectsequence.
2.40.4 SMS Weapons Replaceable Assemblies. The SMS consistsof the following WRAs: 1. Storesmanagementprocessor
2.40.1.2 Fuel lank Jettison Unit. ‘ho FlYUs, one each for stations2 and 7, are located in the enginenacelles. The FTJUs provide eject pulses to the squibsin thejettison releasemechanism for emergency,ACM, or I selectivejettison of the fiel tanks.
2. Fuel tankjettison unit 3. Type 1 decoders 4. Type 2 decoders
For a description of Type 1 decoders,Type 2 decoders, gun control unit, missile power ml&y unit, missile power supply, AWW-4, and SMS functions, refer to I NAVAIROI-F14A4D-1A.
5. Gun control unit 6. Missile power relay unit 7. Missile power supply 8. AWW-4. 2.40.1.1 Stores Management Processor. The SMP is a programmable,digital computerthatprovides the central processing and command functions of the SMS. It operatesasa remoteterminal on MBUS-2. The SMP communicates with the SMS WIWs and acts as the bus controller on the armamentbus. The SMP controls emergencyjettison,the gun, andsomeAIM-9 tictions via discretes that are independent of the
1A
1B
3
4
2.40.2 Multistatus Indicator. The MS1 (Figure 2-132) is a liquid crystal display locatedbelow MFD 1. The MS1 is poweredby the HUD subsystem. MS1 displays aredependenton the MCS. When the HUD PWR switch is setto TEST, all LCD segmentson theMS1 are displayed.The MS1 displays weapontype andstatusof eachstorestation. The upper row of the display identities the weapon.The lower row displaysweaponstatus. Two horizontal dashedlines at a store station indicate that the missile at that stationhasFAILED or is HUNG. A blank display on a station indicates no weapon is loadedor the weapon loadedis not recognized.
5
6
6B
6A
LEOEND SYUSOL II -Bb c3 E3
STATUS READY FAIL!3
OR HUNG - UNUSABLE
READY AND SELECTED, DEGRADED SELECTED
AND DEGRADED
Figure 2-132. Multistatos Indicator ORIGINAL
2-264
NAVAIR 01.Fl4AAD-1
2.40.3 Stores Jettison Modes. Four jettison modes areavailable: 1
1. Emergency (EMER) 2. Air combat maneuver(ACM) 3. Selective@EL)
JETT pushbuttonon the landing gearcontrolpanel with weight offwheels (Figure2-133).Emergencyjettisonhas priority over all other SMS t&ctions. This momentaty, nonlatchingpushbuttonandtheEMERG STORESJETT (ACK) light areilluminated for 5 secondsby the Sh4Pto indicate emergencyjettison has been commanded.For single storesloadedon a station,storeswill bejemsoned I at lOO-mil&cond intervalsin the following sequence: 1. Stations2 and 7 simultaneously
4. Auxiliary (AUK). Weaponarming aud fuzing and missile motor igni1 tion aresafed&abled during all jettison releasemodes.
2. Stations 1B and 8B simultaneously
I
3. Station 4 External fuel tanks, Phoenix, and Sparrow missiles can be releasedin EMERG, ACM, and SEL jettison modes only. Air-to-ground (A/G) weapons loaded on BRU-32 bomb racks can be releasedin all four jettison modes.ITERs andweaponsloadedon JTERs cannotbe releasedfrom their parent BRU-32 bomb racks in any of the jettison modes. Sidewinder missiles (rail launched)cannotbejettisoned. I,,,,,,(
4. Station 5 5. Station 3 6. Station 6. A&r the releasesequenceis completed, the SMS updates the stores inventory. Unlike other jettison modes or launch attempts,a storethat is not releasedis not declared a HUNG store and is eligible. for ~1‘Isequentjettison or launch.
l
Storesshall bejettisoned abovethe minimum fragmentation clearance altitude, when possible,eventhoughweaponarming and fuxing is safed/disabledin all jettison modes.
2.40.3.2 ACM Jettison. ACM jettison provides for rapid releaseof any preselectedcombiition of jettisonablestores.In additiontoRI selectionof thosestations to be separated,the only ACM jettison interlock is the LDG GEAR handleUP.
l
JettisoningA/G storesduring a normal releasetrain may result in store-to-storecollision in nearproximity to the aircratt.
l
If jettisoned during a takeoff emergency, external fuel tanks may collide with the aircraft because of their unstable characteristics.
Stationsareselectedfor jettison via the DEU. Figure 2-134 illustrates selection and display of external fuel tanks for ACM jettison. Only those stations having a jettisonable store.loaded that have not been de&red failed areavailable for ACM jettison selection. Eachdepressionof a stationbutton causesthatbutton display to toggle betweenJETT and SAFE. The DEU selectionsare not forwardedto the SMS until the enter button is depressed.Selectedstations are indicated on the MFD SMS format with an inverted “V” abovethe stationnumber.The symbol is removedif deselectedby the RIO and upon completion of an ACM jettison attempt or successtitljettison.
a If a jettison or delivery condition existed such that A/G storeswere releasedfrom stations 3 and 6 and not t?om stations4 and 5, an AFT CG advisory on the MFDs will not be posted. 2.40.3.1 Emergency Jettison. Emergency jettison is used to separateall jettisonable storesfiorn the aircrafl as fast as possible. The only interlock require1 ment for jettisonable stores is weight off wheels. The emergencyjettison circuit is electrically isolated from all otherreleasefunctionsofthe SMF’ andhasa separate electrical path to eachjettisonable store station. The mode is initiated by depressingthe EMER STORES
2-265
Note ACM JETT selectionsare retained in SMP nonvolatile memory. This allows selections to be retainedandenablesACM JETT without anoperableMCS. However,ACM JETT designations must be reselectedafter performing system reset to restoreACM JETT symbology on the MFD SMS format. ORIGINAL
NAVAIR
0%F14AAD-1
DISPLAY INDICATION
FUNCTION
ACM JETT pushbutton
Enables ACM jettison. Pushbutton is under ACM switch cover. When pressed, onl those stores selected via the DEU are jettisoned. To ensure release of al Y selected stores, the ACM JETT pushbutton must be depressed and held for at least 2 seconds.
2
ACK light
Redundant indicator for emergency jettison activation. Illuminates for 5 seconds, indicating the SMP has acknowledged the emergency stores jettison command.
3
EMER STORES JET-f pushbutton/light
Enables emergency jettison. When depressed with weight off wheels, activates emergency stores jettison signal to the SMS and illuminates light for 5 seconds, indicating the SMP has acknowledged the emergency stores jettison command. Jettison function is disabled with weight on wheels.
3
SEL JETT switch
Allows RIO to jettison from selected station(s). locked switch with guarded positions.
3 3 4
It is a three-position,
lever-
JETT - Actuates normal selective ‘ettison of the store(s) located at the station(s) designated by the JETTIS b N STA SEL switch. SAFE -
Normal operating position. Inhibits jettison in selective mode.
AUX - Releases all AIG stores loaded on BRU-32s from the station selected on the JETTISON STA SEL switch with a single switch movement. JETTISON STA SEL switch
Allows selective jettison of Phoenix or Sparrow missiles and auxiliary tanks. Allows selective or auxiliary jettison of air-to-ground stores. OFF Station
Inhibits selective and auxiliary jettison. -
Selects store(s) for jettison.
Figure 2-133. JettisonControls 2-266
NAVAIR Ol-Fl4AAD-1
SMS OPTION
SELECTED
ACM JEl-nSON SELECT SYMBOLS
PRES?.lNO DESIRED STAT,ON OPTlON TOOGLEa sETwEaN SAFE *ND JETT OPTlOrd
Figure 2-134. ACM JettisonSelectionand Display
2-267
ORIGINAL
NAVAIR Ol-l=‘l4AAD-1
ACM jettison is initiated by the pilot raising the ACM guard (Figure 2-133) and depressingthe ACM JE’IT pushbutton.For single storesloadedon a station, stores will be jettisoned at lOO-millisecondintervals in I the following sequence:
LDG GEAR handleUP. This mode is activatedby the RIO selectingthe stationto be jettisonedvia thejettison STA SEL switch and then selecting AUX on the SEL JE’IT switch. Auxiliary jettison of an A/G store loaded directly on a BRU-32 is via gravity force only.
1. Stations2 and 7 simultaneously p&i-) I
2. Stations IB and 8B simuItaneou~ly Sinceauxiliaryjettison for single A/G stores loadeddirectly on BRU-32s is a gravity drop ratherthanan ejectionseparation,theaircraft will he restrictedin its flight envelopewhen jettisoning through this mode.
3. Station4 4. Station5 5. Station 3
2.41 MISCELLANEOUS
6. Station 6.
I
After the releaseattempt is completed,the SMS updatesthe storesinventory. Unlike emergencyjettison, a store that is not releasedis declared HUNG. Such storesarenot eligible for launchbut arestill eligible for emergency or selective jettison. Additionally, A/G storesloadedon BRU-32s will still be eligible for auxiliary jettision. 2.40.3.3 Selective Jettison. Selective jettison is used to separatesingle jettisonable storesstation-bystationandalsoallows simultaneousjettisonofbothfuel tanks.The RIO selectsthedesiredstation(s)for selective jettison.
I
Selectivejettison is accomplishedby placing the MA ARM switch to ON, the LDG GEAR handle UP, the JETTISON STA SEL knob set to the desired station, and the SEL JJXI switch to JETT. After the release attemptis completed,the SMS updatesthe storesinventory. Unlike emergencyjettison, a store that is not releasedis declaredBUNG. Such storesare not eligible for launch,but are still eligible for emergencyor selective jettison. A/G storesloadedon BRU-32s will still be eligible for auxiliary jettison.
Do not attemptjettison of externalfuel tanks until wing fuel tanks are depleted. Wing fuel may be lost if the external tank quickdisconnectvalve sticks in the open position.
I
2.41.1 Boarding Ladder. A boarding ladder consistingof threefolding sectionsis housedin theleft fuselage betweenthe two cockpits. It is held in the closed positionby two mechauicallocking pins actuatedby the laddercontrol handlein the face of the boardingladder The laddermustbe manually releasedor stowedfrom the groundlevel.Unfolding theremainingtwo sectionsplaces theladderin a Rallyextendedposition.The bottomrungof theladderis approximately26inchesabovethedeckwhen in a fully extendedposition,with thenosegearunkneel~ and 12inchesabovethe deckifthe nosegearis kneeled.A LAD/CANOPY cautionlight on thepilot cautionadvisory paneladvisesthepilot that the boardingladderis not in a full up-and-lockedposition. 2.41.1.1 Boarding Steps and Handhold. There aretwo positive locking board steps,one on either side of theboardingladderdirectly below eachcockpit. They may be openedor closed from either cockpit or while standingon the boarding ladder. A single handhold is directly abovethe hoarding ladder.It is a spring-loaded door that fairs with the fuselagewhen released. 2.41.2 Nose Radome. The noseradomeis attached to theaimmfl by a top hinge andbottommountedlatches, permittingit to be rotatedup for accessandmaintenance. A jury strut attachedto the lower part of thedome canbe fastenedto the aimrafi bulkheadto hold thedomeopen.A minimum overheadclearanceof 16 feetis requimdwhen openingthe radome.The radarantem must be stowed beforeopeningthe mdome. Antennastow position is 0” azimuthand60“ tilted down.
2.40.3.4 Auxiliary (AUX) Jettison. Auxiliary jettiSO*is a nonejectionreleasemode for single A/G stores loaded on BRU-32s. Lie selectivejettison, this mode requires the MA ARM switch to be set to ON and the ORIGINAL
EQUIPMENT
2.268
Note After the noseradome is raisedand the jury strut fastenedin position, releasehydraulic pressureto take the load off the hydraulic system.
NAVAIR Wl=f4AAD-1
2.41.3 Systems Test and System Power Ground Panel. The SYS TEST and SYS PWR ground check panel (Figure 2-135) is on the RIO right consolepanel (accessiblefrom the boarding ladder with the canopy open)for controlling the activation of electrical circuits using ground external power. The panel cover is designedsothat, when it is closed,the switches inside are in the proper position for flight. In addition, when the landing gear handle is in UP, all switches are deactivated. The panel serves a maintenanceand preflight purposeand is not intendedfor useby the flightcrew. 2.41.4 External Baggage Container (CNU-1WA). The external baggage container (Figure 2-136) is a modified Aero ID 300-gallonfuel tankthat incorporates forward andalI baggagecompartments.Each compartment has an accessdoor (forward, letI side; aft, right side), a shelf, and a baggagetiedowo harness. The tiedown harnessconsistsof two setsof seatbeltstrapsthat form a crossoverpatternto secmebaggageto the shelf. The externalbaggagecontainermay be loadedwith any equipmentthat tits within the confines ofthe shelf,does not exceedthe shelf weight, andmaintainsthe cg limits. Locatebaggageas nearthe centerof the shelf aspossible. Careshould be takento ensurethat strapsaretight to precludeany significant shift of cargo.
Figure 2-135. SystemsTest and SystemPower Ground Panel
WEIOHT: LENOTH: DIAMETER: CAPACITY: S”SPENSION:
Figure 2-136. CNU-188/A External BaggageContainer 2-269 (Reverse Blank)
ORIGINAL
NAVAIR 01.Fl4AAD-1
CHAPTER
Servicing
3
and Handling
3.1 SERVICING DATA
pressuregaugeadjacentto the refuel receptacleon the ground refuel and defuel panel. Positioning of these valves can be used for selective ground refueling of either the fuselageor wing and drop tanks. The diit reading vent pressuregauge indicates pressurein the systemvent lines. When aircraft fuel tanks are full, tireling stopsautomatically.For hot refueling procedures, refer to paragraph7.6. For defueling procedures,refer toNAVAIROl-F14AAD-2-1.
The following servicing data is for use by the flightcrew and maintenancecrews who are unfamiliar with servicing the a&aft (Figure 3-1). When operating in andout of military airfields, consult the currentDOD IFR Supplement for compatible servicing units, fuel, etc. Figure 3-2 contains a tabulation of servicing data andpower units requiredto supportthe aircraft. 3.1.1 Ground Refueling. Single-point refueling is provided for pressuretilling of all aircraft fuel tanks through a standardrefueling receptacleon the lower right side of the forward fuselage.Ground refueling is controlledby two procheckselectorvalves andthe vent
The maximum refueling rate is approximately 500 gpm at a pressureof 50 psi. Nominal and minimum pressureis approximately 15 psi; maximum pressureis 50 psi.
Figure 3-1. Aircraft Servicing Locations
3-1
ORIGINAL
NAVAIR WF14AAD4
DESlGNAllON
enginecontrol)shall be set for type fuel in use.
ChevronFlo-Cool
wipes. Afler l-minute drying,wipe clean with
Figure3-2. AircraftServicingData(Sheet1of 2)
ORIGINAL
3-2
NAVAlR
OI-FI4AAD-1
POWER PNEUMATIC/ GAS TURBINE STARTING Acceptable Units
USN
ELECTRICAL POWER
ASHORE: NCPP-105 RCPT- 105 AiM47A-4 AFLOAT: AlS47A- 1
Ground Support Equipment Requirements
200 Ib/min at 75i3 (STD. DAY)
PNEUMATIC SYSTEM
psi
NR 5C (Electrical) NR 8 (diesel) MA-l MA-1A AIM32C-5 AIM32C-6
AHT-63164 TTU-226/E (AHT-73) MJ-3
115*20Vac, 400 f 25 Hz, 60 kVA, 3 phase rotation
70 Ib/min at 3 psi and 60°F
50 gallmin maximum at 3,000 psi
Emergency Landing Gear
3,000 psi at 70°F
Combined
1,600 psi at 70°F
Flight Hydraulic
TIRES TYPE
1,600 psi at 70°F
Canopy Normal (1,200 psi Minimum)
3,000 psi at 70°F
Canopy Auxiliary (600 psi Minimum)
3,000 psi at 70°F
Wheel brake accumulators
(2)
HYDRAULIC
NC8A MD-3 MD-3A MD-3M MA-3MPSU A/M32A-60 A/M32A-60A
PRESSURE PRESSURE
Hydraulic
AIR CONDITIONING
PRESSURE
Nose (2) 22X6.6-10 20 Ply
Ashore
105 psi
Afloat
350 psi
Main (2) 37X11.50-16 26 Ply
Ashore
245 psi
Afloat
350 psi
1,900 psi at 70°F
Arresting Hook Dashpot
6OO*lOpsi
Main Gear Shock Struts (2)
980 psi
Nose Gear Shock Strut
1,300 psi
Dry nitrogen, specification BB-N-41 B. Type 1, Grade A; is preferred for tire inflation and charging pneumatic systems since it is Inert, and therefore will not support combustion.
Figure 3-2. Aircraft Servicing Data (Sheet2 of 2)
3-3
ORIGINAL
NAVAIR O1-FlUAD-1
Ensurethat both the fueling unit and the aircrafi areproperlygrounded,bondingcableis connected between aircraft and refueling source,andthat fue extinguishingequipment is readily available.
l
l
During ground refueling operations, the direct-readingvent pressureindicator shall beobservedandrefueling stoppedifpressure indication is in the red band (above4 psi).
l
If the aircraft is being regularly serviced with JP-4 type fuel, the main fuel-control, fuel-grade (specific gravity adjustment) selectoron eachengine shouldbe resetto the IP-4 position, If the aircraft is being regularly servicedwith JP-8 or JP-5 fuel, the fuel-control,fuel-grade(speciticgravity adjustment) selector on each engine should be reset to the JP-8 or JP-5 position. Satisfactoryengineperformancedepends upon trimming of the engine fuel controls to ensureratedthrust, to prevent exceedingenginetemperaturelimits, and to ensureairflow compatibility with the air inlet duct opening.
3.1.3 Integrated Drive Generator Oil. The IDG has a filter bypass indicator at the bottom of the filter bowl (Figure 3-3, sheet 2). Extension of the indicator indicates contamination of the filter andthe needfor filter element replacement.Refer to NAVAIR Ol-F14AAD-2-1 for IDG oil filter replacement and servicing. IDG oil level is checkedat the IDG mounted on the forward right side of the forward accessorygearboxof eachengine.It is servicedat thepressuretill port on the right side.
Removal of JP-8 type fuel from the aircraft is not requiredbefore refueling with JP-5. If removal of JP-8 from the aircraft aboard ship is necessary,it shall not be defueledinto the storagetankscontaining JP-5.
3.1.2 Engine Oil. Engine oil level is proper when overflow oil startsto exit thedischargeport during servicing. For normal servicing, the sight gaugeon the oil storagetank is the primary indicator determining when servicing is required.During servicing, overflow oil exits the overflow dischargeport when the tank is properly serviced (Figure 3-3, sheet 2). Servicing is accomplished using PON-6 servicing cart. Normal oil consumption is 0.03 gallon per hour with the maximum being 0.1 gallon per hour. For oil servicing procedures, refer to NAVAIR Ol-F14AAD-2-1. The protrusionof a bypassindicator underneaththe oil scavengepump indicatesa cloggedfilter elementandrequiresreplacement. ORIGINAL
Do not overservice oil storage tank. Overservicing can causescavengepump failure and subsequentenginefailure.
Note Engine oil level shouldbe checkedwithin 30 minutes of engine shutdown,otherwiserun engineat 80 percentor greaterfor 10minutes to ensureproper servicing.
Note l
Lubricating oil (MIL-L-23699) is toxic and flammable. Protection includes chemical splashproof goggles, gloves, andgoodventilation; keep sparks,flames, and heat away. Keep lubricating oil off skin, eyes, and clothes; do not breathe vapors. Wash hands thoroughly after handling.
3-4
3.1.4 Hydraulic Systems. The main hydraulic systemsareservicedat the flight andcombinedhydraulic systemgroundservicingpanels.A hydraulicpressure filling cart is requiredto servicethe systemswith fluid, and an air-nitrogencart is requiredto preloadthe reservoirs. The outboardspoiler backup module is serviced at the servicingpanel on the outboardnacelleof the port engine.Additional hydraulic servicing is requiredat the main landing gearshock strut (Figure 3-3, sheet2), the nosewheelshock strut (Figure 3-3, sheet 2), and the arrestinghook dashpot(Figure 3-3, sheet 1). The flight reservoir fill and groundhydraulic power accesspanel and the flight system filter module (Figure 3-3, sheet 1) are on the starboardside. The combined hydraulic systemreservoirtill and filter module (Figure 3-3,sheet3)areontheportsideoftheaircratLIndication of hydraulicsystem thtidcontaminationcanbedetected by the position of the buttons on the Delta-P type filter units.
NAVAIR 01.Fl4AAD-1
MAIN LANDING GEAR SHOCK STRUT
Figure 3-3. Aircraft Servicing (Sheet2 of 3)
ORIGINAL
3-6
NAVAIR
0%Fi4AAD1
Figure 3-3. Aircraft Servicing (Sheet3 of 3)
3-7
ORIGINAL
NAVAIR 01-Fl4AAD-1
Temperaturerecording gaugesat the filter modules indicate the maximum temperatureattainedby the hydraulic fluid during the last tumup or flight. After a readinghasbeentaken,the temperahuegaugesmust be resetprior to the next hnnup.
All personnelin the immediate areashall wearearprotectionwheneveran engineis operating. Note If enginesare run up in front of a blast deflector,exhaustjet wake is deflectedup and to the sidesresulting in distortion of the patternsshown.
3.1.5 Pneumatic Systems. The pneumatic power supply systems,which provide for normal operationof the canopyand for emergencyextensionof the landing gear,aregroundchargedthrougha common tiller in the nosewheelwell (Figure 3-3, sheet3). The auxiliary canopy openpneumaticbottle is in the turtlebackbehindthe cockpit (Figure 3-3, sheet 1). Additional pneumatic servicing points areat both hydraulic systemsservicing panels,brake systems,and arrestinghook.
At maximum afterburnerpower, nozzles are nearly fully open; at military power, the nozzlesare nearly fully closed.
Individual pneumatic servicing points and pressure gaugesareprovided for the auxiliary andparking brake systems. Noie Dry nitrogen, specification BB-N-41 lB, Type 1, Grade A, is preferredfor tire inflation and for charging pneumatic systems since it will not supportcombustion.
p&A&--l Illumination of RDR ENABLE cautionlight on RIO CAUTION ADVISORY panelindicatespossibleradar radiation on deck.
3.1.6 Backup Oxygen Supply. The backup gaseous oxygen supply is servicedto a maximum of 2,100 psi from an accessin the forward right side of the fuselage. Servicing pressurecan be observedon a gaugein the pilot’s cockpit.
3.2.2.1 Hazards to Personnel. Minimum safe distancesfor personnelfrom groundoperationradarare indicatedin Figure 3-5, sheets1 and2. When the planar arrayradarantennais not radiating, minimum safedistancefrom other radiating antennasis 6 feet.
3.2 GROUND HANDLING
3.2.2.2 HERO Condition. HERO conditions exist when ordnanceor weaponscontainingelectroexplosive devicesarepresent.Hazardto personnelandequipment is greaterbecauseof the lower power density level at which EED react to radio frequencyradiation. The requirement to maintain a minimum safe distancefrom ground operatingradarcausesthe RF radiationhazard areato increasein size, therebyoverlapping into previously safe areasfor personnel.During HERO conditions, minimum safedistances(personnel)from ground operatingradar(Figure 3-5, sheets1 and2) shall not be consideredsafe.Minimum safedistancesduringHERO conditionsare shown in Figure 3-5, sheets3 and4.
3.2.1 Danger Areas. Engine exhaust and intake danger areas are shown in Figure 3-4. Noise danger areasare shown in Figure 3-6. (Figure 3-4 showstemperahnedistribution with afterburnersat maximum nozzle opening for idle, military, and maximum power.) Figure 3-4 showsexhaustjet wake velocity distribution with afterburnerat maximum nozzle opening for idle, military, and maximum power.
The high temperatureand velocity of the engine exhaust is extremely dangerous. Stay outsideengineexhaustareaincluded within a 90” cone extending900 feet behind the aircraft.
HERO unsafeordnanceconditionsincludeassembly/ disassemblyof ordnancesystems,testsinvolving electrical connectionsto the ordnance,suchasprimer resistance check, continuity checks, bare squibs, primers, blastingcaps,andotherEED having exposedwire leads and unshieldedordnancesubassembliessuchas rocket motors, warheads,and exerciseheads.
Suction at the air intake is strongenough to kill or seriously injure personnelby drawing them into or againstthe inlet. ORIGINAL
3.2.2 Radar Radiation Areas. The following paragraphsdescribe the hazardsto personnel,hazardsof electromagneticradiation to ordnance,and fuel ignition hazardsgeneratedduring ANIAPG-71 radaroperation.
3-6
NAVAIR 0%Fl4AAD-1
NOTE
MIUTARY
POWER
20 26 30 35 ‘lo
Figure3-4. Rumq DangerAreas- ExhaustJetWakeVelocityandTemper&m
ORIGINAL
Figure 3-5. RadarRadiation HazardAreas (Sheet1 of 4) ORIGINAL
NAVAIR
-
Ol-F14AAD-1
-Illtt H t 100
Figure 3-S. RadarRadiation HazardAreas (Sheet2 of 4)
3-11
ORIGINAL
NAVAIR Ol-Fl4AAD-l
.D,srANCE ,NCL”DES6 db aAFi3-vFACTOR .APO-71ANTaNNPI AzlMlmi SCANCENTSR SCANNED* es .ANTENNAELwAllON SCANCENTERFU(ED ATW
El
HERO S”SCEFnsl.F ORDNANCE WarEM AREA5 SHOWN ARE SASED ON 4.06 InWlcm~ DENSITY.
Figure 3-5. RadarRadiation HazardAreas (Sheet3 of 4) ORIGINAL
3-12
“AZARD POWER
NAVAIR Ol-Fl4AAD-1
HAZARDS
10
HERO UNSAFE
ORDNANCE-HERO
ORDANCE
HERO S”SCEPTlaLE
1. ORONANCE ASSEMBLY OR DISASSEMBLY S”CN AS REPAIR. ISKEEP. PARTS EXCHANGE. OR DEARMING. OEF”ZING, OR “NLOADlNG OF ORDNANCE.
ORDNANCE
SYSTEMS
ANY ORDNANCE PROVEN Ia” TESTS, TO CONTAIN EED THAT CAN BE ADVERSELY AFFECTED BY RF ENERGY TO T”E WlNT THAT THE SAFETY AND/OR REUANUM IS IN JEOPARDY WHEN THE SYSTEM IS EMPLOYED IN EXPECTED RF ENVIRONMENTS. SOME ARE s”SCEPT,aLE TO THE RF ENWRONMENT FOR ONLY A PART OF THE STOCKPlLE TO LAUNCH SEO”UENCE. FOR EXAMPLE. THE CONNECTlON OF AN “MaluCAL CABLE IN THE l.OAOlNG PROCEDURE MlaY BE THE ONLY TME ORDNANCE IS CONSlOEREO S”SCEPT,BLE. AT AU OTHER TIMES. IT MAY BE CONSlOEREO HERO SAFE ORDNANCE. HEROSAFEORONANCE
4.
UNSHIELDED WARHEADS.
ORDNANCE SUCH AS AND EXERClSE HEADS.
ROCUET
MOTORS.
AN” ORDNANCE T”AT IS SUFFlClENTLY WIELDED OR OTHERWSE PROTECTED THAT AU Em CONTAINED ARE ,MM”NE TO ADVERSE EFFECTS THAT DEGRADE SAFETY OR REL,AB,L,TY WHEN EMPLOYED IN AN RF ENVIRONMENT. THE ORDNANCE SHALL BE CONSIDERED HERO SAFE, PROVIDED THAT CENENAL “(EN0 REOUREMENTS HAVE SEEN COMPLIED WITH.
WHEN THE APO-,I-,XN-I, RADAR IS NOT RADIATING. OR IS RAD,AT,NG ,NTO A DUMMY LOAD. MlNlM”M SAFE DISTANCE FOR ORDNANCE FROM ONBOARD R&MATTING ANTENNAS SHALL BE 160 FEET.
LEGEND: HERO “NSAFE ORDNANCE HAZARD AREAS SHOWN ARE BASED ON 2.025 mW/cd POWER DENSITY.
NOTES .O,STANCE .ANTENNA SCANNED .ANTENNA
INCLUDES 6 db SAFE,‘” FACTOR ELEVATION SCANNER CENTRR 0 TO SW AZ,,,,“,,, SCAN CENTER FIXED AT 0
0
HERO S”SCEPT,BLE ORDNANCE SYSTEMS HAZARD AREAS SHOWN ARE BASED ON 4.05 mW/cmZ WWER DENSITY. OVER T,,E CARRER
SlOE ,RANSMISSION
ABOARD
Figure 3-5. RadarRadiation HazardAreas (Sheet4 of 4) 3-13
ORIGINAL
NAVAIR 01-FlUAD-
SOUND
I
LE”EL.5
INdSA
THIS TABLE CONTAINS ESTlMATED SOUND LEVELS FOR FIIO-GE400 ,MlXED FLOW, AUGUMENTED, AFTERBURNING TURBOFAN ENGINE. SOUND LEVEL CONTOUR LETTERSA~ s. c. AND D ,SHDWN IN THIS ILL”STRATION) REPRESENT A SPECIFIC rIBA VALUE. WHEN dSA VALUE IS IN THlS T.wLE, IT SHALL SE S”SSTlT”TED IN PLACE OF CONTOUR LETTER.
6
NOTE SOUND LEVEL CONTOURS SHOWN ARE FOR SINGLEXNGINE OPERATION. CONTOURS ARE SYMMETRICAL ABOUT ENGINE CENTERLINES D”RlNG DUALENGINE OPERATION.
‘EARPLUGSAND EAR MUFFSSHALL WHEN PERFORMING ENGINE R”N”P.
SE WORN
TOGETHER
‘IF ENGINES ARE R”N UP IN FRONT OF BLAST DEFLECTON. EXHAUST JET WAKE AND SHOULD SHALL SE DEFLECTED UP AND TO SIDES. RES”,.TlNG IN GISTORTION OF CONTOUR PATTERNS SHOWN. ‘AT MAXIM”?4 POWER. BURNERS ARE AT MmIM”fd AT MILITARY POWER THE IMINIMUM OPENINGS).
F110-GE.400 ENGINE AFTERNOZZLE OPENING (ZONE 5). NOZZLES ARE FULLY CLOSED
Figure 3-6. Noise DangerAreas ORIGINAL
3.14
NAVAIR 01.F14AAD-1
HERO susceptibleordnance systems are any ordnancesystemsproven (by tests)to containEED that can be adverselyaffectedby RF energyto the point that the safety and/or reliability of the system is in jeopardy when the system is employed in expectedRF environments.Some systemsaresusceptibleto the RF environment for only a small part of the stockpile-to-launch sequence.For example, the connectionof an umbilical cable in the loading proceduremay be the only time the system is consideredsusceptible.At all other times in the system’slife, it may be consideredHERO safeordnance. HERO safe ordnanceare any ordnancesuffrciently shieldedor protectedthat all EED containedby the item are immune to adverse effects that degrade safety or reliability when employed in its expectedRF environment (provided that general HERO requirementshave beencomplied with).
aircraft shall be spottedso the nose radomeoverhangs the side of the carrier.All necessarysafety precautions shall be enforced to prevent injury to personneland damageto equipmentaboardthe carrierandon adjacent ships that may accidentallystray into the main beam of the radar.
3.2.2.3 Fuel Ignition Hazard. When performing fueling or defueling operations,useminimum safedistancesoutside of radiation hazardareas.Fuel ignition hazardoccurs within 90 feet of the aircraft where RF radiationinducedsparkscould ignite flammable vapors of fuels.Fuel ignition hazardis basedon SW/cm* peak power density.
Before and during towing, ensurethat the needle(s)in the AUKPARK brakepressure gauge(s)remainsin the greenbandto ensure sufficient pressureto lock the wheels.
Goodhousekeepingoperationsare of utmost importance in areaswhere radar transmissionis anticipated. RF radiation may cause steelwool to be set afire or metallic chips to-produce sparks, which in turn may ignite spilled fuels or oils aroundaircraft andbuildings. Keep all areasclean andrefuse in approvedcontainers. 3.2.2.4 Transmission Aboard Carrier. Radar transmissionaboardcarrier shall be limited to over-theside operationat the discretion of the commander.The
3-15
3.2.3 Towing Turn Radii and Ground Clearances. Forward andrearwardtowing (Figures3-7 and 3-8) canbeaccomplishedwith a standardtow bar (NT-4 aircraft universaltow bar) and the tow tractor.The pilot cockpit shall be mannedwith qualified personnelduring towing operations.
3.2.4 Tiedown points. Aircraft tiedown points are illustrated in Figure 3-9. When mooring a parked aircraft, do not dependupon chocksalone to hold the aircraft in position. Tiedowns shall be installed in a symmetrical pattern being careful not to chafe against the aircraft structure. The normal six-point tiedown (Figure 3-9, sheet 1) locations permit all maintenanceservicing, including engineremoval. iackina. and weanonsloading. Standardchain-type tiedowni’are used ‘for an 18-p&t symmetrical . tiedown during heavy weather (Figure 3-9, sheet2).
ORIGINAL
NAVAIR Ol-F14AAR-1
CENTER
l
DO
NOT
SWl”EL
NOSEWHEEL
NORMALLY TOWED
AIRCRAFT WITH
RADOME
SHALL
NOT
6 FEET 4 FEET
***rC :-----.. BE
OPEN.
Figure 3-7. Towing Turn Radii
ORIGIN/IL
FORWARD
MORE
THAN 9v LEFTOR RlGHTFR0P.l CENTER WHILE AIRCRAFT IS BEING TOWED OR PVSHED FORWPiRD OR AFT. PARKED. OR SPOTTED. SWIVELING NOSEWHEEL MORE THAN 90* WILL SHEAR SPLINED OUTPUT SHAFT OF STEERING DAMPER UNIT AND CAUSE LOSSOF SHiMMY WmPlNG AND STEERING. AND JAMMING OF NOSE LANDING GEAR SHOCK STRUT DURING RETRACTION. l
FOR
3-16
8-M lNCHES 4-712 INCHES
(STATIC) (KNEELED,
TOW,NG
NAVAIR 0%Fl4AAD-1
DO NOT EXCEED 90D MAXlM”M A”AILABLE NOSEWHEEL SW,“EL ANGLE DURING PARKING OR SPOTTING IN TGHT SPACES: STEERING DAMPER “NIT WILL BE DAMAGED.
.
WINO AND TNL WALKERS. MEN SHALL BE AYAILABLE
AND MAIN LANOINO GEAR CHOCK AT ALL TIMES DURING TOWING.
.
IN NOSEWHEEL WELL, BRAKE ACCUMULATORS PRESSURE GAGE SHALL INDICATE 3,999 psi. ON PILOT CENTER CON. SOLE. BRAKE PRESSURE INDICATOR NEEDLE SHALL BE AT RIGHT END OF NX GREEN BAND. WINGS SHOWN IN 69’ SWEPT POSITION
CENTER
PO,
BAR
MAlN LANOlNG GEAR TIE DOWN RlNG fZl. TOW BAR (TILLER BAR) IS REWIRED AT NOSEWHEEL FOR DlRECTlONAL CONTROL
,2O’MAXlM”M AVAILABLE NOSEWHEEL SWIVEL .4NGLE LEFT OR RIGHT FROM CENTER
_
_. FROM
3TE TH WNGS IN ANY SWEEP __ . - 2o” (UNSWEPT) TO 75” lOVERSWEPT)
(TILLER BAR, IS REQUIRE AT NOSEWHEEL FOR DlRECTlONAL CONTROL
ANGLE TOW
/ MD-SA TOW TRACTOR. AT-75 TOW TRACTOR, OR ANYTRACTORUNDER 3 FEET 9 INCHES
TRACTOR
,
AIRCRAFT TOW FITTINGS INCORPORATED IN LOWER STRUCTURE OF EACHNACELLE
\ NT-4 NRCRAFT “NIVERSAL TOW
BAR
Figure 3-8. Towing
3-17
ORIGINAL
NAVAIR Ol-FWAAD-1
Figure 3-9. Tiedawn Arrangement(Sheet 1 of 2)
ORlblNikL
3-18
NAVAIR
AIRCRAFT
TIEDOWN
01.Fl4AAD-1
FITTINGS
Figure 3-9. Tiedown Arrangement(Sheet2 of 2)
3-19 (Reverse
Blank)
ORIGINAL
NAVAIR 01.FI4AAD-I
CHAPTER 4
Operating
Limitations
4.1 LIMITATIONS
2. Maximum canopyopen speed -
60 knots
This section includes the aircraft and engine limitations that muat be observedduring normal operations. The aerodynamicand structural limitations in this section apply only to F-14D aircraft for the store station configurationsshown in Figure 4-l. Engine limitations apply to all aircraft with the Fl IO-GE-400engine.
Use of antiskid must be in accordancewith the following procedures:
4.1.1 Engine Limits. Engine instrument markings for various operation limitations are shown in Figure 4-2. Engine operating limitations are shown in Figure 4-3.
a. Selectantiskid while stoppedon the runwayin thetakeoff position; afterlanding,mm antiskid off once slowedbelow 15 knots prior to clearing the runway.
The engine secondary (SEC) mode may be intentionally selected in flight only under the following conditions:
b. Use only during landing or abortedtakeoff. c. Do not useantiskid while taxiing. 4.1.6 Ejection Seat Operation Limits. See ejection envelopecurves,Chapter16, Figure 16-l.
1. Engine operating between 85-percent ‘pm and military power
1. Maximum speed(seat) -
2. Airspeed less than 1.OTMN. 4.1.2 Starter Limits. The startercranking limits are as follows: 1. Crossbleed 2. Startcart -
600 knots.
[WPIRNING)
2 minutes.
Ejection above 350 knots is hazardous,the decision to exceed350 knots rests with the aircrew.
5 minutes.
When the time limit is reached,10 minutes cooling is requiredbetweencranking.
4.1.7 Autopilot Limits. Autopilot should not be usedunderthe following conditions:
4.1.3 Airstart Envelope. The engine spooldown andwindmill airstartenvelopesareshownin Chapter14, Figure 14-3.
1. Airspeedsgreaterthan 400 KCAV0.9 TMN 2. Altitude above42,500feet.
4.1.4 Crosswind Limits. Crosswind takeoffs and landingsarepermitted with a crosswind componentnot to exceed20 knots at 90”.
4.2 AIRSPEED LIMITATIONS The limits and restrictions in this part representthe maximum capability of the aircratl commensuratewith safeoperations.Aerodynamic andstructuralexcessesof
4.1.5 Ground Operations Limits 1. Maximum tire speed -
pi-z-1
190knots. 4-I
ORIGINAL
NAVAIR
Ol-Fl4AAD-1
STORE CONFIGURATION lN*) 1Bl 182 1c
. . . l
l
.
I
.
l1A
16
AIM-9 AIM-9
AIM-9
l-
345&6
88
BA
AIM-9
AIM-9 AIM-9 -
TANK
TANK 4 AIM-7 W”) AIM-9 4 AIM-7 AIM-9 AIM-9 281 AIM-9 AIM-9 AIM-9 4 AIM-7 282 AIM-9 AIM-9 AIM-7 4 AIM-7 AIM-7 2B3 AIM-7 4 AIM-7 AIM-7 284 TANK 4 AIM-7 TANK .w*j AIM-9 AIM-9 AIM-9 TANK 4 AIM-7 TANK AIM-9 2Cl TANK 4 AIM-7 TANK AIM-9 2c2 AIM-9 AIM-7 TANK 4 AIM-7 TANK AIM-7 AIM-9 2C3 AIM-9 AIM-7 TANK 4 AIM-7 TANK AIM-7 2C4 4 AIM-54 3A(*) AIM-9 4 AIM-54 AIM-9 AIM-9 3Bi AIM-9 AIM-9 AIM-9 4AIM-54 3B2 AIM-7 4 AIM-54 AIM-7 AIM-9 383 AIM-9 384 AIM-7 4 AIM-64 AIM-7 AIM-64 AIM-54 AIM-9 385 AIM-9 4 AIM-64 386 AIM-54 4 AIM-54 AIM-54 TANK 4 AIM-54 TANK 3C(‘) AIM-9 TANK 4 AIM-64 TANK AIM-9 AIM-9 3Cl AIM-9 3C2 AIM-9 TANK 4 AIM-64 TANK AIM-9 AIM-7 TANK 4 AIM-54 TANK AIM-7 AIM-9 3c3 AIM-9 AIM-7 TANK 4 AIM-54 TANK AIM-7 3c4 AIM-54 TANK 4 AIM-54 TANK AIM-54 AIM-9 3c5 AIM-9 3C6 AIM-54 TANK 4 AIM-54 TANK AIM-54 en multir (‘) These store conf ration limi 11~0apply 10~8stub pylc are carric t stations 1 E 6. Flight operating limitations applicable to the above configurations are also applicableto down loadings, except down load of external tank to MXU-776/777 which shall be considered as a clean store station for limitation purposes. For captive carriage of inert or live AIM-54, installation of ejector cartridges in LAU-132 is mandatory in order to provide jettison capability. ForcaptivecarriageofinertorliveAIM-7,installationofejectorcartridgesinLAU-92ismandatoryinordertoprovidejettison capability.Thisdoes notapplytoCATM-7F-Zmissiles usedfor ballast (refertoNAVAlR01 -F14AAD-75 Weapon Stores Loading Manual). For shorebased operations all CATM-7F-1 (Sparrow training rounds) shall be configured with a modified shear wafer to preclude inadvertent actfvation of the guidance and control unit, and subsequent ejection of the missile. Simultaneous loading of AIM-7 on store station 4 and AIM-54 on store station 3 and 6 is an authorized configuration. Limitations of fuselage AIM-54 apply for carriage, individual missile limitations apply for launch/jettison. AIM-9 conffgurations include both LAU-7 and LAU-130 carriage. IWARNINO) . In all cases the center of gravity position must remain within limits. The aft limit can be easily exceeded if stations 3 and 6 are not loaded. l
With MA ARM ON and all conditions satisfied for AIM-54 launch, an ATM-54 (training round) will be ejected if the trigger or launch button is depressed.
l
With MA ARM ON and all other conditions satisfied for AIM-7 launch, a CATM-7F-1 (Sparrow training round) will be ejected when the trigger or launch button is pressed unlessamodifiedshearwaferisinstalled. Emergency/selectiiejettisonofaCATM-7F-1 is Still Dossible with a modified shear wafer installed.
Figure 4-1. Store StationConfiguration
ORIGINAL
4-2
NZtS
NAVAIR Ol-Fl4AAD-1
F 11 O-GE-400 OIL: MILL-23699 OR MIL-L-7808 FUEL: MIL-J-5624 JP5 (JP-4, JP-8 ALTERNATES)
Figure 4-2. InstrumentMarkings
4-3
ORIGINAL
NAVAIR Ol-Fl4AAD-1
FllO-GE-400
Figure 4-3. Engine OperatingLimits
ORIGINAL
4-4
NAVAIR 0%Fl4AAD-1
these.limits shall be enteredon the maintenanceaction form for appropriatemaintenanceaction.
4.2.1.3 In-Flight Refueling 1. Refueling probe -
4.2.1 Maximum Airspeeds. Maximum speeds are presented in calibrated knots and true Mach number. These values are derived from the positionerror-correction curves of the production pitot-staticoperatedairspeedandaltitude system.AOA is presented utilizing the conventional indicated units AOA while sideslip angle limits are presentedin terms of degrees rudderdeflection.
4.2.1.1 Cruise Configuration. With wing sweepin theMANUAL or AUTO mode, themaximum allowable airspeedsare shown in Figure 4-4.
20°.
2. 5 0.7 TMN -
25’.
3. < 0.8 TMN -
SO’.
4. S 0.9 TMN -
60’.
5. > 0.9 TMN -
68”.
4.3 ACCELERATION LIMITS
4.3.2 Approach Configuratlon 1. Landing gearand/or landing flaps and slats to 2.Og(symmetrical or rolling). 4.4 ANGLE-OF-ATTACK
0
LIMITS
4.4.1 Cruise Configuration. AOAislimitedbythe maximum allowable load factor of Figure 4-5, the maneuveringlimits of Figure 4-8, and the sideslip limits only underthe following conditions:
280 KCAS.
2. Landing flaps andslats -
3. In-flight refueling (approachconfiguration) 170to 200 KCAS.
4.3.1 Cruise ConfiguratIon. See Figures 4-5 and 4-9.
4.2.1.2 Approach Configuration 1. Landing gear -
200
Coordinatedturns with small rudderand lateralstick inputsaredefinedassymmetrical flight.
In emergencywing-sweepmode, the following combination of Mach and wing-sweep schedule must be used: -
2. In-flight refueling (cruise configuration) to 300 KCAS/0.8 TMN.
Note Limits are based on a gross weight of 49,548 pounds. See Figure 4-5 for the variation of maximum ?oad factor with grossweights greaterthan49,548pounds.
Note Unless otherwise specified, the limits presentedhereinpertainto flight with the stability augmentationsystemon.
1. <0.4TMN
400 KCAZVO.8TMN.
1 WARNING
1
225 KCAS. With roll SAS on, departureresistanceis reducedbecauseof adverseyaw generatedby roll SAS inputs. Subsonicmaneuveringwith roll SAS on shall not be conductedabove15 units AOA with landing gearretracted.
With the landing gearextendedor in transit, abrupt rolls or uncoordinated turns above 225 KCAS can cause structural failure of the landing geardoors.
1. Wing sweep -
AUTO.
2. Clean or all air-to-air storeloadings exceptthose that include wing-mountedAIM-54.
After takeoff, move the FLAP handle to the UP position passing 180KCAS to ensure flap and slat airspeedlimits are not exceeded.
Under all other conditions,maneuveringis permitted only to the AOA limits of Figure 4-7 or the maximum allowable load factor of Figure 4-5, whichever occurs 4-5
ORIGINAL
NAVAIR 01-F14AAD-1
DATE : DATA BASIS
:
FEBRUAFIY FLIGHT
IS.92 TEST
1.1’ 0.2
0.4
I’ 0.6
1’1’ 0.6
1’1’1’ 1.0
13
TRUE
MACH
1.4
1.6
I’ 1.6
I’ 20
I 2.2
NUMBER
1 / 1 ~, /I / i . , / , j , /I / , / , i 2 i ................. .I ....i.....i.. .I......... I..... ...,;j STORE CONRGURATIONS ,c, zc, 2c2, 2Q, wND 2c4 +;-~--~I--~~-+i~-:~::-: ....r /...f 1...... .I I.........r ....i”“l”“““” ....T .............. ....1’ ................... ...............(- .......*.... ...............* ............... ....$-~ 1”” .........t”” ..... .....(““i’- ”..v +...~.-~ ..- .,_ +.j “4. .“;. [+L i “1:” .......~3.. .I .... .....y ....I......... ............... ....$.....+. .... ..... ................. ................... .....+ ....“....j.....I.... ....j.- ..... .... ..... ...... ,-.+ j ~fi_:: ..i.. i..~, :.I.. I.. i..~ .... .... .I ..... I/ / i /ids
1 40
0 02
6.4
0.6
0.8
1.0
1.2
TRUE
MACH
1.4
1.6
1.6
NUMBER
Figure 44. Maximum Allowable Airspeeds(Sheet1 of 3)
ORIGINAL
4-6
210
2.2
NAVAIR 01-FlUAD-I
DATE DATA
: BASIS
:
FESRUARV FLIGHT
,332 TEST 1
~~-7
f :I
0
/
j
:
,i.!i,i,iiSlil
i
yj I
1:;
I
,
0.4
0.2
I
I
0.6
,
0.3
.q
I
I
1.0
1.2
TRUE
o.
:
,
0’
I,/,/
I ’ i STORE CONFIQURAVIONS 1B1, ?A, Zi‘l, 2i,Zi 283, Ah 264’ ‘( + .‘.....i ^... f + (....,...,.... y.‘.... i...+...,..2 ._..;... . . .. .i..+-; . ...... I....4 i-J j ,-!
MACH
I 1.4
, 1.0
I
, 1.8
I
I 2.0
i
40I
30
I....;
i
. . . ..
j
J
J
i .....
J”...]
I.,,.;
/
.,.
.,,.j.....f ..... J / I.....: / i
J
J
2.2
NUMBER
1:: j:::::/:..t :I
3::::J:::::l::::: t::::;::::t::::i:::::i::::: . ,.,.. j
I..-~..J.”
./ . i.-.c..i.llll..;il;~~.
ii
... . / j..ll:[IlllilllJff:::
10
0.2
0.4
0.6
0.0
1.0 TRUE
1.2 rn MACH NUMBER
1:s
1s
i0
iz
Figure 4-4. Maximum Allowable Airspeeds(Sheet2 of 3)
4-7
ORIGINAL
NAVAIR
Ol-Fl4AAD-1
DATE: DATA
BASIS
FEBRUARY1032 :
FLIGHT
o
TEST
,‘i,:i)!,,ifi!,rfl,,/q I 0.2
I,,,, /. I,
! I,
0.4
I, 0.0
I, 0.0
1.0
i x: .i/ I, ,.a
i
$8
I,
1.4
1.6
; ~ ’ / 1 ; ; ’ ’ j ’ ’ ’ ’ : STORE CONFIGURATIONS X1, SC,, SC?. . ....* 8 i...& ~ . .....i L /..... ....+..... ... ..i.... ~ /:
5o -J:j
O
,i I, 1.8
’
;: IV’
?C?. ?Ne \Ci? “’ ““’ “‘.. ““i”” ‘.“‘r ... ..... f ..... ....I i ....! l.... .i....f....f ..... I
0.4
/
/‘/ I/ 0.6
I 0.8
a.2
i l&i
j!. I..!
I 2.0
:::::t:::j ::::1:::::/:::::p&j ::::Lj :::::/:::::p::f
0.2
I 1.0 TRUE
I 1.4
12 MACH
I..,.
:ii I
, I.0
I
1 1.8
NUMBER
Figure 4-4. Maximum Allowable Airspeeds(Sheet3 of 3)
ORIGINAL
./: I,
I
, 2.0
I 2.2
NAVAIR Ql-WIAAD-I
DATE: JUNE ,992 OATA BASIS: PLlOHT
TEST
GROSS
WElOM
- ,000
POUNDS
Figure 4-5. Variation of Maximum Allowable Normal Load Factor With GrossWeight
4-9
ORIGINAL
NAVAIR Ol-F14AAD-1
lessthan 62”, limit lateral stick deflection to one-halfpilot authority.
first, and the maneuveringlimits of Figure 4-8 and the sideslip limits of Figure 4-6.
Note AOA limitations shown in Figure 4-7 apply to designatedconfigurations.
Note Refer to High Angle-of-Attack Flight Characteristics and Engine Operating Characteristics in Chapter 11.
4.5.4 Sldeslip Limits 4.4.2 Approach Configuration. Maximum allowableAOA with landinggearandflaps extendedis shown in Figure 4-6.
4.5.4.1 All External Store Configurations 1. Below 0.7 TMN - Rudderinputs asrequiredto maneuveraircraft at high AOA.
4.5 MANEUVERING LIMITS
2. Above 0.7 TMN - Rudder inputs coordinated with lateral stick as requiredto educeor eliminate the effects of adverseyaw at high AOA.
4.5.1 Approach Configuration. Withlandinggear and/orlanding flaps andslatsextended,abruptyaws are prohibited. Refer to Figure 4-6 for approachcont&uration sideslip limits. With landing gearextendedor in transit, abruptrolls and uncoordinatedturns shall not be performed above 225 KCAS. 4.52 Cruise Configuration. With maneuverslats/ flaps extended,maximum allowable load factor is 6.5g or the limits of Figure 4-5, whichever is less.
Rapid rudderinputs causenoseuppitch and may generatesnaproll departures. 3. Above 1.70 TMN prohibited.
Subsonicmaneuveringwith roll SAS on shall not be conductedabove 15 units AOA with the landing gear retracted. Cross control inputs shall not be used in the areaof the flight envelopeindicated in Figure 4-8.
Intentional
sideslips
pi&-( If a supersonicenginestall and/or failure occurs, arrest roll rate with lateral stick only. Yaw SAS will maintain sideslip angle within acceptablelimits.
When automaticmaneuveringflaps/slatsare not operating,uncoordinatedlateral control inputs shall not be usedin theareaofthe flight envelopeindicatedin Figure 4-8.
Note Use of full availablerudderis permittedat all airspeedsif required to counteractadverse yaw encounteredin maneuveringflight.
4.5.3 Rolling Limits. With maneuverslatsand flaps extended,maximum allowable load factor is 5.29or the limits ofFigure 4-9 (roll SAS on or roll SAS off) whichever is less.Rolling limits areshown in Figure 4-9.
4.5.5 Prohibited Maneuvers. Thefollowingadditional maneuversareprohibited: 1. Intentional spins. 2. During afterburneroperations:
Do not initiate full lateral stick inputs above4.5g ifa 5.2g limit appliesor above 3.5gifa4.0glimit applies.Control system dynamics may cause load factor to increasebeyondlimits.
a. Sustainedzero to negative0.5g flight. b. Flight from negativeO.Sgto negative2.4g.sfor more than 10 seconds.
If outboard spoilers fail with airspeed greaterthan 400 KCAS and wing sweep ORIGINAL
3. At MIL power or less:Zeroor negative-gflight for more than 20 seconds. 4-10
NAVAIR Ol-Fi4AAD-1
LANDING GEAR AND/OR FLAPS EXTENDED
Figure 4-6. Maximum Allowable Angle-of-Attack RudderDeflections
4-11
ORIGINAL
NAVAIR Ql-FlUAD-
CRUISE CONFIGURATION
Figure 4-7. Angle-of-Attack Limits
ORIGINAL
4-12
NAVAiR WFl4AAD-1
Figure 4-8. ManeuveringLimits 4. AIM-9 launch with landing flaps and slats extended.
Cruise Configuration
4.6.2 Approach Configuration 1. Pitch SAS off -
LBA.
5. Fuel dumping with aftcrbumer operatingor with speedbrak~ extended.
2. Yaw SAS off -
6. Dual-engine afterburner takeoffs, waveoffs, bolters,of catapult launches.
3. Roil SAS off - Not permitted during takeoff and landing flap and slat transition.
7. Single-engine maximum afierbumer takeoffs, waveoffs, bolters, or catapultlaunches. 8. ACLS mode illA approaches.
Roll SAS must be let? on for carrier landings with storeasymmetrygreaterthan 170,000inch-pounds.(Example: weaponrail at station 6 and AIM-54 missile at station 8 equals170,000inch-pounds.)
9. Roiling maneuverswith AOA changegreaterthan 360’ arc prohibited.
4.7 TAKEOFF AND LANDING FLAP AND SLAT TRANSITION LIMITS
4.6 SAS LIMITS
LBA.
4.7.1 Clean and Symmetric Stores Loading. See Figure 4-10.
4.6.1 Cruise Configuration 1. Pitch SAS off -
LBA.
2. Yaw SAS off -
1.OTMN.
1. All transitionswill be made in less than 45Obank angle,roil SAS on. 2. All normal (flaps and slats fully down) takeoff transitionswill be initiated at a minimum altitude of 200 feet AGL.
3. Roil SAS off - 1.0TMN (wing-mountedAIM54); 1.52TMN (externaltanks, fuselageAIM-54, /VG stores);I.6 ‘I’hIN (all other configurations).
3. All othertransitionswill be madeat standardfield operatingaltitudes,but no lessthan800 feetAGL. 4-13
ORIGINAL
NAVAIR
Ql-Fl4AAD-1
F-14D
ROLL SAS ON
MANEUVERING DATE: DATASASS :
SEPTEMBER ESTIMATED
0.2
0.4
,884 FUGHT
TEST
0.0
1.0
0.8
1.2
TRUE
ROLLING
MANEUVERS
ENVELOPE
RESTMCTSO REGION
I-
380’ MAXMUH
SANK
2 - 380’ UAXIMVM
ANGLE
MAXIMUM
BANK
BANK
2 - NO ABRUPT SO’
2.0
1.8
2.2
NUMBER
CHANGE
CONflGURATlONS WIT” 0T”ER CONF,GVRAT,ONS
130’ MAKIMUM
REGION
MAUI
1.s
To:
4.00 -ALL 5.20 -ALL
REGION
1.4
ANGLE
STICK
SANK
ANGLE
AND:
EXTERNAL
CHANGE
CHANGE
FUEL
TANKS
OR WING-MOUNTED
AIM-54
AT IO:
AT OTHER
THAN
10 (So MAXIMUM)
INPUTS:
ANGLE
CHANGE
AT ,G ONLY
NOTE: 00 NOT W.CEEQ
MAXIMUM
ALLOWABLE
AIRSPEED
FOR STORE
CONFIGURATION.
Figure 4-9. ManeuveringLimits -
ORIGINAL
4-14
NATOPS
LIMITS
Rolling (Sheet 1 of 2)
OF FIGURE
4-4
APPLY.
NAVAIR
OI-FI4AAD-I
F-14D ROLL SAS OFF MANEUVERING ENVELOPE DATE DATA
: SASS
SEPTEMBER ESllYArED
:
,964 FLlGHT
TEST
50
40
30
M
10
a 0.2
a.4
as
0.8
1.0
1.2
TRUE
ROLLING
MANEUVERS
RESTRICTED REGION
I-
MACH
1.4
1.6
1.8
To:
360’ MAXlM”M SANK ANGLE CHANGE - 180’ MAXIMUM SANK ANGLE WANGE (OG MINIMUM TO 5.30 MAXIMUM)
AT 10 AT OTHER
TNAN
10
AIM-54: ENVELOPE
- FOR ALL OTHER CONFIGURATIONS W,TH EXTERNAL FUEL MOUNTEG AM-S.,, OR AIR-TO-GROUND STORES: ROLL SAS M”ST SE ON ASOVE 1.52 TMN REFER TO ROLL SAS ON MANEUYERlNG ENVELOPE 3 - ROLL
2.2
N”MSER
- FOR CONFIGVRATIONS WV”, WING-MOUNTEO ROLL SAS MUST SE ON ABOVE 1.0 TMN REFER TO ROLL SAS ON MANEUVERING
REGION
2.0
SAS MUST SE ON REFER TO ROLL SAS ON MANEVVERlNG
TANKS.
FUSELAGE
ENVELOPE
NOTE: 00 NOT EXCEED
MAXIMUM
ALLOWABLE
AIRSPEED
FOR STORE
Figure 4-9. ManeuveringLimits -
4-15
CONFIGURAnON.
NATOPS
LIMITS
OF “GVRE
4-4 APPLY.
Rolling (Sheet2 of 2)
ORIGINAL
NAVAIR
Ol-F14AAD-1
Note Do not attempt shipboard landing with inoperative roll SAS and greater than 170.000 in-lbs asymmetry unless divert field unavailable. FLAP TRANSITIONS: CLEAN OR SYMMETRICAL Less than 45” angle of bank
UP TO 66,000 IN-LB ASYMMETRY
GREATER THAN 66,000 IN-LBS ASYMMETRY
1. Wings level
1. Wings level
!. Roll SAS on
2. Roll SAS on
2. Roll SAS on
I. Minimum 200 feet AGL on takeoff
3. Minimum 200 feet AGL
3. Minimum altitude of 1,200 feet AGLfor takeoff and landing
I. Dirty-up altitude minimum 600 feet AGL
4. Dirty-up
at minimum 800 feet AGL
4. Minimum 180 knots.
i. Minimum
5. Minimum
180 knots
180 knots
Available roll control will be marginal to inadequate in event of asymmetric flap/ slats without lockout. Note Incompatibility of flap transition limit with existing Case I procedures recognized. Although improvement of flap/ slat system reliability has been accomplished, not enough data is available concerning failure mode/rate of improved asymmetry sensor. Minimum flap transition altitude may be waived in cases of operational necessity.
Figure 4-10. Flap Limitations ORIGINAL
4-16
4. All flap and slat extensionsand retractionswill be madeat a maximum of 12 units AOA.
siles on fuselage stations until the following AAC are incorporated:
4.7.2 External Stores Loading With up to 66,000 Inch-Pounds (5,500 Foot-Pounds) Asymmetry. AIM-7 on Stations 1B or 8B equals
(I) AAC 618 pylon.
Modifies multipurpose
64,000inch-pounds.
(2) AAC 673 structure.
Modifies fuselagebackup
1. All transitions will be made in wings-level flight with roll SAS on. 2. All normal (flaps and slats fully down) takeoff transitionswill be initiated at a minimum altitude of 200 feet AGL. 3. All flap and slat extensionsandretractionswill be madeat a maximum of 12 units AOA.
(3) AAC 688 - Modifies pylon-mounted swaybraces. 4.9
BARRICADE
ENGAGEMENT
LIMITS
1. Wings at full forward sweep angle (20”) 51,800pounds(maximum). a. Flaps and slats extendedor retracted.
4.7.3 External Stores Loading With Greater Than 66,000 Inch-Pounds (5,500 Foot-Pounds) Asymmetry. All transitions will be made in wings-
b. No externalstoresexceptAIM-7 or AIM-54 on fuselagestationsonly.
level flight with roll SAS on at a minimum altitude of 1,200feet and at a maximum of 12 units AOA. 4.6
GROSS WEIGHT LIMITS LAUNCH, AND LANDING
1. Catapultlaunch -
-
c. Empty external fuel tanks permitted only for landing gearmalfunction.
TAKEOFF,
2. Wing-sweep angle greaterthan 20° up to 35O46,000pounds(maximum).
76,000pounds. a. Flaps andslats extendedor retracted.
p-G--,,,,,,,
b. No externalstores,exceptempty externalfuel tanks for landing gearmalfunction only.
Single-enginerateof climb at 76,000-pound gross weight using optimum flight control techniqueis predictedto bebetween300 and 600 fpm. Emergencyjettison of storesmay be required to establish adequate rate of climb.
3. Wing-sweep angle greater than 35” permitted. 4.10
OF GRAVITY
POSITION
LIMITS
Unless otherwise stated, the following cg limits
apply:
1. Field takeoff and emergencylanding (minimum rateof descentonly) - 72,000pounds. 2. Field landings -
CENTER
Not
store Configurations
60,000pounds,
3. Field carrier landing practice or carrier landings - 54,000pounds.
1;;i;2c, IBl,
a. Landing approachesto touchdown shouldnot exceed17 units AOA to avoid nozzle/ventral tin damage.
2c,-4
182, lC, TARPS,
All other configurations
Maximum Forward
r3%
Maximum Aft
MAC j 18.5% MAC
6.3% MAC
17.5% MAC
6.3% MAC
17.0% MAC
b. Only minimum descentrate landings are permittedwhilecarrying AIM-7E/F and/orAIM-9 on the multipurposepylon, or AIM-7E/F mis-
4-17
ORIGINAL
NAVAIR Ol-F14AAD.1
Throughout theseflight operatinglimits, all cg positions are quotedat the following referenceconditions: 1. Zero fuel grossweight (includes weight of stores carried on flight). 2. Wing-sweep angle= 20”.
4.11.2 External Baggage Container (CNU188/A). The external baggagecontainer (blivet) may be carriedon station4 or 5 with all loadingsauthorized fortheTARPSpod(Figure4-11). Simultaneouscarriage of a blivet anda TARPS pod or hvo blivets is not authorized. The blivet must be configuredwith a long tail cone and no fins. 1. Maximum airspeed -
3. Landing gearand flaps extended.
2. Acceleration limit 1 WARNING
1
The aft cg limit will be exceededif all stations are configured for AIM-54 missiles or Mk 83/84 bombs and only stations4 and 5 are loaded or remain as a result of tiring, dropping, or jettison of stations 1, 3, 6, and 8. If the aft cg limit is exceeded,airspeed/ AOA control may be difftcult. Fuel statesof 5,000to 6,000 poundsresult in the most favorablecg position.Slightly aft wing- sweep positions of 25” to 30° will move the neutral point aft and should restorenormal longitudinal stability.
3. AOA limit 4. Jettison -
LBA.
Figure 4-7.
Not authorized.
5. Carrier operations -
Authorized.
6. Maximum load: 200 poundsmaximum 150poundsmaximum 350 poundstotal.
forward shelf aft shelf
4.11.3 Gun Burst Limits 1. Burst limit -
4.11 EXTERNAL STORES AND GUN LIMITS 4.11.1 280-Gallon External Fuel Tank Limits
520 KCASI0.90 TMN.
200 rounds.
If two consecutive200-roundbursts are tired, a 30secondcooldown period is required.
1. Catapult launch with a partially tilled external tank is not authorized because of surge load considerations.
4.11.4 Launch Limits. Maximum flight conditions for launch of external storesare listed in the following paragraphs.
2. Carriageof externaltanks not incorporatingAYC 598 is limited to 300 KCAS/0.72 TMN.
4.11.4.1 AIM-7FIM
1 WARNING
Note Missiles with K-9 autopilot areidentified by a segmentedblack line underthe missile serial number or letters “POP” after the serial number.
1
CV arrestment,CV touch and go, or normal field landings with full or partial fuel in the external tanks is not authorized becauseof overload of the nacelle backup structure. Only minimum descent rate landings are authorized.
1. Stations 1B and 8B - Vmin to 1.3 Th4N, all altitudes, +lg to limits of basic aircratt for nonzero bank angles and limits of basic aircraft for zero bank angle. 2. Stations3 and 6 - Vmin to Vmax for Ogto +2g, Vmin to 1.4 TMN for +2g to +4g, and Vmia to 1.2 TMN greaterthan +4g, all altitudes,+lg to limits of basic aircraft for non-zerobank anglesand Og to limits ofbasic aircraft for zerobank angle.
Dive anglesin excessof 10“ nosedown with 900 poundsor more fuel in an externaltank will result in fuel venting (dumping).
ORIGINAL
4-18
NAVAIR 01-Fl4AAD-1
3. Station 4 - Vmin to 0.9 TMN for less than 15,000 feet MSL for Og to +Ig, Vmin to Vm, greaterthan 15,000feet MSL for Ogto +lg, and Vmin to vma~ greaterthan +lg, all altitudes,+lg to limits of basicaircraft for non-zerobankangles, and Og to limits of basic aircraft for zero bank angle. 4. Station 5 - Vmin to 650 KCAS less than 30,000 feet MSL for Ogto +l g, Vmia to Vm, greaterthan 30,000feet MSL for Ogto +lg, and Vmin to Vma greaterthan+Ig,allaltitudes,+lgtolimitsofbasic for non-zerobank angles,and Ogto limits of basic aircraft for zero bank angle. 4.11.4.2 AIM-SUM
anglesand Og to limits of basic aircraft for zero bank angle. 2. Stations3 and 6 - Vmin to 350 KCAS, all altitudes,+1.Ogfor straightand level flight. 3. Stations4 and 5 - Vmin to 400 KCAS, all altitudes,+l .Ogfor straightand level flight. pi&-,,,,,,, AIM-7 on stations3 and6 exhibit pronounced outboardmovement whenjettisoned. 4.11.5.2 AIM-!54C
1. All stations - Vmin to Vmax,all altitudes, -1.Og to limits of basic aircraft.
1. Stations 1B and 8B - Vmin to Vmax, all altitudes, +l g to +6g for non-zerobank anglesandOg to +6g for zero bank angle. 2. Stations 3 and 6 - Vmin to 1.4 TM’N, all altitudes,+Ig for non-zerobank anglesandOgto +lg for zerobank angle.
AIM-9 launch is prohibited with landing flaps and slatsextended.
3. Stations4 and 5 - Vmin to Vmax, all altitudes, +lg for non-zerobank anglesand Ogto +lg for zero bank angle.
Note Enginestall may result from firing of AIM-9 missiles. Engine exhaust gas temperature shouldbe monitored after eachtiring.
Note For zero bank angle, limit is Vmin to Vmax, all altitudes,Ogto limits ofbasic aircraft.
4.11.4.3 AIM-54C 1. Stations 1B and 8B - Vmin to Vmax, all altitudes,+lg to limits of basic aircraft for non-zero bank angles,Ogto limits of basic aircraft for zero bank angle. 2. Stations3 and 6 - Vmin to Vmax Ogto +2g and Vmin to 1.4 TMN +2g to +6g, all altitudes,+Ig to +6g for non-zero bank angles and Ogto +6g for zerobank angle. 3. Stations4 and 5 - Vmin to Vm,, all altitudes, +lg to +5g for non-zerobank anglesandOgto +5g for zero bank angle.
4.11.5.3 Capped 280-Gallon External Fuel Tank (Landing Gear and Flaps Retracted) 1. Full, partial, or empty tanks TMN, all altitudes,+lg to +3g.
2. Landing gear and/or flaps extended(emergency only) - Less than 225 KCAS, all altitudes,+lg for straightand level flight. 4.12 BANNER TOWING RESTRICTIONS 1. Airspeed -
220 KCAS maximum recommended
4.11.5 Jettison Limits. Flight conditions for jettison(emergencyonly) of externalstoresare listed in the following paragraphs.
2. Maximum angle of bank idle below 5,000 feet
4.1151
3. Use of speedbrakes-
AIM-‘IF/M
Less than 0.90
30”, 20” throttles at
Prohibited in flight.
1. Stations 1 and 8 - Vmin to Vmx, all altitudes, +lg to limits of basic aircraft for non-zerobank 4-19
ORIGINAL
NAVAIR 01.l=14AAD-1
Note l
During takeoff, adequateclearanceexists to use speedbrakesfor takeoff abortwithout contactingtow cable.
MACH TRIM circuit breakershouldbe reset prior to landing. Attempt reset below 0.6 TMN above5,000 feet, if possible,to minimize trim changetransients.Failure to reset circuit breaker may result in reducednosedown longitudinal control authority. Reduced authority may degrade the pilot’s ability to counter pitchup during waveoffs with aft cg.
. The maximum aircraft grossweight for a shipboard banner launch is 67,000 pounds. 4.13 TACTICAL AIR RECONNAlSSANCE POD SYSTEM LIMITATIONS SeeFigure 4-I 1 for airspeedlimits andstoreloadings authorizedwith TARES pod.
5. AIM-54 carriage/launchis not authorizedat any station.
4.13.1 Authorized Stores Loading
6. Special weight and balance information for TARES pod configuration is available. Refer to handbookof weight and balance(NAVAIR OllB-40).
1. Downloading is authorizedfor storestations 1, 2, 7, and8 only. Stations3 and 6 must remainloaded for cg control. 2. Carrier and field arrestment operations are authorized. 3. Aft cg limit is 17.5-percentMAC, nonjettisonable (captive carry) AIM-7 missiles, specially confrgured interim AIM-7 missile or AIM-54 rails and fairings on stations3 and 6 shall be carried for cg control (seeInterim AIM-7 asballast).Full ammunition pod, ALQ-1001126 or other authorized equipmentsubstitutionmaybe requiredalongwith AIM-7 missiles or AIM-54 fairings and rails to maintain cg within aft limit. Individual weight and balancecalculations shall be performedto ensure cg limits are not exceeded.
4.132 Interim AIM-7 as Ballast. TARPS-equipped aircraft are authorized to use specially contigured interim AIM-7 missiles as ballast. AIM-7 missiles specially configured for TARES use will be designatedas CATM-7%2 or CATM-7F-2. Until then, R40293, R40268, R40302,R40264, R40144, R40298,R40674, R40297, R40274,R40267, and R40235 are authorized #asTARES ballast, and weight and balanceinformation provided for AIM-7F missiles shallbeusedto determine weight and balanceof aircraft.
2. CATM-7F-2 - 440 poundsper missile located at aircraft station381.7.
4. Pulling MACH TRIM circuit breakerwill eliminate stick force requirement during low-altitude, high-speedflight.
ORIGINAL
I. CATM-7E-2 - 360 poundsper missile located at aircraft station 381.7.
4-20
NAVAIR
AUTHORIZED
STORES LOADING
Stations 1 and 8: (2) AIM-7 and (2) AIM-9
MAXIMUM ON
or (4) AIM-9
Stations 2 and 7: (2) finless external fuel tanks
Ql-Fl4AAD-1
AIRSPEED
Sea level to 11,000 feet mean sea level (MSL)-540 KCAS. Above 11,000 feet MSL-600 whichever is less.
KCAS or 1.43 TMN,
Station 5: TARPS pod Stations 3 and 6: (2) AIM-54 Rail and fairings or (2) AIM-7/CATM-7 Stations 1 and 8: (2) AIM-7 and (2) AIM-9
OFF
Sea level to 11,000 feet MSL-620
KCAS.
or (4) AIM-9
Station 2 and 7: (2) finless external fuel tanks
Above 11,000 feet MSL-680 whichever is less.
KCAS or 1.43 TMN,
Station 5: TARPS pod Stations 3 and 6: (2) AIM-54 Rail and fairings or (2) AIM-7/CATM-7 Stations 1 and 8: (2) AIM-7 and (2) AIM-9
ON
Sea level to 11,000 feet MSL-540
KCAS.
or (4) AIM-g.
Station 5: TARPS pod
Above 11,000 feet MSL-600 whichever is less.
KCAS or 1.53 TMN,
Stations 3 and 6: (2) AIM-54 Rails and fairings or (2) AIM-7/CATM-7 Stations 1 and 8: (2) AIM-7 and (2) AIM-9
OFF
680 KCAS or 1.33 TMN, whichever
is less.
or (4) AIM-g.
Station 5: TARPS pod Stations 3 and 6: (2) AIM-54 Rails and fakings or (2) AIM-7/CATM-7 Figure 4-l 1. Tactical Air Reconnaissance
4-21 (Reverse
Pcd System Limitations
Blank)
ORIGINAL
NAVAIR 0%F14AAD-1
PART II
Indoctrination Chapter5 - Inndoctrination
57 (ReverseBlank)
ORIGINAL
NAVAIR
CHAPTER
01.F14AAD-1
5
Indoctrination 5.1 GROUND
TRAINING
5.1.1.5
SYLLABUS
Minimum Ground Training Syllabus. The groundtraining syllabus setsforth the minimum ground training that must be satisfactorily completed prior to operatingthe F- l4D. Ifthe aircrewmemberhasa current F-14A/B NATOPS qualification, the ground syllabus will consist of the F-14D unique systems. The ground training syllabus for eachactivity will vary accordingto local conditions, field facilities, requirements from higher authority, and the immediate unit commander’s estimateof squadronreadiness.The minimum ground training syllabus for the pilot and the RIO is set forth in the following paragraphs.
51.1
5.1.1.1
2. Day landing patternandprocedures 3. Night landing patternandprocedures 4. Shipboardproceduresand landing patterns 5. CCAIACLS procedures 6. In-flight refueling (day/night). 51.2 Waiving Requirements.
Familiarization
Lectures
1. F-14D flightcrew academiccourse. 5.1.1.3
Intercept
Flight
Weapons Lectures
Firing
Flight
Training
I. Has obtaineda currentmedical clearance
Support
2. Is currently qualified in flight physiology
1. F-l4D flightcrew academiccourse. 5.1.1.4
Ground
Whererecentcrewmemberexperiencein similar aircraft models warrant, unit commanding officers may waive the minimum ground training requirementsprovided the flight crewmembermeetsthe following mandatory qualifications:
3. F-14D MFTWST (within 5 days). Support
of Minimum
All F-14D flight crewmembersshall be instructed on the differences from model in which qualified and comply with those items listed below, as directedby the unit commandingofficer.
2. F-14D flightcrew academiccourse
Flight
Landing Practice/Carrier Flight Support Lectures
I. Mirror and Fresnellens optical landing system
1. Flight physiological training as appropriate
5.1.1.2
Field Carrier Qualification
3. Has satisfactorily completed the NATOPS flight manual open-and closed-bookexaminations
Support
4. Has completedat least one emergencyprocedure period in the MFTIWST (within IO days)
I. Weaponspreflight procedures 2.. Arming/dearming procedures 3. Firing procedures
5. Has received adequatebriefing on normal and emergencyoperatingprocedures
4. Safetyprocedures
6. Has receivedadequateinstructionson the useand operationof the ejection seatand survival kit.
5. Jettison/dumpareas. 5-I
NAVAIR 01-F14AAD-1
5.2 FLIGHT TRAINING SYLLABUS Be52.1 Flightcrew Flight Training Syllabus. fore flight, all flight crewmemberswill havecompleted thefamiliarization andflight supportlecturespreviously prescribed.A qualified FRS instructorpilot will occupy the rear seat for the fast familiarization flight. A qualified FRS instructor RIO can occupy the rear seatif the pilot in command has beenpreviously NATOPS qualified in the F-14A/B. The geographic location, local command requirements,squadronmission, and other factorswill influence the actual flight training syllabus andthe sequencein which it is completed.The specific phasesof training arelisted in the following paragraphs. 5.2.2 Fllghtcrew Flight Training Phases
5.2.2.3 Weapons System Employment. Qualification is in accordancewith existing tminingandreadinessdirectives. 5.2.2.4 Field Carrier Landing Practice and Carrier Qualifications. Qualification is in accordance with existing training and readinessdirectives. 5.3 OPERATING CRITERIA 5.3.1 Ceiling/Visibility Requirements. Before the pilot becomesinstrument qualified in the aircraft, field ceiling, visibility, and operatingareaweathermust beadequatefortheentireflighttobeconductedinaclear airmassaccordingto visual flight rules. After the pilot becomes instmment qualified, the following weather iteria apply:
5.2.2.1 Familiarization F-14D HOURS
1. Military power takeoffs
CEILING and VISIBILITY (Feet) (Miles)
2. Buffet boundaryinvestigation
Less than IO
VFR
3. Approach to stalls
1oto20
800 and 2; 900 and l-1/2; 1,000 and 1
4. Slow flight
20 to 45
700 and 1; 600 and 2; 500 and 3
45andabove
Field minimums or 200 and 112, whichever is higher.
5. Acceleration nm to Mach 1.3 6. Subsonicand supersonicmaneuvering 7. Investigateall featuresof the AFCS/stab aug F-14A/E FLEET EXPERIENCED AIRCREW (F-14D HOURS)
8. Formation flight 9. Aerobatics
CEILING and VlSlBlLlTY (Feet) (Miles)
10. Single-engineflight at altitude and airstarts
Less than 10
VFR
11. Simulated single-enginelandings
10to30
7a0,0da;d 1; 600 and 2; 500
12. Landing with full and with no flaps
30andabove
Field minimums or 200 and 112, whichever is higher.
13. Acceleration runs at various altitudes. 5.2.2.2 Instruments
Where adherenceto theseminimums unduly hampers pilot training, commanding offricersmay waive time-in-mode1requirementsfor actualinstrumentflight, provided pilots meet the following criteria:
1. Basic instrument work 2. Penetrationand approaches
1. Have aminimum of 10hourscombinedtime in the F-14-/D
3. Local arearound-robin(day and night) flights. An F-14D pilot is consideredinstrumentqualified if cm’renttyinstrument qualified in the F-14A/R.
2. Completedtwo simulated instrumentsorties 3. Completed two satisfactorytacanpenetrations
ORIGINAL
5-2
NAVAIR OI-Fl4AAb1
4. Completed five satisfactory ground-controlled approaches.
1. Have satisfactorily completedthe groundphase01 the NATOPS evaluation check, including OFTICOTIWSTIMFT emergency procedures check (if available) and have completed a NATOPS evaluationcheckwith a gradeof Conditionally Qualified or betterwithin the past 12months
5.3.2 NATOPS Qualification and Currency Requirements. F-14 NATOPS qualifications are for a specific aircraft series.The following terms aredefined for use in interpreting the F-14 qualification and currencyrequirements.
2. Have flown 10hours in aircraft model, 5 hours01 which shall be in aircraft series, and made five takeoffs and landings in aircraft model within the hut 90 days.
1. Aircrafi type - The broadestclassification of aircraft as to its physical characteristics(e.g., fixed wing or rotary wing).
3. Are consideredqualifted by the commandingoffrcer of the unit having custodyof the aircrafi.
2. Aircrafi model - The basic mission symbol and designnumberof an aircraft (e.g.,P-3, F-14, H-3).
Flight crewmemberswho are current in the F-14A and F-14D may be consideredcurrent in the F-14B. NATOPS requalification for the F-14A, F-14B, and F-14D canbe accomplishedduringthe sameevaluation check,provided the NATOPS open-book,closed-book andboldfaceexams and currencyrequirementsaremet for eachseries.
3. Aircrafl series- The specific version of an aircraft model (e.g.,F-14A, F-14B, or F-14D). 5.3.2.1 Initial NATOPS Qualification in Aircraft Series. Initial F-14 NATOPS qualification in series shall include satisfactorycompletion of the following requirements:
5.3.2A Currency Renewal. Flight crewmembers who have not remainedcurrent shall complete the following requirementsin order to reestablishcurrency:
1. Formal groundphasetraining. 2. The NATOPS open-book,closed-book,andboldface exams. 3. A flight syllabusat a fleet replacementsquadraon. The syllabus shall include 10 flight hours under instruction, 4 hours of which may be flown in a CNO-approvedflight simulator for the sameaircraft series. 4. A separateNATOPS evaluation flight check is required if a CNO-approved simulator is not available.
1. Flight crewmemberswho have not maintained10 hoursin model, 5 hoursof which shallbe in a&rat7 series,and five takeoffs and landings in aircrafl modelwithin thelast90 days)shalldothefollowing: a. Complete a safe-for-flight simulator check with a squadronNATOPS instructor b. Be consideredqualified by the commandingof ficer of theunit having custodyof the aircraft 2. Flight crewmemberswho arecurrentin seriesexcept for a NATOPS evaluation check within the last 12months shall do the following:
Fleet replacementsquadroncommandingofficers may waive the flight hour requirement for radar interceptoffkers. 5.3.2.2 Continued NATOPS Qualification. To maintaina continuedNATOPS qualification after initial qualification in aircraft series until currency is established,pilots andRIOs shall comply with the minimum flight hour requirementsin eachspecific phaseas determined by the unit commanding officer. 5.3.2.3 NATOPS Currency. Flight crewmembers who have more than 45 hours in F-14A/J3/D aircraft model areconsideredcurrentin aircraft series,provided they continueto satisfy the following requirements:
a. Complete a NATOPS evaluation check (in. eluding emergency procedures simulator check,NATOPS open-book,closed-book,and boldfaceexaminations)with the SquadronNA. TOPS instructor. b. Be consideredqualified by the commadingof. ficer having custodyof the aircraft. 3. Flight crewmemberswithout a currentNATOPS evaluationcheck andwho havenot maintainedl( hours in model, 5 hours in aircraft series,and five takeoffs and landings in aircraft model withii thr last 90 days shall do the following:
5-3
NAVAIR 01.F14AAD1
a. If 6 months or less since last flight:
5.3.3.5 Air-to-Air Missile Firing -
Pilot
(1) Perform an emergency procedures and safe-for-flight check in a CNO-approved simulator
1. Have a minimum of 15hourscombinedtime in the F-14A/B/D, 5 of which must have beenflown in the F-14D
(2) Fly one flight with squadron NATOPS instructor
2. Be considered qualified by the commanding officer. 5.3.3.6 Air-to-Alr Missile Firing -
(3) Complete a NATOPS evaluation check (including NATOPS open-book,closedbook, andboldface examinations)
RIO
1. Have a minimum of 25 hourscombinedtime in the F-14-D as crewmember, 10 ofwhich must be intheF-14D
(4) Be consideredqualified by the commanding officer of the unit having custody of the aircraft.
2. Have satisfactorily completed a minimum of two intercept flights .during which simulated firing runswereconductedutilizing thevoiceprocedures andclear-to-fm criteria to be utilized in live fmng
b. If greaterthan 6 months since last flight, a repeat of the initial NATOPS qualification requirementsis requiredat the fleet replacement
3. Be considered qualified by the commanding officer.
SCpdOll.
5.3.3 Requirements for Various Flight Phases 5.3.3.1 Night -
5.3.3.7 Carrier Qualifications. Each crewmember will have a miniium of 50 hours combinedtime in the F-14A/BiD(15hoursminimuminF-14D),ofwhichlS hours is night time (5 night hours in F-14D) and meet the requirementsset forth in the CV NATOPS manual. Minimum hour requirementfor radar interceptofficers may be waived by the commanding offtcer basedupon individual experiencelevel and crew composition.
Pilot
1. CombmedtimeinF-14A/B/Dnot lessthanlOhours. 5.3.3.2 Night -
RIO
1. Combined time not less than 3 hours in the F14A/B/D as crewmember. 5.3.3.3 Cross Country -
5.3.4 Mission Commander. The mission comman&r shallbeaNATOPS-qualifiedpilot or RIO, qualified in all phasesofthe assignedmission, anddesignated by theunit commandingofficer.
Pilot
1. Have a minimum of 15 hours total in the F-14A/BiD as fmt pilot or fly with a qualified instructor RIO
53.5 Minimum Flightcrew Requirements. The pilot and the RIO (or two pilots) constitute the normal flightcrew for performing the assignedmission for all flights. Unit commanders may authorize rear-seat flights for personnelotherthanqualified pilots andRIOs provided suchpersonnelhavereceivedthoroughindoo trination in theuseof the ejectionseatandoxygenequip ment and,in the execution of rear-seatfunctions and emergency procedures. Where operational necessity dictates, unit commandersmay authorize flights with the rear seatunoccupied provided the requirementfor such flights clearly overridesthe risk involved andjustitiestheadditionalburdenplacedon thepilot. Innocase is solo flight authorizedfor shipboardoperations,combat, or combat training missions.
2. Have a valid instrumentcard 3. Have completedat least one night familiarization flight in the F-14-D or fly with a qualified instructor RIO 4. Have completedmaintenancecheckoutfor servicing aircraft. 5.3.3.4 Cross Country -
RIO
1. Have completedat least one night familiarization flight in the F-14A/BiD or fly with a qualified instructorpilot.
ORIGINAL
54
NAVAlR Of-FMAAD-1
5.4 FLIGHT CREWMEMBER FLIGHT EQUIPMENT REQUIREMENTS
9. Sheathknife 10. Flashlight (for all night flights)
In accordancewith OPNAVINST 3710.7,the flying equipmentlisted below will be worn or carried, as applicable, by flight crewmembers on every flight. All survival equipment shall be securedin such a manner that it will be easily accessibleandwill not be lost during ejection or landing. All equipment shall be the latest availableasauthorizedby the Aircrew PersonalProtective Manual, NAVAIR 13-1-6.
11. Strobe.light 12. Pistol with tracer ammunition or approved flare gun 13. Fire-retardantflight gloves 14. Identification tags
1. Protectivehelmet 2. Oxygen mask
15. Antiexposure suit in accordancewith OPNAVlNST 3710.7
3. Anti-g suit
16. Personalsurvival kit
4. Fire-retardantflightsuit
17. Othersurvival equipmentappropriateto climate of thearea
5. Steel-toedflight safety boots 6. Life preserver
18. Full pressuresuit and hfk 4 life preserveron all Ilights above50,000 feet MSL
7. Harnessassembly
19. Pocket checklist
8. Shroudcutter
20. Navigation packet.
5-S (Reverse Blank)
NAVAIR 0%Fl4AAB1
PART III
Normal Procedures Chapter6 -Flight
Preparation
Chapter7 - Shore-BasedProcedures Chapter 8 - Carrier-BasedProcedures Chapter9 - SpecialProcedures Chapter 10- Functional Checkflight Procedures
59 (ReverseBlank)
ORIGINAL
NAVAIR Ql-FI4AAD.1
CHAPTER 6
Flight Preparation 6.1 PREFLIGHT BRIEFING
7. Ordnanceand storescarried/preflight/restrictions on use
Preflight briefings shall be conducted immediately beforethe launch of scheduledflights and must be carried out in an expeditiousbut thoroughmanner. Ample time shouldbe given for briefing with externalassetsas well as for conducting internal element briefs. When schedulinga brief, considerationshouldbe madeto ensurethat enoughtime is given for the aircrew to finish briefing, don all flight gear,check out any specialitems requiredfor themission (authenticators,cameras,guns), mad the aircraft discrepancybook, and man up the aircraft in order to make the scheduledlaunch time. For this reason,it is imperativethat all pilots and RIOs be in flightsuits ready for the brief at the designatedtime.
8. Communicationsplan 9. AreaMOTAMs 10. Clearance/NAVAlDs 11. Ground/deckprocedures 12. Takeoff/departure/rendezvous 13. En route/formation 14. Tanking plan
Thebriefshouldoptimallybeconductedinadesignated btiefmg room, free of distractions,with a white dry erase boardand l/72 scale aircraft models. A briefmg board shouldbe put up prior to the brief, depictingapplicable admin items, mission objectives,flight conduct, special instructions,andnecessarydiagrams.Aircrew shouldutilize appropriatetactical manuals and current weapon school manualsandjournals for mission planning.The brief shall include,but not be liiited to, the following.
15. Combat checks 16. Recoveryprocedures(VFR/IFR) 17. Jokeribingofuel 18. NORDO procedures 19. Emergencies/diverts/SARbirdstrike
6.1.I Admin. The following items should be covered for eachflight, regardlessof the mission.
20. Training rules
1. Event number
2 1. Contingencies.
2. Launch/recoverytimes/recoveryorder
6.1.2 Missions. Aircrew should brief each section that appliesto their expectedmission. Missions not specifically discussedin this chapter should be covered using the appropriatetactical manual.
3. Lineup/call signs/avionicsplan 4. Mission assigned/alternatemissions
6.1.2.1 Low-Level/Strike
Ingress
5. External assets/callsigns 1. Time hack 6. Weather 2. Controlling agencyroute brief a. Base, en route,target,area,divert a. Restrictions/hotareas b. Water/air temperature,seastate 6-1
ORIGINAL
NAVAIR 0%F14AAD-1
8. WeaponeeringIswitchology
3. Current charts/CHUM 4. Entry/exit times
a. Targettype
5. Formation/altitude/airspeed
b. Weapon
6. Navigation mode/plan
c. Attack/delivery mode
7. Communications
d. EuzeIdelay
8. Checkpoints/timing
e. Functioning delay
9. Tmnpoints/corrections
f. Interval
10. Radarplan/searchcontracts
g. Stick length
11. Threat awareness(SAM, AAA, A/A)
h. Frag pattern
12. DECM/RWR/expendables
i. Manual MIL setting
13. Target areaingressIP -
j. Stationsselected
Target
9. Releaseconditions
14. Abort criteria/procedures
a. Dive angle
IS. Safety.
b. Airspeemach
6.1.2.2 Air-to-Ground/Strike 1. Time hack
c. Release/recoveryaltitude
2. A/G checklist complete
d. Heading
3. Range/area
e. Slant range
4. Time on target
f. Time of fall
5. Communications
10. Off-target rendezvous/egress/RTF
6. Swing tighter consideration
11. Hung ordnance/jettison
7. Target areatactics
12. Abort criterialprocedures 13. Safety.
a. SEAD window
6.1.2.3 Air-to-Air
b. Target ID/acquisition
1. Mission type/objectives/strikeintegration/f?iendly assets
c. Tactic/ha&up tactic d. Aircraft interval/sequence
2. Threat awareness(A/A, SAM, AAA) e. Aim points/backupaim points
3. ROEiPID criteria
f. Threat awareness(SAM, AAA, A/A)
4. GCJIcontrolIbull’s-eye
g. DECM/RWTUexpendables
ORIGINAL
6-2
NAVAIR Ol-F14AAD-1
e. Section/divisionmaneuvering
5. Precommit
f. Engage/blowthrough
a. Position/time/CAP management
9. Postmerge/egress
b. Formation/visual lookout c. Radar gameplan
a. Target areaconsiderations/frag
d. Defensein depth
b. Flow/new ROE c. Radargameplan
6. Commit a. Authority/criteria
d. Visual lookout doctrine/commit
b. Abort/reset
e. Rendezvous 10. Defensive considerations
7. Intercept a. Geometry/flow
a. Communications
b. Formation/altitude/airspeed
b. Threat/noseposition/RWR
c. Communications (cadence/priority)
c. Missile/guns defense
d. Radarsearchresponsibilities
d. E-pole. 6.1.2.4 TARPS
e. Meld/targeting
1. Mission type
f. Sort/lock range/nosort
a. SSCYmappingIstandofoint target
g. Drop criteria/factorbandit range h. Degrades
2. Pod checks -
on deck/airborne
i. Float/strip
3. Operatingarea/routeiTOT
j. PreplannedcoordinatedmaneuverS
4. Navigation mode/plan -
k. Radarwarning receiver
a. INS/GPS/visual/DR
i. Abort/reset
b. Checkpoints
primary/secondary
c. PosttargetIPs
8. Approachingthe merge/merge
d. Topography/terrain
a. Missile employment b. Fuel package
5. Target acquisitioniJD/placement
c. Crank/expendables
6. Sensors a. Primary/secondary/tertiary
d. IRCM
6-3
ORIGINAL
NAVAIR 01-F14AAD-1
b. Vg’H settings
11. DECM/RWwexpendables
c. Troubleshooting
12. Egress
7. Formation/altitude/airspeed
a. Target areaconsiderations/fmg
8. Communications
b. Rendezvous/RTF 13 Abort criteria/procedures
9. Radarplan
14. Safety.
10. Threat awareness(SAM, AAA, A/A)
ORIGINAL
6-4
NAVAIR 01.Fl4AAD-1
CHAPTER
Shore-Based
7
Procedures
7.1 CHECKLISTS
all discrepancieshave been properly correctedor deferredprior to acceptingthe aircraft as readyfor flight.
Aircraft checklists are available in two forms, based on the degreeof Eightcrew familiarization; since the sequenceremains the same,the only difference in the forms is the degreeof amplification. As the flightcrew becomesmom proficient in type, a more abbreviated form is available to promote operationalefficiency, and safety is not compromised since in all instancesthe thoroughnessof checks remains the same. The placardedlanding checklist on the forward cockpit instrument panel is a fundamentalelementin this instance.In the interest of procedural standardization,the shorebasedand carrier-basedproceduresare maintainedthe same,exceptfor the responserelative to the checks.The expandedprocedurespresentedin this flight manual describein detail thoseitems that shouldbe checkedon eachflight. Adherenceto theseprocedureswill provide the flightcrew with a detailed statusof weaponssystem performanceincident to flight. However, it is incumbent on the flightcrew to expandthe checksas necessaryto verify the corrective statusof previously reporteddiscrepancies.Referenceshouldbe madeto the functional checktlightprocedures(Chapter lO,paragraph10.2)for moredetailedteststhat can be performedon the aircraft andweaponssystemsif deemednecessary.The flightcrew should be thoroughly familiar with the details of the proceduresoutlined herein so that the abbreviated checklist forms of the proceduresmay be safely employed. As the fmt level of simplification, NAVAIR Ol-F14AAD-1B containsa reprint of the normal procedures,with less amplifying information.
7.2.1 Area Around Aircraft. En route to the aircraft, attention should be directed to the maintenance effort going on in the line area.The flightcrew should ensurethatno hazardoussituationsexist. The entirearea should alsobe generallyexamined for FOD hazards. The areaaround the aircraft that may not be visible from the cockpit should be examined.Particular attention shouldbe paid to supportequipmentadjacentto the aircraft.It shouldbedeterminedthatthe wings andflight controls can be safely moved and that the effect of jet blast during start and taxi will not create a dangerous situation. 7.2.2 Foreign Object Damage and Leak Inspection. Engine intakesand adjacentdeckareaareof prime concernsincethe Fl lo-GE-400 is highly susceptible to FOD damage and the engines are capableof picking up objects from the deck. AICS ramps, bleed doors, ECS cooling intakes, exhausts,and afterburner ducts are catchalls for loose objects. They should be closely inspectedfor security and foreign objects,Inspectall panelsfor security and loose fasteners.While inspectingthe aircraft for FOD, the flightcrew should also be alert for any evidenceof oil, hydraulic fluid, or fuel leaks. 7.2.3 Ground Safety Devices and Covers. The following items shouldbe installed:
7.1.1 Tactical Air Reconnaissance Pod System. A [T] preceding the text of a procedural step identities items pertaining only to TARPS aircraft.
2. Nose landing geargroundsafety pin
7.2 EXTERIOR INSPECTION
3. Tailhook safetypin (ashore)
A properpreflight inspectionbeginswith a thorough review of aircraft statusand past maintenancehistory. An understandingof previous discrepancies,corrective action and their impact on the flight canbest be gained at this time. The flightcrew should ensurethat any and
4. Wheel chocks
1. MLG ground safety locks (two)
5. LAU-7/LAU-138/LAU-92 ground safetypins 6. Sidewinderseeker-headcovers (if applicable). 7-l
ORIGINAL
I
NAVAIR Ol-F14AAD-1
7.2.6 Inspection Areas. The following exteriorinspection is divided into 10 areas. (See Figure 7-l.) Checkspeculiar to only one side are designated(L) or (R) for the lefl or right side. Both the pilot and RIO should preflight the entire aircraft individually.
The following items should be removed: 1. Intake, probe,bleed door, and ECS duct covers 2. Water-intrusiontape 3. Launch abort mechanism lock (if the aircraft is to be towed)
7.2.6.1 @ Forward Fuselage 1. Accesspanelfastenersforward of engineinlets No Loose or Missing Fasteners.
4. Tailhook safetypin (shipboard). 7.2.4 Surface Condition. All surfaces should be checkedfor cracks, distortion, or loose or missing fasteners.All lights andlensesshouldbecheckedfor cracks and cleanliness.
2.
Gun (L) - Safety Pin Installed in Clearing Sector Holdback Assembly, Louvers Clear.
3.
Probes - Secure, Openings Clear, AOA Probe Free For Rotation.
7.2.5 Security of Panels. All fastenersshould be flush and secureon all panels.
4.
Nose wheelwell: a. Electrical leads -Connected, No Evidenceof Overheating.
7.2.6 Leaks. All surfaces,lines, andactuatorsshould be checkedfor oil, fuel, and hydraulic leaks.Particular attentionshouldbe paid to the undersideof the fuselage, enginenacelles,and outer wing panels.
b. Hydraulic lines -No
7.2.7 Movable Surfaces. All movable surfaces (flight controls and high-lift devices) should be inspectedfor position, clearance,and obvious damage,
Chafing or Leaks,
c. Doorsandlinkages-Cotter PinsInstalled,No Distortion. d. Brake accumulators- 1,900Psi Minimum.
Figure 7- 1. Exterior Inspection ORIGINAL
7-2
NAVAIR QMIUAD-1
e. Canopyair bottlegauge- 1,200Psi Minimum.
Planecaptainto verify that all visible damagehas beenblended.
f. Emergencylanding gearnitrogen bottle gauge - 3,000 Psi Minimum.
3. ECS heat exchangerinlet and fan
g. Emergency landing gear air releasevalve EnsureThat Valve Is in ClosedPosition.
a. Fan-Free
Rotation.
b. Overspeedpin - Recessed. h. Retract actuator- Piston Clean, No Leaks. c. ECS inlet - Free of FOD, CablesConnected i. Flight maintenanceindicator-
Secure.
j. Antiskid controlbox BIT flags-Not
@JN. 4. Inlet-Free
Tripped.
of StandingWater, Drains Clear.
I
7.2.8.3 @ Right Nacelle and Sponson
k. Cabin pressureport screens- Clean.
1. Station 7 and 8 stores
1. Master arm override- Cover Closed. 5.
Nose strut - Piston Clean, Free of Cracks and Scoring, andUplock Roller Free.
6.
Steeringactuator- Secure,No Leaks.
7.
Launch bar andholdback fitting
a. Stores-Aligned. b. Accesspanels-Secure. c. Sidewindermissile launcher I (1) LAU-7 Sidewinder coolant doors Latched.
a. Abort - Full Up.
I (2) LAU-138 chaff loading and gas bottle safetyhandle - Stowed. I
b. Roller - Free Rotation. c. Uplatch and holdback- Free Movement.
d. Storessafetypins - Installed. 8. Nosewheels and tires - Inflation, No Cuts, Bulges, UnevenWear, or ImbeddedObjects. 9. Drag brace-No
If externalt ankMXUdl1
Leaks, Door Secure.
10. Approach lights Secure.
aboard:
e. Groundsafety handle-Pulled.
Lenses Clean, No Cracks,
f. Fuelquantitysightgauge-Ball
Float Vertical.
g. Sway braces- Tightened Down. 11. TV camera- Check,Blue Desiccant. h. Hook latchedindicator- White Vertical Line Visible.
12. Dual chin pod - IRST, TV Cameras(or simulators), and Anticollision Light Secure.
i. Inboard and outboard fuel caps - Fastened With Butterfly Latch SecuredFacing AA.
13. Radome - Lock Handle Fastened, Rosemont ProbeStraight.
2. Main wheelwell 14. OBOGS concentrator vent outlet Obstructions.
-
No a. Doors and linkages- Secure.
7.2.8.2 @Right Inlet 1. Ramps, metal seals, and rubber seals Free of Dirt, Grit, and Cracks.
b. Uplock microrollers -Free. Intact,
c. Uplock hooks- Secure, d. Hydraulic lines-No
Chafing or Leaks.
2. IGV-BladesandStatorsFreeofNicksandCmcks. 7-3
ORIGINAL
NAVAIR Ol-Fl4AAD-1
3. Drag brace Forward.
Secure, Downlock Safety Pin
14. Ventral Clear.
7.2.8.4 @I Right Glove and Wirig
4. Side brace- Seatedin Latch. 5. Main struts scoring.
No Damage, IDG Oil Cooler Intake
1. Slats, flaps, and cove doors Hinges Secure.
Pistons Clean, Free of Cracks or
2. Wing cavity seal-Free
6. Brakes - Pucks Safety-Wined; Wear Indicators Visible (pins at least flush). Lower Torque Arm Swivel; Key and Key RetainerProperly Installed and Safety Wired.
Surfaces and
of Cuts and Chafing.
3. Formation and position lights Clean.
Intact, Lenses
7.2.8.5 @Aft and Under Fuselage
7. Hubcap - Secure,Safety-Wired.
1. Horizontaltails - LeadingEdgesFreeof Damage.
8. Main wheels and tires
2. Exhaustnozzlesand fakings:
a. Wheels and tires - Inflation, Cuts, Bulges, Uneven Wear, ImbeddedObjects(look behind chocks)
a. Nozzlesandfairings - No Crackedor Missing Flapsor Seals.
9. Gear down microrollers -Contact Made. b. Fairing cable - Properly Tensioned (pull on cable, fairing flaps should not move).
10. Engine compartment (ii applicable) a. Integrated drive generator-transmissionfluid -Fluid Visible, Filter (two) Pins Flush.
c. Bottom surface- No Scrapesor Cracks, d. Spraybars and flameholder- Intact.
b. Engine oil servicing caps-Check. e. Turbineblades-No Evidenceof Overheating. c. Bilges-No Leakage.
FOD, EvidenceofOverheating,or 3. Fuel vent -No
d. Fuel, oil, andhydraulic lines-Free ofchaflng or Leaks.
Leakageor FOD.
4. Tailhook a. Hook point - Smooth.
e. Bleed air lines Damage.
No Heat Discoloration or b. Nut and cotter pin -
f. Al3 fuel pump filter - Pin Flush.
c. Safety pin Latched Up.
g. Lube andscavengebypassfilter -Pin Flush. h. Oil nozzle filter -Pin I 1. Flight hydraulic reservoirFilter Pins Flush.
Remove if Hook Is Securely
5. Backup flight control module -No Leaks (feel afl of inspection doors), Filter Pins Flush, Close Both Access Doors.
Flush. 1,800Psi Minimum,
6. Fuel dump FOD.
12. Flight hydraulic system tape gauge-Minimum of Sevenon Tape.
No Leakage From Mast, Free of
7. Stations3 through 6 stores
Note Engine must be running for an accurate reading.
a. Stores-Aligned. b. Accesspanels - Secure. c. Storessafety pins - Installed.
13. Hook dashpotpressuregauge- 800 i10 Psi. ORIGINAL
Installed.
7-4
NAVAIR Ol-Fl4AAD1
8. Fuel cavity drains-No
2. Main wheelwell
Leakage.
a. Doors and linkages- Secure.
9. [T] Pod - Check for Security 10. [T] Protectivewindow covers-Removed.
b. Uplock microrollers -Free.
Il. [T] Camerawindows - Clean,
c. Uplock hooks-Secure.
12. [T] Camerasensorcontrol - As Briefed.
d. Hydraulic lines-No 3. Drag brace Forward.
13. [T] Light meter - Facing Outboard. 14. [T] Lens filter -As
Chafing.
Secure, Down Lock Safety Pin
Briefed. 4. Side brace-Seated in Latch.
7.2.8.6 @Left Glove and Wing 1.
Slats, flaps, and cove doors Hinges Secure.
5. Main struts - Pistons Clean, Free of Cracks or Scoring.
Surfaces and
6. Brakes- Pucks Safety-Wired; Wear Indicators Visible (pins at least flush). Lower Torque Arm Swivel; Key and Key RetainerProperly Installed and Safety-Wired.
2. Wing cavity seal-Free of Cuts and Chafing. 3. Formation and position lights Clean.
Intact, Lenses
7. Hubcap-Secure, Safety-Wired. 7.2.8.7 @I Left Nacelle and Spot-son 8. Main wheels and tires 1. Station 1 and 2 racksand stores a. Wheels and tires - Inflation, Cuts, Bulges, UnevenWear,ImbeddedObjects(look behind chocks).
a. Racks and stores-Aligned. b. Accesspanels-Secure.
b. Uplock hooks- Secure. c. Sidewindermissile launcher 9. Gear-upmicrorollers - ContactNot Made. (1) LAU-7 Sidewinder coolantdoors Latched.
10. Engine compartment(if applicable) a. IDG - Fluid Visible (two) Pins Flush.
(2) LAU-138 chaff loading and gas bottle safety handles- Stowed.
b. Engine oil servicing caps-Check. d. Storessafetypins - Installed. c. Bilges-No Leakage.
If externaltanksaboard: e. Ground safetyhandle- Pulled.
FOD, Evidenceof Overheating,or
d. Fuel, oil, and hydraulic lines - Free of Chafing or Leaks.
f. Fuel quantitysightgauge-Ball Float Vertical. e. Bleed air lines - No Heat Discoloration or Damage.
g. Sway braces-Tightened Down. h. Hook latch indicator Visible.
f. Afterburner fuel filter - Pin Flush.
White Vertical Line
g. Lube andscavengebypassfilter - Pin Flush. i. Inboard and outboard fuel caps - Fastened With Butterfly Latch SecuredFacing Aft.
7-5
h. Oil nozzle filter - Pin Flush.
ORIGINAL
NAVAIR
Ol-F14AAD-1
11, Combined hydraulic reservoirmum, Filter Pins Flush.
6. Speedbrake- No Distortion or Leaks.
1,800Psi Mini-
7. Vertical tails andrudders-No Distortion, Lights Intact.
12. Combined hydraulic systemtape gauge -Minimum of Sevenon Tape.
7.2.8.10 Note
1. Canopy lanyard - Connected, Yellow Flag Attached at Both Ends.
Engine must be running for an accurate reading. 13. Airstart door CoversTight. 14. Ventral Clear.
2. Auxiliary canopy bottle - Cable Taut.
Ground Hydraulic and Electric
3. Canopyhooks and seal- Secure,SealIntact.
No Damage, IDG Oil Cooler Intake
4. Ejection seatsafe-and-armdevice safetypins (see Figure 7-2) -Pulled.
7.2.8.8 @I Left Inlet
5. Auxiliary canopybottle gauge- 800psi Minimum.
Ramps, metal seals,and rubber seals Free of Dirt, Grit, and Cracks.
Intact,
6. Blade antennas-Intact. 7. Canopy - Clean, Free of Cracks and Deep Scratches.
IGV - Blades and StatorsIGV Freeof Nicks and Cracks.
7.3
Plane captainto verify that all visible damagehas beenblended.
EJECTION
SEAT INSPECTION
The pilot andRIO shall perform the following checks on their respective ejection seatsprior to flight. The ground safety pin in the seat thing handle is the only ground safety device. It must be removed and stowed before flight. Abbreviated preflight checklists for the ejection seatareprovided in thepocket checklist andon the ejection seatheadbox.
Ice detector(L) - Secure. ECS heat exchangerinlet and fan a. Fan-Free
@ Canopy
Rotation.
b. Overspeedpin -Recessed.
1, SAFE/ARMED handle - SAFE.
c. Inlet-Free ofFOD, CablesConnected(two).
2. Manual override handle Locked.
Full Down and
5. Outboard spoiler module temperature indicator and servicing - No Leaks, Fluid Indicator Rod Protruding.
3. Catapult manifold valve - Secure,Hoses Connected.
6. Inlet-Free
Check that retaining pin is installed.
7.2.8.9
of StandingWater, Drains Clear.
@ Fuselage
Top Deck and Wings
1. Bleed exit doors Intact.
4. Top latch mechanism-Latched.
Free of FOD, Hardware
Check that indicator plunger is flush with end of top latch plunger.
2. ECS heat exchangerexhausts-Free of FOD and Cracks.
(WARNING1
3. Antennas-Check. 4. Overwing fakings -No 5. Eyebrow doorsORIGINAL
If the top latch mechanismis not latched,the seat could rise up the catapult rails during aircraft maneuvers.
Crackedor Bent Fingers
Intact, 7-6
NAVAIR Ql-F’l4AAD1
b. Emergencyoxygen manual actuator Connectedand Stowed.
5. Parachutewithdrawal line - Connected. Check that parachutewithdrawal line is correctly securedto parachutedeploymentrocket stinup.
c. Emergency oxygen and locator beacon lanyards - Connected to Deck.
6. Left pitot head- Stowed. 13. Oxygen/communicationsandanti-g lines -Connectedto Aircraft Connections.
7. Thermal batteries- Not Expended. Check that battery-expendedindicator on electronic sequenceris not activated.
14. Personnelservicesdisconnectblock - Secured to SeatBucket, LanyardAttached to Deck. 15. Lapbelts- Secure.
8. Left trombonetubes-Connected, Retaining Pin Installed.
Pull up on each lapbelt to ensure that lugs are securein seatbucket locks.
9. Leg restraint lines - Secured to Deck, Not Twisted, End Fittings Secured in Seat Bucket Locks. 10. Seattiring initiators -Firing to Sears.
16. Negative-gstrap- Secure. 17. Right trombone tubes Pin Installed.
Linkage Connected
11. Pyrotechnic quick disconnects Red BandsNot Visible.
Connected,Retaining
18. Right pitot head- Stowed.
Connected,
19. Parachutecontainerlid - Secure,Sealed. 12. Survival kit-Check. a. Oxygen pressuregauge-In
Check environmental seal indicator for correct indication
the Black.
Figure 7-2. Ejection SeatSafe-and-Arm Module 7-7
ORIGINAL
NAVAIR Ol-Fl4AAD.1
20. Parachuterisers-Properly Routed.
3. TONE VOLUME controls-set.
Check that risersare routeddown forward face of parachutecontainerand behind retentionstrap.
4. ICS panel a. VOL knob -As
Desired.
21. Ejection seatand canopypins - Stowed. b. Amplifier -NORM. 7.4 PILOT PROCEDURES c. Function switch -COLD The interior inspectionprovides a systematiccoverage of all cockpit controls to ensureproper setupprior to the application of externalpower, assumingno external air-conditioning sourcewill be usedprior to engine start.Thesecheckscorrespondto the condition that the plane captainshould set up in the cockpit aspart of the preflight. Each cockpit setup consists of a sequential sweepof controls on the left console,instrumentpanel, and right console.
5. Radio VOLUME panel. a. JTIDS SEL switch -Set. b. VOLUME knobs-As
Desired.
6. Tacan mode switch-OFF. a. Channel-
7.4.1 Interior Inspection
MIC.
Set.
- Pilot b. VOL knob - Counterclockwise.
1. Harnessing- Fasten. 7. STAB AUG switches-OFF. a. Leg restraint lines and garters - Connect. 8. U/VHF - OFF. ConnectD-rings on leg restraintlines to upper and lower garters, left and right side. Ensure that leg lines are not twisted or looped.
piGi-
b. Lapbelt - Connectand Adjust.
With electrical and/or hydraulic power on the aircraft, wings can move if wing contrrt systemsfail.
Connect lapbelt strapsand adjustsnugso asto provide securelap restraintin flight andseatkit suspensionfor ground egressor ejection. c. Parachutereleasefittings nessBuckles.
9. Wing-sweep switch-MAN.
Attach to Har-
10. Lefl and right throttles - OFF. 11. Exterior lights master switch - Set.
d. Anti-g and oxygen/communication leads Attach.
Position switch in accordance with standard procedures for day or night and field or carrier operations.
When connecting the oxygen/communication fitting, avoid twisting the hard hose,
12. FLAP handle-
e. Inertia reel - Check,
CORRESPONDMG.
13. Throttle friction lever - OFF (all).
Position shoulderharnesslock lever forwardto lock position. Check that both shoulderstraps lock evenly and securely. Move lever aft to unlock harness.
14. ASYM LIMITER switch-ON
Attach composite fitting without causing unnecessarytwisting of hard hose.
16. BACK UP IGNITION switch - OFF.
15. L andR ENG mode switches - PRI.
17. THROTTLE TEMP switch -
2. OBOGS master switch-OFF.
ORIGINAL
(guarddown).
7-8
NORM.
NAVAIR 01.F14AAD-1
Note The Fl IO-GE-400 engine automatically compensatesfor temperaturevariations. 18. TBROTILE MODE switch -
34. Circuit breakers-Checked. 35. HYD HAND PUMP -Check. Extend handpump handle and stroke to check tirmness of pumping action and an indication of pressure buildup on the brake pressuregauge. Stow handpumphandle in a convenientposition for readyaccess.
BOOST.
19. L and R INLET RAMPS switches -AUTO. 20. ANTI SKID SPOILER BK switch - OFF.
36. HOOK handle -Corresponding.
21. FUEL panel
37. GUN ROUNDS panel - Set.
a. WINGEXT TRANS switch -AUTO. b. REFUEL PROBE switch -
38. DISPLAYS panel
RET.
a. BUD MODE switch - Set.
c. DUMP switch-OFF. d. FEED switch -NORM
b. HJDDECLUTTERswitch
(guarddown).
24. Parking brake -
Set.
c. BUD FORMAT switch - Set.
22. LDG GEAR handle - DN. 23. NOSE STRUT switch -
-
d. HUDMJI ALT switch - BARO.
OFF.
e. BUD PWR switch -OFF.
Pull.
f. ECM switch - Set.
25. Altimeter -Set.
g. TCS FOV switch - Set.
Setfield or carrier elevation as applicable. 26. Radaraltimeter - OFF.
39. ELEV LEAD knob-Set.
27. Standbyattitude gyro - Caged.
40. SW COOL switch - Set.
28. Lefl and right FUEL SHUT OFF handles- In.
41 L and R generatorswitches -NORM.
29. MA ARM switch -
OFF (guarddown).
p&E-)
30. ACM switch - OFF (guarddown). Ground engine operationwithout electrical power supplied by either the generatorsor externalpower may cause20-mm ammunition detonationbecauseof excessiveheat in the gun ammunition drum.
31. MultifUnction display mode switches- OFF. Note Visually checkfor security of cockpit equipment, particularly the multifunction displays, BUD, andinstroment panel gauges. 32. Clock -Wind
42 EMERG generator switch down).
and Set.
NORM (guard
43. Air-condition controls
33. Fuel BINGO -Set.
a. TEMP mode select switch-AUTO.
Settotal fuel remaining value for initial activation of fuel BINGO caution reminder consistentwith mission profile to be flown.
b. TEMP thumbwheel control-As (5 to 7 midrange).
7-9
Desired
ORIGINAL
NAVAIR Ol-F14AAD-1
c. CABM PRESS switch -NORM. d. AIR SOURCE -OFF. Wings will move to emergencyhandleposition regardlessof wing-sweep cb position.
44. WSHLD AIR switch -OFF. 45. ANTI-ICE switch -AUTO/OFF.
Note If wings arein OV SW, do not extendhandle.
46. ARA-63 panel a. CHANNEL selector- Set.
3. ICS -Check.
b. POWERswitch -OFF.
4. Laodinggearindicatorandtransitionlight-Check.
47. MASTER LIGHT panel controls- As Required. Set external and interior lighting controls consistent with day or night and field or carrier operating conditions.
5. MASTER TEST switch-check. Coordinatewith RIO.
48. MASTER TEST switch -OFF. 49. EMERG FLT HYD switch down).
Check gear position indication down and transition light off,
a. LTS.
AUTO (guard
Check that all warning, caution, and advisory lights illuminate. The brightnessofthe indexer lights shouldbe setduring the test.
50. HYD TRANSFER PUMP switch - SHUTOFF (guard UP).
b FIRE DET/‘EXT.
5 1. CANOPY air diffuser lever - CABIN AIR.
L and R FIRE lights illuminate to verify continuity of respectivesystem. The GO light will illuminate verifying continuity through the four squib lines, that 28 Vdc is available at the lefl and right fire switches, and that the fire extinguishercontainersarepressurized.
52. VIDEO CONTROL switch -OFF. 53. INBD and OUTBD spoiler switches (guard down).
NORM
54. Storagecase - Inspect. C
Check adequacyof flight planning documentsand storageof loose gear.
INST Check for the following responses after 5 seconds:
7.42 Prestart - Pilot
(1) RPM - 96 percent.
1. External electrical power - ON.
(2) EGT - 950 *lo “C.
2. If wings arenot in OV SW:
Initiates engineovertemperatie alarm.
a. WING SWEEP DRIVE NO. 1 and WG SWP DRNO.2/MANUVFLAPcb’s--ll(LDl, LEl).
(3) FF -
10,SOOPph.
(4) AOA (units) - 18 zt.5
b. EmergencyWING SWEEP handle -Extend and Match Captain Bars With Wing Position Tape.
Reference and indication. (5) Wing sweep -
45 *2.5O.
Program, command,and position. ORIGINAL
7-10
NAVAIR
(6)
FUEL QTY - 2,000 +200 Pounds(both cockpits).
(7)
Backup oxygen pressure2,100Psi.
(8)
L and R FUEL LOW lights nated(both cockpits).
Engine Start - Pilot. Prior to engine start, the pilot and plane captain should ascertainthat the turnup area is clear of FOD hazards, adequatetiresuppressionequipmentis readily available, and engine intakes and exhaustsare clear. Although the engines cannot be startedsimultaneously,either can be started fmt. The following procedureestablishesstarting the right enginefirst. Wheneverpossiblethe aircraft should be positioned so as to avoid tailwinds, which can increasethe probability of hot starts.
7.43
1,800to Illumi-
d. MASTER TEST switch - OFF. 6. EjectionseatSAFE/ARMED handles-
Ol-Fl4AAD-1
ARMED.
pi&-( Verify seatarmedwith RIO. 7. CANOPY -Clear
Coordinatemovement of any external surfaces and equipment with the plane captain or director.
RIO To Close.
(,,,,,,,I Flightcrews shall ensurethat handsand foreign objectsare clear of front cockpit handholds and top of ejection seatsand canopy sills to preventpersonalinjury and/or structural damageduring canopyopeningor closing sequence.Only minimum clearanceis afforded when canopy is transitioning fore andaft.
If enginechugsand/orrpm hangupis encounteredwith one engineturning during normal ground start, monitor EGT for possiblehotstart.AIRSOURCEpuahbutton shouldbe set for the operatingengine until ‘pm stabilizes at idle; then set to BOTH ENG.
Note
To preventpossible engineovertemperature during crossbleedstart attempts,select the operatingenginefor air soumeand retam to BOTH ENG after rpm stabilizes at idle or above.
If CLOSE doesnot closethe canopy,depress the grip latch, releaseand push handle outboard and forward into BOOST. If it is necessaryto use BOOST, the handle shall be returned to CLOSE to avoid bleed-off of pneumaticpressure.
1. ENG CRANK switch - L (left engine).
8. LAD/CANOPY light - OFF.
2. ENG CRANK switch -OFF.
Planecaptainshallstow boardingladderandsteps. 9. Inform RIO -Ready To Start.
3. ENG CRANK SWITCH - R (right engine). 4. ENG CRANK SWITCH -
10. Starterair -ON.
OFF.
5. EMERG FLT HYD switch -Cycle. a. EMERG FLT HYD switch -
LOW.
Checkthat ON flag is displayedin EMER FLT LOW hydraulic pressurewindow. Verify control over horizontaltail andruddercontrol surfacesas viewed on surfaceposition indicator.
The ECS air sourceshall remain off during enginestartuntil externalair is disconnected in order to reducethe possibility of bleed air duct contamination.
7-11
ORIGINAL
NAVAIR
01-Fl4AAD-1
b. EMERG FLT HYB switch-HIGH.
a If the START/VALVE caution light illuminatesafter the ENG CRANK switch is off, selectAIR SOURCE to OFF to prevent starteroverspeed.
Checkthat ON flag is displayedin EMER FLT HI hydraulic pressurewindow. Verify control over empennageflight control surfaces and higher surfacedeflection rate. c. EMERG FLT HYD switch -AUTO
(LOW).
Check that OFF flags are displayed in both EMER FLT HI and LOW hydraulic pressure windows.
. When attempting a crossbleedor normal ground start, do not attempt to reengage the ENG CRANK switch if the engine is spooling down and rpm is greater than 46 percent. Between 30- and 46-percent rpm, the ENG CRANK switch may not stayengagedbecauseof normal variations in startercutout speed. Note
During cold starts, oil pressuremay exceed 65 psi. This pressurelimit should not be exceededfor more than 1 minute.
Combinedandbrakeaccumulatorsshouldbe charged prior to backup module checks. Checks should be made slowly enoughto ensurecontinuous ON indication in the hydraulic pressure indicator and to prevent damageto the pump or motor.
7. Right throttle -IDLE
at 20-PercentRpm.
Note
I
Ensure combined and flight hydraulic pressures are zero prior to testing emergency flight hydraulic systemto allow propercheck of 300-psipriority valve. 6. ENG CRANK switch - R (right engine). Placethe crank switch to the R position wherethe switch is solenoid held until automatically releasedto the neutral (OFF) position at the starter cutout speedof approximately 49- to 5 1-percent ‘pm. Manual deselect of the switch to OFF will interrupt the crank mode at any point in the start cycle. Oil pressureand flight hydraulic pressure rise will becomeevident at 20-percentrpm.
If an idle crossbleedstart is attemptedwith high-residual engine EGT and/or throttles areadvancedfrom OFF to IDLE prior to 20percentrpm, higher than normal EGT readings may occur. If the EGT appearsto be rising abnormally, increasingthe supply engine to 80-percent‘pm may yield a normal starttemperature. Note l
AdvancingtheR throttleTom OFF to IDLE automaticallyactuatesthe ignition system. An immediateindication of fue.1flow (300 to 350 pph) will be exhibited and light-off (EGT rise) should be achievedwithin 5 to 15seconds.Peakstartingtemperatureswill he achievedin the 40- to 50-percenttpm range.Atler a slighthesitation,theEGT will returnto normal. Exceeding890“C constitutes a hot start.During the initial starting phase,the nozzle shouldexpandto a fullopen(100percent)position.
l
If the START VALVE caution light is illuminated after the ENG CRANK switchisoffor ifthe ENG CRANKswitch does not automatically return to off, ensure that the ENG crank switch is off by 60-percentrpm and selectAIR SOURCE to OFF to prevent starteroverspeed.
If no oil pressureor hydraulic pressureis indicated,start shall be abortedby setting ENG CRANK switch to OFF. Ifthe ENG CRANK switch doesnot automatically return to the OFF position by SO-percent‘pm during start, ensurethat theENG CRANK switch is offprior to 60percent ‘pm to preventstarteroverspeed.
ORIGINAL
7-12
NAVAIR 0%F14AAD-1
Note Lossof electricalpower may result in smoke enteringthe cockpit via the ECS. If the transferpump doesnot pressurizethe combinedsystemwithin 5 seconds,immediately setHYD TRANSFER PUMP switch to SHUTOFF.
8. R GEN light - OFF. The right generatorshould automatically pick up the load on the left and right main ac buses as indicatedby the R GEN light going out at approximately 59-percent‘pm.
14. HYII TRANSFER PUMP switch - SHUTOFF. 15. Repeatsteps6 through 10 for left engine.
9. R FUEL PRESS light -OFF.
16. Starterair -
The fuel-pressurelights should go off by the time the engineachievesidle ‘pm. 10. Idle engineinstrumentreadings -
Disconnect.
17. AIR SOURCE - L ENG, R ENG, thenBOTH ENG.
Check.
Verify cockpit airflow in eachposition.
a. RPM - 62 to 78 Percent.
18. OBOGS masterswitch - ON.
b. EGT - 350 to 650 “C (nominal). c. FF - 950 to 1,400Pph (nominal). Ensure ECS service air is available to OBOGS prior to selecting the OBOGS master switch ON.
d. NOZ position - 100Percent. e. OIL-25to35Psi
(nominal)(15psiminimum).
f. FLT HYD PRESS 11. External power -
19. HYD TRANSFER PUMP switch-NORMAL.
3,000 Psi.
20. Groundsafetypins -Remove and Stow.
Disconnect.
Planecaptainshouldremove landinggearpins and stow them. 7.4.4 Poststart - Pilot Ground engine operation without electrical power supplied by either the generatorsor externalpower may cause20-mm ammunition detonationbecauseof excessiveheat in the gun ammunition drum. 12. ENG CRANK switch-L
1. STAB AUG switches-All
ON.
2. MASTER TEST switch - EMERG GEN.
(let? engine).
When combined hydraulic pressurereaches3,000 psi, tetum switch to neutral(centerposition).
Check that NO GO light illuminates for about 1 seconduntil emergencygeneratorpower is connectedto essentialbusesandGO light illuminates. When disconnectingthis test, the resultantpower interruption causesthe standardattitude heading referencesystemlight to illuminate momentarily, 3, VMCU operation -
13. HYD TRANSFER PUMP switch-NORMAL Hydraulic transfer pump will operatefrom flight sideto maintain the combined sidebetween2,400 to 2,600psi.
7-13
CHECK.
Following disengagementof the emergencygenerator.a oroner check of the VMCU is indicated by illummaiion of the PITCH STAB 1 and 2, ROLL STAB 1 and2, YAW STAB OP andOUT, SPOILERS, HZ TAIL AUTH, RUDDER AUTH, ORIGINAL
NAVAIR
01.F14AAD-1
AUTO PILOT, and MACH TRIM lights during thepower transient(approximately 1.25seconds). Once normal power is restored,all lights go out exceptthe RUDDER AUTH light (resettablewith the MASTER RESET pushbutton)andthe PITCH and ROLL STAB AUG switcheswill be OFF. 4. Advise RIO that test and check is completed. 5. STAB AUG switches-All
raisedposition. Then raisehandleto full extension andhold until HZ TAIL AUTH cautionlight goes out and OVER flag appearson wing-sweep indicator. Move handle to full aft OV SW and stow. 8. Wing-sweepswitch - AUTO. 9. WING SWEEP DRIVE NO. 1 and WG SW DR NO. 2/MANUV FLAP cb’s -IN (LDl, LET)
On. 10. WING/EXT TRANS switch - OFF.
6. AFTC -CHECK.
11. MASTER RESET pushbutton- Depress. a. L ENG mode switch - SEC. 12. OXYGEN SUPPLY valve-ON. L ENG SEC light illuminates; left NOZ indicator pointer below zero.
Turn OXYGEN SUPPLY valve ON, place mask to face and check for normal breathingand regulator and mask operation. Turn OXYGEN SUPPLY valve OFF, check no breathing.
b. L ENG mode switch - PRI. L ENG SEC light goesout; NOZ indicator to 100percent.
13. COMM/NAV/GEAR/DISPLAYS
c. R ENG mode switch - SEC.
- ON.
a. UHF MODE switch - T/R or T/R & G.
R ENG SEC light illuminates; right NOZ indicator pointer below zero.
b. Tacan function selector- T/R. c. MFDs -ON.
d. R ENG mode switch - PRI. d. ARA-63 POWER switch -ON. R ENG SEC light goes out; NOZ indicator pointer to 100percent.
e. HUD PWR switch-ON. f. Radaraltimeter - ON. g. VIDEO control switch - ON.
Selecting secondary(SEC) mode closesexhaust nozzles increasingexhaustnozzlejetwake hazard.
14. Trim -Set
15. Standbygyro-Erect.
Note
16. MASTER RESET pushbutton- Depress.
Performing AFTC checkduring OBC inhibits AICS ramps from programming. Rampsmust be resetbeforeanotherOBC can be performed.
17. MASTER TEST switch - OBC. Coordinatewith RIO and plane captain.
Operatingenginesin secondarymode inhibits the engine monitoring systemportion of FEMS until primary mode is reselected.
Increasedsuction aroundintakesduring inlet rampprogramming andthe automaticmovement of the horizontal stabspresentsa FOD hazardand the potential for injury to ground personnelnot clear of theseareas.
7. EmergencyWING SWEEP handle- OV SW. If wings are not in oversweep,move the wings to 68’ using WING SWEEP emergencyhandle in ORIGINAL
000.
7-14
NAVAIR
01.F14AAD-1
transition light goesout when fully retractedand doors closed.
18. Autopilot-Engage. 19. Failure history tile - Clear.
23. WSHLD AIR switch - Cycle. 20. MFD OBC TEST -Select. 24. MASTER TEST switch -OFF. The following systems are automatically exercised during the l-1/2 minutes required to complete the OBC tests. a. The AICS self-test turns on hydraulic power and exercisesthe ramps through full cycle: STOW-EXTND-STOW. During the test, the respective RAMP light illuminates until the ramps return to the fully stowed position and the hydraulics are shut off. A failure is indicatedby an INLET light and/or OBC readout.
If engaged, verify that autopilot disengages automatically. 25. WING/EXT TRANS switch-OFF. 26. Trim - Checkedand Set 000.
b. Pitch, roll, yaw stab aug; authority stops; AFCS computers; Mach trim compensator; autopilot, spoiler.
Ensure adequateclearancebefore moving wings.
During the courseof the test, the STAB AUG lights remain illuminated until the test is satisfactorily completed.All lights should be off at termination of test.
For CV operations,omit steps27 through47.
Note
27. EmergencyWING SWEEP handle- 20”. Move the emergencyWING SWEEP handle to 20” (full forward) and engagethe spider detent. Stow handle and guard. HZ TAIL AUTH light illuminates coming out of OVSW. Light goesoff when OVSW stopsremoved.
OBC commencementwith nose-downtrim may result in a force-link disconnect when thestick hits theforward stick stopduring the pitch parallel actuatorchecks.
28. MASTER RESET pushbutton- Depress.
a. Autothrottle - This test is a computerself-test with output commands inhibited to prevent throttle movement. 21. Speedbrakeswitch - EXT, then RET. Cycle speedbrakeswitch to EXT, releaseand check for partial extension.Select EXT again, checking indicatorfortransition for full extension.SelectRET andcheck indicator for an indication of full retraction. Check for stabilizer position fluctuation during speedbrakeextensionand retraction to verify integratedtrim operation. 22. REFUEL PROBE switch - All EXT, Then RET. Cycle the probeto the extendposition, noting illumination ofthe probe transition light with switchprobeposition disparity. Check probenozzlehead for condition, Retractprobe and again check that
7-15
The W/S caution legend on the MFD and the WING SWEEP advisory light go out and the AUTO and MAN modes are enabled. 29. External lights flight).
Check (prior to night/IMC
During night operations,aircraft with inoperabletail and aft anticollision lights will not be visible from the rear quadranteven under optimum meteorologicalconditions,thus increasingmidair potential. 30 Flaps and slats -Dbl.
Check for full deflection of the flaps and slatsto the down position and automatic activation of the
ORIGINAL
NAVAIR 0%Fl4AAD-l
outboardspoiler module. Check for 3” TEU stabilizer position.
SPOILER light should illuminate and all spoilers should fail down. Verify that the GO light illuminateswith l-inch lateral stick in eachdirection.
31. Flight controls - Cycle. 40. MASTER TEST switch - OFF. Complete full-cycle sweepof longitudinal, lateral, directional, and combined longitudinal-lateral controls while checking for full authority on surface position indicator. Check that all spoilersextend at the same rate with slow lateral stick deflections and extend to full up position. Observethe following:
46. Maneuver flaps - DN.
+30° Rudder.
d. Longitudinal-lateral combined 15’ TED Horizontal Tail.
47. Wing-sweep switch-MAN fzzjljJ
If wing-sweep commandedposition indicator (captain’s bars)doesnot stop at 50°, immediately select AUTO with wing-sweep switch.
A stabilizer vibration may occur when the control systemlinkage is held in contactwith a total tail stop during stick cycling checks. This vibration is acceptable, provided it damps when the control stick is moved to clear the stop in contact.Clearancefrom the stopcanbestbe verified by movement of the matching stabilizer indicator needle away from its maximum travel position.
48. Maneuver flaps-Crack
Check maneuverflap retraction. 50. Emergency WING SWEEP handle- 68”.
Verify horizontal tail shift with DLC input. 33. ANTI SKID SPOILER BK switch BK.
5 1. EmergencyWING SWEEP handle- OV SW.
SPOILER
52. Wing-sweep switch -AUTO. 53. MASTER RESET pushbutton-Depress.
34. INBD and OUTBD SPOILER FLR ORIDE switches- ORIDE.
Note CV checklist resumes.
STICK SW.
54. ANTI SKID SPOILER BK switch - BOTH.
36. INBD and OUTBD SPOILER FLR ORIDE switches -NORM. 37.
55. ANTI SKID-BIT.
MASTER TEST switch-OFF.
56. ANTI SKID SPOILER BK switch-OFF.
38. MASTER RESET -Depress.
57. Displays-Check.
39. MASTER TEST switch - STICK SW. ORIGINAL
Up.
49. Wing-sweep switch-BOMB.
32. DLC - Check.
35. MASTER TEST switch-
50°.
35’ TEU,
Note
I
43. ANTI SKID SPOILER BK switch -OFF.
45. Flaps and slats -UP.
24’ Total Differential Tail.
c. Directional control -
42. Spoilers andthrottles L Check.
44. INBD and OUTBD SPOILER FLR ORIDE switches- ORIDE: I
a. Pitch control - Horizontal Tail 33’ TBU to 7’ TED. b. Lateral control -
41. MASTER RESET pushbutton- Depress.
58. Tacan TEST button -Depress. 7-16
NAVAIR 01.Fl4AAD-l
59. AKA-63 -BIT. 60. HUD-VIDEO -BIT. Carrieroperationswith aninoperativeRATS will increase CV wind-over-deck requirements.Failure.to notify CV OPS may result in damageto the ship’s arresting gear and aimraE tailhook assemblystructure.Consult applicablerecoverybulletins.
61. Altimeter -Set.
62. Compass -CBECK. Validate inertial navigation system derived magnetic heading on the displays by crosschecking with the SAHRS derived heading on the BDHI. Cross-checkine can also be accomalished bv cycling the naGgation system between INS and SAHRS. 63. SAHRS attitude reference-Check. Check SAHKS attitude referenceby boxing, then unboxing SAHRS on the MFD OWN A/C format. HUD attitude shouldnot change. Note Do not perform this check by boxing sAHR!x, then boxing INS. This will nlanually select INS, preventing an automatic changetoSAHRSintheeventofINSthilute.
2. Nosewheelsteering- Cycle OFF, Then ON. pi&-) Failure to cycle nosewheelsteeringfollowing hook check will enablenosewheelsteering centering to remain engagedand can causemispositioning of the launch bar during catapult hookup. This may result in launch bar disengagingt?om shuttle during catapultstroke. 7.4.5 Taxiing. To set the aircraft in motion starting fivm a static position requires advancingthe throttles slightly. While departingthe line area,flightcrew should clear theextremities of the aircraft andthe wings should remain at 68’ or in OV SW to minimixe the spanclearance.Oncein motion, IDLE thrust is normally sufficient to sustain taxi speeds and full nosewheel steering authority may be real&d.
64. Flight instruments -Check. 65. Oxygenmonitor-Test.
7.4.5.1 Taxi Speed. Taxi speed should be maintained at a reasonablerateconsistentwith traffic, lighting, and surfaceconditions. Subsequentto flight, while returning to the line at light grossweights, one engine may be.shut down to prevent excessivetaxi speedsat IDLE thrust
7.4.4.1 Final Checker (Ashore) 1. NOSE STlZUT switch - KNEEL; Check Launch Bar DN. m Ensureall tiedowns have beenremoved before selectingKNEEL.
Before taxiing aim&with wings in oversweepand full wing fuel tanlm,trim stabilizer to zero to prevent wingtip and stabilizer interference.
2. Hook - DN; Check EATS Advisory Light On, Then up. 3. LAUNCH BAR switch-Cycle.
When taxiing across obstacles ensure nosewheelis centeredto precludelaunch bar from impacting nosewheelwell doors.
4. NOSE STRUT switch - EXTD. 7.4.4.2 Final Checker Aboard CV
To prevent overheating,do not ride the wheelbrakes.
1. Hook -Down On Director Signal,CheckEATS Advisory Light On, Then Up. 7-17
ORIGINAL
NAVAIR Ql-FI4AAB1
4 FEET2
INCHES
T
8-S/8 ,NCHES WATIC) L 3FEET 2 FEET
l/4 INCH
IKNEELED)
Figure 7-3. Taxi Turn Radii (Maximum Nosewheel Steering709 ORIGINAL
7.18
NAVAIR 0%Fl4AAD-1
7.4.6 Taxi - Pilot
Note When shuttingdown one engineduring taxiing, the right engine is normally shut down so that normal braking is maintained. 7.4.5.2 Taxi Interval. Thetaxiintervalshouldbesufficiant to avoidtaxiingin anotheraircraft’sjet wash,which presentsadditionalFOD potential.Although the antiskid systemis armedat speedslessthan 15knots,the antiskid systemis not operative.The nosewheelsteeringcan mmain engagedthroughoutthe taxi phase.Application of wheelbrakes in conjunction with nosewheel steering shouldbe pertormedsymmenically to minimixe nosetire side loads.In minimum radius turns (Figure 7-3) using nosewheelsteering,the inboardwheel rolls backward as the axis of rotation is betweenthe main gear.Because of the distance from the cockpit to the main landing gear,the pilot should make allowance for suchin turns to preventturning too soonand cutting comers short.
Taxiing with the left engine securedis not authorized.Normal braking and nosewheel steeringcontrol will be lost if the hydraulic transferpump (BIDI) fails while taxiing with the left enginesecured. 1. Parking brake - Release. 2. Nosewheelsteering -Check.
7.4.5.3 Crew Comfort. Crew comfort during taxi operationsis affectedby the nosestrut air curve characteristics,which maintains the strut in the fully extended (stiff strut)position exceptduring deceleration.Because of the wide stanceof the main gear,differential application of wheelbrakesis effective for turning the aircraft without the use of nosewheelsteering.
NWS ENGA light illuminates upon engagement. Checkcontrol andpolarity in staticposition before commencingto taxi. Note If nosewheelsteer@ is inoperative,the emergencygearextensionair releasevalve may be tr+d,whichwillpmventrwentgearretmction. 3. Brakes -Check. Check for proper operation by applying letI or right brakeindividually andobservingbrakepressurerecoveryto the fully chargedcondition. 4. Turn-and-slipindicator -Check.
On-deck engine operations for extended periods can result in an unacceptable buildup in fluid temperatures(hydraulic, engine oil, and IDG oil) by taxiing heat exchangercapacities.Since the letI LDG supplies the majority of the electrical power, it is more susceptibleto overheating than the right. Tail winds or large power demand,or both, at high ambient air temperaturesincreasethe chancesof fluid overtemperature.
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5. Ordnance- Safe. Perform the following functions at prescribed location prior to takeoff in accordancewith base operating procedures: a. Missile seekerand tuning -Check b. Gun andexternalstemsRemovedand Armed.
GroundSafetyPi
7.4.7 Takeoff. The ainxatt takeoff checklist should be completedprior to calling for takeoff clearance,and all annunciator lights should be off, except NWS ENGA. Full flaps and slats am optional for all takeoffs regardlessof thmst or gross weight conditions. Both tlight crewmembersshould be operatingin HOT MIC during this phaseof Sight to enhancecommunications in eventof emergency.Upon tower clearanceand after visually clearingthe approachzone,the pilot shouldtaxi ontothe runway (takedownwind side if anotheraimraft to follow) androll straightaheadto align the nosewheel andto check compassalignment.
Sincethe outboardspoiler module is automatically energizedwith the flap handle down and weight on wheels, it is necessary to restrict the amount of flaps down operationon the deck to preventmodule fluid overheating.
7-19
ORIGINAL
NAVAIR Ol-IWAAD-1
Hold in position for takeoff using the toepedalbrakes with nosewheel steering engaged. Perform engine checksat 85- to 9Opercentrpm. SelectME on the roll and monitor engineperformance. pi&-l TakeotTswiththeHUDuncagedcanproduce HUD symbology that is difficult to interpret during turning or asymmetric flight conditions. If takeoff is anticipated following an uncaged landing, selecting the cage/seam switch on the inboardthrottle will ensurethe HUD retmns to the cagedformat.
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7.4.7.3 Takeoff RolULiftOR. Minimum ground roll takeoff proceduresdo not differ from the normal procedures.Maintain the control stick at the trimmed condition during the prerotation ground roll phaseto minim& aircraft drag. At the precomputed rotation speed (refer to NAVAIR 01-F14AAP-l.l), smoothly pull the control stick aft to position the HUD waterline at a 7’ to 10“ pitch attitude until safely airborne. With the flaps down, the aircraft seems to balloon from the runway in a near-level nose attitude with a more docile transition to flight than characteristic of swept-wing aircraft.
l
Note Do not use the parking brake to restrain the aircraft under the high-power conditions sincetire skid might result.
diStanW. l
0 If static engine nnmp greater than 90percent rpm is required,rmmp shouldbe performedone engineat a time. 7.4.7.1 Afterburner Takeoff. AB takeoffs areliited to single-engine, minimum afterburner takeoffs, waveoffs,bolters, or catapultlaunches.Dual-engineafterburnerandsingle-enginemaximum afterburnertakeoffs, waveoffs, bolters, or catapult launches are prohibited.Refer to Chapters4 and 11. 7.4.7.2 Brake Release. Aftertakeoffpowerchecks arecompletedandat a safeinterval behindthepreceding aircraft, releasethe toe pedal brakes.Nosewheelsteering should be used for directional control during the initial takeoff roll. Although the rudderbecomeseffective at 40 to 60 knots, to ensureadequatedirectional control in the event of an engine failure, nosewheel steeringshouldremain engageduntil 100KCAS. Refer to NAVAIR 01-F14AAP-1.1 for nosewheelsteeringon and off abort data.
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l
Although on-deck pitch attitude rotation in excessof lOa provides marginal tailground clearance,the aircraft is airborne well before such a phenomenonbecomes a’liiting factor.
7.4.7.4 After Lift-Off. After lift-off, relax the aR stick force as the a&raft acceleratestoward an in-trim condition. Raise the landing gear control handle after ensuringthat the aircraft is detinttely airborne.Pitching moments associatedwith gear retraction arenegligible and a gear-upindication should be achieved about 15 secondsafter initiation.
Ilhrminationof indexerlights is not apositive indication that the main landing gear am clear of the runway. Raising the gearbefore a positive rate of climb is establishedwill result in blown main tires. At approximately 180KCAS (dependingon longihrdid acceleration)the FLAP handlecanbeplacedin the UP position. A moderatenoseuppitching moment occurs during the flap and slat retraction phase,which takes approximately 8 seconds. Do not attempt to countera lateral drift becauseof a crosswindcondition. The use of large lateral control d&&ion should be avoided to keep from breaking out the wing spoilers, which have a negative effect on lift anddrag. Differential tail authority within the spoiler deadband(l/2-inch lateral stick deflection) is adequate for maintaining wings-level flight or effecting gradual turns with symmetric thrust. Before reaching the flap (225 KCAS for
Note Takeoffs performed with standing water on the runway may result in unstableengineoperationbecauseofwater ingestion. The nose strut should return to the fully extended position upon brake release; failure to do so will increasethe takeoff groundroll. Use of differential braking to wntrol directional alignment should be avoidedbecauseof its attendanteffect on groundroll distance.
ORIGINAL
Note The useof excessiveback stick on takeoff may causethe tail st&ces to stall, delaying aim&t rotation andextendingtakeoff
7-20
NAVAIR OI-F14AADI
10” flaps) and gear (280 KCAS) limit speeds,the pilot shouldascertainthat all devicesareproperly contigured for higherspeedflight. A gradualclimbout pitch attitude should be maintained until intercepting the optimum climb speed.A recheckof engineinstrumentsandconfiguration statusshouldbe performedafter cleanupduring the climbout phase.
pitching moment associatedwith main flap and slat retraction after takeoff. Slow-speed handling characteristics are superiorto the flaps-up contiguration.Additionally, possible automatic maneuvering flap/slat extension during rotation/transition to flight can be avoidedby extendingmaneuveringflaps beforetakeoff. 7.4.9 Formation Takeoff. Formation takeoffs are permitted in the Saps-up/maneuvering Saps-downconfigurationsfor section only. However, they shall not be permittedat night,with crosswindcomponentin excessof 10knots,with standingwateron therunway,on runways lessthan 8,000feet long and 200 feet wide, or with dissimilar aimaft All aspectsof the takeoffmust be briefed by the flight leader.Briefing shouldinclude Sap setting, power settings,use of nosewheelsteering,abort pm dues, andsignalsfor power andconfigurationchanges.
7.4.8 Flaps-Up Takeoff. Before thetakeoffroll, the proceduresfor flaps-up takeoff are identical to flaps down, except that the flaps remain retractedand only inboard spoiler brakesare available. During the pterotation groundroll phase,maintain thecontrol stick at the trimmed condition to minimize aircraft drag.At theprecomputedrotationspeed,smoothly pull the control stick afi to position the HUD waterline at a 7Oto 10” pitch attitudeuntil safely airborne. Do not exceed10’ ofpitch attitudeuntil well clearof the runway,as excessivenoseupattitudeswill causethe vertical tins andtailpipes to contacttherunway surface.
Transition to flight will occur smoothly as compared to the ballooning effect in flaps-down takeoffs. After main gearlit&off, relax the aft stick force as the aircraft accelerates.
7.4.9.1 Military Lead. With the completion of the takeoff checks,the lead aircraft will takeposition on the downwind side of the runway with the wingman on a normal paradebearingwith no wing overlap.Upon signal from the leader,the engineswill be advancedto 90percentpower. When ready for flight, the pilots shall exchangea thumbs-upsignal. On signalfrom the leader, brakesarereleased,MIL is selected,leaderthenreduces power 2 percent.Directional control is then maintained with nosewheelsteeringuntil rudderbecomeseffective. During takeoff roll, the leader should make only one power correction to enhancethe wingman position. If optimum position cannotbe obtained,relative position should be maintaineduntil the flight is safely airborne. At the precomputedrotation speed,the leader should rotatethe aircrafi 7’ to 10” noseupon the HUD or MFD and maintain this attitude until the flight is airborne. Turnsinto the wingman will not bemadeat altitudesless than 500 feet aboveground level.
Becauseof the smooth, flat transition to flight, cam shouldbe takento avoidprematurelandinggearretraction andresultingblown tires Raisethe landing gearcontrol handleonly afterensuringthatthe aimtail is airborne.
7.4.9.2 Wingman. The wingman should strive to matchtheleader’sattitudeaswell asmaintainparadebearing with wingtip separation.Whenboth aircratlaresafely airborne,thegearis retractedon signaltiom the leader
Becauseof increasedlongitudiial control effectivenesswith the flaps retracted,overcontrol of pitch attitude during takeoff is possible. Large or abrupt longitudinal control inputs shouldbe avoideduntil well clear of the runway.
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Note During flaps-up takeoffs, all flap/wing electromechanicalinterlocksareremoved from the CADC and wing-sweepcontrol box, allowing possible inadvertentwing sweepin the eventof a CADC failure. Outboard spoilers are inoperative with weight on wheels.
7.4.8.1 Maneuvering Flaps Takeoff. Maneuvering flaps provide improved takeoff performancewhen comparedto theflaps-upconQuration andeliminate the 7-21
In the event of an abortedtakeoff, the aborting aircraft must immediately notify the other aircraft and the tower. The aircraft not aborting should ensure positive wingtip separationis maintained and selecttill militarypower to accelerateaheadofthe aborting aimaft. This will allow the aborting aimrat? to move to the centerof the runway and engagethe available arrestinggear,if required. ORIGINAL
It is imperative that the wingman be alert for the ove.mmningsituation andtaketimely action to preclude this occurrence.Should an overrunning situation develop after becoming airborne, the wingman should immediately increase.lateral separation l?om the leaderto maintain wing position. Safe flight ofbothaircmftmuatnotbejeopardizedinan attempt to maintain position.
RIO CHALLENGE
PILOT RESPONSE
0.
‘MASTER TEST SWITCH
‘OFF”
9.
‘BI-DIRECTIONAL’
‘NORMAL’
10.
‘INBD AND OUTBD SPOILER FLR ORIDE SWITCHES
‘ORIDE”
11.
‘COMPASS AND STANDBY GYRO
‘ALL HEADINGS MATCH, STANDBY GYRO ERECT’
12.
‘OXYGEN
7A.10 TakeoffAborted. See Chapter 13, paragraph 13.1. 7.4.11 Takeoff Checklist. Prior to takeoff, the checklist will be completedby the challenge(RIO) and reply (pilot) method via the ICS on HOT MIC as a double-checkof the aircrafi configuration status. For CV operations,steps 1 through 9 may be completed while tied down. For field operations,stops 1 through 15 should he completed in the warmup area.
CV - APPROACHING CAT ON DIRECTOR’S SIGNAL 13.
WINGS (visually checked)
20’, AUTO, NO WING-SWEEP CAWs.
14.
‘FiAPS AND SLATS (visually checked)
As REQUIRED
15.
‘SPOILERS AND ANTISKID’
‘SPOILER MODULE ON, SPOILER BRAKES SELECTED” (field) ‘SPOILER MODULE SPOILER ON. BRAKES OFF (CV):
RIO CHALLENGE
PILOT REPLAY
1.
‘BRAKES”
‘CHECK OK, ACCUMULATOR PRESSURE Up”
16.
7RIM
2.
‘FUEL TOTAL lb.’
‘NORMAL FEED, AUTO TRANSFER, DUMP OFF. TRANSFEd CHECKED (if AUX tanks cmied). TOTAL, ~~;D~E~PP.)
‘0.0.0: @Id) AS REQUIRED (Cv)
17.
‘SAHRS ATTITUDE REFERENCE
‘GOOD SAHRS ATTITUDE’
10.
‘DISPLAYS
SET FOR TAKEOFF. HUD CAGED’
FORWARD AND RIGHT FEED TANKS FULL BINGO SET-’
19.
‘HARNESS LOCKED’
‘LOCKED’
20.
‘CONTROLS” (RIO visually check for full spoiler deflection)
‘FREE, STICK FULL FORWARD AND AFT. FULL SPOILER DEFLECTION, LEFT AND RIGHT, HYDRAULICS 3,000 PSI
21.
‘ALL WARNING AND CAUTIONS OUT
ILL WARNING AND CAUTIONS OUT
3.
‘CANOPY CLOSED, LOCKS ENGAGED, LIGHT OUT, STRIPES ALIGNED. HANDLE IN CLOSE POSITION’
‘CLOSED, LOCKS ENGAGED, LIGHT OUT, SEAL INFLATED. HANDLE IN CLOSE POSITION
I 4.
‘SEAT. ARMED, STRAPPED IN EIGHT WAYS COMMAND EJECl- (as b&fed)
‘ARMED, STRAPPED IN EIGHT WAYS, PILOT/MC0 IN WINDOW (as indicated)
5.
“STAB AUG
%LL ON
6.
-ATLS’
7.
‘ALL CIRCUIT BREAKERS SET”
ORIGINAL
ASHORE - IN TAKEOFF POSlllON 22.
“ALL IN’
7.22
‘ANTISKID/ SPOILER BRAKES
‘BOTH” (if operable)
NAVAIR 01.F14AAD.1
7.4.12 Ascent Checklist. feet (whichever occursfmt):
At level-off or 15,000
5. ANTl SKID SPOILER BK switch - BOTH (If operable,CV-OFF).
1. Cabin pressurization- Check.
6. Altimeter - Set.
2. Fuel transfer-Check.
7. Radaraltimeter -ON/BIT
3. In-flight OBC - Run.
8. Fuel’quantity and distribution - Check.
4. Oxygen monitoring system-Test.
9. Armament - Safe.
1 WARNING
Check.
10. CANOPY DEFOG/CABIN AlR lever -DEFOG.
1
11. ANTI-ICE switch - AUTO/OFF. Subsequentfailure of theoxygenmonitor system will not be evidentto theaircrewresulting in OBOGS output of unknown quality.
12. Display mode - TLN. 13. Steering-AWL.
Note Pilot should ensureoxygenmonitor test button is releasedas soon aspossible after illumination of the OBOGS caution light to preclude unnecessary depletion of the backup oxygen system.
14. ARA-63/ACLS -
ON/BIT Check.
15. RADAR WARNING RCVR PWR switch OFF. 16. ASPJ SYS switch - STBY.
7.4.13 In-Flight OBC. If desired or required OBC checkshould be run.
17. CHAFF/FLARE dispenserswitch - OFF. 18. RDR switch - STBY OR KMIT (pulse).
1. OBC disabledon pilot MASTER TEST PANEL - Check.
piiii-,,,,,,,
2. Verity MA ARM -OFF. 3. Multifunction display
The RIO shouldplaceRDR switch to STBY or XMIT (pulse)on final approachto prevent unnecessaryexposureof flight deck personnel to RF radiation hazard.
a. Select OBC basic format. b. Depressdesiredtest.
19. [T] Resolutionrun - Complete.
This initiates the m-flight BIT. Note Before reconnaissancesystem shutdown, run tihn leaderto protecttargetimagery from inadvertentexposureduring film download.
7.4.14 Preland and Descent 1. HOOK/HOOK BYPASS - As Desired. 2. Exterior lights-As
Desired.
20. [T] FRAME switch -OFF.
3. Displayed headinglBDHI - Check With MAG Compass. 4. Wing-sweepswitch-As
21. [T] PAN switch -OFF. 22. [T] IRLS switch -OFF.
Desired.
23. [T] FILM switch-OFF.
7-23
ORIGINAL
NAVAIR Ql-Fl4AAD-l
down to the deck without flaring so as to accurately establish a touchdown point and achieve initial compressionof main gear strutsto arm the spoiler brakes. Before selecting system switch to OFF, delay 15 secondsfor sensorshutdown,IR door to close,and mount to drive to vertical.
Note Landing with DLC engagedwill reducethe amountof afi stickdeflection available.DLC should be deselectedwhen establishedon landing rollout,
24. [T] TARES control panel SYSTEM switch OFF. 7.4.15 Pattern Entry. Entry to the field t&tic pattern will be at the speedand altitude prescribedby local courserules.Wings shall be repositionedto 20’ prior to deceleratingthrough220 KCAS. When approachingthe initial for the break,wings may be positionedmanually full aft to facilitate multiplane entry andbreak deceleration. Break proceduresshall comply with squadron, field, and/orCV standardoperatingguidelines. 7.4.16 Landing 7.4.16.1 Approach. At theabeamposition for landing, the aircraft should be at the prescribed altitude, trimmed up to 15units AOA with theLanding Checklist completed Indicatedairspeedshouldbe cross-checkedwith gmss weight in wings-level flight to verify AOA accuracy.Direct lift control and the approachpower compensator shouldbe engagedasdesiredandcheckedfor properoperation.Thetumofffromthe180°positionshouldbemade basedon surthcewind conditionsandintervaltraffic (type, pattern,touch-and-goor tonallanding,etc.) soas to allow suflicient straightawayon tlnal prior to touchdown The quality of the approachand touchdown is enhancedby starting t?om on-speedand altitude. The low thrustrequiredin the landing approachleaveslittle margin for corrections6om a high, fastposition. Therefore, the pilot must control theseparametersprecisely from the onsetof the approachto touchdown.Inertia and tail movement in conjunction with engine thrust response chamcteristicsdictate the use of small, precise corrections on the glideslope for the most effective control technique.Lateral overcontrol produceslarge yaw excursions that complicate lineup analysis. All turns shouldbe coordinatedwith rudder inputs. The landing shouldheplannedfor the downwind side of the runway with traffic behind, or opposite,the nearest traffic on landing rollout, or on the turnoff sideof the runway. Pilots shouldpracticeflying on thefield optical landing aid system wheneverpossible. Fly the aircraft
ORIGINAL
7.4.16.2 Touchdown. To avoid tail-ground clearanceproblems,pitch attitudeshouldnot exceed15 units AOA. At touchdown,immediatelyretatdthmttlesto IDLE and contirm spoiler brake deployment. Expeditiously lower the nosegearto the deck and,without allowing the noseto comeup, smoothlyprogramthe stick full at?, 7.4.16.3 Roll Out. The braking techniqueto be utilized with or without antiskid selectedis essentiallythe same; a single, smooth application of brakeswith constantly increasing pedal pressure. Do not pump the brakes.Directional control during rollout may require somedifferential braking. Nosewheelsteeringmay be usedduring rollout hut it must be engagedwith the rudder pedals centeredto avoid a directional swerve upon engagement.Restrict the use of nosewheel steering during rollout until or unlessrequiredfor directionalcontrol. Underconditions of normal braking (antiskid selected),the antiskid system is passiveand has no effect on wheelbrakeoperation. However, if maximum deceleration is desired, commencebraking as the noseis loweredand smoothly apply sufficient pressureto activatethe antiskid system. When an impending skid is sensed,antiskid operation will result in a seriesof shortwheelbrakereleasesanda surgingdeceleration.Constantpedalpressureshouldbe maintained.Approaching taxi speed(about 15 knots), easebrake pressureand deselectantiskid. f a If brakesamlost,releasebrakepedalsand secureantiskid. l
If antiskid is not deselectedbefore 15 knots,continuedhardbrakingcould result in blown tires.
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Ensurefeet are off brakesbeforecrossing field arrestinggear.
NAVAIR Ol-Ff4AAD-I
Note If maximum-effort braking or antiskid is not required,or antiskid is not selected,delaying brake application until the aircraft aerodynamically deceleratesbelow 80knots greatly reduces the possibility of blown tires and overheatedbrakes. Follow the PostlandingChecklist for propercontiguration cleanupprocedures.Clear the areabehindbefore turning off acrossthe runway. The right enginemay be shut down to reduce residual thrust during low-gmssweight taxiing. 7.4.16.4 Touch and Go. Fortouch-and-golandings, MIL thrust is applied after touchdownwhile thumbing speedbrakesin manually to configure the aim&l for a goaround. Automatic m&action of speedbrakesoccur uponapplicationof MIL thrust as a safetybackupmode of retraction.Contml for rotation is greaterthan experienced on takeoff, although the aircraft has the same basic liftoff characteristics.Fuel required per pass is normally 300 pounds,contingenton tragic pattern 7.4.16.5 Minimum Descent Rate Landings. Minimum descentratelandingsarerequiredfor heavyweight andlanding gearemergencylandings.Aircraft pitch attitude at touchdown is critical.
Do not exceedlo0 pitch attitude(on the waterline) and 14 units AOA at touchdown to prevent speedbrake,exhaustnozzle, and/or ventral tin damage. After touchdown, throttles should be immediately placedat the idle stops.The nosewheelshould be loweredto the ground, fully compressingthe main landing gearstruts.Delaying eitheraction will delay thedeployment of ground roll braking spoilers and may increase landing rollout. Additionally, until ground roll braking spoilersaredeployed,lateralcontrol remainsresponsive andpilot-induced lateraloscillation is possible.Aerodynamic braking should not be used as speedbrakes,exhaustnozzle, and/orventral fin damagemay occur. The Fresnel lens may be used for preciseglideslope control until arrestingthe approachrateof descent.Do not attemptto recentera high ball in close.The approach shouldbe flown on speedat 15 units AOA. At approximately 30feet AGL (2 to 3 secondspriorto touchdown), arrestthe rate of descentby a slight addition of power. Maintain approachattitudeuntil touchdown.If theFres-
nel lens is not available or runway length is critical, fly a shallow approachto touchdownin the fmt 1,000feet of runway. 7.4.16.6 Crosswind Landings. If landing is required at crosswindconditions abovethe limits or on a wet runway with crosswindsappmachingthe limits, an arrestedlanding should be made. Crosswind landing tests with a 20-knot component with all spoilers extendedhave been completed.With this limit, crosswindlandingspresentno unusualdimctional control problemswith up to a 20-knot component with all spoilen extended.Touchdown should be on speed,fm, and within the fust 500 feet. Lateral drift before touchdown must be eliminated by the wingslevel crab or wing-down technique(this is especially important on a wet runway). Upon touchdown, lower the noseto the runway to improve the straight tracking characteristics.With a 20-knot component,the upwind wing will raiseslightly. However,aerodynamiccontrols (rudders)will effectively maintain a straight track until approximately 80 KCAS where differential braking may be reauhed.Ifdirectional control is mareinal. , nosewheel stee-&gshouldbeusedto maintain control.Nosewheel steering will probably be required during crosswindconditions with a wet runway. If a landing must be ma& in crosswindconditionsin excessof the limits, do not arm the spoiler brakes for landing and againmaintain a wings-level attitude with lateral stick It must be realizedthat antiskid will not be available. At some crosswind component, the upwind wing will be raised excessivelyand as a result, diitional control will be marginal. It is estimatedthat this will occur with a greaterthan 25-knot crosswind component. 7.4.16.7 Landing On Wet Runways. Ifoperable, antiskid shall be used on wet runways to minimize the possibility of skidding or blowing tires. Standingwater greatly decreasesbraking effectivenessand may cause total hydroplaningin certainconditions.(Referto Chapter 18,Extreme WeatherOperations.)Intermittent puddles may cause wheels to lock while braking with antiskid not engaged.As the locked wheel leavesthe puddle and encountersa good braking surface,it will skid and blow unless brake pressureis released.The following proceduresare recommendedwhen landing on a wet runway: 1. Determine field condition before approach(braking action, crosswind component, arresting gear status).
light is out. Check thatbrakeaccumulatorpressure is tidly charged.
2. If adversewind andrunway conditionsexist, make a short-field arrestedlanding. In the eventthat the arrestinggearis not engaged,executea waveoff or bolter as appropriate.
During aircraft carrier (CV) qualifications and other operations when the landing gear are not raised after catapult launch, the pilot shall check the LAUNCH BAR advisory light is off prior to eachlanding.
3. Considerationshould be given to reducingtouchdown speedby flying a no-DLC approach.Plan the pattern to be well establishedon fnal in a wings-level attitude (crab, if required)on speed. Land on runway centerline, using normal FCLP landing techniques.
3. SAS - ON. 4. Flaps -Full
4. If a rollout landing is desired,touch down on centerline within the first 500 feet of runway.Landing rollout proceduresare the same as in a normal landing. When directional control is clearly established, utilii normal braking. During the highspeed portion of the landing roll, little or no decelerationmay be felt. Do not allow the aircraft to deviate Tom a straight track down the runway. If a skid develops, release the brakes, continue aerodynamic braking, and use rudders or nosewheel steeringfor directional control. Reapplythe brakes cautiously. If the skid continuesand adequate runway remains, select power as required and fly away. If conditionsdo not permit flyaway, use the long field overrun gearif required. If the aircraft is leaving the runway to an unprepared surface,secureboth engines.
Check for flap and slat full-down indication and no FLAP light. 5. DLC -Checked. 6. Hook-As
Desired.
Transition light should be out. 7. Harness-Locked 8. Speedbrakes-
EXT (out).
Check indicator for full specdbrakeextension. 9. Brakes -Check. 10. Fuel - Check.
Note A blown tire on landing rollout may result in directional control diff~culties,particularlyat high speeds.Refer to Chapter 15, Landing Emergencies, for blown-tire emergency procedures.
7.4.18 Postlandlng - Pilot 1. Speedhrakeswitch - RET. 2. ANTISKID SPOILER BK switch -
7.4.17 Landing Checklist. TheplacardedLanding Checklist should be completed in sequenceprior to arriving at 180”abeamthe touchdownpoint. All checklist items areessentialelementsto be checkedprior to each landing.With the ICS on HOT MC, the pilot shouldcall out the accomplishmentof eachstepsothat the RIO can doublecheckthat all items havebeenperformed. 1. Wing-sweep switch - 20° AUTO. Check wings in AUTO sweep control mode and verify at 20°.
OFF.
3. Flaps and slats -UP. Move FLAP handle UP and check for complete retraction of main flaps and slats and auxiliary flaps (flaps indicator - 0” and no FLAP caution light). Check automatic deactivation of the outboard spoiler module. As soon as the auxiliary flaps are retracted (8 seconds) the wings will sweepafi if commanded. 4. Wing-sweep switch -BOMB.
2. Wheels - THREE DN.
m
Check for wheels-down indication on all three gear,LAUNCH BARlight,andthat geartransition
ORIGINAL
DN.
7-26
Enstue that emergencyWING SWEEP ham dle and wings move to 55”.
NAVAIR 0%Pl4AAD-l
5. EmergencyWING SWEEP handle - OV SW. Raisehandleandmove aft to 6S”. Raisehandleto full-up extension and hold. When HZ TAIL AUTI-I caution light goesout and the OVER flag appears,move emergencyWING SWEEP handle full at?(7S0sweepposition) andstow. Rotatehandle guardto stowedposition.
Do not pull parking brake subsequentto a field landing if the brakes have been used extensively. 15. V/UHF radio MODE switch - OFF.
6. Ejection seats - SAFE (coordinatewith RIO).
16. Standbyattitudegyro - CAGE.
Raise SAFE/ARMED handlesto lock seatactnation devices.
17. Left throttle (alert RIO) - OFF. Alert RIO and upon signal from plane captain, secure left engine. Check emergency generator automaticoperationupon shutdown.
7. Avionics - OFF. Turn off all avionics (radaraltimeter, displays,tacan, ARA-63) exceptradio.
18. EMERG generatorswitch - OFF.
8. Right throttle - OFF.
19. Lights - OFF.
Note
Turn off internal and externallight switches.
. the right throttle (with the left th&tle at IDLE) to preventinadvertentcontactwith the left throttle, moving it at?to the cutoff position.
Verify Pilot.
21. CANOPY handle -Clear
RIO To Open.
22. Flightcrew -Egress.
. Run both engines at idle for 5 minutes before shutdown, especially if they have beenrun at high power. 9. OBOGS masterswitch -OFF
20. EIECT CMD indicator -
7.5 RIO PROCEDURES 75.1 Interior Inspection - RIO
(alert RIO).
1. Circuit breakers- Set.
IO. OXYGEN SUPPLY valve - OFF.
2. Left and right foot pedals -Adjust.
11. HYD TRANSFER PUMF’ switch - SHUTOFF.
3. Harnessing -Fasten.
Prior to shutoff, check hydraulic transfer pump operationin thecombined-flight direction with the IWD PRESS, OIL PRESS, R GEN, and R FUEL PRESS caution lights illuminated.
a. Leg restraintlines andgarters -
Connect.
D-rings on leg restraintlines to upper and lower garters,left and right sides.Ensure that leg lines arenot twisted or looped.
COMwt
12. Ordnance- Dearm (field). Dearm and safety ordnance in accordancewith local operatingprocedures.
b. Lapbelt -
Connectand Adjust.
Connectlapbelt strapsand adjustsnugso asto providesecurelap restraintin flight andseatkit suspensionfor ground egressor ejection.
13. Wheels-Chocked. 14. Parking brake -Pull.
c. Parachutereleasefittings - Attach to HarnessBuckles.
7-27
ORIGINAL
NAVAIR 01-F14AAD-1
c. MODE -As
d. Anti-g and oxygen/communication leads ATTACH.
Desired.
d. FILL switch-As When connectingthe oxygen/communication fitting, avoid twisting thehard hose.
Set.
12. V/UHF radio MODE switch-OFF. 13. RADAR COOLING switch-OFF.
e. Inertia reel - Check. Position shoulderharnesslock lever forward to lock position. Check that both shoulderstraps lock evenly and securely. Move lever aft to unlock harness.
14. EJECT CMD lever - Set. Determinedby squadronpolicy. 15. Data storageunit - Secure.
4. ANT SEL panel -As
Desired. 16. ARMAMENT control panel
5. [T] TARPS control panel switches-OFF. a. SEL JETT switch - SAFE. 6. ICS panel b. MSL PREP switch - OFF. a. VOL knob - Set. c. MSL SPD GATE knob -Per
SOP.
b. Amplifier-NORM. d. MSL OPT switch -NORM. c. Function selector -COLD
MIC. e. JETTISON STA SEL switch - OFF.
7. SENSOR control panel 17. Radio frequencycontrol indicator -As a. TCS FOV-
WIDE.
b. TCStrim -
Asset.
c. MVR source -As
18. Standbyattitudegyro - Caged,Turn Needle/Ball Centered.
Briefed.
19. Clock - Set and Wind.
d. MVR RECORD - OFF.
20. Sensorhand control panel.
8. Tacan mode switch - OFF.
a. RDR switch -OFF.
9. JTIDS
b. IRST switch -OFF.
a. MODE switch - STBY.
c. TCS switch -OFF.
Note If the primary Iink system for the mission is JTIDS, ensurethe JTJDSMODE switch is in STBY position. STBY provides the backup battery power required to hold the crypto variables and initialization datarequiredfor JTIDS missions. 10. KY MODE/TACAN/CMD
21. Tactical information display -
As Desired.
Note TID NAV MODE and DEST switches are inoperative 22. DD power switch - OFF.
panel- As Desired
23. MFD 3 power -OFF.
11. KY-58
24. ECM switch - OFF.
a. PLAIN switch - PLAIN.
25. NAV MODE switch - OFF.
b. Power switch - OFF.
26. Data entry unit power - OFF.
ORIGINAL
Desired.
7-28
NAVAIR 01-Fl4AAD1
41. POWER SYS TEST switch-OFF.
21. RADAR WARNING RCVR a. PWR switch - OFF. b. DISPLAY TYPE switch -As
7.5.2 Prestart - RIO. The following checks are performed by the RIO after starting air and electrical power are.applied prior to startingengines.
Desired.
28. ASPJ a. SYS switch -
OFF.
b. BIT switch -
OFF.
l
Starting air, which provides full ECS capability, must be connectedto the aircraft with elect&al power to cool tempemturecritical avionics.
l
If startingair is not available,a forced-air gmund cooling unit andservoair must be connected before turning on avionics equipment.
l
Ifelectricalpowerisnotumneotedwithspare starikgair,theECSwilIdrivetofullhot.
c. TAC switch -NORM. 29. MFA priority switch -NORM. 30. AN/ALE-39 PWRMODE switch -OFF. 3 1. Data-link panels a. TEST/NORM&J switch b. FREQ selector -
NORM.
Set.
. To prevent overheating the outboard spoiler module, pull the OUTBD SPOILER PUMP circuit breaker (2B3) anytime externalpower is connectedand the flaps are extended.
c. Power switch -OFF. d. REPLY switch-NORM. e. MODE switch - TAC/JTlDS (as required).
l
Note The data-link MODE switch must be set to therequiredlink system(JTIDS or TAC) for appropriateMFD display processing. f. ADDRESS -
Set.
Failure of the COOLING AIR light to illuminate on external electrical power indicates a miswired or failed sensor.The COOLING AIR light will not be available to indicate a subsequentECS turbine failure.
1. Seat,KS, and U/VI-IF foot switches -Adjust.
32. APX-76 -OFF.
Adjust seatheight sohelmet is beneaththecanopy breaker.Adjust ICS and UBF foot pedal fore-aft position for sitting comfort.
33. IFF MASTER knob - OFF. 34. MODE 4 switch -Out.
2. External power and air -ON.
35. IFF ANT switch - DIV.
3. ICS - Check
36. INTERIOR LIGHTS panel-As
Desired.
Verify two-way communications between flight crewmembersand adjustvolume to a comfortable level.
31. RADAR BEACON switch -OFF. 38. RADAR BEACON MODE switch -As
Desired.
39. GND CLG switch - OFF.
4. DL, JTIDS, tacan,andU/VI-IF - Set. Set communications/tacan!commandcontrol in accordancewith mission andflightcrew operating procedures.
40. SYS TEST-SYS Pm. ground check panel Closed. 7.29
ORIGINAL
NAVAIR 0%Fi4AAD1
5. Fuel quantity -
7.5.3 Engine Start - RIO. The RIO must monitor pilot proceduresand plane captainsignals to ensure maximum safetyduring the engine startsequence.
Check.
6. Lights-Check Check for illumination of consoleand instrument lighting.
7.5.4 Poststart - RIO 1. NAV MODE switch - Align.
7. LTS test-Check 2. DD power switch -ON. Check that all caution and advisory lights and E4X lights illuminate.
Failure to tutu DD power on prior to RDR switch causesa false DD power fault indication in ORT.
Note 3. RDR switch - XMIT.
During pilot INST test, the RIO should observefuel counterdecreaseto 2,000 pounds and MASTER CAUTION and FUEL LOW lights illuminate.
Verify that the SENSOR COND advisory light illuminates. 4. RADAR COOLING switch - ON.
8. Ejection seats-ARMED.
Verify that the SENSOR COND advisoty light goesout.
Arm ejection seatby releasingcatch and rotating SAFE/ARMED handledown to ARMED.
5. MFD3
9. CANOPY handle -CLOSE.
a. Power switch -
RIO will normally close canopy. Ensure verbal clearancefrom pilot. Check that CANOPY light goesout with tirll forward transitionof canopyinto the sill locks. Check that SEAT UNARMED light doesnot illuminate.
b. BRIGHTNESS and CONTRAST -Set. 6. DEU -On. 7. MSL PREP switch -
1 WARNING
DAY/NIGHT/AUTO.
1
As Required.
8. TCS switch - ON. 9. Align coordinates-
Flightcrews shall ensurethat handsand foreign objects are clear of front cockpit handholds, top of ejection seats,and canopysills to prevent personal injury and/or structural damage during canopy opening or closing sequence.Only minimum clearanceis affordedwhen canopyis transitingfore andaft.
VerifyQdatc
10. OXYGEN SUPPLY valve-ON. Turn OXYGEN SUPPLY valve ON, place mask to face, and check for normal breathingandregulator and mask operation.Turn OXYGEN SUPPLY valve OFF, ensureoxygenflow hasstopped.
Note If CLOSE does not close the canopy, depress the grip latch and release and push handle outboard and forward into BOOST. If it is necessaryto useBOOST, the handle shall be returned to CLOSE to avoid bleed off of pneumaticpressure.
11. [T] TARPS control panel SYSTEM switch RDY. ObserveDATA/MANNg/H 12. [T] IRLS switch - STBY. Observe IR NR light illuminated for cooldown period (maximum of 17minutes).
10. Acknowledge -Ready To Start.
13. Tacanmodeswitch-T/R. ORIGINAL
light illuminated.
7-30
21. Handcoatml -
14. IFF MASTER knob - STBY. a. Set CODE koob -As
22. ASPJ SYS switch -
Required.
STBY.
23.RATIARWARNlNGRCVRpenel
b. IFF panel -Test.
(1) MC switch (2)
Set.
-Set.
a. Display type switch -NORM.
Out.
Ml,M2,M3-Test.
b. PWRswitch -
ON.
Select NORM and observe that TEST light illuminates.
c. TEST switch - SPL. d. MODE button - LMT.
(3) MC -Test.
24. DATA LINK power - As Required.
Observethat TEST light illuminates. 25. D/L reply - As Required. c. IFF ANT switch -
As Desired. 26. AAI control panel -
15. JTIDS MODE switch -
Set.
As Required. a. TEST/CHAL CC switch -Test.
16. Communications -
ON/Set. Check DD display.
17. KY-58 -
As Required. 27. AN/ALE-39 (per threat) -
Set.
18. Standbyattitude gyro-Erect. a. BURST switch 19. DD-
Set. b. BURST INTERVAL
20. TID contmls -
Set. c. SALVO
a. CONTRAST-
Set. d. SALVO INTERVAL
b. BRIGHT control - Set. c. CLSN -OFF.
28. CANOPY DEFOG-CABIN AIR lever-CABIN AIR.
d. RID/DSBL -OFF.
29. Indicator lights -
e. ALTNUM-ON.
30. [T] V/H check
f. SYMELEM
-
ON.
8. DATALINK
-
AsRequired.
Test.
a. Manual V/H thumbwheels set - 360 Knots/ 200 Feet. b. V/H switch -Test.
h. JAM strobe - As Required. c. ObserveMAN V/H light is out. i. NON AlTK -
As Required. d. V/H switch - MANUAL.
j. LAUNCH ZONE -
As Required.
k. VEL VECTOR -As
Required.
31. [T] Vertical frame check 1. RANGE scale-
a. Manual V/H thumbwheels set - 350 Knots/ 1,800Feet.
As Required.
b. FRAME switch -VERT. r-31
ORIGINAL
c. FILM switch -
Note Before IRLS system check, observeIR NR light out following cooldown and BIT. Observefilm countermovement by 1 foot.
RUN.
Observeexposureinterval of 1.Osecond,Same cameragreenlight illuminated, andcheckcamera fixme counterfor properoperation.
a. IRLS switch - WFOV.
d. FILM switch -OFF.
b. MamralViHthumbwheelset-350Rnots/600 Feet.
e. FRAME switch - VERT. 32. [T] PAN autocyclechock
c. FILM switch -
a. PAN switch - CTR. b. FILM switch -
Observegmen IRLS light tlashing at 5-second intervalandcheckproperfihn counteroperation.
RUN.
Observeexposureinterval of 1.Osecond,green PAN light illuminated, and check camera frame counterfor properoperation. c. PAN switch -
-
d. FILM switch-
OFF.
e. IRLS switch -
STBY.
After INS ALIGN COMPLETE computer messageor when readyfor takeoff:
LEFT or RIGHT.
Observeexposureinterval of 2.0 seconds,PAN go light ilbuninated, and check camera tiame counterfor properoperation. d. FILMswitch
RUN.
35. NAV mode switch-
INS.
ObserveMFD transition tiom align format.
OFF.
36. DEST data- Verify. 37. BRG/DIST to destination -Check.
m
38. OWN A/C groundspeed- Check. Do not run PAN BIT (it may cause film jams).
39. MAG VAR - Check. 40. Notify pilot-Ready
33. [T] PAN pulse mode check
7.5.5 Taxi - RIO. The RIO primary responsibility during taxiing is to act as copilot/safety observer.BIT checksmay be performed while taxiing, provided that RIO attention is not diverted from copilot/safety observerduties.
a. Manual V/I-I thumbwheel set - 350 Knota! 13,500Feet. b. PAN switch - CTR. C.
FILM switch-RUN. Observe exposure interval of 5.0 seconds, greenPAN light illuminated, and check camera tiame counterfor properoperation.
1. Record ORTABIT and maintenancedisplay results on BER form. 2. OWN A/C groundspeed- Check. Own-aircratl groundspeedwhen stoppedshould be less than 3 knots.
d. FILM switch -OFF. e. PAN switch-OFF.
3. [T] OWN A/C altitude - CHECK.
34. [‘IJ IR sensorcheck.
ORIGINAL
To Taxi.
7-32
NAVAIR 0%F14AAD-1
7.5.6 In-Flight Reconnaissance System Check - RIO. En route to targetarea:
7.5.7.1 Serial Frame Camera Failure 1. [ T] FILM switch-Cycle
OFF/RUN/OFF.
2. I;T&FRAh@
Cycle OFFNERT or
1. [T] FRAME switch - VERT. switch -
2. [T] PAN switch - CTR. 3. [T] IRLS switch -
WFOV.
3. [T] FILM switch - RUN.
4. m FILM switch-RUN.
4. [T] FILM switch - OFF.
Run only long enoughto check operationand observeFRAME, PAN, and IRLS greenlights illuminated and check frame and foot counters.
5. [T] V/H-h4ANUAI.z. 6. [T] Thumbwheels- Set High Vg&I Value.
5. [T] FILM switch-OFF.
7. [T] FILM switch -RUN.
6. [T] IRLS switch - STBY. 7. [T] PAN switch-LEFT
If not corrected: 8. [T] FILM switch -OFF.
or RIGHT.
8. fT] FRAME switch - FWD.
9. [T] FRAME switch -OFF.
Note Prior to selectingFILM switch to RUN, delay 15 secondsfor camerapositioning.
7.5.7.2 Mount Failure 1. [Tl FUME switch- Cycle to OppositePosition. If not corrected
9. [Tj FILM switch-RUN.
2. [T] FRAME switch - OFF.
Run only long enoughto check operationand observe FRAME and PAN greenlights illuminated and check for proper film counteroperation.
pllGy+j
10. [T] FILM switch - OFF. a Initiate correctiveaction only onetime. 11. IT] FRAME switch - OFF. a If mount light doesnot go off, securesensor andwait 5 minutes to try again.
12. [T] PAN switch -OFF.
7.5.7.3 Panoramic Camera Failure
Note Keep manual V/H thumbwheels matched with actualaltitudeandairspeedto avertpossible degradedimagery if an automatic shift to the manual mode occurs.
1. [Tl FILM switch -
Cycle OFF/RUN.
2. [T] FILM switch-OFF. 3. [T] PAN switch -Cycle
7.5.7 TARPS Degraded Mode Procedures
4. [T] FILM switch-
OFF/CTR.
RUN.
If not correctedz
m
5. [T] FILM switch-OFF. Prior to initiating corrective action on malfunctioning sensors,ensurethat other sensorsare either in OFF or STBY. 7-33
6. [T] PAN selector-
LEFT or RIGHT.
7. [T] FILM switch -
RUN. ORIGINAL
NAVAIR Ol-FlUAD-
4. [T] IRLS switch -NFOV.
If not corrected: 8. [T] FILM switch - OFF.
5. IT] FILM switch -Cycle
9. [T] PAN selector-
6. [T] V/H switch - MAN.
OFF.
RUN/OFF.
7. Thumbwheels- 350 Knots/350 Feet. m 8. [T] FILM switch -RUN. Do not initiate BIT.
If collected:
7.5.7.4 Manual V/H Failure
9. [T] V/H switch -
1. [Tl Thumbwheels- 350 Knots/200 Feet.
If not corrected:
2. [T] V/H switch - Test. 3. [T] MAN V/H light out -
10. [T] FILM switch-OFF. Good Test.
11. [T] IRLS switch - OFF.
4. [T] MAN V/H light on - Thumbwheel Failure.
Note For actual combat missions, fail indications may constituteabort criteria.
7.5.7.5 IRLS Failures 7.5.7.5.1 Cooldown Malfunction (IR NR Light Illuminated)
7.5.8 Postlanding
-
RIO
Note Before shutdown,run IBIT. Note resultson BER card.
1. [T] IRLS switch - OFF. 2. [T] IRLS switch - STBY. After cooldown is complete, IR NR light will be out (2 minutes) then illuminates for the remainder ofBIT (80 seconds).If IRNR light remainson for more than 17 minutes, IR cooling system is malfunctioning; turn the systemoff. 7.5.7.5.2 Other IR LS Malfunctions (IR LS Light Illuminated)
1. Ejection seat- SAFE (coordinatewith pilot). 2. EJECT CMD lever - PILOT. 3. Harnessing -
Unstrap.
4. Radarbeacon- OFF. 5. IFF -MODE
1. [T] FILM switch - Cycle OFF/RUN/OFF.
4 HOLD, Then OFF.
6. Data link - OFF.
2. [T] BUS switch - OFF.
7. ASPJ SYS switch-OFF.
If IR LS light remainsilluminated, assumelR door malfonction and continuewith checklist.
8. INS - VIS FIX.
3. [T] IRLS switch - STBY.
9. NAV MODE switch - OFF.
Observe IR NR light illuminated for cooldown period (17 minutes),thenout for 120seconds,then on for remainderof AUTO TEST (80 seconds). Note Note time IR LS light ilhuninates during BIT. ORIGINAL
AUTO.
10. RECORD switch - OFF. Requites at leaat 20 secondsto allow tape to un threadprior to removal of electricalpower. 11. IRST switch - OFF.
7-34
NAWAlR WFlaAD-1
12. RDR switch - OFF.
3. Right throttle-OFF.
13. DD power switch - OFF.
4. Wheels-Chocked.
14. RADAR COOLING switch - OFF.
5. Parking brake- Pull.
15. Tacanmode switch - OFF.
m
16. JTIDS MODE switch - STBY/OFF. If heavy braking is used during landing or taxiing followed by application of the parking brake, normal brake operationmay not be availablefollowing releaseof the parking brake if the brakes are still hot. Check for normal brake operation after releasing the parkingbrakeaodbeforecommencingtaximg.
Note If network operationsa anticipated within 24 hours, select STBY; otherwise, select OFF. Do not leavethe system in DATA SILENT or NORM for more than 90 seconds without electrical power or the battery will be.depleted. 17. Standbyattitudegyro -CAGE.
6. REFUEL PROBE switch EXTD (as desired).
18. OXYGEN supply valve - OFF.
7. WDJGEXT TRANS switch-As
If external tanks or wings accept fuel in FUS EXTD, select ORIDE on WING/ EXT TRANS switch.
20. [T] TARPS control panel switches-OFF. 21. DEU-OFF.
Ifwings or externaltaoksdo not acceptfoe1 in ALL EXTD, selectFUS EXTD andtorn WING/EXT TRANS switch OFF.
22. MFD - OFF 23. Report - Ready for Shutdown.
8. REFUEL PROBE switch-RET.
Afler shutdownof both engines:
9. WING/EXT TRANS switch - OFF.
OPEN (alert pilot).
7.7 DECK-LAUNCHED INTERCEPT PROCEDURES
25. Flightcrew -Egress. 7.6 HOT REFUELING PROCEDURES Before commencinggroundhot refoelmg operations, a qualified groundcrewshall inspect the exterior of the aircraft for any discrepanciesthat might be hazardousto reftteling or farther flight operations.One groundcrew shall remain io a position on the right sideof the aircraft within view of both the pilot and refueling crew. Any hazardouscondition requiresthe immediate termination of refueling operations. After refueling, the flightcrew should refer to appropriate checklists to configure the aircraft for takeoff, dependingon intentions. 1. Fire extinguishingequipment -
Desired.
Note
19. VAJHZ radio MODE switch - OFF.
24. CANOPY handle-
FUS EXTD/ALL
Available.
2. All emitters- STBY or OFF. 7-35
Note Tbeseproceduresassumethataquickreaction, full-mission-capablelaunch is essential.Pr+ startpmoxhuesandcockpitconfigurationmay vary in accordancewith airwing policy and specific EMCON conditions.All CNI equipment,asapplicable,shouldbeplacedin ON or STBY, YAW STAB AUG switch shouldbe selected ON, and the HYD TRANSFER PUMP switch shouldbe in NORMAL before application of electrical power. The LTS, INST, EMERG GEN, WG SWP, andSTICK SW testson MASTER TEST panelshouldbe conductedandverified duringperiodicaircmfi tumups.Compliancewith theTakeoff Checklist is mandatory to ensureproper aircraft configurationbeforelaunch. ORIGINAL
NAVAIR
7.7.1
0%F14AAD-1
14. Ordnancecrew -Arm.
Pilot Procedures
Note
1. External electrical power - ON. 2. Seat -ARM. 3. Fire detect -Check. 4. Lett engine- IDLE. 5. Right engine-IDLE.
7.8
6. Displays -ON.
Sparrowtune occursafter CW is enabled andcan complete atler TX timeout.
.
PH attack capability is present after launch and Sparrowtnne occursautomatically wheneverCW is enabled.
HOT SWITCH
PROCEDURES
Increasedpotential hazardsexist in hot switch operations when an engine is running with canopyopenand front seatunoccupied.To minimize this potential hazard, minimum time should be spent in this condition. Pilot switch should be expedited and crew unstrap should be done with canopy closed.Pilot-to-pilot brief shouldbe accomplishedwith a pilot in the aircraft.
7. OBC - Select. 8. SW COOL -NORM. 9. OBC -Deselect. 10. Hookoperation -
.
Check
Note The RIO will vacate the aircraft fust. When
II. Takeoff Checklist.
the RIO is on the ground,flight deck,or hangar deck, the pilot will exit. This is particularly important during shipboardoperations.
12. Ordnancecrew -Arm. 7.7.2 RIO Procedures
1. Parking brake - Pull. 1. NAV MODE switch - CV ALIGN. 2. HYD TRANSFER PUMP switch -NORMAL. 2. CAINSWPT-
Select. 3. RDRswitch-OFF.
3. MFD3-ON. 4. Alignment coordinates-
4. IRST switch -OFF. Verify/Update. 5. TCS switch -OFF.
5. Seat -Arm. 6. RECORD switch - OFF. 6. RDR switch - XMIT. 7. TCS switch -ON.
7. [T] TARPS control panel SYSTEM switch OFF.
8. IRSTswitch -ON.
8. Let?throttle - OFF.
9. MSL PREP switch -NORM.
9. ASYM LIMITER switch -ON
(guarddown).
10. ENG MODE SELECT - PRI.
10. [T] TARPS control panel SYSTEM switch RDY.
11. THROTTLE MODE switch - MAN. 11. [T] IRLS switch - STBY. 12. Throttle friction lever- Increase. 12. Takeoff Checklist (complete.non-OBC functions). 13. Ejection seats -SAFE. When ALIGN QUALITY $2.0: 14. Flightcrew -Unstrap. 13. NAV MODE - INS. ORIGINAL
7-36
NAVAIR 01.Fl4AAD-1
15. Cockpit -Check FOR FOD.
7.9.3 Radio Procedures and Pattern Entry. A radio check with Paddles is advisable before pattern entry to co&m Charlie time. Approachesto the field for break will be controlled by the tower and t&n switchedtoPaddlesforFCLPpatterncontml.Atnotime will an aircraft remain in the pattern without a UHF receiver. On each succeeding pass, the following voice report will be made at normal meatball acquisition positions:
16. CANOPY handle- OPEN. 17. Flightcrews -
Switch.
18. Flightcrew - StrapIn. 19. Ejection seats -Armed. 20. CANOPY handle -CLOSE.
1. Side number
21. FIRE DETI’I’BST -TEST.
2. TOMCAT
22. THROTTLE MODE switch -
BOOST.
3. Ball/Clam
23. Throttle friction lever - As Desired.
4. Fuel state
24. Left engine - Start.
5. Type of approach, if appropriate (automatic, degraded, etc.).
25. RDR switch-
STBY. 7.9.4 Pattern. The patternshouldbe a racetrackwith the 180” approximately l-1/4 miles abeamat 600 feet abovefield elevation(seeFigure 74). The lengthofthe grooveshouldbe adjustedto give a wings-level descent onthe glideslopeof20 to 25 seconds(approximately3/4 mile). For maximum grossweight at touchdown,refer to Chapter 4, Operating Limitations. The turn to the downwind leg should be commencedafter climbing to pattern altitude (600 feet AGL) utilizing 30” angle of bank and 150 KCAS. Turning t?om the 180’ power shouldbe adjustedto maintain optimum angleof attack. A gradualdescentmay be commencedat this position with a minimum altitude of 450 feet AGL at the 90” position and350 feetAGL asa minimum until the pilot is receiving glideslope information. At approximately 49, the meatball appearson the Fresnel lens.Fly a rate of descentsuch that the ball is centeredas the aircraft arriveswings-levelin the groove.For manual,automatic, and DLC approachtechniques,refer to Carrier-Based Procedures,Chapter8.
26. TCS switch - STBY. 21. IRST switch - STBY.
EnsureTARPS maintenancepersonnelhave loaded sensorsand cleared aircraft before initiating power to TARPS pod. 28. [T] TARPS control panel SYSTEM switch RDY. Note The Poststart Checklist shall be completed with respect to aircraft configuration and switch positions prior to taxi. 7.9 FIELD CARRIER LANDING PRACTICE 7.9.1 Preflight Inspection. A normal preflight inspection will be conductedwith specific attention directedto tire condition,nosestrutextension,AOA probe conditions, and windshield cleanliness.Check that the hook bypassswitch is in FIELD.
7.9.5 Night FCLP. All provisions that apply to day FCLP also apply to night FCLP, plus the following items: 1. External lights-BRIGHT
and STEADY.
2. Hook bypassswitch -FIELD. When comfortably situated in the pattern, instruments should be flown as much as possible up to the 45” position.
7.9.2 Takeoff. The takeoffwill be individual.
7-37
ORIGINAL
NAVAIR Ol-F14AAD1
NOTE
“‘CROOWINO’
u ” INOlCATES LsOTERMlMOLoGY THE UHF TO DESCRl8E THE PATTEFtN.
“AWROACH
TURN”
Figure 7-4. Field CarrierLanding Practice
ORIGINAL
7-38
USEDOVER
NAVAIR
01.F14AAD-1
CHAPTER 8
Carrier-Based 8.1 CARRIER
Procedures
PREFLIGHT
8.2
Launch. Applicable aircraft launching bulletins, the CV andLSO NATOPS Manuals and the pertinentCV air operationsmanualshall be readby all flight crewmembersprior to carrier qualification. In addition, thepredeploymentlecturesyllabuscontainedin Chapter I of the CV NATOPS Manual shall be completed.
8.1.1
Briefing. A thoroughbriefing shall be accomplishedby the flight leaderprior to launch.This briefing shouldcall particularattentionto currentBINGO fields, emergencyprocedurespeculiartocarrieroperations,operating area NOTAMS, fuel management, and ship NAVAID status. Aircraft configuration, gross weight, expectedWOD, andapplicablelaunchtrim settingswill be verified prior to man-up. 8.1.2
8.1.3 Preflight. Preflight inspection should be accomplishedwith particular attentiongiven to nosestrut, main landing gear, tires, hook, and undersideof the fuselage.Note carefully the actual wing sweep,the lateral spacingbetweenparked aircraft, and the general directionof engineexhaust.Do not preflight the aircraft topsideat?of the bleed air doors if spottedwith the tail outboardof the safety nets. In the cockpit, particular attentionshould be given to the flightcrew displays to ensurethat the retaining devices have been installed. Ensurethat the WING SWEEP handle is securein the oversweepposition when applicable. If the wings are not in oversweep,ensurethat the emergency WING SWEEP handle position correspondswith the actual wing position. Leave the emergencyWING SWEEP handleguardup, extendthe emergencyWING SWEEP handle,andpull WING SWEEP DRIVE NO. 1andWG SW DR NO. ZMANUV FLAP circuit breakers(LDl, LEl). Crossbleedstartsshould not be performedunless the areaaft of the aircraft is clear.Tiedowns shouldnot be removedandenginesshouldnot be startedunlessthe auxiliary brake air pressure gauge indicates a full charge.
START AND POSTSTART
Shipboardstartandpoststartprocedu abbreviations of the shore-basedchecklists are as delineatedfor the poststart-pilotprocedures.Certainstepsareomitted becauseaircraft arespottedtoo close togetherto allow the wings to be swept forward while tied down. Cranking the left engineprior to starting the right, as outlined in the shore-basedprocedureswill ensurethat auxiliary brakepressureis available andwill ensurethat backup flight control module is full of hydraulic fluid prior to cycling. Carrier Alignment. Carrier alignment of the INS and SAHRS concurrentlyor of the INS alonecan be accomplishedusing SINS data or manually entered ship’s position, speed,and heading.A stored heading SINS alignmentis also available.
8.2.1
Concurrent SINS Alignment. For either data-link or deck-edge-cabletransmissionof SINS data:
8.2.1.1
1. EnsureSAHRS AC/DC cb’s (lA3,lAS, lA6,913) arepulled prior to application of electricalpower. 2. DATA LINK power switch-ON. 3. DATA LINK MODE switch - CAINSWPT. 4. Verify parking brake is set. Note Application of SAHRS powerprior to selecting CV ALIGN will not allow SAHRS to properly align. 5. NAV MODE switch - CV ALIGN. 6. ResetSAHRS cb’s. 7. Select OWN A/C MFD format by depressing DATA pushbuttonon MFD MENU1 display. The CV SINS DATA format will appear. 8-1
ORIGINAL
NAVAIR
8.
Ol-Fl4AAD1
DEU CV ALIGN page and depressingthe VLA option key.
Verify that SHDG is not boxed.If it is, depressthe SHDG pushbuttonto unbox it.
9. Monitor the progressof alignment by observing the QUAL andTIME acronymsandthe align scale on the MFD OWN A/C format. The SINS (ship) latitude, longitude, andINS north andeastvelocities canbe evaluatedon the MFD OWN A/C format. An INS ALIGN COMPLETE messagewill normally occur in 7 minutes. At this time the align quality should be below 1 nm per hour.
8.2.1.2 Concurrent SINS Stored Heading Carrier Alignment. Perform a reference alignment by
following the SINS carrieralign procedurein paragraph 8.2.1.1.When the INS ALIGN COMPLETE message appears on the HUDiVDI formats, return the NAV MODE switch to OFF. 1. Repeat steps 1 through 7 of concurrent SINS alignment.
Note
2. Verify that SHDG is boxed on CV SINS DATA MFD format.
Do not selectSAHRS during CV ALIGN to check alignment progress. Wait until INS alignment is complete and INS hasbeen selected on the NAV MODE switch beforeselecting SAHRS.
3. Repeatsteps9 and 10ofconcurrentSINSalignment. 8.2.1.3
10. SAHRS alignment progressmay be monitored at this time by selectingthe NAV page. Note
. The SAHRS alignmentprocesswill initiate a&r the INS determinesa valid trueheading (approximatelyat INS quality value of 5). SAHRS quality value should reinitiate to approximately3 1.2at thattime. l
Manual
Carrier
Alignment.
1. Repeatstep 1 and steps4 through8 for concurrent SINS alignment. When the DATA pushbuttonon the MFD is depressed,the CV MANUAL DATA format will appear. 2. Enter best knowledge of ship latitude, longitude, speedandheadingvia the DEU or DD.
If power has been applied to the aircraft foranextendedperiodoftimepriortoINS CV align being initiated, the SAHRS may complete a ground align (NORM) and a SAHRS completemessageappearson the MFD. After the INS CV align is initiated, the SAHRS will initiate a concurrentCV align normally, but anotherSAHRS align completemessagemay not occur.
Note
Entry ofVLA isneverrequiredformanual carrier alignment. When using the DEU, dataentry is made via the DEU CV ALIGN format,usingthe LAT, LONG, CSPD, and CHDG option keys and the appropriate quadrant and numerals.
11. It is advisableto continuealignment after appearanceof the INS ALIGN COMPLETE messageif time permits. When ready to take the alignment, the inertial navigation mode may be selectedby settingthe NAV MODE switch to INS.
Data entryusing theDD requiresselection of the NAV category from the MFK pushtile and the boxing of the OWN A/C acronym prior to enteringthe carrier latitude and longitude via the DD LAT, LONG, quadrant,and numeral pushtiles. Entry of carrier speedandheadingvia the DD requiresthe boxing of the WIND acronym prior to using the DD SPD, HDG, and numeric pushtiles.
Note Although SINS alignmentnormally requires no entry of data, if a SINS alignment takes place at any carrier location other than the flight deck, then it is advisableto enterthe correctvertical lever arm via the DEU. This is theheight in feet of theaircraft INS above the carrier SINS location. This entry can be made only via the DEU by calling up the ORIGINAL
Concurrent
Manual carrier alignment should be used only when SINS dataor the SINS carrieralign modeis unavailable. This can be determinedby the appearanceof the CV MAN DATA format on the MFD with MAN boxed.
3. Repeat steps 9 to 11 for concurrent SINS alignment. 8-2
NAVAIR Ol-Fl4AAD.1
Note In concurrentmanual carrier align, the INS ALIGN COMPLETE computer message may take 15minutesor longerto appear.The navigation quality at this time may not be better than 3 r&per hour. Becauseof the extensivealignment time, it may be necessaryto launch prior to the receipt of the INS ALIGN COMPLETE computermessage.
8.4 CATAPULT HOOKUP (DAY) Settheattitudedisplaysto showlevel flight at normal strut extension.Proper positioning on the catapult is easily accomplished if the entry is made with only enoughpower to maintain forward motion and if the plane director signalsare followed explicitly. pii-,,,,,,,
8.2.2 SAHRS Standalone Carrier Alignment. The SAHRS standaloneCV alignment mode is manually selectedfmm the SAHRS ALIGN MFD format. The WI-IRS hasno true standalonecarrier align mode like the INS. During concurrent INWSAHRS carrier align modes,the SAHRS dependsupon the INS to provide an initial input of true heading. Since this is not availablein SAHRS standalonecarrieralignment,when the SAHRS CV pushbutton is depressedin SAHRS standaloneoperation,it is commandedto a DG mode. Oncetheparkingbrake is releaseda DG headingcanbe enteredvia the DEU. When the aircraft is airborne,the slaved mode can be selectedor if a system velocity sourceis present,in-flight restartcanbe selectedto bring the SAHRS to a normal operationalmode.
. All functional checksshall be performed before taxiing onto the catapult. Ensure thattheTakeoffChecklist is completeand thatthepropertrim is setfor launchbefore enteringthe nosetowapproachramp. l
8.3 TAXIING Shipboard taxi operations differ slightly from the field. Taxiingaboardship requireshigherpowersettings andmustbe conductedunderpositive control of a plane director. Any signal from the plane director above the waist is intendedfor the pilot and any signal below the waist is intendedfor deck-handlingpersonnel. 8.3.1 Nosewheel Steering. The nosewheelsteering systemcharacteristicsareexcellentandenableextremely tight corneringcapability.At full nosewheelsteeringdeflection (709, the inside mainmountwheel backsdown and turn radius will be restrictedif the inside brake is locked.For a minimum radiusturn, momentarilydepress the brakeon the inside wheel and then allow the inside wheeltoroll t?eelywhile controllingtheturn late by braking theoutsidewheel.For normal turns,symmetricbrake applicationsshouldbe appliedto control aircraftforward motion.Forwardmotion shouldbc initiatedbeforeeffccting a tight radiusturn to reducepowerrequirements. 8.3.2 Taxi Speed. Taxi speedshould be kept under control at all times, especially on wet decks and approachingthe catapultarea.Be preparedto usetheparking brake should normal braking fail. While taxiing, both ejection seatsshouldbe armed. The parking brake is an excellent featurethat may be used to prevent leg fatigue during taxi delays. However, it should not be usedonce.forward of thejet-blast deflector. 8-3
All catapult launchesshall be conducted with the HUD in the cagedmode. If approaching the catapult after an uncaged HUD landing, cycle the TLN display mode button to ensurethe HUD defaults to the cagedformat.
The catapultdirectorwill direct the pilot to approach the catapulttrack, using nosegearsteeringand brakes. Upon signalf?omthe planedirectorandwhenpositioned immediatelybehindthe mount of the lead-intrack,kneel the aircraft.If the launch bar is to be lowered from the cockpit, upon signal from the plane director,deflect the nosewheelto lower thelaunchbar,centerthe nosewheel, anddisengagenosewheelsteering.If the launchbar is to be loweredby the deck crew, no pilot actionis required. After the hold-backbar hasbeenattachedto the aircrall andcheckedby squadronmaintenancepersonnel,thecatapult directorwill directtheaircraft forwarduntil the holdback bar is snug againstthe catapult buffer unit. The aircraftwill be stoppedin position for shuttletensionup. The attitudedisplayswill show2” to 3’ nosedownwiththe aircraftin the kneeledposition. pi&-,,,,,,, Nosewheel centering can contribute to launchbar misalignment in the catapultshuttle. which could result in prematurelaunch bar separationduring launch.The nosewheel centeringlatching relay must be deactivated by depressingthe nosewheelsteeringbutton after the hook check and beforeenteringthe catapult.It will alsodeactivatethenosewheel steeringautomaticdisengagementfimction; nosewheel steering must be manually disengagedwhen entering the catapult. ORIGINAL
NAVAIR
Ol-F14AAD-1
ensurethat longitudinal trim settingsareadjustedifnecessary(Figure 8-2).Upon receipt ofthe “tension-up and releasebrakes” signal, releasethe brakes, ensurethe parking brake is off, and advancethe throttles to MIL. Ensurenosewheelsteering is disengagedprior to performing control wipeout. When a tumup signal is receivedfrom thecatapultofficer, grip thethrottlesfirmly, check engine instruments,ensurethat the caution and advisory panel is clear, and the RIO is ready. When satisfiedthat the aircraft is functioning properly, salute thecatapultofficer.Normally, a 3-to 5-seconddelaywill occur before the catapult tires. Optimum launch technique is to maintain a loose grip on the control stick while allowing it to move aft during the catapultstroke.
. If the LAUNCH BAR light illuminates immediately upon selectingKNEEL with the NOSE STRUT switch, a malfunction in thesystemhasoccurredandthe landing gearwill not retractfollowing the catapult launch. . Nosewheel steeringis designedto disengageand the NWS ENGA light goesoff whendeck personnellower the launchbar on the catapult. The arrestinghook must havebeencycled on deck andthethrottles set at IDLE to enable the system. This feature prevents the pilot from inadvertently damaging the launch bar during control checks after final tensioning.
l
8.4.1 Catapult Trim Requirements. The following Tequirementsareapplicableto cleanaircraft or any combination ofair-to-air store, externaltank, grossweight combinations, and launch cg locations between 7.0percent and 18.5-percentMAC.
l
Failure to allow the control stick to move aft during the catapultstrokewill result in degradedpitch rateand excessivesink off bow. Catapult launch with a partially filled external tank is not authorized.
Note To determinecenterof gravity for a particular aircraft, refer to NAVAIR Ol-IB-4, Handbookof Weight and Balance.
Initial catapult tiring results in a short-termvertical accelerationof 15g to 20g causedby full compression of the stored-energynosestrut.Firmly restrainthethrottles to preventtheir aft travel during the catapultstroke.
Figure 8-l lists recommendedcatapultlaunch longitudinal trim settings.
At shuttle release,the energystoredin the nosestrut is released,rotating the aircraft up to the initial flyaway attitudeofannroximatelv 10” noseun. The nitch trim for launch is dLs?gnedfor hinds-offopkration: The control stick will, without pilot input, return to the trimmed position shortly after shuttle release.If the trim is set nrooerlv. the aircraft should rotate and flv away at the prober&itude without pilot input. During rotaiion the flightcrew will sense the aircrafl characteristics and shouldbe preparedto make control inputs asnecessary to ensurea safe flyaway. During low excessendsueed catauult launches(lessthan 15 k;lots excess).AOAwill spikk up to 17 uniis, then gradually decreaseduringthe flyaway.
Anticipated End Airspeed
loto 20 21 to 50
Longitudinal Trim (degrees) Trailing Edge Up
I
1
I
i
1
i
1
ii
7
I
4
I
0
1
Catapult Abort Procedures (Day). If after tumup on the catanult,the pilot determinesthat the aircraft is down, thepilot-givesthe no-gosignalby shaking his headfrom sideto side.Never raisethehandinto view or ._make any motion that might be construedas a salute. Afer the catapult otlicer observesthe pilot no-go signal, he will cross his forearms over his head,and then give the standardreleasetensionsignal. When the catapult is untensioned,the catapultofficer will signal the 8.4.3
Figure 8-1. CatapultLaunch Trim Requirements 8.4.2 Catapult Launch. Aircraftlaunchgrossweight will. be cross-checkedand verified by signal with the flight deck personnelprior to kneel. If the aircrafi is to be catapultedwith a partial fuel load, the pilot should ORIGINAL
8-4
NAVAIR
AIRCbAFi l&tiCH F~ELvCG PLUS As
Ol-Fl4AAD-1
CO = ZEdO,
” ”
Figure 8-2. Center-of-GravityVariation With Fuel Loading pilot to raisethe launchbar.The pilot shallensurethatthe throttlesareseatedin the catapultdetentandwill raisethe launchbarwith the LAUNCH BAR ABORT switch.
l
To avoid damageto the launch bar retract mechanism, do not actuate the LAUNCH BAR ABORT switch with thenosewheeldeflected off center.
If the aircraft is down after the go signal is given, transmit the words “Suspend, Suspend”; however,the flightcrew shouldbe preparedfor the catapultstrokeand to perform emergencyproceduresif required.
When the launch bar is clear of the shuttle, the catapult officer will move the shuttleforward of theaircraft launch bar. At this point the aircraft is no longer in dangerof being launched.The catapultofficer will signal thepilot to lower the launchbar andthenstepin front of the aircraft and signal the pilot to throttle back.
l
Unkneelingthe nosegearwhile the launch bar is in the catapult track or shuttle will damage the launch bar linkage and bungees.The pilot shouldunkneelthe aircraft only when he is surethat the launch bar is freeto rise anduponsignal from the catapultofftcer or taxi director.
8.5 LANDING Carrier Landing Pattern (VFR). The VFR carrierlanding pattern (Figure 8-3) shall be in accordancewith the CV NATOPS manual. The patternstarts with the level break at 800 feet and 300 to 350 knots. The breakinterval will beapproximately one-halfofthe desired ramp interval time (15 to 17 secondsnormal interval). When establishedwings level on the downwind leg, descendto andfly the patternat 600 feetMSL. EngageDLC upon completion of flap extension.
8.51
If the aircraft is down prior to it being pushedor pulled back for releasefrom the holdback fitting and when directedby the catapult officer, the launch bar shall be raised by the LAUNCH BAR ABORT switch. 8-5
NAVAIR
OI-FI4AAD-1 MAXIMUM
LANDING
GROSS WEIGHT
54,000
Figure 8-3. Carrier Landing Pattern
ORIGINAL
0-6
POUNDS
NAVAIR
01-F14AADI
degrade flying qualities resulting in significant glideslope and lineup deviations. Pitch compensation for DLC inputs is optimized for approachairspeeds. Activation of DLC at higher airspeedswill result in inducing noticeablechangesin pitch attitude.DLC may be employedby vernieror bang-bangcontrol depending on the extent of the correction required. DLC is most effective in correctingfor glideslopedeviations caused by gusty conditions or ship burble. Caution should be taken not to use DLC to compensatefor a major overpoweredor underpoweredcondition.
Note
Selection of DLC during the Sap extension cycle can generate excessive pitch rates. DLC is to be selectedonly upon completion of the flap cycle. DLC must be deselected prior to flap retraction to avoid excessive pitch trim changewith automaticDLC stowageduring the flap retractioncycle. Slow to 15units AOA or computedon-speed(whichever is faster)and verify airspeed/AOA correlation,engageAPC if desired,check for proper DLC operation, and complete the Landing Checklist prior to reaching the 180”position. The 180” tum is commenced 1 to 1.2 nm abeamthe LSO platform to arrive at the 90” position at approximately450feetMSL. The nominal bankangle throughoutthe turn should be 25” to 27”. Glideslope meatballacquisitionwill occurat approximately0.6nm. Do not descendbelow 300 feet prior to acquiring the ball. On rollout to final, slightly overshoot the ship’s wake.Optimum time on glideslopeis approximately 15 to 18seconds.
Caution must be taken to avoid sustained full-down DLC commandsfor a high condition attherampasthis will resultin excessive sink ratesand subsequenthard landings. Once establishedon glideslope,keepthe scangoing, cross-checkingmeatball,lineup,andAOA. Be alert for a waveoff.With roughseasandpitchingdecks,someerratic meatball movementsmay be encountered.If this is the case,averageouttheball movementsto maintaina smooth and saferate of descent.To avoid being “cocked up,” anesta “come down in close” with power andup DLC. Attemptsto arresthigh sink rateswith noseattitudealone could result in landing damageto the ventral tins and atterbumer.Also, avoid droppingthe noseprior to touchdown asthissignificantly increasesthe chancesof a hook skip bolter.Upontouchdown,addfull MIL power,manually retractspeedbrakes, andmaintainatI stick pressureto minimize chancesof a hook skip bolter.Selectionof MIL power will automaticallydisengageDLC and retractthe speedbrake.
The LSO and tower must be informed if the landing is to be made in any wing or flap configuration other than 20° wing sweep,flaps and slatsdown, or BATS inoperative, to ensure wind-over-deck requirements are met. Do not attempt shipboard landing with inoperative roll SAS and store asymmetry greaterthan 170,000inch-poundsbecause of lateral pilot-induced oscillation in the approachunless field divert is not possible.(Example: weaponrail at station 6 and AIM-54 missile at station 8 equals 170,000inch-pounds.)
A goodstart is imperative to minimizing lineup corrections while on the glideslope and will prevent the tendencyto chaselineup. Small, coordinatedrudderinputs shouldbe usedto reducethe noseyaw that is easily generatedby lateral stick inputs.
Note
85.3 Approach Power Compensator Technique. Practiceis requiredto developthe proper con-
With the hook down, airspeedin excessof 300knotsmay causethehook transition light to illuminate. Manual Approach Technique. The rapid engineresponsecharacteristicsallow the pilot to make timely, small amplitude power changes to make glideslope corrections. Because of the rapid engine responseand high-throttle sensitivity, the pilot must avoid overcontrolling power. DLC should be engaged for all approaches.Approachesflown without DLC will 8.52
8-7
trol habits necessaryto use the APC. For the APC to perform satisfactorily,smooth attitude control is essential. Large, abrupt attitude changesresult in excessive power changes.APC use is not recommendedin gusty conditions.The APC will overcontml AOA fluctuations resulting in largeairspeedand/orglideslopedeviations. The APC systemwas designedto be usedwith the engines operatingin the primary mode and is not recommended with either one or both of the engines in secondarymode. ORIGINAL
NAVAIR 01-F14AAD-1
As the initial turn from the 180”position is made,the aircraft will momentarily indicateup to 2 units slow. The APC will adjust power to correct back to onspeedcondition throughouttheremainderof the turn.Upon rollout on glideslope,the pilot must override the tendencyfor the noseto pitch up by maintaining slight forward stick. The aircraft will indicate 1 to 2 units fast, which will slow to onspeedwithin 5 seconds.The use of DLC in conjunction with small attitude changes to maintain glideslope will minimize AOA deviationsand result in optimal APC performance.Timely useof DLC canalso be used to more rapidly correct from a fast or slow condition. Close-in correctionsarevery critical. Ifa high in-close situation develops, the recommendedprocedure is to stop the meatball motion and not attempt to recenterit. A low in-closecondition is difficult to correct with APC and often results in an over-the-topbolter. It may be necessaryto disengageor manually override APC in order to safely recover from a low in-close situation. Throughout the approach, the pilot should keep his hand on the throttles in the event APC disengagesinadvertently. A smooth throttle transition from AUTO to BOOST mode can be achievedby depressing the CAGE/SEAM button on the inboardthrottle grip. 8.5.4 Waveoff Technique. A waveoffwill be initiated immediately upon a signal or voice call from the LSO. MIL power should be used for all dual-engine waveoffs. Maintain the landing attitude until a positive rate of climb is established.Do not over rotatethe aircraft in close as this significantly increasesthe chance of in-flight engagement.
Dual engine afterburner takeoffs are prohibited. Inadvertent arrestment or in-flight engagement in dual afterburner would result in catastrophic damage to the aircraft and/or arresting gear. Normally, waveoffs will be taken straightahead,especially when closein. When using APC, waveoff technique is the same as for manual approachesexceptthat a force of approximately 8 poundsis requiredto disengagethe throttle torqueswitches.Disengagementof the APC by overriding thethrottle forcesresultsin thethrottle MODE switch automatically returning in BOOST and illuminates the AUTO THROT light on the pilot left-handladderlight assembly.A time delayrelay holds the AUTO THROT light on for 10 secondsfollowing APC disengagement.
ORIGINAL
If a force in excessof 14 pounds is applied to break the throttles out of the automatic mode, the throttle MODE switch will return to BOOST but the throttle mode will revert to manual. The switch must be cycled to MAN and back to BOOST to regain the BOOST mode. 8.5.5 Bolter Technique. The bolter maneuver is effected by selecting MIL and slight aft control stick until the desiredflyaway attitude is established.
The use of excessivebackstick on a bolter may causethe tail surfaceto stall, delaying aircraft rotation and causing the aircraft to settleoff the angle. 8.5.6 Bingo Fuel. Fuel reserves should be programmed dependingon distanceof the field from the CV, aircraft configuration, and en route weather.This bingo fuel quantity should be set beforetakeoff. 8.5.7 Arrested Landing and Exit From the Landing Area. As the aircraft touches down, advance throttles to MIL. Upon completion of landing rollout, reducepower to IDLE. Raisethe hook andflaps and select wing-sweep BOMB while allowing the aircraft to roll aft. Apply brakeson signal.Flaps retraction requiresapproximately 7 seconds.When the flaps are fully retractedthe wings will sweepaft. Engagenose, wheel steeringandtaxi forward on the come-aheadsignal. If the wings sweep aft to 55’, auxiliary and main flap retractionhasbeenverified and full-afl wing sweep may be selectedusing the emergencyhandle.The RIO should monitor wing-sweep position while taxiing. Oversweepshould be selectedprior to final spot and shutdown.The enginesshouldremain runninguntil the cut signal is given by the plane director.If at any time during this phaseof operationsa brake failure occurs, pull the parking brake. If the aircraft continuesto roll, drop the hook, advise the tower, and signal for chocks to be installed(usenosewheelsteeringto ensurethatthe aircraft remainson the deck).Do not unstrap,dearmthe ejection seat, or leave the cockpit until tiedbwns have beeninstalled. Note Aircrew shall inform tower in the event of RATS failure on landing. 8-8
NAVAIR 01.F14AAD-1
8.5.8 Carrier-Controlled Approaches. Should these proceduresconflict with the applicable CV Air Operations manual, the latter shall govern. Detailed pilotcontroller voice procedures must be established in accordancewifh eachship’s CCA doctrine. Figure 8-4 shows a typical carrier-controlled approach.Mode I, mode IA, and mode II ACLS approachesare described in Chapter17, Automatic Carrier Landing System.Aircrew shouldhavea thoroughunderstandingof this chapter and the AFCS and APC portions of Chapter2 prior to attemptinga coupledACLS approach.
will begiven and “platform” will be reported.Continue descentto 1,200feet. 8.511 Ten-Mile DME Fix 1. At 10miles, reportside numberand IO-mile gate. 2. Commence transition to landing configuration, unless otherwise directed by CCA, maintaining 1,200feet. 3. Gearand flaps shall be down by 6 miles.
8.5.9 Hold Phase. Five minutesbeforepenetration, defoggingshall be actuatedandmaximum comfortable interior tempera- will be maintained to preventpossible fogging or icing on the windshield and canopy.
4. Complete the landing checklist. Check anti-ice, lights, and rain removal, asrequired. 8.5.12 Six-Mile DME Fix. Foraprecisionapproach radarapproach,maintain 1,200feet at approachspeed until interceptingthe glidepathat 3 to 3.25 miles, unless otherwisedirected.
Note Fuel dump is accomplishedby gravity flow and its effectivenessis reducedduring the penetrationdescent.Fuel dump, if required, should be planned accordingly for the level leg.
For an air surveillance radar approach, a gradual descentof 600 fpm can be commenced departing the 6-mile DME fix. Maintain 600 feet until the aircraft interceptsthe centerof the glideslope at l-1/4 to l-1/2 miles on a 3.5” slope. Commencea descentof 500 to 700 fpm, using the following checkpoints:
1. Before descent, check shoulder harness handle locked, set lights as directedby existing weather, and lower arrestinghook. 2. Accomplish final changesto radio and IFF upon departingmarshal or earlier. After these changes aremade,thepilot shouldmakeno furtherchanges exceptunderemergencyconditions. 3. When commencing penetration, initiate a standard descent:250 knots, 4,000 fpm, speedbrakes as required.
If a gearand/orflaps down penetrationis required,ensmethatthe wings areprogrammed forwardof 22” prior to lowering flaps.If flaps areloweredwith wings sweptaft of 22”, auxiliary flap extensionwill be inhibitedresulting in rapid nosedownpitchingrates. 4. Radar and barometric altimeters shall be crosscheckedcontinuously when below 5,000 feet. 8.5.10 Platform. At 20 miles passingthrough 5,000 feet, aircrat?descentshall be slowed to 2,000 fpm. At this point, a mandatory,unacknowledgedvoice report will be broadcastby eachpilot. The aircrafi sidenumber 8-9
1. 1 mile - 460 feet. 2. 3/4 mile - 360 feet. 3. l/2 mile - 260 feet. 8.5.13 Meatball Contact. When transitioning to a visual approach,report call, side number, TOMCAT, meatballor Clara(no meatball),fuel state,andtypepass. The LSO will acknowledge,and instructions from the final controller will cease.Pilots are cautionedagainst premature contact reports and transition to visual glideslope during night recoverieswhen visibility permits sighting the ship beyond 2 to 3 miles. The height and dimensionof the entire lens or mirror optical beam at I-114miles is over 200 feet andthe true centercannot be distinguished.This, coupledwith the relatively short length of the runway lights, will give the pilot the illusionof beinghigh when, in fact, the aircraft may be well below optimum glideslope.An additional advantageof delaying the meatball report (even thoughthe ball is in sight) is that the final controller will continue lineup instructions that can greatly assist the pilot in establishing satisfactorylineup. Use the vertical velocity indicatorto setup a rateof descentof 500 to 700 fpm. The AN/ARA-63 is anexcellentaid during the approachand shouldbe usedwheneverpossible.
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Ol-Fl4AAD-1
Figure 8-4. Carrier-ControlledApproach (Typical)
ORIGINAL
8-10
NAVAIR
8.6 WAVEOFF
AND BOLTER
In the event of a waveoff or bolter, climb straight aheadto 1,200 feet and maintain 150 knots. When directedby CCA, initiate a level turn to the downwind leg reporting abeamwith fuel state.(If no instructions are receivedwithin 2 minutesor4 miles DME, attemptradio contact; if unable, assumecommunications failure and initiate thedownwind turn to thereciprocalof tinal bearing reporting abeamwith fuel state.If no acknowledgment is received,starta turn at 4 miles or 2 minutes to interceptfinal bearing.)A 20” bank angle at 150knots on theupwind turn establishesthe aircraft at the desired 2 miles abeamon the downwind leg. CATCC clearsthe aircraft to turn inbound to intercept tinal bearing. A level, on-speedapproachturn of 18” to 22” bank anglefrom the normal downwind position allows the aircraft to properly intercept final bearings at a minimum of 3 miles aft of the ship. Traffic spacingaheadmay require that the aircratl continueon downwind leg well past the normal abeamposition before being directedto turn to final bearing. No attempt shouldbe made to establishvisual contactwith the ship when executinga CCA until the final approachturn has beenexecuted. Note
The radar beacon(AN/APN-154) should be turnedoff as soonaspracticableafter landing to avoidcausinginterferencewith AN6PN-42 control of otheraircraft in the pattern. 8.7 NIGHT FLYING Night carrier operations will have a much slower tempo than daylight operationsand it is the pilot’s responsibility to maintain this tempo. Normal day carrier operationsshall be usedexceptas modified below.
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Individual flight briefings will include all applicable items outlined above, with particular emphasis on weatherandbingo fuel. Preflight. In addition to normal cockpit preflight, ensurethat external light switches are properly positioned for poststartlight check. Install night filters on applicablecockpit displays. 8.7.2
8.7.3 Postetart. Adjust cockpit light to desired brightness.When readyfor taxi, indicatewith appropriatesignal. 8.7.4 Taxi. Night deck-handlingoperationsareofnecessity slower than thoseused during the day. When a doubt arisesas to the meaning of a signal from a taxi director, stop. Catapult Hookup (Night). Proceduresfor aircraAcatapulthookupat night areidentical to thoseused during day operations.However, it is difftcult to determine your speedor degreeof motion over the deck.The pilot must rely upon,andfollow closely,the planedirector signals. 8.7.5
Catapult Launch. On turnup signal from the catapult officer, ensurethrottles in MIL and check all instruments.When readyfor launch,placeexternallight master switch ON (bright and steady).After launch, establishan 8” to 10” pitch attitude, cross-checkinginstrumentsto ensurea positive rate of climb. Retractthe landing gear.An altitude of 500 feet is consideredto be minimum altitude for retraction of flaps. When well establishedin a climb, switch lights to flashing or as applicable for an instrument climbout. The standby indicator should be used in the event of a primary display(s) malfunction.
8.7.6
Briefing. Before initial night flight operations, all pilots should receivean additional briefing from the following persons:
8.7.1
If wings sweepback inadvertently,close attention should be paid to maintaining positive ratesof climb. The loss of lift incurred by prematurewing sweep aft can result in significantly decreasedrates of climb, with very little changein pitch attitude and trim requirements.
1. Flight deck offtcer 2. Catapultofficer 3. Arresting gearofficer
Catapult Abort Procedures (Night). The pilot no-go signal for night launcheswill be to not turn on the exteriorlights, andto transmit on land or launchhis aircraft side number,the catapultthe aircraft is on, and the words “Suspend, Suspend.” After the catapult is untensioned,the catapultofftcer will signal to raise the
8.7.7
4. LSO 5. CATCC.
a-11
ORIGINAL
NAVAIR Ol-F14AAD-1
launch bar. The pilot shall ensurethat the throttles are seatedin the catapult detent or throttle friction is full forwardbeforeraisingthe launchbarwith the LAUNCH BAR ABORT switch. When the launch bar is clear of the shuttle, the catapult officer will move the shuttle forward of the aircraft launch bar. At this point the aircraft is no longer in dangerofbeing launched.The catapult offricerwill signal the pilot to lower the launchbar and then step in front of the aircraft and signal the pilot to throttle back.
If the aircraft is down aRer the go signal is given, transmit the words “Suspend, Suspend”; however, the flightcrew should be preparedfor the catapult stroke and to perform emergencyproceduresif required.
ORIGINAL
l
If the aircraft is down prior to it being pushedor pulled back for releasefrom the holdback fitting and when directedby the catapult launching officer, the launchbar shall be raised by the LAUNCH BAR ABORT switch.
l
Unkneelingthe nosegearwhile the launch bar is in the catapult track or shuttle will damagethelaunchbarlinkageandbtmgees. The pilot should unkneelthe aircraft only when surethat the launchbar is freeto rise and upon signal from the catapult officer or taxi director.
8.7.8 Arrested Landing and Exit From Landing Area (Night). During approach,all lights shall be on bright and steady.At the end of arrestmentrollout, turn off externallights and follow the director’s signalswhile effecting the normal aircraft cleanupprocedures.
8-12
NAVAIR
CHAPTER
Special 9.1
IN-FLIGHT
REFUELING
01-Fl4AAD-1
9
Procedures 5. REFUEL PROBE switch tion light OFF).
PROCEDURES
As Desired(transi-
Note
6. Wing sweepswitch - As Desired.
Before commencing in-flight refueling operations,each flight crewmember shall become familiar with the NATOPS Air Refueling Manual, NAVAIR OO-80T-110, and in-flight refueling system description.
7. Visors -
In-Flight Refueling Controls. Regardless of fuelmanagementpanelswitchpositioning, at low fuel statesthe initial resupply of fuel is dischargedinto the left- and right-wing box tanks. Thereafter,distribution of the fuel to the forward, aft, wing, and externaltanks is controlled by the WfNG/EXT TRANS switch position. The split refueling system to the left and right engine feed group provides for a relatively balanced centerof gravity condition during refueling. Selective refueling of the fuselageor all fuel tanksis provided on the REFUEL PROBE switch with the probe extended. In the FUSEXTD position, normal fuel transfer and feedis unaltered.This position is usedfor practiceplugins, fuselageonly refueling, or return flight with a damaged air-refueling probe. The ALL/EXTD shuts off wing and externaltank transferto permit the refueling of all tanks. The REFUELING PROBE switch circuit usesessentialdc No. 2 powerto control operationof the probeactuatorthroughredundant-extendsolenoidsand a single-retractsolenoid.
MAN/wing-sweep angle
RecommendedDown.
9.1.1
In-Flight Refueling Checklist. The inflight refueling checklist shall be completed before plug-in.
9.1.2
1. RDR switch -
STBY.
2. Arming switches 3. DUMP switch -
SAFE. OFF.
4. AIR SOURCE pushbutton -
To prevent fuel fumes from entering the cockpit through the environmental control system(ECS) becauseof possiblefuel spills during in-flight refueling, select AIR SOURCE pushbuttonL ENG. 9.1.3
In-Flight
Refueling
Techniques
Note
The following procedures, as applied to tanker operation, refer to single-drogue tankeronly. Refueling altitudes and airspeedsaredictatedby receiver and/or tanker characteristics and operational needs,consistentwith the tanker’s performanceand refueling capabilities. This covers a practical spectrum fmmthedeckto35,OOOfeet, 170to300knots,andwingsweep angles of 20” to 68”. Optimum airspeedand wing-sweep position is 240 knots and approximately 40” wing sweep.This configuration increasesaircraA angle of attack enoughto lower the receiver’svertical tails below thetanker’sjetwash anddecreases bow wave effect. SAS-off tanking can most easily be performed at 200 KCAS with 40” of wing sweep. Approach. Once cleared to commence an approachand with refueling checklists completed, assume a position 5 to 10 feet in trail of the droguewith the refueling probe in line in both the horizontal and vertical reference planes. Trim the aircraft in this
9.1.3.1
L ENG.
9-l
ORIGINAL
NAVAIR 01-Fl4AAD-1
effected.This advancedposition is evident by the tanker’s amberreadylight going out andthe greenfuel transfer light coming on. While pluggedin, merely fly a close tail-chaseformation on thetanker.Although this tuckedin conditionrestrictsthe tanker’smaneuverability,gradual changesinvolving heading,altitude, antior airspeed may be made. The precise flying imposed on both the tankerandreceiverpilots requiresa lot of“heads down” time, yet a sharplookout doctrine must be maintained. This is the receiverRIO’s primary responsibility.
stabilizedapproachposition and ensurethat thetanker’s (amber)ready light is illuminated before attempting an approach.Select a referencepoint on the tanker as a primary alignment guide during the approachphase; secondarily,rely on peripheralvision of the drogueand hoseand supplementaryremarks by the RIO. Increase power to establishan optimum 3- to 5-knot closurerate on the drogue.It must be emphasizedthat an excessive closure rate will causea violent hose whip following contact and/or will increase the danger of structural damageto the aircraft; too slow a closurerateresultsin the pilot fencing with the drogueas it oscillatesin close proximity to the aircraft nose.During the final phaseof theapproach,thedroguehasa tendencyto move slightly upward and to the right as it passesthe nose of the receiveraircraft becauseof the aircraft-drogueairstream interaction. Small correctionsin the approachphaseare acceptable.However, if alignment is off in the final phase,it is best to immediately return to the initial approachposition andcommenceanotherapproach,compensatingfor previous misalignments by adjusting the referencepoint selectedon the tanker.Small lateralcorrections with a “shoulder probe” are made with the rudder, andvertical correctionswith the horizontal stabilizer. Avoid any correctionsaboutthelongitudinal axis since they causeprobedisplacementin both the lateral andvertical referenceplanes.
9.1.3.4 Disengagement. Disengagement from a successfulcontact is accomplishedby reducingpower and backing out at a 3- to S-knot separationrate. Care shouldbe takento maintain the samerelative alignment on the tanker as upon engagement.The receiverprobe will separatefrom the drogue coupling when the hose reachesfull extension. When clear of the drogue: 1. REFUEL PROBE switch 2. Probetransition light -
Check Out.
3. AIR SOURCE pushbutton 4. Wing-sweep switch -
9.1.3.2 Missed Approach. If the receiver probe passesforward of the drogue basket without making contact,a missed approachshould be initiated immediately. Also, if the probe impinges on the canopy-lined rim of the basket and tips it, a missed approachshould be initiated. Realization of this situation can be readily ascertainedthroughtheRIO. A missedapproachis executed by reducing power and backing to the rear at an opening rate commensuratewith the optimum 3- to Sknot closure rate made on an approach.By continuing anapproachpastthebasket,apilotmighthooktheprobe over the hose and/or permit the drogue to contact the receiver aircraft fuselage.Either of the two aforementioned hazardsrequiremore skill to calmly unravel the hoseand droguewithout causingfurther damagethanto make anotherapproach.If the initial approachposition is correctly in line with the drogue,the chanceof hooking the hose is diminished as the need for last-minute corrections is minimized. After executinga missed approach, analyze previous misalignment problems and apply positive correctionsto precludea hazardoustendency to blindly stabat the drogue.
BOTH ENG.
AUTO.
Resumenormal flight operations. 9.2 FORMATION FLIGHT The following formation descriptions are recommendedguidelinesfor F-14 multiplane positioning. pii-1 Paradeformation IFR/VFR and loosecruise flight shall not be performed with the flight leadutilizing autopilot ground-trackdestination steeringbecauseof the midair collision potential associatedwith inadvertent waypoint steering selection and rapid aircraft AOB changes.
9.1.3.3 Contact. When the receiver probe engages thebasket,it will seatitself into the droguecoupling and a slight ripple will be evident in the refueling hose.The tanker’sdrogueandhosemust be pushedforward 3 to 5 feet by the receiver probe before fuel transfer can be ORIGINAL
RET.
9-2
9.2.1 Parade Formation. The basic parade position is either left or right echelon,or a combination of both, as in fingertip three-planeformation. The parade formation is usedprimarily for multiplane maneuvering at night, in IMC, or during entry into or exit from an airport traffic area.
NAVAIR
0%F14AAD-1
1. Line ofbearing is determinedby placing the upper leading edge of the lead aircratt’s intake on the pilot’s helmet.
Wing sweep:20” Configuration: Clean or dirty. 1. Line ofbearing is determinedby placing theupper leading edge of the lead aircraft’s intake on the explosive seat warning triangle below the RIO cockpit.
2. Wingtip separationis determinedby a position on thebearingline wherethetrailing edgesofthe lead aircraft’s ventral tins are aligned.At this position, the trailing edge of the exhaust nozzles should appearin line to the RIO.
2. Wingtip separationis determinedby a position on thebearingline wheretheleadingedgesofthe lead aircraft’s ventral tins are aligned.
3. Stepdown is determined by allowing approximately 6 inches of the lead’s oppositeenginenacelle to show below the nearenginenacelle.
3. Stepdownis determinedby aligning the lead’s opposite engine nacelle just under the near engine nacelle.
This position should provide the wingman with approximately 12 feet of wingtip separationand 12 feetof stepdown.
This positioning should provide the wingman with approximately 5 feet of wingtip separationand 10 feet of stepdown.
Slot (dash+
Break Formation. The basicbreak formation is either left or right echelon,or a combination of both as in a fingertip three-planeformation. This formation is usedprimarily for multiplane entry into the overhead breakpattern.
1. Line of bearing is determinedby lining up on the lead aircraft’s centerline.
9.2.2
2. Approximately 20 feet of nose-to-tail separation can be establishedby placing the wingman’s canopy bow on the lead aircraft’s exhaustnozzles.
Wing sweep:68” Configuration:Clean.
3. Approximately 25 feet of stepdown should be used. This position may be cross-referencedby placing theupperleadingedgeof dash-2’sordash3’s intake on the pilot’s helmet.
1. Line ofbearing is determinedbyplacing the upper leading edge of the lead aircraft’s intake on the explosive seat warning triangle below the RIO cockpit.
9.2.4
2. Wingtip separationis determinedby a position on the bearingline whereapproximately 1 foot of the forward edge of the lead’s opposite ventral tin shows in front of the nearventral tin.
Wing sweep:20” Configuration: Clean.
Cruiseis thebasic formation used for multiplane transit to or from an operating areawhere increasedmaneuverabilityis desired. Cruise
Formation.
3. Stepdownis determinedby aligning the lead’s opposite engine nacellejust under the near engine nacelle.
1. Line ofbearing is determinedby placing theupper leading edge of the lead aircraft’s intake on the RIO’s canopybow.
This position should provide the wingman with approximately 15 feet ofwingtip separationand 10feet of stepdown.
2. A secondline of bearingis determinedby placing the lead aircraft’s wingtip light on the forward upperUHF antenna.
Diamond Four-Plane Formation. The diamond is the basic four-plane formation used for entry into the overheadbreakor for aerial fly-bys.
3. Wingtip separationis determinedby allowing approximately 1 foot of the lead’s oppositeexhaust nozzle to show behind the nearexhaustnozzle.
9.2.3
This position should provide the wingman with approximately 64 feet of wingtip separationand 10feet of nose-to-tailseparation.
Wing sweep:68’ Configuration: Clean. Right andleft echelon(dash-2anddash-3,respectively)
9-3
ORIGINAL
NAVAIR 01.Fl4AAD-1
9.2.5 Aircraft Lighting During Night Formation Flight. The lead aircraft anticollision lights will normally be off during night formation flight in parade. However,thepossibility existsthat thewing aircraft can inadvertently stray into a position aft of the normal bearing where only a single white tail light on lead is visible. In this position, seriousmisjudgment of separation and closure.rate can occur.To prevent this, lead aircraft anticollision lights shouldbe on when the wing aircraft is not in normal parade and mission requirements permit. 9.3 BANNER TOWING 9.3.1 Ground Procedures. The following proceduresareprovidedfor guidance.Local courserolesmay dictate modification of thesesteps: 1. When tower clearanceonto the duty runway has beenreceived,tow aircraft taxis to position as directedby tow ho&up crew. Tow pilot holds this position until releasedby tow hookupcrew.Escort pilot maintains position on taxiway at approach endof runway. 2. When signaledto do so by tow hookup crew, tow pilot proceedsto taxi down runway. 3. Upon receiptofvisual taxi signal from tow hookup crew to slow down, escortpilot relays this signal to tow pilot via UHF radio. 4. Upon receiptofvisual taxi signal from tow hookup crew to stop, escortpilot relays this signal to tow pilot via UHF radio. 5. Upon receipt of signal from tow hookup crew that tow hookup is complete, escortpilot requeststow pilot to take up slack. 6. TOWpilot proceedsto taxi down the runway. 7. When bannermoves forward onto runway, escort pilot transmits, “Tow aircraft hold, good banner,” and taxis onto runway abeambannerfor takeoff. 8. When ready, tow pilot transmits, “Tower, Lizard 616 for bannertakeoff, escortto follow banner.”
1. When clearancehas been received, tow aircraft taxis to the catapult shuttle in use as directedby flight deckpersonnel.Tow pilot holdsthis position until releasedby catapult director. 2. When signaledto do so, bannercrew lays banner on flight deck 45 feet starboardof waist catapult centerlineand 10 feet aft of unit horizontal stabiIator,with bannerbar perpendicularto thecatapult centerline. 3. Banner crew sequentiallypositions nylon towline bundle lengthwiseand parallel to catapulttrack in position in front of banner.Nylon towline, with preparedend facing bannerbuckle, is attachedto bannerusing swivel andconnectinglink. Steelcable leader (75 feet of 3/16-inch diameter) is attached to forward end of nylon towline bundle using connectinglink. 4. Banner crew then utuolIs leader forward, down angledeckandparallel to catapulttrack to prevent entanglement and kinks. The forward end of leaderis brought back and laid on deck near the aircraft’s right main landing gear.Forward endof leaderhasMk 8 Mod 0 targetreleasering attached to it. 5. Upon clearance from catapult officer, banner crewmember crawls underneath aircraft with leaderin handjust aft of right ventral tin. He then attachesMk 8 Mod 0 targetreleasering to banner tow adapter.Upon appropriatesignals from the flight deckdirector, thepilot lowershook to assure properdetachmentof targetreleasering and then raisesthehook. The bannercrewmemberwill then reattachtargetreleasering. 6. After hookup, the bannercrewmemberexits from beneathaircraft at sameplacehe entered.He then walks towardisland andgives thumbsup signal to catapult officer. The banner,towline, and leader are now readyfor launch. 9.3.3 Flight Procedures. Flight testshave demonstrated no significant degradationof aircraft performanceandhandlingcharacteristicswhentowing a banner.
9. After bannerbecomesairborne,escortpilot commencestakeoff roll. 9.3.2 Shipboard Procedures. The following proceduresareprovided for guidance.Local rules may dictatemodification of thesesteps:
ORIGINAL
Angle ofbank shouldbe limited to 30” or less to preclude contact between the tow cable and afterburnernozzle.
NAVAIR Ol-Fl4AAD-1
180 to 200 KIAS until flaps are up, then continue to climb out at 200 to 220 KIAS.
Note Depending on the airspeedof the tow aircraft, the bannerwill normally hang 200 to 400 feet below the tow aircraft’s altitude.
Note The maximum aircraft gross weight for a shipboardbannerlaunch is 67,000pounds.
Refer to Chapter4 for bannertowing restrictions.
9.3.3.2 Cruise/Pattern. No specialpilottechniques are required when towing a banner.En route cruising speedsof 180to 220 KIAS will provideadequateenergy for mild maneuveringwhile minimizing bannerfray If a low-pattern airspeedis desired, extend flaps/slatsif necessaryto maintain AOA at or below 12 units. The tow aircraftmust call all turns to allow the chaseaircraft to position itself on the outsideof the turn.
9.3.3.1 Takeoff. Normal takeoffprocedures.including rotation speedsandtechniques,aresuitablefor takeoff with the banner.
Takeoff ground roll with banner can be estimatedby addinga factor of 10percent to basic aircraft takeoff performance. If aircraft lift-off will not occur prior to crossingthe long-field arrestinggear,the gearmustbe removedto precludethebanner being tom off.
If the banner is shot off or falls off in flight, the remaining cable should be droppedin the gunneryarea or in a confirmed clear area.After the cable is released, a chaseaircraft shouldjoin to verify that the cable has beendropped.
If the crosswind componentis in excess of 10 knots, the takeoff roll should be madeon the upwind sideof the runway to prevent the bannerfrom striking the runway lights on the downwind side of the runway.
[pi&-I Without thebanner,any remainingcablewill flail unpredictably. The chase should approachthetow aircraft from abeam,avoiding a cone-shapedarea defined by the tow’s 4to S-o’clock positions.
Note Adequateclearanceexists to preventcontact betweenthe tow cableand speedbrakesduring ground operation.If takeoff is aborted, basic emergencyproceduresare applicable. The tow cablewill be releasedwhen the tailhook is lowered.
9.3.3.3 Descent. Airspeeds of 160 to 220 KIAS shouldbe used for descent.Flaps and slatsmay be utilized to increasethe rate of descentas desired.
After liftoff, continuerotation to 15’ (maximum of 209, while raising the landing gear.Do not exceed17 unitsAOA. Climb out at 180to 200 KIAS until the flaps areup, then continueclimb at 200 to 220 KIAS.
l
l
Speedbrakesshould not be usedwhile towing since limited clearanceexists between the cable and speedbrakesduring extension andretraction in flight.
Note Avoid use of afterburnerto preventdamageto tow cable.
9.3.3.4 Banner Drop. The tow aircraft should extend its flaps and reduceairspeed(140to 160KIAS, 12 units AOA maximum) for the drop. The bannershould be droppedin wings-level flight at a minimum aircraft altitude of 1,000 feet AGL. The chaseaircraft should ensureadequateclearanceexistsbetweenthebannerand groundobstaclesduring approachto the drop zone and provide calls to assist in lineup. Release is normally called by the tower when the banneris over the center of the drop zone. Releaseis accomplishedby lowering the tailhook. In most cases,the bannerwill hit down
Tow airspeedsin excessof 220KIAS will result in excessivebannerfraying.
For shipboardoperations,after lift-off, rotate to 15” (20” maximum) not to exceed17units AOA while raising the gearand flaps. Prior clearancemust be received t?omthe tower for anunrestrictedclimb. Maintain heading until the banneris well clear of ship. Climb out at 9-5
ORIGINAL
NAVAIR
01.Fl4AAD-1
range of the releasepoint. However, high-wind conditions may require the tow aircraft to adjust the release point to avoid downwind travel ofthe banner.Following bannerrelease,the tailhook should be raised. Shipboard Banner Drop. The tow aircraft shouldextend its flaps and reduceairspeed(140 to 160 KIAS, 12units AOA maximum) for the drop. The banner should be dropped in a clear area in wings-level flight at a minimum altitudeof 1,000feetMSL. If a clear areais not available, the banner should be droppedapproximately 1 mn abeam the port side of the carrier. Releaseis called by the air officer when the banneris over the drop zone. Bannerreleaseis accomplishedby lowering the tailhook.
KIAS, 12 units AOA maximum and descendto 100to 200 feet AGL. This will dragbanneroff on ground(or water). Have escort pilot confirm that bannerbreaksoff on ground collision, and determine length of remaining tow cable.
9.3.3.5
[ WARNING
1
The escortpilot must remain well clearof the remaining cable. The last 25 percentof the remaining cable will flail unpredictably. 2. If 100 feet or greaterremaining tow cable length is confirmed by escort pilot, plan to touch down 1,000to 1,500feet long,runway lengthpermitting.
When the tailhook is lowered for banner release,ensurethat the balanceball is centered or slightly right (IeA yaw). If any right yaw is present,tow cable/tailhook entanglement is possible.
Every effort must be made by the tow pilot not to drag the remaining tow cable across lines, fences,or other obstaclesbecauseof propertydamagethat will result.
Banner Release Failure. If the arresting hook fails to extend,the bannercannot be released.In this case,the following procedureis recommended:
9.3.3.6
Note
1. In gunnery range(or other clearedarea)descend to low altitude, extend flaps, slow to 140 to 160
9-6
The long touchdown should be carefully plannedbecauselong-field arrestmentis impossible.
NAVAIR 01-Fl4AAD-1
9.4 FUEL MANAGEMENT SYSTEM OPERATIONAL CHECK The following fuel managementsystem operationalcheck can be usedby flightcrews to perform a check of the fuel transfer system, including FUEL FEED switch, WlNG/EXT TRANS switch, sump tank interconnectvalve, foselagemotive flow isolation valves, low-level thermistors,andbox-beam vent valves. In addition, the procedure tests for proper functioning of the automatic electrical controls in the fuel feed system. The tinal four procedures (steps5 through 8) can bestbe performed in a shore-basedenvironmentwhereminimum fuel on deck requirements arenot as restrictive. PROCEDURES
COMMENTS
Initial conditions: FWDlR 8 AFT/L - 3,000 pounds (approximately) L 8 R FEED - 1,500 to 1,750 pounds (full) UR WINGS - Empty (0 to 200 pounds) TOTAL - 6,000 pounds (approximately) 1.
WING/EXT
2.
of FEED
Switch should not move until automatic interconnect occurs. Verifies proper automatic electrical operation.
FUEL FEED switch - FWDlR Monitor 500~pound split, AFT/L high.
2.
Verifies sump tank interconnect manual operation and aft fuselage shut off.
3.
FUEL FEED switch - AFT/L Monitor 500~pound split, FWDIR high.
3.
Same as step 2 except valve shut off.
4.
FUELFEEDswitch - NORM Verify FWD/R high split remains
4.
Verifies system returns to isolated
5.
Verifies cell No. 2 or 5 tow-level thermistor’s proper operation to trigger automatic interconnect function.
6.
Verifies sump tank interconnect valve opens via automatic operation and L/R box-beam vent valves open. Verifies proper operation of FWDlAFT motive systems.
7.
Verifies proper operation of cell Nos. 2 and 5. and left box-beam and right box-beam low-level thermistors.
6.
Verifies sump tank interconnect valve remains open via left side motive flow pressure. This verifies proper operation of motive flow isolation valve.
f.l.l;;;~NG/EXT
switch -OFF.
on tapes for operation
1.
5.
TRANS
Ensure 4,500 pounds switch.
TRANS
forward
valve open via motive flow valve
fuselage
motive flow
mode with no leaks.
constant.
switch returns
AFT/L - 1,700 f200 pounds. or FWDlR - 2,100 f200 pounds. 6.
Monitor tapes/feeds
for system balancing. N&S
Balancing normally begins 6 tog minutes after WING/EXT TRANS switch returns to AUTO. 7.
Afler landing. run both engines LOW lights illuminate. Verify: R FUEL LOW at L FEED L FUEL LOW at R FEED
6.
-
until Rand
L FUEL
1,000 %?OO pounds, 1.000 QOO pounds.
Shut down right engine and pull R FUEL SHUTOFF handle. Continue to run left engine to verify continued R FEED quantity decrease. Then shut down left engine.
9-7 (Reverse Blank)
ORIGINAL
NAVAIR 01.F14AAD-1
CHAPTER 10
Functional
Checkflight
Procedures
10.1 FUNCTIONAL CHECKFLIGHTS Functional checkfiights will be.performed when directedby,andinaccordancewith,OPNAVINST4790.2 series and the directions of NAVAIRSYSCOM type commanders,or otherappropriateauthority. Functional checktlight requirementsand applicableminimums are describedbelow. Functional checktlight checklistsare promulgatedseparately. 10.2 CHECKFLIGHT PROCEDURES To completethe requiredchecksin the most efficient and logical order, a flight profile has been established for eachcheckflight conditionandidentifiedby the letter correspondingto the purposefor which the checkfligbt is being flown (A, B, or C, as shown in Figure 10-l). The applicable letter identifying the profile prefixes each check in the Functional Checkflight Checklist, NAVAIR 01-F14AAD-IF. The postmaintenance checkflight procedures are specific, supplementary checksto be performed in conjunction with NATOPS normal procedures(Chapter7). Checkflight personnel will familiarize themselveswith theserequirementsbefore each flight. Thorough professional checkflights are a vital part of the squadron maintenance effort. Checkcrewsperform a valuable service to the maintenance departmentby carrying out this function. The quality of service provided by checkcrewsreflects directly in the quality of maintenanceand, reciprocally, enhancementof flight operations.To avoid degradation of this valuable service,always adopt the attitude that thoroughness,professionalism,and safety are primary considerationsfor all checkflights. A daily inspectionis requiredbefore eachcheckilight.
10-l
Figure 10-l. Flight Profile Note Shipboardconstraintscan precludecompletion of some items on the applicable flight profile checklist.
ORIGINAL
NAVAIR Ql-FMAAD-1
10.3 FUNCTIONAL CHECKFLIGHT PROCEDURES (PILOT) 10.3.1 Prestalt 4BC
1. Fuel quantity and distxibution. Check for proper fuel quantities in each system. Left tape 6,200 pounds maximum, light tape 6,600 pounds maximum, wings approximately 2,000 poundseach,and the externaltanksapproximately 1,800pounds. Check total. Left
Right
FEED FUS WING Exr TOTAL
A
2. KS.
a. Normal. b. Backup. c. Emergency. A
3. Refuel probe.
a Extend (with handpump). b. Retract (with handpump). A
4. OXYGEN SUPPLY valve -
A
5. Backupoxygen -
ON.
Check.
Turn OXYGEN systemmasterswitch to BACKUP, thenOFF. Placemask to faceandcheck for normal breathing,regulator,andmask operation.Checkno breathingafter approximately 30 seconds.
A
6. Seatadjustment -
A
7. canopy rigging.
Check
a. Both cockpit handlessameposition during operation. b. BOOST not requ&d to close.
ORIGINAL
IO-2
NAVAIR 0%FWUD-1
PROFILE 10.3.2 Start ABC
8. ENG CRANK switch -
L (left engine).
Observeauxiliary brakepressurerise. Observecombined hydraulic systempressurerise. ABC
9. ENG CRANK switch -
OFF.
ABC
10. ENG CRANK switch -
R (right engine).
ABC
11. ENG CRANK switch -
OFF.
Note Planecaptainwill bleed FLT andCOMB HYD systems during steps8 and 10. ABC
12. EMERG FLT HYD switch -
Cycle.
a. EMERG FLT BYD switch -
LOW.
Checkthat ON flag is displayedin EMER FLT LOW hydraulic pressurewindow. Verify control over horizontal tail and rudder control surfacesas viewed on surfaceposition indicator. b. EMERG FLT BYD switch -
HIGH.
Check that ON flag is displayed in EMER FLT III hydraulic pressurewindow. Verify control over empennageflight control surfacesandhigher surfacedeflection rate. c. Eh4ERGFLT HYD switch -
AUTO (LOW).
Check that OFF flags aredisplayedin bothEMER FLT III andLOW hydraulic pressure windows.
Combined and brake accumulatorsshould be charged prior to backupmodule checks.Checksshouldbe made slowly enoughto ensurecontinuous-onindication in the hydraulic pressureindicator. ABC
13. BACKUP IGNITION -
ON.
Note With weight on wheels and BACK UP IGNITION switch ON, main high-energyignition is off. ABC
14. ENG CRANK switch -
R (Right engine).
Placethe crank switch to R wherethe switch is solenoidheld until automatically r&ased to the neutral (OFF) position at the startercutout speedof SS-percentrpm. Manual deselectof the switch to OFF will intemtpt the crank mode at any point in the start cycle. Oil pressure and flight hydraulic pressurerise will becomeevident at 20-percentrpm. 10.3
ORIGINAL
NAVAIR 0%FUAAD-1
‘ROFILE Note
Whenusingwellssystemair for enginestar&manual &selectionof startercrankswitchmaybere+red. BC
15. Right&Me - IDLE (20-percent rpm) m lfan idlecrossbleed startisattempted with highresidual EGT (after hot start)and/orthmttleis advancedfinrn OFFto IDLE priorto 20-percent rpm, higherthannormalEGTreadings mayoccur.Ifthe EGTappears to be risingabnormally,increasing the supplyengineto 80percentRPMmayyielda normalstarttemperature.
0 AdvancingtherightthrottlefYomOFFto IDLE automaticallyactuates theignitionSystem. An immediate indicationof fuelflow (300to 350pph)will beexhibitedandlight-off (EGTrise)shouldbe achieved within 5 to 1s seconds.Peakstartingtemperahlms will be’achieved in the40- to 50-percent rpm range. After a slighthesitation,theEGTwill returnto normal.Exceeding 890“C constitutes ahot start.During theinitialstartingphase,thenozzleshouldexpandto a f&open (100percent)position. 0 Iftheenginehssbeenshutdownwithiuthepiist60
minutes,monitorit closelyfor a hot/hungstart.If tbe startisabotibof ahotstart(EGTabove890 “C),motortheengine uutiltheEGTislesstbao250Y!. 0 Lossof electricalpowermayresultin smokeentering thecockpitvia theECS.
4BC
16. Rightengineinstrumentreadings. a. RPM -
62to78Percent.
b. EGT -
350to 650‘C (nominal).
c. PP - 950to 1,400Ppb(nominal). d. NO2 positione. OIL -
MO-Pencent Open.
25to 35 Psi(nominal)(15psiminimum).
f. FLT HYD - 3,000Psi. ORIGINAL
10-4
NAVAIR 01.FlhAAo-1
17. External power -
Disconnect.
Removal of ground electricalpower causesthe right genaatar to supply power to the right and left main electrical buses. 18. Tailhook -
EMERG DOWN.
19. ENG CRANK switch When combin position.
L (left engine).
hydraulic pressurereaches3,000 psi, return switch to neubnl (center)
20. HYD TRANSFER PUMP switch -
NORMAL.
Hydraulic transferpump will operatet?om tlight sideto maintain the combinedsidebetwam 2,400to 2,600psi.
If the transferpump does not pi~surize the combined system within 5 seconds, immediately set HYD TRANSFER PUMP switch to SBUTOFF. 21. ENG CRANK switch -
OFF andCheck BI-DI.
22. EIYD TRANSFER PUMP switch -
SHUT OFF.
23. Repeatsteps14, 15, and 16 for lek engine. 24. BACK UP IGNITION switch 25. Starterair -
OFF.
Disconnect.
26. AIR SOURCE -
L ENG, R ENG, then BOTH ENG.
Verify cockpit airflow in threepositions. 27. Right throttle -
OFF Then Immediately to IDLE.
Observerpm decreasethen rise to idle ‘pm. Note Failure of the engine to relight above 59 percentindicatesa failure of the N2 decelerationauto-relightlogic. 28. Left throttle -
OFF Then Immediately to IDLE.
Observerpm decreasethen rise to idle rpm. Note Failure of the engine to relight above 59 percentindicatesa failure of the N2 decelerationauto-relightlogic. 10.5
ORIGINAL
NAVAIR 0%Fl4AAD-1
ROFILE BC
29. HYD TRANSFER PUMP switch 30. Restoreno-1
NORMAL.
tailhook andraise.
,BC
31. Idle engine instmment readings.
BC
32. OBOGS masterswitch -
ON. pLijzLJ
Ensure.ECS serviceair is available to OBOGS prior to selectingthe OBOGS masterswitch ON. 10.3.3 Poststart BC
33. EMERG GBN/VMCU operation -
Check.
Voltage drop obtainedwhen emergencygeneratoris turned offwill activate VMCU. This will result in instantaneousillumination of the following lights for 1 to 2 seconds: a. PITCH STAB 1 and 2 b. ROLL STAB 1 and 2 c. YAW STAB OP and OUT d. HZTAILAUTH e. RUDDERAUTH f. SPOILERS g. AUTOPILOT h. MACHTRIM. When normal voltage is regained,VMCU is deactivated,all lights will go out except RUDDER AUTH. ORIGINAL
10.6
NAVAIR Ol-F’l4AAD.1
PROFILE ABC
34. AFTC -
Check.
a. L ENG selectswitch -
SEC.
L ENG SEC light illuminates; left NOZ position indicator pointer below xero. b. L J3NGselectswitch -
PRI.
L ENG SEC light goesout,NOZ position indicator to 100percent. c. R ENG selectswitch -
SEC.
R ENG SEC light illuminates; right NOZ position indicator pointer below zero. d. R ENG select switch -
PRI.
R ENG SEC light goesout; NOZ position indicator pointer to lOOpercent. m Selecting secondary(SEC) mode closes exhaustnoxzles, increasingexhaustnozzlejet wake hazard. Note l
Performing AFTC check during OBC inhibits AICS ramps from programming. Rampsmust be resetbefore anotherOBC can be performed.
l
NOZ position indication is lost in SEC mode.
35. MASTER TEST switch - WG SWP. Wing-sweep mode switch must be in AUTO. Wing-sweep program index moves f?om 20’ to 44’ and back to 20’. The following lights illuminate at startof test and areout at test completion (approximately 25 seconds):WING SWEEP, FLAP, and REDUCE SPEED. Note l
During the wing-sweeppreflight test,both altimeters may fluctuatemomentarily.
l
The WING SWEEP advisoty light illuminates 3 secondsatIerthe teststarts,thengoesout andilluminates again 8 secondsinto the test.
l
The WING SWEEP advisoty light goesout at theend of the test.The RUDDER AUTH, HZ TAIL AUTH, andMACH TRIM lights illuminate for the entiretest andremain ilhnninated at the end of the test. 10-7
ORIGINAL
NAVAIR Ql-Fl4AAD-1
PROFILE A
36. UHF/VHFOTIDS/KS. Check complete operationof pilot COMM switch -
AB
UHF 1, UHF 2, JTIDS, ICS.
37. OBC (autopilot ENGAGE). fior to running OBC, clear FHF. a. After ramps areextended -
SelectRamps to STOW.
b. Verify RAMP lights go off and INLET lights illuminate. c. When OBC is complete: (1) Resetboth AICS andcheck that INLET RAMPS arein AUTO. (2) Reinitiate completenormal OBC. (3) Upon completion, recordOBC, MCF and FHF. ABC
38. Speedbrakeswitch. a. EXT-RET. b. Verify stabilizers shift 2’ TED (clean) or 3’ TED (AIM-54 rails) on extension and oppositeon retraction(ITS).
ABC
39. ECS. a. AIRSOURCEpushbuttonsshouldbepressed:LENG,RENG,OFF,thenbacktoBOTH ENG. There will be slight reductionin flow with single-engineair sourceselected.There shouldbe no excessiveinterruptionsin airflow when sourcechangesaremade. b. Cockpit temperatureconhol (TEMP mode selectorswitch) should be checkedin both MAN and AUTO modes to eosurepropertemperaturecontrol.
ABC
40. Flaps down. a. Verify stabilizer shifts 3’ TEU (ITS).
ABC
41. Flight controls a. Trim -
Full Nose Down (9’ TED).
b. Stick full aft c. Trim -
TRIM.
Check for Free Movement.
FullNose Up (grater than 18’ TEU) (17 to 19 seconds).
d. Stick full forward -
Checkfor FreeMovement.
e. Yaw trim - 7OLeft to 7ORight (12 to 14 seconds). f. Trim -
ORIGINAL
Full Left (check 6Odifferential tail split).
IO-8
NAVAIR 9%FldAAD-1
PROFILE g. Stick full left Extension. h. Trim i. ABC
Check Power Approach Spoiler GearingandUniform Spoiler
Full Right (16 to 18 seconds);Check 6ODifferential Tail Split.
Stick - Full Right; Check PowerApproach Spoiler Gearing and Uniform Spoiler Extension.
42. Flight controls -
Cycle.
Observefollowing: a. Longitudinal b. Lateral -
33OTEU to 7OTED Horizontal Tail (33” to 10” without ITS).
24” Total Differential Tail.
c. Depressautopilot emergencydisengagepaddle d. Directional -
30°Rudder.
e. Longitudinal f. ABC
Spoilers -
14” Total Differential Tail.
Lateral Combined, 35’ TEU to 15” TED.
55’.
43. Spoiler checks. a. DLC -
Check.
(1) Engage DLC. Verify stabilizer shifts 2-3/4” TED. Inboard spoilers extend to 17-l/2”. (2) Full up DLC. Verify stabilizer returnsto trim. Inboard spoilers go to -4-112”. (3) Full down DLC. Verify stabilizer remains 2-3/4Obelow trimmed position and inboard spoilersextendto 55”. (4) Stick 2 inchesleft (check spoilergearing). (a) Left wing outboard+30”. (b) Left wing inboard+55O. (c) Right wing both -4-l/20. (5) Stick right 2 inches(check spoiler gearing), (a) Right wing outboard+30°. @) Right wing inboard+55O. (c) Left wing both -4-l/2”.
IO-9
ORIGINAL
NAVAIR 0%FI4AAD-1
,ROFlLE Note If either right SPOILER position indicator shows one position highor then actual spoilerposition (that is, DN vice droopedandextendedvice DN), e spoiler zero-degreeswitch hasfailed. Spoiler symmebyprotection circuitry is inoperativeand spoiler ground-roll braking in flight is possible. b. SPOILERBK -
Select.
c. SPOILER FLR ORIDE operation. (1) INBD end OUTBD SPOILER FLR ORIDE switches (2) MASTER TEST switch -
ORIDE.
STICK SW.
(3) Verify all spoilersremain extended(559. (4) INBD end OUTBD SPOILER FLR ORIDE switches -
NORM
Verify INBD andOUTBD spoilersfait down and SPOILER light illuminates. m With SPOILER FLR ORIDE switches in ORIDE, spoiler symmetry protection circuitry is disabled. Ensurethat switchesarein NORM. (5) Verify spoilersdown. (6) MASTER TEST switch (7) MASTERRESET d. MASTER TEST switch -
OFF.
Depress. STICK SW.
(1) Verify GO light illumioates with l-inch lateral stick inputs left and right. (2) MASTER TEST switch (3) MASTERRESET -
OFF.
Depress.
Verify SPOILER light goesout and all spoilers extendto 55’. e. SPOILER BK/THROTTLE inte.rlocks 44. Displays 45. Tacan 46. ARA-63 -
CHECK. BIT. BIT.
Check HUD, VDI, and standbygyro needles. ORIGINAL
10-10
Check
NAVAIR Of-FMAAD-1
PROFILE A
47. Gunsight -
Verify (manual mode).
a. Select A/A. b. SelectGUN. c. Selectmanual mode via CAGE/SEAM switch. d. Dial in 34 mils. Verify the manualreticle is positionedover the HUD headingtick AB
48. Autopilot emergencydisengage. a. Paddle switch -
Hold Depressed.
b. Verify throttles in manual mode. A
49. OXYGEN Monitor -
TEST.
The TEST button must be held for up to 1 minute to vent oxygen from the monitor oxygen sensor.Oncethemonitor sensesinsufficient oxygenconcentration,thecockpit cautionlights will be illuminated and oxygen supply sourceshiftedto BOS. Releasethe TEST button as soon as the OBOGS light is illuminated. Verify OBOGS light is extinguishedwithin 20 seconds.
The monitor will fail without any indication to the aircrew. For this reason,it is essentialthat the pilot testthe monitor function prior to launch andprior to ascending above 10,000 feet MSL. If the aircrew suspectsthe onset of hypoxia at any time, immediately select BACKUP. The monitor may be testedoncethe aircraft has descendedto a maximum cabin altitude of 10,000 feet by reselectingON on the OBOGS masterswitch. Note The monitor can take up to 2 minutes to warm up, dcpendingon the ambienttemperature.The OBOGS light will not be illuminated during the warmup period. 10.3.4 Taxi ABC
50. Turn needle/slipindicator -
Check.
10.35 Engine Runup AB
51. Engine runup -
Check.
10-11
ORIGINAL
ROFILE
Onboardship,useof MRT andMIN AB is restrictedto s amimum of 30 secondsto preventdamageto the holdbackbar andtheJBD.
Lafl
Right
Llmlts
NO2 position (%) AT MIL
clod
OIL (PSI)
25to65
RPM (%)
95 to 104 nominal (107.7 maximum)
EGT (‘C)
935’
FF (PPH)
9,ooo to 12,000
s. Verify hookis stowedandRATSlightis out. b. Rightenginemodec. Rightthmttle -
SEC.
ME.
Noteacceleration time (lessthan10seconds). d. Rightenginemode- PRI. Recordengineparameters. e. Hook - DOWN. Verify RATSligbtand3-to 6-percentrpmdecay. f. Rightthrottle -
MIN AB.
Verify rpmincreases 3 to 7 percent. g. THROTTLEMODEswitchh. Rigbttluottle -
MAN.
IDLE.
i. THROTTLEMODE switch-
BOOST.
j. Hook-UP. Verify hookis stowedand,RATSlight is out. k. Repeatstepsb throughj with left engine.
ORIGINAL
1012
nominal 3 to 10
NAVAIR 0%FMAAD-I
PROFILE 10.3.6 Takeoff and Climb A
52. Landing gear -
Retract(9 to 15 secondsnominal).
A
53. Barometerand radaraltimeters -
AB
54. AFTC -
Check Below 5,000Feet.
Check. Note l
SEC modetransferwhile in minimum AB may result in pop stalls. Nonemergency manual selection of SEC mode airborne should be performed in basic enginewith the power set above85-percentRPM.
l
If the fan speedlimiter circuit hasfailed, enginerollback may occur with the selectionof SEC mode. In the eventof enginerollback, PRI mode most be rese= lected above 59-percentrpm or flameout will occur and an airstartwill not be possible.
a. LENGmodeswitch b. Left throttle -
-
SEC.
Check Basic Engine Power Response.
c. L BNG mode switch -
PRI.
d. R ENG mode switch -
SEC.
e. Right thmttle -
Check Basic Engine Power Response.
f. R ENG mode switch -
PRI.
g. Cycle AICS cb’s at a constantsubsonicMach. 10.3.7 10,000.Foot Check AB
55. OXYGENmonitor -
TEST.
The TEST button must be held for up to 1 minute to vent oxygen tirn the monitor oxygen sensor,Oncethe monitor sense3insuflicient oxygenconcentmtio~ the cockpit cautionlights will be illminated andoxygensupplysouxe shiftedto BOS. Releasethe TEST buttonassoon asthe OBGGS light is -ted. Verify OBGGS light extinguishedwithia 20 seconds. I,,,,,,,( The monitor will fail without any indication to the aircrew. For this reason,it is essentialthat the pilot testthe monitor function prior to launch andprior to ascending above 10,000feetMSL. Ifthe aircrewsuspectstheonset of hypoxia at any time, immediately select BACKUP. Themonitormaybetestedoncetheaircrafthasdescended to a maximum cabin altiti of 10,000feet by reselecting ON on the OBGGS master switch. IO-13
ORIGINAL
NAVAIR 0%F14AAD-I
‘ROFILE LBC
56. Fuel transfer -
LB
57. ECS check (250 knots).
Check
In CV environment, eusureexternal tanks are empty prior to ECS checks. ECS check shouldbe performedat altitudeabove 8,000 feet so cabin pressurizationcan be checked,but low enoughto preventlargecockpitpressmechangeswhen cockpitair is secured. a. Cabin altitude approximately8,000 feet. b. Air distribution -
CANOPY DEFOG-CABIN AIR.
c. Radarpower switch -
STBY (coordinatewith RIO).
d. AIR SOURCE pushbutton -
OFF.
Cockpit pressurizationwill quickly bleed off with cabin pressure altimeter moving upward toward aircratl altitude. m Oxygen breathing time on BACKUP is limited. Note l
When ECS service air to the OBOGS concentrator is shut off, the aircrew has approximately 30 seconds before depleting residual OBOGS pressure and mask collapse.
l
Restorationof serviceair (selectingRAM) will return OBOGS to operation.
e. CABIN PRESS switch -
DUMP.
Cockpit will completely depressurixe. f. RAM AIR switch -
INCR (35 to 50 seconds).
As ram air door opens(upto 50 secondsto openfully), therewill bean increasein cockpit airflow. g. AIR SOURCE pushbutton -
RAM.
With RAM selected, 400° manifold is repressurized,which maintains canopy seal, airbags,and antennawaveguidespressurization.As canopysealreinflates,cockpit pressurization available from ram air will be much more apparent. ORIGINAL
IO-14
h. CABINPRESSswitch - NORM. i. AIR SOURCEpushbutton- BOTHBNG. j.
Radarpowerswitch -
XMIT (Coordinate with RIO).
58. MFD OBC TEST - Select. 103.8 lS,OOO-Foot Checks
59. stab&e at 300knots. a Full stickroll -
SASOFF-ON.
Note Cdl extensionof down-wingspoilers.SASon roll acc&mtion will be slightly higherbecause of increased horizontaltail authority. b. Pit&pulse -
SASOFF-ON.
At slowspeeds, pitchSASOFFis hardlynoticeable. Lackof pitchSASbecomes more apparentasspeedincreases. c. Rudderpulseleft aadright -
SASOFF-ON.
Yaw excursions shouldceaseimmediately uponengagement of YAW STAB. 60. wii-aweq
andmaneuver devices(checkat 0.5Mach).
a Maneuverdevi~sb. Wiigaveep switch -
EXTD. AFT(checkthatwingsstopat 500).
c. Maoeuverflapspartialupwith thumbwheel. Ensurethatdevicesretract. d. Wing-sweepswitch -
BOMB.
(1) Verify maneuverdevicesautomatically retractandthenwingssweepto 55’. c. Wmgaweepswitch -
MAN FULL AFT.
f. Wing-sweep switch -
AUTO.
g. Emergency WING SWEEPhaodle-
Cycle 22’, -68’. -22”.
(1) Verify spiderdetentengage emergency WING SWJIEPcautionoff.. (2) MASTERRESETpushbutton- Depress. CheckWING SWEEPadvisorylightoff. h. Maneuverdevices-
EXTD.
i. Accelerateto greaterthan0.79Machandcheckmaneuverdevicesautomatically retmeted(maneuver devicesstartautomaticretractionat 0.68a.02 Mach). 10-15
OUIGINAL
NAVAlR 0%F14AAO-1
PROFILE
j. Decelerate to lessthan0.68Machandcheckmaneuverdevicesremainretracted. k. Wing-sweep switch - AUTO. ABC
61. ASYM LIMITER switch - Check(airspeed 300knots). a. Throttles-
MlLorLess.
b. ASYM LIMITER switch c. L&throttle -
OFF.
MAX AS.
Observe111AR available. d. ASYM LJMITERswitch-
ON.
Observereductionto minAR (12percent). e. Repeatstepsa throughd for right engine. ABC
62. High AOA AUTO MAN devices. a. Roll SAS -
OFFandALPHACOMPcb (RBl) In.
b. Throttles-
IDLE.
c. Slowlyincrease aircragAOA andallowaircraftto stabilize;maneuver devicesextendat 10.5unitsAOA. Note
Themaneuver deviceAOA signalfrom the nosealpha probeto CADChasafasterresponse ratethanthesignal t?omthe left-sidefuselageprobeto AOA indicator, causingalowreading(error)ontheindicator.Thiserror is directlyproportionalto the aircrafiAOA maneuver rate. Therefore,to determinewhen maneuverdevice extension occurs,performthehigh-AOAmaneuverdevice checkby slowlyincreasingaircraftAOA andallowingaircratlto stabilize. d. Maneuverdevicesretractat 8 unitsAOA. e. ALPHACOMPcb - Out. ABC
63. Approaches to stallsandapproach configurationcheck(approximately 15,000feet). a. Cleanstall. (1) Stabilizein levelflight at 15unitsAOA. (2) Ensuremaneuver devicesretracted. (3) Slowlydecelerate to buffet onset.Note AOA (light air&onebuffet at 12to 13 units,increasing to moderateintensityat 15unitsAOA).
ORIGINAL
10-16
NAVAIR Ol-Fi4AAD-1
(4) Continue decelerationto 28 units AOA. Note any abrupt or significant rolloff tendencies. b. Clean stall with maneuveringdevicesextended. (1) Stabilize in level flight at 15 units AOA. (2) Extend maneuveringdevices. (3) Slowly decelerateto buffet onset.Note AOA (light airtiame buffet at 13 to 14 units AOA). (4) Continue decelerationto 28 units AOA. Note any abrupt or significant rolloff tendencies. (5) When AOA is below 15units, retractmaneuveringdevices. c. Approach configuration check. (1) Perform landing checklist (ml1 SAS ON, ALPHA COMP cb out). (2) DLC -
Engage.
Check for excessivelateraltrim mquimments. (3) AUTO THROTTLE. (a) Responseto longitudinal stick. (b) Responseto tom entry, steadyrollout. (c)
Responsein HOTMORMKOLD.
(d) AUTO THROT light. 1. Manual overtide. 2. CAGE/SEAM button. d. Dii
stall.
Slowly decelerateto level flight to 20 units AOA. Note any abruptor significant rolloff tendencies. e. Attempt speedbrakeextensionat MlL power. f.
ALPHACOMF’cb
-
In.
64. Strncturalintegrity check (0.9 Mach at 10,000feet). a. High-speeddash -
MILTHRUST.
b. High-gturn.
IO-17
ORIGINAL
NAVAIR 0%FMAAD-1
‘ROFILE c. Anti-g valve operation. d. HUDg-Cheek. 10.3.9 AIrstarts (20,000 Feet) 46
65. Radarpower switch -
4B
66. Spooldown air&art.
STBY (coordinatewith RIO).
a. Stabilize at 300 lolots. b. Right thmttle -
OFF ThemIDLE at 60-percentrpm. Note
Subidle stall can be clearedby cycling the throttle to OFF and immediately returning it to IDLE. c. Stabilize at 300 hots. d. Left throttle 48
OFF Then IDLE at 60-percentrpm.
67. Radarpower switch -
XMIT (coordinatewith RIO).
10.3.10 Climb to 35,000 Feet 48
68. Fuel management. Left
Rl9ht
FEED FUS WING EXT TOTAL
9B
69. ECS check a. Automatic cabin temperaturecontrot b. Manual cabin temperaturecontn~l. c. Cabii altitude schedule(appmximately 14,000feet at 35,000 feet).
9B
70. Afterburner light-off -
Check (cheekat 210 knots).
a. ASYM LIh4lTER switch -
OFF.
IO-18
NAVAIR 0%FMAAD-I
b. Throttles I
MAXAB.
Verify AB light-off within 10seconds. c. Throttles -
Less Than MIL.
d. ASYh4 LIMITER switch -
ON.
71. Engine instruments(engineMIL power at 0.9 Mach). Left
10.3.11
Right
Limits
OIL (PSI)
25 to 65
RPM (%)
107.7 maximum
EGT (‘C)
935’
High-Speed
72. Idle lockup -
Dash (35,000
Feet)
Check.
a. Jam throttles -
MAX AB (accelerateto 1.2 Mach).
b. Both throttles to MIL until nozzles close, then IDLE above 1.1 Mach and verify less than 2-percentrpm decay.
Monitor rpm decaywhile retardingthrottles to IDLE to ensureproper idle lockup operation. Discontinue idle lockup check if rpm decaysmore than 2 percentabove 1.1Mach. Place throttlesto MIL and decelerate. c. Jam throttles -
MAX AB (accelerateto 1.5Mach).
d. Engine instmments -
Monitor. Left
Limits
Right
NO2 position (“h)
50 to 60 (open)
OIL (PSI)
25 to 65
RPM (%)
107.7 maximum
EGT (“C)
935’
e. Mach trim compensation -
Check.
10-19
ORIGINAL
‘ROFILE
f. wii-sweep program - Check. g. Comparepitot-staticinstrcments at 1.5Mach. Pilot stby
RIO stby
Calibrated
Altitude Airspeed 10.3.12 Zoom (40,000 Feet)
73. Pitchup to FL 400. 74. Cabinpressurization andBCS -
Check(approximately 17,000feetat 40,000feet).
1013.13 20,000-Foot Checks 75. AFCS check.
a. Attitodehold. (1) Autopilot - Engage;VerifyNo Transient. (2) Checkfor smoothoperationin CSS.
b. Headinghold. (1) Headinghold - Engage. (2) Let3andrightpedalsideslip(3) CSS letI or right to 5’ roll -
CheckReturnto Reference Heading. Aircmtl ShouldReturnto 0” Angleof Bank
c. Altitudehold (1) ALT hold (2) A/P REF -
Select(verifyA/P REFadvisoryilluminates). NWSpushbutton-
Depress(verifyA/P REFadvisorygoesoff).
(3) Check for altitudecontrol.
(a) A30feet in levelflight. (b) 60 feetin 30°angleof bank. d. Groundtrackhold@ESTsteeringnot selected). (1) GT hold -
Select(verifyA/P REFadvisoryon).
(2) A/J?REF - NWSpushbutton- Depress(verifyA/F REFadvisorygoesout). ORIGINAL
10.20
NAVAIR 01.F14AAD-1
PROFILE (3) Verify A/P establishescrab into wind to hold selectedtrack. (4) Autopilot emergencydisengagepaddle switch (5) PITCH andROLL STAB AUG switches ABC
Depress.
ON.
76. Negative alpha/FOD check (20,000feet,300 knots). a. Tbrottles -
MJL..
b. Roll inverted in wings-level attituda and set-
l.Og.
p&i-) Negative-gmaneuveringat high grossweight shouldbe avoidedbecauseof possiblility of aircmfl departure. c. Check for nomal engineoperationand FOD or loosegear. A
77. Air-to-air check. a. Weaponselectorswitch b. Test target -
LR
Select.
c. Attacksteering -
LAR-Vc.
d. Collision steering. e. Attacksteering -
LAR-V,.
(1) MR. (‘4
SR
f. Target intercept. (1) VSLhigh. (2) VSL low. (3) hml.4 (4) PLM. (5) PAL. (6) Selectgun. (7) ObserveproperHUD display.
10-21
ORIGINAL
NAVAIR Ql-FUAAD-1
PROFILE g. Glmsigllt -
check
(1) RTGSiMANUAL. (2) MMGS. A
78. Air-to-groundcheck. a. SelectA/G.
A
79. Fueldumpcheck. a. Speedbrake switch b. DUMP switch -
EXT.
DUMP.
(Observeno ibe1dump). c. Speedbrake switch - RET(observefuel dump). d. DUMP switch A
OFF.
80. Fuelsystemcheck(totaltie1lessthan8,000pounds). a, WING/EXTTRANSswitch -
OFF.
b. FUELFEEDswitch - FWD/R Monitor500-Pound Split,AFT/L High. c. FUELFEEDswitch - AFT/L Monitor5OOPoond Split,FWDiRHIGH. d. FUELFEEDswitch- NORM. Verify FWD/Rhighsplitremainsconstant. 103.14 Approach ABC
81. Landingchecklistcomplete.
ABC
82. ACLSIARA-63-
ABC
83. Airspeedand AOA(15 unitsAOA) - Check.
Check.
a. AOA, INDEXER,HUD. (1) Grossweight (2)
ORIGINAL
pods.
knots (124 knotsW knotsat 44.000-pouud grossweight.Add 3 knotsper2,000poundsover44,000-pound grossweight).
Airspsea-
10.22
NAVAIR 0%F14AAD-I
10.3.15 Touchdown 84. Verify exhaustnozzle lessthan26 percent. a
Three to sevensecondsatIer touchdown,nozzles 100percent.
85. Walkaroundimpection -
Complete.
10.4 FUNCTIONAL CHECKFLIGHT PROCEDURES (RIO) 10.4.1 Prestart 1. ICS. a Normal. b. Backup. c. Emergency. 2.lNDLT-TEST. 3. Seatadjustment -
Check.
4. canopy rigging, a
Both cockpit handlessameposition during operation.
b. BOOST not requiredto close. 5. NAV MODE switch a
ALIGN.
After displays are on, verify and/orenteralignment coordinates.
10.4.2 Poststart 6. Multifunction display. 8. Verify navigation display. 7. ALR-67 -
BIT.
8. Altimeter -
Set and Check; RecordError
When the local barometric pressureis set, all altimeters should agreewithin 75 feet at field elevation. 10.4.3 Taxi 9. BDHI -
Cross-CheckHeadingWithVDI/HUD.
IO-23
ORlGlNAL
NAVAIR
‘ROFILE A
0%FMAAD-1
10. NW -
check (at takeoff endof runway). Groundspeed
IO.44
Takeoff
Time
and Climb
11. Engine romp -
Check at ML.
95 to 104 nominal
9
12. Airspeed -
check (200 knots).
Pllot Standby
RIO Standby
KIAS
A
13. Altimeter -
KIAS
ALTIMETER
A
14. Tacan and NSV position -
A
15. MS navigation and radarmapping check. a. Radarmap -
ABC
15,000-Foot
KCAS
Check. INSISAHRS
10.4.5
HUD
Cross-Check.
Check All RangeScales. Checks
16. Stroctural integrity check. a. Anti-g valve operation, b. Setradar power switch to STAY beforepilot ECS chock
ORIGINAL
to-24
NAVAIR WFIUAD-I
10.4.8 20,000-Foot Checks 17. Radarpower switch -
XMIT (airstartscomplete).
10.4.7 Climb to 35,000 Feet 18. Engine instmmeota -
Record.
I
Left
OIL (PSI)
Right
Limits 25 to 65
I
I
RPM (%)
107.7 maximum
EGT (“C)
935’
19. D/L. -
Check
20. Selectassignedtiequency andADDRESS. 21. Receive D/L messages. 8. Steeringsymbols. b. TID targetdata. c.
Data-link
messages,
10.4.8 High-Speed Dash (35,000 Feet) 22. Engineinstruments -
Record. Left
Llmlts
Right
NO2 position (%)
50 to 60 (open)
OIL (PSI)
25to65
RPM (%)
107.7 maximum
EGT (“C)
935’
10.4.9 Descent 23. Air-to-air check a. Radarmodes (1) PULSE. (2) PD SRCH.
1O-25
ORIGINAL
NAVAIR 0%FlrlAAD-1
(3) RWS. (4) TWS AUTO. (5) Tws&4AN. (6) HRWS. b. MLC switch -
OUT-AUTO-IN (PD SRCH).
c. Navigation. (1) Tacanfix -
Recod(donotinitiateupdate).
A Latitude
(2) Radarfix -
A Longitude
Record(do not initiate up+@.
A latitude
(3) Visual fix -
A Latitude
A Longltudo
Record (do not initiete update).
A Longltude
I
d. Weaponsystemschecksagainstsuitableairbornetargets. (1) Intercepttargets,check operationin PD SRCH, RWS. aud TWS MAN. (a) Observetransitionto PULSE SIT. (b) Retum to PULSE SRCH. (c) Close to visual rangeend verify DD display. (2) VSL mode -
HI-LO LOCK-ON.
(3) MRL mode -
Check LQCK-ON.
e. lm-
Check Modes 1,2,3, and 3C.
lo-26
PROFILE A
24. Air-to-ground check. a. Select A/G. b. Select CTGT mode. (1) verify symbology. (2) 30° dive 12,000-footroll-in. (3) Designatetarget. (4) verify solution. (5) Maneuver-designatorremains on target. (6) Complete 30° dive. c. Select CCIP mode. (1) verify symbology. (2) 30° dive 12,000-footroll-in. (3) Fly impact point over target. (4) Complete 30° dive. d. Air-to-ground GUN sight. (1) SelectGUN. (2) Dive angle greaterthan 15’. (3) Check symbology. e. Exit A/G.
ABC
25. Perform radarIBIT and recordresults.
A
26. NSV -
SAHRS.
a. Pilot check HUD and VDI display andmaneuveraim&. b. Radarantennascan -
Check.
10.4.10 Approach A
21. Airspeed a. Comparewith pilot airspeedat 15units AOA, recorderror
lo-27
knOts.
ORIGINAL
NAVAIR 0%FlUD-1
ROFILE 10.4.11 Landing BC
28. lb&u - PS, or power switch 10.4.12
BC
STBY.
In Chocks
29. INS/SAHRS and visual -
Check andUpdate in Chcka.
a. Record closeouterror. A Latitude
A Longitude
INS SAHRS
b. Initiate 6x enable. c. Observeahcraft symbol shift on TID. ,BC
30. Call up maintenancecurrentfailures.
Record
18.4.13 Postflight LBC
ORIGINAL
3 1. Walkaround inspection -
Complete.
lo-28
A rime
Groundspeed
NAVAIR 0%F14AAD-1
PART IV
Flight Characteristics Chapter 1 1 -
Flight Characteristics
61 (ReverseBlank)
ORIGINAL
NAVAIR 01-Fl4AAD-1
CHAPTER
11
Flight Characteristics 11.1 PRIMARY FLIGHT CONTROLS
11.1.4 Stability Augmentation. Pitch SAS increasesdamping of the longitudinal, short-perioddynamic response,but the aircraft can be operatedsafely throughoutthe flight envelopewithout it.
Primary flight controls are devices that changethe flightpath of the aircraft. They consist of the differential horizontal stabilizer for pitch and roll control, the spoilers for supplementary roll control, and the rudders for directional control. A stability augmentation system is provided for the three axes of aircraft motion. 11.I.1 Pitch Control. The horizontaltail is effective t?om under 100knots to over Mach 2. Its effectiveness gives the aircraft several capabilities not enjoyed by otherfighters,including low takeoff rotation speedsand theability to reachor exceedlimit load factorover much of the subsonicand supersonicenvelope; it is also an excellentdrag device below 100 knots on landing rollout. The major disadvantagesof the large horizontal stabilizer authority are that the pilot can generatehigh enoughpitch rates(particularly in the nosedowndirection) to causecoupling under certain conditions, and that a pitch attitude sumcient to scrapetailpipes and ventral tins can be attainedon landing rollout or takeoff rotation. 11.1.2 Roll Control. Differential deflection of the horizontal tail surfacesprovides primary roll control throughoutthe flight envelopeand is the only roll control whenthe wings aresweptbeyond62” (disablingthe spoilers). Spoilers are very effective at low to medium AOA for roll control, and reduce the aft fuselagetorsional loads induced by the differential tail. The spoilers are also the primary mechanism for direct lift control and spoilerbraking. 11.1.3 Directional (Yaw) Control. Twin rudders furnish directional control. Through strong dihedraleffect (roll becauseof sideslip), good roll control is also availablefrom rudderinputs at medium and high AOA. Rudderpower is sufficient to provide adequatecontrol underall asymmetric store loading conditions.
Roll SAS increasesroll accelerationduring the initial lateral stick input. The SAS reducesdifferential tail deflection to limit maximum roll rate to lessthan 180”per secondto reduceaft fuselageloads and to preventroll coupling in the transonic speedrange. An undesirable byproduct of the roll-rate limiting is an oscillatory roll rate perceivedas a nonlinearroll responseencountered in full lateral stick deflection rolls at medium subsonic speedsandhigher.Becauseroll SAS providesstructural protection,flight above0.93Mach is prohibitedwithout roll SAS with wing-mounted AIM-54 (loadings 3B5, 3B6,3C5,3C6). Shouldtactical considerationsnecessitate violating this restriction, restrict rolls to less than full lateral stick deflection and to not more than 180’ of bank anglechangeat one time. This minimizes the possibility of aircraft damage. Initial roll accelerationis slower without roll SAS; however,high AOA handling qualities are improved (seeparagraph11.6). With regardto controllability, yaw SAS is the most critical ofthe stability augmentationfunctions.Directional dynamicresponse(yawoscillationsor dutchroll) is poorly dampedwithout it. In regionsof reduceddirectionalstability above24 units AOA or when supersonic,the SAS dampensyaw ratesthat might otherwisecauseloss of control,or structuraldamage.Below 0.93Mach,with yaw SAS OFF, normal maneuveringcan be accomplishedif extracareis takento control yaw and sideslipexcursions with rudder(maintaincoordinatedflight). I I .2 SECONDARY FLIGHT CONTROLS Secondaryflight controls affect the flightpath of the aircraft althoughthey haveotherprimary purposes,such as increasing1iA or drag. Secondaryflight controls of the aircraft includemain, auxiliary, andmaneuverflaps, leading edgeslats, speedbrakes,DLC, and the variable sweepwing.
II-I
ORIGINAL
NAVAIR Ol-Fl4AAD-1
11.2.1 Maneuver Flaps and Slats. Maneuver flaps and slatsprovide increasedbun performance(increasedmm rate/decreasedtmn radius)when extended. Additionally, the extensionof the maneuver slats decreasesdeparturesusceptibility by increasingpositive dihedral effect (roll becauseof sideslip). The longitudinal trim changeupon extension and retraction of the devicesis slight (2 to 4 poundsaft on extension,approximately 2 poundsforward on retraction).
In the transonicregion, from Mach 0.8 to 1.5,static longitudinal stability is essentially neutral. There is, however, a minor reversal in the stick force gradient (forward stick force may haveto be relaxedto maintain level flight when accelerating)at approximately Mach 0.95.Above Mach 1.5,the stick forcegradientbecomes neutral. Since the engine line of thrust is below the aircraft cg, reducing power causesa slight nosedown pitch; power addition causesa noseuppitch.
11.2.2 Landing Flaps, Slats, and DLC. Trim changesduring extension and retraction of flaps/slats are significant. During extension of flaps/slats at 200 knots, an initial push force of approximately 5 pounds is required followed by a pull force of up to 15pounds. Engagementof DLC at approachspeedscausesessentially no trim change.Forces during retraction of the flaps/slatsare generally oppositeand of approximately the same magnitude.The force requiredduring retmction of flaps/slatsmay be less objectionablethan those during extension,as the flaps are generally raisedat a slower airspeedand, therefore,require less opposing force.
11.3.2 Dynamic Longitudinal Response Characteristics. The initial responseof the aircraft to a longitudinal stick input is greatly dependenton the dynamic longitudinal responseor “short period” characteristics.Dynamic longitudinal responseto pilot inputs is somewhatsluggishin cruiseand approachcontigurationswhen comparedto most othermodem day fighters. In cruiseconfigurationthis may not beevidentuntil high gain,closecoupledtasks,suchastine gunsighttracking, areattempted.Here, the pilot’s tendencyis to overdrive the aircraft with the control stick resulting in a slight porpoisingof the nose.This canbe avoidedby applying a longitudinal stick input andwaiting for a noseresponse before applying a further correction.
Note Retractingthe flaps with DLC engagedmay require up to 30 poundspush force to maintain pitch attitude when the DLC automatically disengagesas the flaps pass25”.
In approach configurations, the sluggish nose responsewill be most noticeableduring approacheswithout DLC, asmore nosemovement must accompanythe largerpower adjustmentsrequiredto maintain onspeed AOA when flying the ball.
11.2.3 Speedbrakes. The speedbrakes provide somedecelerationcapability throughoutthe flight envelope. However, the most effective means to slow the aircraft is to reducethrust while applying g, since the speedbrakesaremarginally effective at moderateto low speeds.Extensionand retractionof the speedbrakesresults in a pitch trim changethat varies with flight conditions. In general, this change is not objectionable except at higher airspeedswhere the rapidity of the change(1.5 secondsfor full extension)may preventtine (f3 mil) gunsighttracking andpossibly lead to a minor caseof pilot-induced oscillation. 11.3 GENERAL FLIGHT CHARACTERISTICS 11.3.1 Static Longitudinal Stability. Static longitudinal stability indicates the direction of longitudinal stick force required with changing airspeed from a trim condition. At slow speeds where the wings are not sweeping, static longitudinal stability is slightly positive (forward stick is required for increasing speeds,aft stick is required for decreasing speeds). At speeds where the wings are automatically sweeping aft, static stability becomes neutral to slightly negative. ORIGINAL
11-2
11.3.3 Maneuvering Stick Force. Maneuvering stick force,or stick force per g of the aircraft, is predictable throughoutmost of the flight envelope.That is, an increasein force commandsa correspondingincreasein g (approximately4 poundsper g). The stick force per g generally changesvery little with altitude, airspeed, loading, or cg position. Stickdisplacementsrequiredduringmaneuveringare relatively large and may be uncomfortable to some pilots. While the stick forcesare not especiallyhigh, the stick must be placedrelatively close to the pilot’s torso to attaina given g. This givesthe pilot lessleveragewith his arm andis more tiring, especiallyat lower airspeeds andhigherAOA, where stick force per g can be ashigh as 10poundsper g. 11.3.4 Roll Performance. The roll performance (maximum roll rateattainable)is generally satisfactory, particularly athigh airspeeds.At lower speeds,however, the high-aspectratio and roll inertia of the aircraft restrict its time to roll to considerably less than that of smaller, more nimble tactical aircraft (A-4, F-16). The sluggish maximum roll rate at low airspeedsand high AOA aredefinite tactical limitations.
NAVAIR
Largeaft stick inputs appliedwith lateral stick during supersonicrolling maneuversresultin increasedadverse sideslip and should be avoided. High Mach number, high-altituderolling maneuversmay resultin oscillatory sideslipandroll ratchetingduringaggressivemaneuvering with roll SAS off. Depending on the phasing of thesedynamics, centering lateral stick may be insufficient to stopthe rolling motion andoppositelateralstick may be requiredin order to terminate roll. 11.3.5 Roll Response. The roll responseto control inputs is good with three exceptions.First, at high airspeeds,the roll-rate limiting feature of the roll SAS causesmarkedvariations in roll accelerationduring the initial lateralstick input, which resultsin a roll-rate oscillation. Natural pilot compensation for this characteristic may lead to a lateral pilot induced oscillation during maximum roll-rate maneuversat high airspeeds. Additionally, at high airspeeds,roll responseto small inputs is overly sensitive, primarily becauseof low breakoutforces and a nonlinearity causedby an abrupt increasein roll rate when the stick is displacedlaterally just enoughto break out the spoilers.This can result in bank angle overshoots during maneuvering flight. Lastly, at high angles of attack, at all airspeeds,the cumulative effect of severalphenomenaresults in a lateral controlreversalin which the aircraft rolls in a direction opposite to the lateral control input. This characteristicis further amplified in paragraph11.6.6, Lateral Control Reversal. 11.3.6 Dutch Roll. Although large lateral stick inputs can excite the dutch roll mode of the aircraft in cruiseconfiguration,the most severedegradationin flying qualities from the dutch roll is in approachcontiguration. During an approach, the dutch roll is characterizedbyawallowing,snakeymotionofthenose thatseverelydegradeslineup control. The period on this motion is quite long, and hasthe unfortunateresult that the pilot perceivesa headingerror when referencedto centerline,when in fact the flightpath is correct. More consistentlineup control canbe gainedby coordinating lateral stick inputs with rudder. Trim Characteristics. The trim ratein pitch is slow. During accelerationruns in MAX power at low altitude,trim may haveto be run nearly continuouslyto maintain longitudinal stick force at or nearzero.Lateral control authority and roll rates at slow speedswill be reducedby almost one-halfwith full stick deflection in the direction of full lateral trim becauseof decreased spoilerdeflection(seespoiler gearingcurves in Chapter 2). Therefore,when maximum lateral control authority is required,suchasduringan asymmetricflap condition, trim in the direction of stick displacement should be avoided.Runaway trim in any axis is controllable.Dur11.3.7
11-3
Ol-Fl4AAD-1
ing field landings,the aircraft can be recoveredsafely with runaway trim; however, carrier approacheswith full runawaypitch trim may be difficult. Trimming the aircraft to level flight can be broken down into two areas.At airspeedsslower than those using automaticwing-sweepprogramming, the aircraft is relatively easyto trim to level flight becauseit has positive longitudinal static stability. At airspeedswhere the wings automatically move with a change in airspeeds,it becomesvery difficult to achievea hands-off trim. Becauseof thechangein aircraft pitching moment causedby movement of the wings, the nose tendsto pitch furtherdown with eachincreasein speedor further up with eachdecreasein speed. Changesin thrust settings normally require a trim change,particularly in the approachconfigurations.A reductionin power causesa slight nosedownpitch. 11.4
ASYMMETRIC THRUST FLIGHT CHARACTERISTICS IN COMBAT AND CRUISE CONFIGURATION
11.4.1 General. With one engineinoperative,flight characteristicsare considerably affected by the thrust asymmetrygeneratedby the operatingengine.The distance of the enginesfrom the aircraft centerlineproduces flight control requirementsand flying qualities not presentin centerlinethrust aircraft. Flight control requirementsare a function of the thrust setting on the operatingengine.The thrustrequiredto maintain flight, andthereforethe magnitudeof the thrust asymmetry,is a function of the following. 11.4.1.1 Gross Weight. Heavier grossweights require higher thrust settingsto maintain level flight and, therefore, larger control deflections to counter the greaterasymmetricthrust. 11.4.1.2 Configuration. Aircraft configurationvaries the amount of thrust required at a particular flight condition. At cruisecontigurationairspeeds,control requirementswill be significantly reducedcomparedto landing configurations,which will requiresignificantly higherthrust settingsand in turn largercontrol forcesto maintain desiredflightpath. Airspeed. At maximum endurance airspeeds,minimum thrust is required to maintain level flight; therefore, the smallest asymmetric moment is produced.Higher or lower airspeedswill requirehigher power settingsand, therefore,increasedcontrol forces. At airspeedsabove maximum endurance,the greater asymmetrywill be offset largely by the additional control poweravailable.Minimum control speedis reached 11.4.1.3
ORIGINAL
NAVAIR
01-Fl4AAD-1
11.51
at the point when maximum rudder deflection is no longer sutlicient to maintain directional control. 11.4.1.4 Altitude. Net thrust is strongly dependent on altitude.For a constantthrottle setting,theasymmetric thrust is considerably higher at sea level than at higher altitudes.The FllO producesconsiderablymore thrust than the TF-30 powered F-14A. At maximum afterburner,the F 11O’sthrustat 10,000feetis equivalent to that of the TF-30 at sealevel. Bank Angle. Bank angle increases induceddragand,therefore,requireshigherthrustsettings to maintain level flight. The higher thrust setting demands increasedrudder deflection in a turn compared to thatrequiredin level flight at the sameairspeed.Turn direction, into or away from the failed engine,signiticandy affects rudder requirements. In straight-line flight, someamountofrudder deflectionwill berequired to offset the yawing moment from asymmetric thrustat zero bank angle. Five degreebank angle into the good enginewill introducea sideforcecomponentcountering the thrust asymmetry and thereby reducing the rudder requirement. 11.4.1.5
11.4.1.6
Asymmetric
Thrust
Limiting
System.
With operativeATLS, themagnitudeofany asymmenic thrustin MAX power will be reduced,therebyreducing the controlrequirementsto maintain the flight condition or reducing time to recover if a departurehas occurred. ATLS should be engagedfrom startup to shutdown. ATLS can be turnedoff if required for tactical considerationssuch as a single-engineACM bugout. 11.5
ENGINE
STALLS
AND FLAMEOUT
The Fl 10 enginesdemonstrateexceptional operability throughoutthe flight envelope.No “hung stalls” (similar to the classic TF-30 stall) have beenobserved in flight tests. Self-clearing “pop” stalls, which may producean audible“bang,” may occurabove35,000feet whenbelow 100knots in MAX power andusually occur in conjunction with an Al3 blowout. To datethesestalls haveresultedin no enginedamage,are self-clearingin approximately 1 second,and haverequiredno pilot action for engine recovery.However, throttlesshould be reduced to idle when subsonic (MIL when over 1.1 Mach) to minimize the possibility of engine damage during a11engine stalls. A supersonicstall may cause inlet buzz resulting in a rough,bumpy ride (+2.5 to -1g at 6 cycles per second).Inlet buzz shouldsubsidewhen deceleratingbelow 1.2 Mach. When supersonic,any wing drop tendenciesshould be controlled with lateral stick alone.
ORIGINAL
11-4
Medium
and High-Subsonic
Airspeed.
Above approximately 100 knots, sufficient controllability exists to control a maximum AB/stalled engine thrust asymmetry with operative ATLS. Aircraft responseto an engine failure is generally mild and is characterizedby slow buildup in yaw rate followed by slowly increasingrolloff in the samedirection as yaw. This responseis insidious since the aircrew will only notice the roll as it masks the yaw rate. Rudder is the primary control to offset yawing moment from asymmetric thrust.Higher airspeedsprovide more ruddereffectiveness and increase pilot ability to control yaw causedby asymmetric thrust. I,,,,,,,1 The use of lateral stick to offset the uncommandedroll causedby yaw from asymmetric thrust at high AOA will generateadverse yaw and aggravatethe yaw causedby asymmetric thrust. The result may be a yawing, rolling departure. Yaw rate increaseafter an enginestall or failure may be completely masked by roll if the pilot doesnot recognizethatthe enginemalfunction hasoccurredandthat aircraft motion is the result of that malfunction. Therefore, when anyuncommandedrolloff or yaw rateoccurs during maneuvering flight with maximum thrust, the pilot should reduceAOA, reduce thrust, counter with rudder,and avoid the use of lateral stick alone. 11.52 Low Subsonic Airspeed. Asaircmllspeed approacheszero, flight control effectivenessalso approacheszeroandmaximum thrustasymmetrycouldgeneratea rapid yaw rate buildup if correctiveaction is not taken. If thrust asymmetry is encountered,the pilot should immediately retard both throttles smoothly to IDLE, while maintaining neutral control.
Theseactions should prevent yaw rate buildup and allow the aircrafl noseto fall through and regain flying speed.After throttles are reduced,the pilot shouldlock his harnessin anticipation of a possibledeparture. piiF,,,,,,, Lossofthrust on oneenginewhile maneuvering at low airspeedmust be dealt with immediately sinceflight control effectiveness may be insufficient to counter the yaw rategeneratedby asymmetric thrust.
NAVAIR 01-FI4AAD-I
If both enginesarc stalled after retardingthrottles to IDLE, at leastone enginemust be securedimmediately to preventturbine damageandprovidemaximum potential for anairstart.If possible,securetheenginethat did not stall initially (the secondengineto stall). The cause of the first enginestall may not be known at this point; however, it is possible that the secondstall may have been induced during the throttle transient to IDLE. Leaving one engine in hung stall minimizes the likelihood of total loss of hydraulic and electrical power (emergencygenerator).See Chapter 14 for a detailed discussionof compressorstall and airstart emergency procedures. II.6
increaseaircraft basic weight. As aircraft weight is increased,more AOA is required to produce the same normal accelerationor g. As AOA increasesabove 12 to 14 units AOA, directional stability decreases.Therefore,externalstoresmay havea twofold effecton directional stability. Flight test has shown store loadingsup to and including 3C3 (four AIM-54s, two AIM-7s, two AIM-9s. andtwo tanks)canbe safely flown to the limits ofthe basicaircraftwith roll SAS offas long asthe cruise configurationmaneuveringlimits presentedin Chapter 4 are complied with. No significant changein flying qualitiesoccursbecauseof aft cg location.
HIGH ANGLE OF ATTACK FLIGHT CHARACTERISTICS
Severalcharacteristicsof the F-14 affect its behavior in high AOA flight. Among thesearedirectional stability, dihedraleffect, storesloading,the stability augmentation system,and maneuverflaps/slats. 11.6.1 Directional Stability. Directional stability is the tendencyof the aircraft to returnto trimmed, zero sideslip when disturbed.At low AOA, the aircraft exhibits positive directional stability and,ifsideslip is generatedby a control input or turbulence,the aircraft will returnto the trimmed, zero-sideslipcondition. As AOA increases,directional stability begins to drop and, for a clean aircraft, becomesnegativeat approximately 20 to 22 units AOA. At high AOA with negativedirectional stability, the aircrat?becomesmore difftcult to fly becausethe pilot must maintain the zerosideslipcondition with rudder inputs. 11.6.2 Dihedral Effect. Dihedral effect is the tendencyof the aircraft to roll in reactionto sideslip being generated.The F-14 exhibits positive dihedral effect throughoutthe positive-AOA envelope(tendingto roll away from sideslip)but negativedihedraleffect at negative AOA. This tendency is borne out by the aircraft responsefrom a rudderinput. When right rudder is applied from a straight-and-levelflight condition, the aircraft seessideslip from the left and so rolls to the right or away from the sideslip. Positive dihedral effect is a stabilizing influence in the areaof reduceddirectional stability (high-AOA flight). 11.6.3 Stores. As external stores are added to the aircraft,the high-AOA flying qualities degradebecause of a decreasein directional stability. Flight tests have shownthat no one store is significant by itself. Rather, eachstorecausesa small decreasein directionalstability that accumulatesas additional storesare loaded.In addition to degradingdirectional stability, externalstores II-5
Maneuvering with significant external storeloadingsshouldbe approachedwith cautionif thepilot is usedto maneuvering the cleanor nearly cleanaircraft, sincethe high-AOA flying qualities will be degradedfrom the clean aircraft. 11.6.4 Stability Augmentation System. The effect of the SAS on aircraft high-AOA flight characteristics rangesfrom minor to very significant. With the pitch SAS off, the nose will be slightly more sensitive during closecontrolled taskssuch asgunsighttracking. During large amplitude maneuvers, slightly higher AOA may be reached.In general,pitch SAS on or off will not significantly influence departurecharacteristics or recovety and no limitations concerning its use are necessary.Turning the yaw SAS off significantly decreasesthe departureresistanceof the aircraft. HighAOA maneuveringshould not be conductedwith the yaw SAS off. All discussionon high-AOA flight characteristicsin this section assumesthat the yaw SAS is engagedand operating.Roll SAS has the oppositeeffect. With the roll SAS on, maximum differential tail authority commandedby lateral stick (*12’) is nearly doubled from that commandedwith roll SAS off (i7”). Additionally, engagementof roll SAS enablesthe roll rate feedbackcircuitry, which will attempt to arrestaircraft roll commanded with no lateral stick inputs (as when rolling theaircraft with ruddersonly at high AOA) with differential tail oppositethe roll. This inadvertent crosscontrolalonecancausedeparturesfrom controlled flight. High-AOA maneuveringshall not be conducted with the roll SAS on. Unless otherwise stated,the following discussionassumesthe roll SAS is off. II.65 Maneuvering Flaps and Slats. Maneuver flaps and slats extensiondelaysbuffet onsetbelow 0.7 Mach, reducesthe intensity of the buffet, reducesthe effectsof adverseyaw at high AOA through increased ORIGINAL
NAVAIR
Ol-Fl4AAD-1
positive dihedral effect (roll causedby sideslip), and increasesthe sustainedg available. Above 0.7 Mach, buffet onset occurs prior to the maneuverflap/slat extensionthreshold,but oncethe maneuverflaps/slatsare fully extended,buffet is reduced.Maneuver flaps/slats will not extendabove0.85 Mach becauseof the wingsweep interlocks. Although maneuver flaps/slats increasethe severity of the wing rock between20 and 28 units AOA, overall departureresistanceof theaircraft is greatly improved (Figure 11-1, sheets I and 2). This wing rock may bc damped with rudders,but greater ditliculty may be encounteredwith maneuverflaps and slatsextended,particularly at low airspeeds.If this occurs,the wing rock may be dampedby neutralizingthe lateral andthe directional controls and momentarily reducing AOA to below 20 units. Since maneuverflaps and slat extensionand retmction is fully automatic, no changesin high-AOA flying techniquesare required. Maneuverflaps/slatsshouldbe utilized in the automatic mode from takeoff to landing.
Maneuveringwith inoperativemaneuvering flaps/slatsshouldbe approachedwith cautionifthe pilot is usedto maneuvering the aircraft with automatic flaps/slats, since the high-AOA flying qualities will be degradedfrom the automatic flap/slat aircraft. If maneuveringflaps/slatsare inoperative, maintain coordinated flight with lateral inputs and rudder. Lateral Control Reversal. Since roll control is provided by wing mounted spoilersanddifferential stabilators, the aircraft exhibits proverse yaw throughoutthe flight envelope(yaw in the direction of the lateral stick input). At high AOAs, several other aerodynamicandphysicalpropertiesoverpowertheproverseyaw and will yaw androll the aircraftoppositethe commandedinput. The primary contributor to this roll reversal is the negative directional stability at high AOAs (above 18 units at 0.9 Mach, andabove2 1 units at 0.15 Mach). The sequenceof eventscausingthis roll reversalis as follows (for the sakeof exampleconsider a left stick input): 1) The aircrafi initially rolls in the direction commanded(left); 2) as the aircraft starts to roll left, airstream’s direction relative to the aircraft changesCornthe verticalplane(planeofsymmetry) into letI sideslip (the definition of kinematic coupling); 3) becauseof the negativedirectional stability, the aircrafi reactsto theleft sideslipby diverging in yaw to the right, further increasingthe left sideslip;4) becauseof strong dihedral effect, the aircraft respondsto the left sideslip
11.6.6
ORIGINAL
II-6
and right yaw rate by reversing the roll to a right roll. ‘Ihe net effect in the eyes of the pilot is that at high anglesof attack, the aircraft respondsto lateral control inputs by feinting in the desireddirection andthen rolling and yawing opposite to the direction commanded. For this reason,generoususe of the ruddersis recommendedat high AOAs in order to roll the aircraft. Roll SAS on during high-AOA maneuveringwill aggravate the aircraft’s tendency for lateral control reversal and will result in cross-control inputs during rudder-only rolls. 11.6.7 Miscellaneous. Speedbrakeposition hasno effect on high-AOA flight characteristics.Wing-sweep anglesaft ofthe AUTO schedulereducebuffet intensity, but departureresistanceis reducedand more altitude is requiredfor dive pullout when recoveringafter a departure. Therefore,the AUTO sweep scheduleis best for high-AOA maneuvering. 11.6.6 Stall Characteristics. The lg level stall (maneuverflaps/slatsretracted)is characterizedby the onsetoflight airframebuffet at 12to 13units AOA. This increasesto moderate intensity at 15 units AOA with essentiallyno changein intensity at AOA ashigh as60”. Buffet is not a satisfactorycueto determineairspeedor AOA during high-AOA maneuvering.The reductionin directional stability is apparentat 20 to 28 units AOA and even small control inputs will producemild wing rock (+lO’ to 15”). Above 25 units AOA, lateral stick deflectioncauscsrolloppositestickdeflection.The stick should be centeredlaterally above 25 units AOA, and the rudderusedto maintain balancedflight. Ruddersare effectiveat controlling yaw andbank angleat all AOAs. Largerudderor lateral stick inputs producean increase in AOA assideslip increases.If the decelerationis continued to full aft-stick defiection, AOA is equivalentto approximately 45” to 55”. The cockpit AOA indicator pegsat 30 units AOA, which is equivalentto approximately 25” true AOA. Pitch attitude at stall is between IO0to 2O’abovethe horizon with no externalstoresand 10” to 15” below the horizon with maximum external load. Somelongitudinal porpoisingmay occur at full aft stick.
Maneuver flaps and slats delay buffet onsetto 13 to 14 units AOA and reduce the magnitude of buffet in high-AOA flight. Wing rock, commencing at 20 to 28 units AOA, is more severe(up to +25” AOB) andmore difftcult to damp with maneuverslatsextendedbecause of the increaseddihedraleffect. The cleanstall is definedas the applicationof full at? stick combined with ratesof descentup to 9,000 fpm. As much as 5,000feet is requiredfor recoveryfrom the fully developedstall.
NAVAIR Ol-FI4AAD-1
ROLL SAS ON FLAPS/SLATS AIRCRAFT CONFIGURATION: (2) FUSELAGE-MOUNTED (2) PYLON SPARROWS (2) PYLON SIDEWINDERS (2) ZBO-GALLON EXTERNAL DATE: DATA
AUGUST 1963 BASIS: FLIGHT
AUTO
PHOENIX
TANKS
TEST
0.3
0.4
0:5
0.7
0.6
0.9
0.6
1.0
MACH ROLL
SAS ON PROHIBITED
IN THIS
AREA
NOTE
REGlON
1
50 “/SEC
YAW
RATE
IN 5 SECONDS
WITH ROLL SAS OFF, FLAPS/ SLATS AUTO, ONLY REGION 3 TYPE DEPARTURES EXPERIENCED DURING FLIGHT TEST.
REGION REGION
2 3
50’ /SEC 50 “/SEC
YAW YAW
RATE RATE
IN 6 TO 10 SECONDS. GREATER THAN 10 SECONDS,
OR 50 O/SEC
YAW
RATE
NOT
OR LESS,
FLAT
SPIN
ENTRY
LIKELY.
REACHED.
Figure 1l-l. Lateral-Control-InducedDepartureAreas (Sheet 1 of 2)
11-7
ORIGINAL
NAVAIR 01.F14AAD-1
ROLL SAS OFF FLAPS/SLATS AlRCRA” CONFIGURATION: (2) FUSELAGE-MOUNTED (2) PYLON SPARROWS (‘2) PYLON SIDEWINDERS (2) 280-GALLON EXTERNAL DATE: DATA
AUGUST 1983 BASIS: FLIGHT
RETRACTED
PHOENIX
TANKS
TEST
63
0.4
0:s
019
0:7 MACH
Vm
UNCOORDINATED LATERAL PROHIBITED IN THIS AREA
CONTROL
INPUTS
REGION
1
50 a /SEC
YAW
RATE
IN 5 SECONDS
REGION REGION
2 3
50’ /SEC 50 O/SEC
YAW YAW
RATE RATE
IN 6 TO IO SECONDS. GREATER THAN 10 SECONDS,
OR 50 O/SEC
YAW
RATE
NOT
OR LESS,
FLAT
SPIN
ENTRY
REACHED.
Figure 1l-l. Lateral-Control-InducedDepartureAreas (Sheet2 of 2)
ORIGINAL
11-8
LIKELY.
NAVAIR 0%FMAAD-I
11.6.9 Vertical Stalls. If the aircraft is allowed to decelerateto zero airspeedin a vertical or nearvertical attitude,it will slide backwardsmomentarily, thenpitch over(usuallybackwards)to a nearvertical dive. Aircraft motions during the initial fall will be predominantly inertial with randompitching andyawing asthe aircraft accelerates.After the initial nosedownpitch, theaircraft maypassthroughtheverticaltonearlevelflightattitude, yaw in one direction, and then return to a vertical dive attitude.This may occur more thanonce.This tendency is more pronouncedat aft wing sweeps,but canusually be controlled with longitudinal control inputs. Some recoveriesmay be accompaniedby large random yawing and/or rolling motions that will generally dampen without pilot action asthe aircraft accelerates.The controls shouldbe releasedwhen airspeeddecreasesbelow 100 knots in the vertical stall to prevent inadvertent inputsthat may lengthenrecoverytime. Control inputs shouldnot be applieduntil the aircraft is nosedown and accelerating.Rudder and lateral stick are also effective in dampingoscillations oncethe aircraft is noselow and accelerating.The aircraft is very responsiveto longitudinal stick inputs at all ADA at speedsabove 100knots.
In an upright departureat approximately 50” per second yaw rate or less, if full forward stick is applied to reduceAOA, the aircraft will generallyrecover.At over 50” per secondyaw rate, lateral/directionalcontrol inputs (rudder opposite yaw, lateral stick into yaw) are requiredto recover the aircraf?.If theseinputs arenot made,theyaw ratewill continueto build andthe aircraft may enterthe flat spin.The time to reach50” per second yaw rate after control input or engine failure is very critical. If 50” per secondyaw rate is reachedin 5 seconds or less, the pilot may not have enough time to neutralize,analyze,and apply recoverycontrols before the aircraft enters a flat spin dependingon type and severity of departure,altitude and AOA at entry, and aircraft configuration.The time to reach50’ per second yaw rate for variousaircraft configurationsasa resultof lateral stick, rudder,or cross-controlinputs is presented in Figures 1l-l through 11-3.Generally,the most severe departuresare induced through the differential tail, which is commandedby lateral stick and/or roll SAS inputs. Rudder inputs, asymmetric thrust, and inertia coupling can causeor contribute to the severity of departures.
Refer to paragraph11.52, Low-Subsonic Airspeed for proceduresto follow in the eventof an enginestall. Refer to Chapter 14 for vertical stall recovery procedures.
11.7.1.1 Mach and AOA Effects. As Mach number increases,tlight-control-induceddeparturesusceptiiility andseverityincreases.Generally,as AOA increases,the severity of the departureincreases.For example, a lateral stick input at 0.9 Mach, 30 units AOA, will produce a more violent departurethan the same input at 0.9 Mach, 20 units AOA. The one exception is rudderinduced departures.As AOA is increasedto about30” (over 30 units AOA), rudder effectiveness decreases asthe rudder is washedout and rudder-induceddepartures become less severe.
During flight tests,vertical stalls in maximum afterburnerpower sometimesresulted in afterburnerblowouts on one or both enginespossibly followed by pop stallsthat may or may not be audibleto the pilot. All the stalls were self clearing with no tendency for EGT to rise out of limits. As the aircraft recoveredandairspeed increased,the afterburnerrelit if thethrottle remainedin the afterburnerdetent.When practicing vertical stalls, basic enginepower settingsare recommendedto avoid inducing engine afterburnertransientsthat have an unknown effect on enginelife. Maximum enginestall margin for the F 110is obtainedat IDLE power. Il.7
DEPARTURE FROM CONTROLLED FLIGHT
11.7.1 General. Although the F-14 is an honestaircraft with moderatedepartureresistance,departurescan be inducedby largeor sustainedcontrol inputs thatgenerally feel unnatmal to the pilot. Since the aircraft has an essentially unrecoverableflat-spin mode, yaw rate must be controlled before it can build and the aircraft transitionsto the flat-spin mode. In general,departures are characterizedby increasing yaw rate.with oscillations in roll andyaw. Yaw rateis maskedby the roll rate and is not evident to the pilot until approximately 90” per secondyaw rate (2 “eyeball-out” g) is reached. 11-9
11.7.1.2 Maneuver Flaps/Slats. Extended maneuver flaps and slats significantly decreasedeparture susceptibility and severity through increaseddihedral effect, ascan be seenby comparingFigure 1l-l, sheets land2. 11.7.1.3 External Stores. As external stores are added,departuresusceptibility andseverityincrease.No onestoreis significant in andof itself. Rather,eachstore causesa small degradationin flying qualities that accumulates asadditional storesare ad&d. In general,fitselage-mounted stores have less effect than pylon- or nacelle-mountedstores. 11.7.2 Lateral-Stick-Induced Departures. Uncoordinatedlateral stick inputs with roll SAS off and maneuver flaps and slats extendedgenerally produce benigndeparturesthat areeasily recoverable.However, when maneuver slats are retractedor roll SAS is on, departurescanbe violent. ORIGINAL
NAVAIR Ol-F14AAD-1
ROLL SAS ON FLAPS/SLATS AIRCRAFT CONFIGURATION: (2) FUSELAGE-MOUNTED (2) PYLON SPARROWS (2) PYLON SIDEWINDERS (2) 28O-GALLON EXTERNAL DATE: DATA
AUGUST 1983 BASIS: FLIGHT
AUTO OR RETRACTED
PHOENIX
TANKS
TEST
013
0:4
0:6
0:5
0:7
0.8
0.9
1.0
MACH ROLL
SAS ON PROHIBITED
REGION
1
50 O/SEC
YAW
RATE
IN 5 SECONDS
REGION REGION
2 3
50 O/SEC 50 “/SEC
YAW YAW
RATE RATE
IN 6 TO 10 SECONDS.
MORE,
OR 50 O/SEC
OR LESS,
IN 11 SECONDS
OR
YAW
REACHED.
RATE
NOT
FLAT
SPIN
Figure 1l-2. Rudder-InducedDeparhueAreas
ORIGINAL
II-10
ENTRY
LIKELY.
NAVAIR
Ol-F14AAD-1
ROLL SAS OFF FLAPS/SLATS AIRCRAFT CONFIGURATION: (2) FUSELAGE-MOUNTED (2) PYLON SPARROWS (2) PYLON SIDEWINDERS (2) 28%GALLON EXTERNAL DATE: DATA
AUGUST 1983 BASIS: FLIGHT
AUTO OR RETRACTED
PHOENIX
TANKS
TEST
35
30
25
0
0.3
0.5
0.4
0.6
0.8
0.7
0.9
1.0
MACH
Fz22z4
CROSS
CONTROL YAW
INPUTS RATE
PROHIBITED
IN 5 SECONDS
IN THlS
REGION
1
50 O/SEC
REGION REGION
2 3
50’ /SEC YAW RATE IN 6 TO 10 SECONDS. 50” /SEC YAW RATE IN 11 SECONDS OR MORE, OR 50’ /SEC YAW RATE NOT REACHED.
OR LESS,
REGION
4
NOT
AREA FLAT
SPIN
ENTRY
LIKELY
TESTED
Figure 11-3. Cross-Control-Induced
11-11
Departure Areas
ORIGINAL
NAVAIR 0%FlUAD-
inputs with the roll SAS on can causevery violent departuresbecausethe roll SAS commandsdifferential tail oppositethe rudder input to arrestroll rate even if the stick is centered.In the high-Mach, high-AOA area,flat spin entry could occur very abruptly and quickly if the aircraft is departedwith roll SAS on (Figure 11-2).
Flight test of uncoordinatedlateral-stick-induceddepartureshave producedyaw rates as high as 70’ per secondin 3 secondswith roll SAS on and flaps/slats AUTO. In the high-Mach, high-AOA area, flat spin entry could occur very abruptly and quickly (Figure 1l-l, sheet1).Abrupt, violent departuresin this areacan be eliminated or reducedto a low peak yaw rate with more easily recoverabledeparturesby coordinatinglateral stick inputs with rudderin the samedirection.
Subsonicmaneuveringwith the roll SAS on shall not be conductedabove I5 units AOA. Subsonic maneuvering with roll SAS on shall not be conductedabove 15units AOA.
Unintentional lateral control inputs can changethese characteristicsdrastically. During high-Mach rudderinputs, cockpit lateralaccelerationis such as to favor unintentional lateral stick inputs. In flight test, as little as l/2-inch lateral stick (roll SAS otl) oppositea lllrudder input combinedto producea 50“ per secondyaw rate in 3 seconds.To avoid unintentional cross-controls,small coordinatedlateral stick should be used when maneuvering with rudderat high Mach (aboveapproximately 0.7 Mach), There is no significant difference in departure characteristicsbetweenthe maneuverflap and slat extendedandretractedconfigurationsfor rudderinputs.
When maneuverflaps/slatsareretractedandroll SAS engaged,departureresistanceis severelydegradedand high yaw ratescanbe attainedvery quickly. In the highMach, high-AOA area,flat spin entry can occur very abruptly and rapidly. In flight tests,72’ per secondwas reachedin as little as 2.0 secondswith lateral g in the cockpit over 1.5g.The rapidity with which the aircraft departscan be very disorienting and could possibly delay recovery. (WARNING) When automaticmaneuveringflaps/slatsare not operating,uncoordinatedlateral control inputs shall not be usedin the areaindicated in Figure 11-1,sheet2. Even with maneuvering flaps/slats in AUTO, the flaps/slatswill be retractedabove 0.85 Mach. Lateral stick inputs occurringabove0.85Mach produceviolent depatturesinFigurell-l,sheet2,butnotinFigumll-1, sheet1, because,as the aircraft deceleratesbelow 0.85 Mach, the maneuverflaps/slatsextend.
11.7.4 Cross-Control-Induced Departures. Sustamed cross-controlsproducejerky, ratchetiugroll and yaw ratesand unpredictableaircraft motion. Generally, as Mach number is increased,fewer ratchetswill occur prior to the steadyyaw rate‘increase.Above 0.5 Mach, theaircrafimotion is very violent andunpredictable,and no ratcheting motion may occur prior to a high yaw acceleration(Figure 1l-3). Below 0.5 Mach, if the roll SAS is off, cross-controlscanbe safely used.The pilot must realize, however,that a cross-controlmaneuveris an intentional departureof the aircraft that produces30” to 40” per secondyaw ratein this low-Mach regime. An enginestall or failure during such a maneuvermay aggravatethe departureand must be reactedto immediately to recoverthe aircraft.
Note Lateral stick inputs should be avoidedwhen maneuvering at high AOA except when cross-controllingat low Mach or coordiiting with rudderat high Mach. 11.7.3 Rudder-Induced Departures. Rudder inputs with the roll SAS off producedabrupt, higb-yaw rate accelerationsbut generally did not exceed50° per secondyaw rate in 10 secondsof control application iu flight test because,as the AGA increases,the rudder washesout and the yawing moment decreases,Rudder ORIGINAL
Cross-controlinputs shall not be usedabove 0.5 Mach when above 10units AOA. Crosscontrols at supersonic speedsshall not be used. 11.7.5 Asymmetric-Thrust-Induced Departures. Asymmetric-thrust-induced departures are similar to those induced by the flight controls. At high
11-12
NAVAIR
altitude (greaterthan 20,000 feet), asymmetric thrust resultsin a mild departurecharacterizedby mild roll and yaw ratesinto the dead engineif the airspeedis above 100knots. The yaw rate is usually masked by the roll rate. If no pilot action is taken, the aircraft usually stabilizes at somemoderateyaw rate from which recovery is easily accomplished.On occasion,the yaw ratewill continueto increaseslowly, taking 20 secondsor more to reach50’ per second.At lower altitudes(15,000feet) yaw ratemay reach50’ persecondin 10secondsbecause of increasedtrust asymmetry. Departuresinduced by asymmetricthrustalonebelow 100knotsorwhenairspeed dmps below 100knots in the departurearecharacterized by mild roll anda smoothgradualincreasein yaw ratethat will attainvalueswell over 50” per second. Thepilot’s naturaltendencyis to opposeuncommanded ml1 with lateral stick, but this aggravatesthe departure, particularlyif roll SAS is on. During maneuveringflight, uncommandedroll shouldbe counteredby rudderand a reductionin AOA. Seeadditionaldiscussionson asymmetric thrustflight characteristicsin this section. Note Departurecharacteristicsbecauseofasymmettic thrustwhile in afierbumerare comparable to anF-14AQ’F-30aircraftif ATLS is utilized and operative. Without ATLS operating,a maximumafterbumer/stalledengine condition at high AOA will result in a more dynamic departurethantheF-14A/TF-30 aircraft. Accelerated
full rudderfollowed by full coordinatedlateral and at? stick producedviolent coupleddepartureswith up to 66’ per secondyaw ratein lessthan2 seconds.Yaw ratesof this magnituderequire prompt positive recoveryinputs by the pilot. External storescontributeto the severityof the departureby decreasingdirectional stability and increasinginertia. pi&-Avoid high-rate, multiple-axis motion becauseof possibleviolent departures. 11.7.6 Departure Recovery. Beforerecoverycontrols areapplied,thecrew mustanalyzeflight conditions to determinethe departuremode entered.The turn nee die indicatesonly the direction of yaw and not magnitudeof yaw rate,since it pegsat 4’ per secondyaw rate. An upright departureis indicatedby AOA peggedat 30 units; an inverted departureby AOA of 0 units. Generally, increasingairspeedis indicative of a recoveryin progress,as is aircraft reactionto pilot control inputs. Upright Departure Recovery. Recovery from upright departuresis positive and generallyrapid. The high control power that allows the pilot to depart theaircraft alsoenableshim to recoverwhenthecontrols areproperly applied and sufftcient altitude is available for recovery.
11.7.9
Accelerated departuresareinitially characterizedby a rapid increasein lateral accelerationbut may become violently oscillatory aboutall threeaxes.Testshaveshownaircraft rates in excessof 120’ per secondin roll and 70” per second in yaw. Pitch rates oscillate up to +30” per secondand lateral accelerationoscillates up to +O&. These oscillationsmay causepilot disorientation,andproperrecovery controls may not be obvious. If this occurs, the properresponsewould be to neutralizeruddersand lateral stick, apply forward longitudinal stick, and lock the shoulderharness.Recovery indications should become apparentwithin two turns. 11.7.6
Ol-Fl4AAD-1
Departures.
11.7.7 Coupling. Coupling occurswhen motions in more than one axis interact. The F-14, like all highperformance aircraft capable of producing high-rate, multiple-axis motion, is susceptibleto coupling. Highrate, multiple-axis motions, particularly at high AOA, can produce violent coupled departures.During flight test,a gunsdefense/collisionavoidancemaneuverusing
11-13
Successfulupright departurerecovery dependson recognition of the departurefrom controlled flight, application of appropriate recovery control inputs, and subsequentrecognition of when the aircraft hasrecovered.Departurefrom controlled flight is usually characterized by an uncommandedroll/yaw or an abrupt noseslice or pitch. Common examplesofthesemotions are lateral control reversal at high AOA, or uncommandedroll andyaw resulting from asymmetric thrust. When appropriaterecovery controls are applied and maintainedas discussedin detail below, recoveryfrom an upright departurewill be indicated by decreasing yaw rate, decreasingAOA, and increasing airspeed. The decreasein AOA and increasein airspeedduring recovery will be evident to the pilot by the aircraft responseto control inputs.The aircraft may stoprolling becauseof sideslip and begin to roll becauseof differential tail commanded by the pilot for recovery from higher yaw ratedepartures.A nosedrop and associated unload may occur,and the roll ratemay increaseunder theseconditions.
ORIGINAL
NAVAIR 01-F14AAD-1
tail commandedby the pilot for recovery. A nosedrop and an associatedunloadmay occur. Theseare indications of a positive recovery in process.
Note The most important action of any upright departure recovery is reducing the AOA. This is enhancedby timely application of forward stick andcounteringthe yawing motion of the aircraft. If the AOA is peggedat 30 units or increasingrapidly, smoothly apply forward stick asrequiredto reduce AOA. Full fonvEd stick may be required. In anupright departurewhere less than 50” per secondyaw rate is observed,if full forwardstick is appliedto reduceAOA, throttles retardedto idle, and rudderis appliedopposite the yaw direction, the aircraft will generallyrecover,as shown in Figure 1l-4. Cockpit indications of yaw direction are the pilot’s turn needle and the spin arrow displays on the TID and MFD (Figure 1I-5). Refer to paragraph11.7.9.1for a detailed discussionof spin arrow displays. An additional noninstrumentindication of yaw direction is the roll direction. In an upright departure,the aircraft yaw rate is the samedirection asthe roll rate. Typically, roll rateis much more evidentto the pilot than yaw rate. The turnneedleandTlD spinam3w may be backedupby referencingthe roll direction. Reducing thrust asymmetry during recovery by retardingthethrottlesto IDLE removesany possiblethrust asymmetry, placesthe enginesin the region of greatest stall margin, and reducestime to recover. Maintaining a thrustasymmetry,particularly with thegoodenginein MAX A/B, will delayrecoveryat high altitudesandmay preventrecoveryat lower altitudes since flight controls may not be powerful enoughto overcomeasymmetric thrust. Asymmetric thrust has its greatesteffect upon upright departurerecoveryat low airspeed,where flight controls are not as effective, and low altitude, where asymmetric enginethrust is the largest. If application of forward stick to reduceAOA and rudderoppositeturn needle/yawdoesnot result in positive recoveryindications,it is likely that 50” per second yaw rate has been exceededand that lateral stick is required for recovery. In this case,optimum recovery controls are full rudder oppositethe yaw rate/turnneedle, full lateral stick into the yaw rate/turnneedle,with asmuch forward stick aspossiblewhile maintaining full lateralstick. Thesecontrolswill recoverthe aircraftout to a yaw rate of approximately 100” per second(Figure 11-4). Yaw rates of 100” per secondor more can be identified by sustainedeyeball-outg. During recovery from departureswhere yaw rates of 50” to 100° per secondareexperienced,the aircraft may stop rolling becauseofsideslip andbegin to roll becauseof differential
ORIGINAL
Il.14
Oncerecoveryindicationsfrom a low yaw-ratedeparture (lessthan 50” per second)are verified, the forward longitudinalstick shouldbe relaxedto maintain 17 units AOA, which will minimize altitudeloss for recoveryand avoid negativeg as airspeedbuilds. Rudder shouldbe neuhlllizedas rotation stops. As recovery from higher yaw-rate departuresis indicated, the lateral stick that was held into the turn direction should be neutralized, and the forward longitudinal stick should be relaxedto minimize altitude loss for recovery and avoid negative g as airspeedbuilds. The aircraft is very responsiveto longitudinal stick inputsat all AOA at speedsabove 100 knots. Pullout shouldbe accomplishedat 17units AOA. Lateral stick and rudder may be used to counter any remaining roll and yaw oscillations. Centrifugetestsindicatethepilot beginsto senseeyeball-out g at about 2g, which occurs at approximately 90” to 100” per secondyaw rate. If sustainedeyeballout g is sensed,it is likely that 100’ per secondyaw rate has beenexceededand optimum recovery conrrolsare full rudderoppositethe yaw rate/turnneedle,full lateral stick into the turn needle,as much aft stick as possible (while maintaining full lateral stick) and roll SAS ON. Roll SAS ON provides the pilot with the greatestpossibility for recoveryifthe yaw rateexceedsapproximately 150” per second. Refer to Chapter 14 for upright departure/flat spin emergency procedures. Recovery controls should be applied and maintaineduntil recovery is indicated,ejection altitude is reached,or increasing eyeball-outg threatensaircrew incapacitation. As yaw rate decreasesduring recovery from very high yaw-rate departures(above 100” per second,or where sustainedeyeball-out g is sensed),the aft stick and full lateral stick recovery controls result in somewhat different recovery characteristics.If theserecovery controls are maintained below a yaw rate of approximately 100°per second,large AOA oscillations may be experiencedas well as oscillations in roll and pitch. The overall recovery may feel very rough and oscillatory. If theserecovery controls are maintained below approximately 80’ per second,recovery will be delayedandthe potential for yaw ratereversalandprogressivedeparturein the opposite direction is greatly increased.For this reason, the control stick which was maintained at? into the turn should be moved forward and into the turn when sustainedeyeball-out g is no longer sensed. Further recovery can then be accomplished as previously described.
NAVAIR 01.FMAAD-1
AIRCRAFT CONFIGURATION: (2) FUSELAGE-MOUNTED (2) PYLON SPARROWS (2) SIDEWINDERS (2) 290-GALLON EXTERNAL DATE: DATA
MAY BASIS:
1995 FLIGHT
F-14 DEPARTURE
RECOVERIES
PHOENIX STICK FORWARD FULL LATERAL STICK INTO TURN RUDDER OPPOSITE
TANKS
TEST
STICK FULL INTO AND AFT RUDDER OPPOSITE ROLL SAS OFF
40
STICK
FORWARI RUDDER OPPOSITE
50
0
100 YAW
RATE
150 - DEGlSEC
REGION
t
STICK - FORWARD/NEUTRAL RUDDER-OPPOSITE TURN
REGION
2
NO RECOVERY: STICK - INTO
REGION
3
TURN
200
LATERAL NEEDLE/YAW
NEEDLE,YAW
SUSTAINED EYEBALL OUT G SENSED: STICK FULL INTO AND AFT, RUDDER OPPOSITE REQUIRED FOR RECOVERY
Figure 1l-4. F-14 DepartureRecoveryDiagram
II-15
ORIGINAL
NAVAIR 0%F14AAD.1
pi&-I
l
Maintaining aft and lateral stick recovery controls below approximately 100” per second yaw ratecan result in large AOA excursionsandoscillationsin roll andpitch, which may complicate recognition of recovery t?om an upright departureand delay recovery. Maintaining these controls below approximately 80” per second will delay recoveryand increasethe potential for yawratereversalandprogressivedeparturein the oppositedirection.
l
11.7.9.1 Spin Arrow Displays. At yaw rates greater than 30” per second,the spin arrow displays (Figure 11-5)havepriority andoverrideall otherdisplay formats on the MFDl and the TID. MFD2 and MFD3 display theVDI format. When a yaw rateexceeding30” per secondis detected,the current format on thesedisplays is overriddenby the spin indicator format. In this format, the spin arrow points in the direction of the spin. Above the spin arrow in the MFD format, vertical tape displays provide airspeed,altitude, and AOA indications. If required,an indication of left or right engine stall is provided. A moving caretshowsyaw rate from 30” to 180”per second.If theyaw rateexceeds180”per second,the caretis pegged.
l
l
Note IfMFDl is not operating,the spin indicator format is displayed on MFD2. If INS and SAHRS failures occur while the spin arrow format is displayed, the pointer on the yaw-rate scaleis removed from the MFD, the spin arrow is frozen, and an “X” is superimposed over the spin arrow. The airspeed,AOA, and altimeter scales are not obscured(Figure 1l-6)
At yaw ratesover 30” per second,the TID display is blanked and the spin arrow appearspointed in the direction of yaw. If the yaw rateexceeds90” per second, the spin arrow will flash at a 4-times-per-secondrate. A fixed scale from 30° to 110” per secondincreasing in the direction of yaw in increments of 20 will be displayed below the spin arrow. A diamond will be positioned above the numbers to indicate the existing yaw rate. For yaw rates in excessof 110” per second, the diamond will travel past 110andbepositioned over a + sign. ORIGINAL
Note The primary referencefor the spin arrow, the INS, is valid for yaw ratesup to 300° per second; the backup reference, the SAHRS, is valid for the sameyaw rates. If INS and SAHRS failures occur while the spin arrow format is displayed, the pointer on the yaw rate scale is removed from the TID anda breakawayX is superimposedover the spin arrow display (Figure 1l-6).
11.7.10 Flat Spin. The only true upright, fully developed spin in the F-14 is the flat spin. It is recognized by the flat aircraft attitude (approximately 10” nose down with no pitch or roll oscillations), steadily increasingyaw rate, and high-longitudinal acceleration (eyeball-outg). It may developwithin two to threeturns following a departureif yaw is allowed to accelerate without rapid, positive stepsto effect recovery. High yaw-rate departuresare usually induced by aerodynamic controls and possibly aggravatedby a thrust asymmetry.The aircrafi may first enteranerectoscillatory spiral as airspeedrapidly decreases.Frequenthesitations in yaw and roll may occurasyaw rate increases: The turn needle and the spin arrow are the only valid indications of yaw and spin direction as they always indicate turn direction correctly, whether erect or inverted. AOA will peg at 30 units, and airspeedwill oscillate between0 and 100knots. The aircraft may also departby entering a coupledroll where yaw rate may build up without being noticed,to thepoint thatwhenroll stops,yaw rate is sufficient to sustaina flat spin. A large sustainedthrustasymmetry,at low airspeed(particularly at low altitude),may alsoproducesufficient yaw rate to drive the aircraft into a flat spin if properrecoverycontrols are not used. In all instances,recovetyshouldbe accomplishedby promptapplicationof departmerecovery proceduresto reduceAOA andcontrolyaw rate. Regardlessof the method of entry, once the flat spin has developed,the flat aircraft attitude (10” nose down), steadily increasing yaw rate, and buildup of longitudinal-g forces not accompaniedby roll and/or pitch rates will be apparentto the flightcrew. AOA will be peggedat 30 units, yaw ratewill be fast (ashigh as 180” per second)and altitude loss will be approximately 700 feetperturn. Longitudinal acceleration(eyeball-out g) at the pilot’s stationwill be 5.5 to 6.5g and at the RIO’s station, 3.5 to 4.5g. Time betweenaircraft departureand flightcrew recognition of a fully developed flat spin dependsupon the nature of the entry (accelerateddeparture,low-speed stalled engine,etc.). The time betweenrecognition of a flat spin andbuildup of incapacitating longitudinal-g forces is dependent
11-16
NAVAIR
Ol-F14AAD-1
TID
SPlN ARROW
YAW RATE CARET
“.FS”“.AC9
Figure 11-S. Spin Arrow Displays 11-17
ORIGINAL
NAVAIR 0%Fi4AAD-1
Figure 11-6. MFD-I/TID Right Spin Display (INS and SAHRS Failed) ORIGINAL
11-18
NAVAIR 01-Fl4AAD-1
upon aircraft loading, thrust asymmetry, flight control position during spin entry, locked or unlocked harness, tightnessof the lap restraints,and flightcrew physical condition and stature.Test data indicate that following recognitionof a flat spin, the pilot may be able to maintain antispin controls for IS to 20 seconds(approximately 7 to 10 turns) but may severelyjeopardize his ability to eject becauseof the incapacitationthat occurs as the g forces build. ConsistentsuccessfulF-14 flatspin recovery procedureshave not been demonstrated, therefore,once the aircraft is confirmed to be in a flat spin, the flightcrew should eject. This decision should not be delayedonce the flat spin is recognized.
Dihedral effect is negativeat negativeAOA. Therefore, a right rudder input producesright yaw, but left roll. This feels naturalto the pilot in inverted flight, and enablesraising a wing with opposite rudder when inverted.At negativeAOA, oil pressurewill indicatezero and illuminate the OIL PRESS caution light andMASTER CAUTION light. pii-,,,,,,, Zero- or negative-g flight in excess of 10 secondsin afterburneror 20 secondsin military power or less depletesfuel feed tanks (cells 3 or 4), causing flameout of both engines.
It is importantto understandthat longitudinal g forces canbepresentin accelerateddeparturesfrom controlled flight and ejection initiated solely becauseof longitudinal g forces is premature. To precludeprematureejection from a recoverableaircraft, verify that the aircraft is not rolling or oscillating in pitch or is not in a coupled departure.If any of these characteristicsare evident, thena flat spin hasnot developedanddeparturerecovery proceduresshould be continued. 11.7.11 Negative AOA Departures. During flight test, a negativeAOA departuremode has beenexperienced.Cross-controlinputsin the low to medium Mach (lessthan0.6 Mach) andlow to medium AOA (AOA less than25units) arearesultedin rapid transitionto negative AOA with up to 2.5 negativeg. The motion was very disorienting,uncomfortable, and confusing. Neutralizing controlswould producea recovery from this departure; useof aft stick would speedrecovery.
Excessive negative-gmaneuveringcan also exceed the aircraft lift limit and causedeparture.Aircraft motion following departurewill be very erratic and disorienting; any induced yaw rate can result in upright or inverted spin entry. Aircraft at high grossweights with externaltanksandstoresrequirearelatively minornegative load to induce this type of departure.
Negative-g maneuvering at high gross weights shouldbe avoidedbecauseof a high probability of departure.
Use of cross-controlin the low to medium Mach (less than 0.6) and low to medium AOA (AOA lessthan25 units) may result in negative-gdepartures. 11.7.12 Inverted Stall/Departure. As in normal stall approaches,there is no clearly defined inverted stall. A moderaterate application of full forward stick in inverted flight results in a negative AOA of about -300.
Dynamic forward stick inputs of moderate ratemay exceedthenegative-glimit of-2.4g. IndicatedAOA will show zerobeyondabout -5” true AOA.
Recovery from an inverted stall is performedby applying full aA stick, while neutralizing lateral stick, to return to positive-g flight. Recovery from negative-g conditions will usually occur immediately. Return to level flight can then be performed from the resultant nosedownattitude by rolling erect with rudder and/or lateral stick and pulling out at 17units AOA.
11.7.13 Inverted Spin. Aninvertedspinmaybeencounteredifthe aircraft unloadswhile thereis a yaw rate present.In flight tests,the invertedspin hasbeencaused by holding full forward stick while inverted, applying full rudder,and holding this combination through360° of roll. Pro spin controls neednot be held to maintain the aircraR in a spin. The inverted spin is primarily identified from cockpit instrumentsby lessthan zero g andan AOA ofzero units. Sincetheinvertedspinis quite disorienting, spin direction must be determinedby observing the turn needledeflection and spin arrow.Altitudelossduring the invertedspin is 800 to 1,800feetper turn andtime per turn is 3 to 6 seconds.Nose attitudein the inverted spin is approximately 25Obelow the hotizon. Warning of possible inverted spin usually occurs
11-19
ORIGINAL
NAVAIR
01-Fl4AAD-1
sufficiently in advancefor the aircrew to takecorrective action. Warning is usually very noticeablein the form of a nosedown pitch (negative g) with a yawing and possiblerolling motion that is quite uncomfortableto the aircrew. 1n the fully developed inverted spin, rudder oppositeyaw/turn needleis the strongestantispin control. Aft stick is a strong antispin control during the incipient spin phaseand a weak antispin control in the inverted spin. In the absenceof asymmetric thrust, the antispin control inputs will recover a fully developed invertedspinwithin oneturn.Lateral stick oppositeyaw is an antispin control, however,it is not included in the recovery proceduresbecauseoppositerudder recovers the aircraft so effectively. If oppositerudderand lateral stick were used,the recoverywould occur very rapidly anda postrecoverydeparturein the directionofstick and rudderwould be highly probable.Refer to Chapter 14 for inverted departure/spinemergencyprocedures.
flight. Recoveryto level flight requitesabout 1,000feet of altitude.
11.8
11.8.3
TAKEOFF AND LANDING CONFIGURATION FLIGHT CHARACTERISTICS
Duringdecelerationinalevel, lg stall approach,light buffet starts at about 19 units AOA. Buffet doesnot significantly changethereafteras the AOA is increasedandprovidesno usablestall waming. A reductionin stick force is felt between24 and28 units AOA. At 25 units AOA, divergentwing rock and yaw excursions define the stall. Sideslip angle may reach 2Y, and bank angle 90” within 6 secondsif the AOA is not lowered.Above 24 units AOA, lateral stick inputsproduceconsiderableadverseyaw.Largesideslip angles,whetherproducedby rudderor lateral stick, are accompaniedby a noserise, which may requireforward stick application to preventthe AOA from increasingto 28 units. Extending the speedbrakesslightly aggravates the stick force lightening at 24 units AOA but improves directional stability significantly, reducing the wing rock and yaw tendency at 25 units AOA. Stall approachesshouldnot be continuedbeyondthe first indication of wing rock. When wing rock occurs, the nose should be lowered and no attempt should be made to counter the wing rock with lateral stick or rudder. Stalls with the landing gearextendedand flaps up are similar to those with flaps extended. Buffet starts at 16 to 18 units AOA and wing rock at 26 units AOA. Figure 11-7 shows stall speedsfor standardday temperatureat sealevel with slats/flaps extendedand gear down. 11.8.1
Normal
Stalls.
Stall Recovery. Stall recovery is easily accomplished by relaxing aft stick force and easing the stick forward, ifnecessary,to decreaseAOA to lessthan 16 units. Maintain 15 to 16 units AOA and stabilized military or afterburnerthrust during recovery to level
11.8.2
ORIGINAL
II-20
Avoid high-rate, multiple-axis motion becauseof possible violent departuresand engine stalls.
Use of cross-controlin the low to medium Mach (less than 0.6) and low to medium AOA (AOA lessthan 25 units) may result in negative-gdepartures. Asymmetric Characteristics
Thrust
Flight
11.8.3.1 Takeoff Configuration. Afterburner takeoffs are prohibited specifically because of controllability concernsin the eventof an enginefailure during takeoff. An enginefailure during a MIL power takeoff with the FllO enginewill produceessentiallythe same characteristicsasa TF-30 poweredaircraft with a MAX A/B-idle thrust asymmetry (MCBs open). The highcompressionratio of the compressorsectionwill result in very rapid spooldown during an engine failure and rotor lock can be anticipatedwithin severalsecondsof the enginefailure. An enginefailure in the takeoff configuration ,producesrapid nosemovement in the diiction of the failed engine.The pilot’s first impressionis usually that the aircraft will departthe runway. Even if the aircraft’s heading swerve is corrected,the aircraft may continue to skid sidewaysacrossthe runway. The wing on the sideofthe failed enginemay rise 10’ to 15”. This is noticeableto thepilot, but easily correctedwith lateral stick. If the airspeedis high enough to allow correctionof the headingswerve,all lateral drift can be stopped.
Aircraft controllability during asymmetric thrust takeoff emergenciesis influenced by rudder position, thrust asymmetry,airspeed,nosewheelsteering,andpilot reactiontime, with pilot reactiontime beingthe most critical factor. During the takeoff roll, rudder control power increasesasthe airspeedincreases,thus improving the pilot’s ability to control an asymmetric thrust condition. Below minimum control groundspeed (VMCG),insufficient ruddercontrol powerwill beavailable(nosewheelsteeringOFF), andlargelateralrunway deviations will be experiencedif the takeoff is continued. The lower the airspeedat which the asymmetry
NAVAIR Ol-F14AAD-1
F-14A + /D
DATE: DATA
FUELm/am: JP-5w-4. JP-a, F”EL DENSITY:6.8 ,o.s, 6.7, lblgal
JANVARY ,990 BASIS: ESTMATED
Figure 11-7. Stall Speedsfor Wing Rock at 25 Units AOA II-21
ORIGINAL
NAVAIR
Ql-FWAAD-I
THRUST ASYMMETRY Military - IDLE
FLAP POSITION Extended
VMCG SPEEDS MAXIMUM 50 FT LATERAL DEVIATION 132 to 138 knots
Militaty - IDLE
Retracted
135to 140 knots
11.8.3.2
Figure11-8. Minimum ControlSpeedCmtmd(VhfCC) occurs,the largerthe lateral deviation. Longer pilot reaction times result in dramatically larger lateral deviations.VMCG speeds(takeoff continued)for the F-14B/D are presented in Figure 11-8. Even if the takeoff is aborted,significant runwaylateral deviationsmay occur beforethe aircraft is brought back undercontrol. Use of the nosewheelsteeringup to 100 knots will reduce the amounts of deviation during the abort. For example, if the engine fails at 90 knots, the lateral deviation will be 10 to 15 feet with nosewheelsteering engaged,and approximately 50 feet with nosewheel steeringdisengaged. Ifthe single-enginefailureoccursduringor atlcrlift-off or catapultlaunch, the aircraft is controllableif proper aircrewtechniquesareemployed.Airborne mdder effectivenessis presentedin Figure 11-9.Rudderis theprimary control for counteringyaw becauseof asymmetricthrust sincelateralstick inputsalonewill induceadverse. yaw in au alreadycritical flight regime.At the tirst indicationof an enginefailure,the pilot shouldnot hesitateto applyup to full rudderto counterroll andyaw. Above 100knots, ruddereffectivenesswithout nosewheelsteeringis suflicient to control this deviationadequately.In addition,use of nosewheelsteeringis undesirableabove100knots becauseof a d.hectionalpilot inducedoscillationtendency.
Failure to limit pitch attitude will place the aircratl in a regime of reduced dictional stability, rudder control, and rate.of climb. The aircraft may be uncontrollable at AOA above20 units. Smoothrotation to lo0 pitch attitude (approximately 14 units AOA) will provide good initial flyaway attitude, ensure single-engine acceleration, and generate adequaterate of climb. See Chapter 13 for single-engine takeoff emergency procedures, and NAVAIR 01-F14AAE-1.1 for single-engineperformancedata. ORIGINAL
Landing
Configuration
-
General.
Asymmetric thrust flight in the landing contiguration must be approachedwith caution. Cross weight should be reducedprior to landing in orderto improve waveoff performance.Rudder trim, augmentedas necessaryby additional rudder pedal deflection, should be used to counterthrust asymmetry. Speedbrakesshould remain retracted during actual single-engine approaches. A straight-in approach should be flown. Avoid turns into the dead engine. Steep angle of bank turns into the dead enginereduce climb performanceand may result in rudder requirements exceeding available control deflection causing lossof control. The uilot mav haveto reducethe thrust onthe operatingengineto regaincontrol, which may not be feasible at low altitude. By performing turns away from the failed engine,both thrust and rudderrequirementswill be reduced.Any maneuveriugreqmredprior to tinal approachshouldbe accomplishedusing a maximum of 20° angle of bank in turns away from the failed engine. Nota The role of the RIO is critical in this regime. He shouldclosely monitor airspeed,bank angle, and AOA throughoutthe approach. Refer to Chapter15 for single-enginelanding emergency proceduresand NAVAIR 01-F14AAP-I.1 for single-engineperformancedata. For additional discussion of landing contigurationsandtechniques,seeparagraphs1183.3 and 1183.4. For additional discussion of asymmetric thrust flight characteristics,see paragraph 11.8.3. 11.8.3.3 Primary.
Landing
Configuration
-
Engine
Nota While shipboardrecoveriesmandatethe use of the minimum recommendedapproachairspeedbecauseof aircraft and arrestinggear st~ctural limitations, field recoveriesbenefit Born slightly faster airspeedsbecauseof the increasedcontrol power and reducedapparent thrust asymmetry. 1132
in
DLC will not beavailablewith theleft engine secured.With the left engineoperatingin primary mode and3,000psi combinedhydraulic pressure,DLC should be engagedwhen establishedon final approach. Any maneuverrequiredprior to rollmg out on final approach should be accomplished using 12 units AOA or less. Onceestablishedon fmal approach,fly 15units or faster (DLC engaged)or 14 units or faster(noDLC) to provide additional control power.
NAVAIR Ol-Fl4AAD-1
SEA LEVEL -
STANDARD DAY
Figure 11-9. RudderEffectiveness 11-23
ORIGINAL
NAVAIR 01-Fl4AAD-1
Airspeed control for a 14-unit approachis difficult, therefore,theremay bea tendencyto overcontrolpower. An effective technique is to have the RIO provide airspeedcalls (i.e., “2 knots slow/fast”) to the pilot during final approach. With DLC engaged,minimize use of the throttle in close and use DLC for fine glideslope corrections. Decreasingthe amount of throttle activity will limit excitation ofthe dutchroll. RATS will engage on touchdown, but does not significantly affect CV bolter performance. MIN A/B (ATLS on) may be used if required, During a bolter, apply rudder simultaneously with power addition to maintain centerline. Adequatedirectional control power existsto preventdrift on bolter. Military thrust waveoff performance in primary mode is good, averaging30 to 40 feet of altitude loss f?om a nominal 600~fpm sink rate. Waveoff performance from high sink ratesis improved using MIN A/B (ATLS on). Altitude loss is minimized by maintaining approachAOA (slight, gradualpitch rotation required).
DLC should not be engagedfor any single-engine SEC mode approaches. Any maneuver requiredprior to rolling out on final approachshouldbe accomplished using 10 units AOA or less. Once establishedon final approach,fly 13units or fasterto improve waveoff capability andprovide additional control power. Note While shipboardrecoveriesmandatethe use ofthe recommendedapproachAOA because of aircraft and arrestinggearstructurallimitations,field recoveriesbenefit from slightly faster airspeeds because of the increased control power and reduced apparentthmst asymmetry.
Note Altitude loss during a single-enginewaveoff is minimized by maintaining approachAOA until a positive rate of climb is established. Avoid overrotating in close as this will increasethe chanceofan in-flight engagement. MIN A/B (ATLS on) may improve waveoff performancefrom high sink rates. Sufficient rudder control power exists to maintain control of the aircraft during MIL andMIN A/B singleengine waveoffs, provided AOA is not allowed to increase above 18 units. Simultaneously add rudder (approximately two-thirds to three-fourths deflection) with power to counterthe asymmetric thrust and track centerline. If a yaw ratedevelopsinto the failed engine, immediately apply full oppositerudderto arresttheyaw rate and then reducerudder as requiredto track centerline. Ruddermay besupplementedby small lateral stick inputs. The useofMAX A/B offers little or no improvements in single-engine waveoff performance and is prohibited. The aircraft is extremelydifficult to control in MAX AIB and large bank angles into the operating engine are requiredto maintain centerline. Late or inadequatecontrol inputsduring a MAX A/B waveoff can result in large lateral flightpath deviations. If unableto control yaw rate during AIS waveoff (possibleATLS .failure), immediately reducepower to MIL. 11.8.3.4 Landing Configuration - Engine in Secondary. Approachesin single-engineSEC mode areconsideredextremely hazardous.Tbrust responsein secondarymode is nonlinearandvery sluggish. At military power, thrust in secondarymode can vary from as ORIGINAL
little as 65 percentto as much as 116percentof primary mode thrust at MIL power. Although the majority of engines produce greater than 90 percent of primary mode thrust (at MIL power), the possibility exists that in the full flap configuration, a low-thrust enginewill not provide enoughthrust for level flight. Engine accelerationtimes can also vary and canbe asmuch as three times longer than in primary mode. Aircraft should recoverashore. Shipboardlandings should only be attemptedas a last resort and only if performanceis adequate. See Chapter 15 for performance check and specific emergencyprocedures.
Airspeed control for a 13-unit approachis difficult, therefore,theremay bea tendencyto overcontrolpower. An effective technique is to have the RIO provide airspeedcalls (i.e., “2 knots fast”) to the pilot during final approach. Extreme care should be usedwhen working off a high and/or fast condition as any large power reduction could result in a situation requiring military powerfor correction. Use small throttle movementsand small attitude adjustments for glideslope corrections. Avoid nosedownattitude changesjust prior to touchdown as this will minimize the chanceof a hook skip bolter. In the event of a bolter, rotate to a 10” pitch attitude,not to exceed 14 units AOA. During a bolter, apply rudder simultaneously with power addition to maintain centerline. Adequate directional control power existsto prevent drift on bolter. Waveoff performance in secondarymode may be poor and high sink rates must be avoided. The poor engineaccelerationin SEC mode makesenginerpm at waveoff initiation a major factor in waveoff perfonnante. Grossly underpowered conditions must be avoided. During single-enginewaveoffs in secondary mode,rotatethe aircraft slightly to capture/maintain14 to 15 units AOA as this will help to break the rate of descent.
11.24
NAVAIR Ol-Fl4AAD-1
(WARNING1 Single-enginewaveoffperformancewith operatingenginein SEC mode will be severely degraded. Extreme care should be used to avoid an underpowered,high rate-of-descent situation. 11.8.4 Degraded Approach Configuration. Refer to Chapter 15 for degraded approach emergency procedures. 11.8.4.1 No Flaps, No Slats, and Wings at 20’. If a no-flap, no-slat landing is anticipated,a straight-in approachshould be performed becauseof the narrow marginaffordedbetween15units AOA and the onsetof airframebuffet. The approachis flown at 15units AOA. Aiime buffet will occur at 16 to 17 units AOA with wing drop (5” to loo) and/or an increasein sink rate. occurring at 16.5to 17.5units AOA. Spoiler effectivenessis slightly degradedbecauseof the absenceof the aerodynamicslot formed when the flaps are extended. Preciseairspeedcontrol is essentialfor a no-flap/no-slat approach.Fast or high/fast approachesresult if timely throttle adjustmentsare not made throughout the approach.The pilot must wave off approachesthat result in largethrottle reductions(to nearidle) in close.
Nose attitude control is more sensitive during a no-flap approach,and care must be exercised not to overcontrol nose corrections in close.Cocked-up,high-sink landing can result in damage to ventral tins and/or afterburners. 11.8.5 Outboard Spoiler Module Failure. When the wings are forward of 62”, loss of outboardspoilers resultsin a decreasein roll authorityandin lateralcontrol effecfivencss.Such loss causesno significant degradation in approachhandling characteristicsand is generally only apparentwhen large bank angle changesare commanded,such as during roll into and out of the approachturn. Ifthe outboardspoilermodule fails when the flaps and slats are down, the spoilers may float up and lock at some position above neutral. This may be accompaniedby trim changesin all three axes,which can be trimmed out. Approach speed will increase slightly if a spoiler float occurs. If the failure occurs when the flaps are up, spoiler float is minimized.
In theevent of outboardspoiler module failure, do not engageDLC or ACLS. 11.8.6 SAS Off. Approach characteristics are not significantly degradedwith partial or total SAS failure. The aircraft is slightly more sensitive to longitudinal control inputs if pitch SAS is lost. Lateral-directional responseto turbulenceincreasesif yaw SAS is lost. Roll SAS failure results in slightly increasedroll sensitivity. Note Pitch SAS lossmay resultin loss of outboard spoilers.Roll SAS loss may result in loss of inboardspoilers. 11.8.7 Aft Wing-Sweep Landings. The aircraft may besafelylandedwith thewings asfar at?as40” (CV) and68” (field). If the wings fail to respondto command, the emergencywing-sweep handle should be used to match the captainbars (commandedposition) with the wing-sweeppositiontape.Matchingthecaptainbarswith the position tapeensuresthe commandedposition is the sameas theactualposition,removinghydraulicpressure tiom the wing-sweepmotors(hydraulicpressurewill still remainpresentatthewing-sweepcontrolservovalve/fourway valve).Thisreducestheliielihood ofhydraulicfailure or asymmetricwing sweepbecauseof the failure of the crossovershaft.Optimum AOA for shipboardat3wingsweepapproachesis 1.5units.AOA may be increasedup to 17units maximum for field landingsto minimize ap preachairspeedfor normalfield landingsor remainwithin publishedarrestinggearlimitations for short-fieldarrested landings.At wing-sweepanglesoft Sl”, eachl-unit increasein approachAOA reducesapproachairspeedby approximately5 knots. Airspeedsfor variousconfigurations areshownin Figure 1l-10. With the wings frozen forward of 50”, the main flaps/slatsshould be used. A normal 15-unit approach should be used in this configuration and approach speedswill remain within field arresting gear limitations. If main flaps/slatsarenot available,maneuvering flaps should be used. Extension of the main flaps/slats only will result in a flap light with the wings aft of 20”. (1 Ifmaneuvering flapsareused,ensurethat the maneuver flap thumbwheel is not actuated during the approach. ORIGINAL
NAVAIR Ol-Fl4AAD-l
Figure 11-l 0. Landing ApproachAirspeed (15 Units AOA) ORIGINAL
11-26
NAVAIR
01.Fl4AAD-1
of 17 units AOA while attempting to minimize the rate of descentjust prior to touchdown. Do not attempt to flare the landing anddo not aerobrake.
Note
Main flaps/slatsextensionwith the wings aft of ZOOwill result in a large nosedownpitch transient. DLC should not be engagedas it increasesfinal approach speeds. APC gains are not optimized for wing sweepsother than 20” and, therefore,APC should not be used. Reducing grossweight will reduceapproach speedby about3.5 knots for each2,000-poundreduction in grossweight at the 68’ wing-sweep position. Pilot over-the-nosevisibility is adequateat both 15 and 17 units AOA. The RIO will lose sight of the ball because of the higher pitch attitudeat 16to 17 units AOA on the standard3.25” field glideslope. Flying characteristicsin aft wing-sweep configumtions aredependenton wing-sweepangleandAOA. As wing-sweep angle increases,trimmed stick position moves aft. At 68” sweep,roll performanceis sluggish but adequateat up to 17 units AOA with roll SAS engaged. At up to 62” wing sweep, differential tail is augmentedwith spoiler for roll control. The aircraft exhibits a very strong dihedral effect wifh the wings swept aft, so rudder may be used to augmentroll performanceif desired. Crosswindlandingshavenot been evaluatedat or nearthe aircraft crosswind limit, but a crabbedapproachis recommendedvice the wingdown, top-rudder technique. Ensure that the fuselage is alignedwith the runway prior to touchdown. Although pitch control is adequate,maintaining trim airspeedis increasinglydifficult with increasingsweep anglebecauseof low stick force cuesfor airspeeddeviations. This necessitatesclosemonitoring of airspeedby the aircrew since the approachindexers are unusable above16units AOA. As wing sweepprogressesfurther aft, stall becomes less clearly defined. There is no strongaircraft buffet when AOA is increasedbeyond17 units. Aircraft waveoffperformanceis adequateat both 15 and 17 units AOA. During single-engineoperation, up to maximum power may be requiredto arrestaircraft rate of descent during a waveoff. Single-engine approacheswith aft wing sweephave not beentestedand ruddercontrol power may be limited in this condition. Fuel permitting, aircraft handling and stall characteristics as well as waveoff performance should be evaluatedat altitude prior to commencing an aft wiugsweepapproach. Ifusing anapproachAOA greaterthan 15units, nozzle clearanceat touchdown is reduced. Additionally, the high rate of descent(approximately 1,000fpm on a 3.2Y glideslope)andbigh touchdownspeedplacebigh stresson the main landing geartires. The recommended techniquefor field landings is to maintain a maximum 11-27
Nozzle clearance is reduced at elevated approach AOA. Ensure that a maximum of 17 units AOA is maintained at touchdown. AA wing-sweep touch-and-goperformancehas not beenflight tested,however,rotationspeedsapproaching or possibly exceeding tire limitations should be expected. Nosetire limitations, runway remaining, status of long-field arrestinggear,andtire pressurizationmust all be factoredinto a decision to go aroundfollowing a hook skip. If committed to landing following a hook skip with operative hydraulics, consideration should also be given to securingthe starboardengine in order to reduceresidualthrust. Engagementspeedslisted in the emergencyfield arrestment guide are groundspeeds. Headwind may be subtractedfrom final approachairspeed,tailwinds must be added, and compensationmust be made for field elevation (addapproximately 10knots to arrestinggear limit for a field elevation of 4,000 feet). 11.9
ASYMMETRIC
WING
SWEEP
11.9.1 Wing-Sweep Design Limitations. An understandingof the wing-sweep designlimitations is necessaryto cope successfullywith an in-flight asymmetric wing condition to avoid the possibility of structural damageand to minimize the possibility of loss of aircraft control. The following discussionis therefore offered.
The wing-sweep feedback position and interlock functions for the auxiliary flaps, main flaps/slats, and spoiler cutout are controlled by the left wing-sweepactuator.Cockpit wing-sweep position indication is controlled by fhe right wing-sweepactuator. The existenceof wing-sweep position feedbackon the left wing only can have a definite impact during a jammed wing-sweep actuator/failed synchronizing shaft condition. A jammed right wing-sweep actuator will result in normal left wing operationbecausewingsweepcommandsarenulled out by the left wing-sweep actuatorposition. A jammed IeA wing-sweep actuator in an intermediateposition, in conjunction with awingsweepcommand, will result in a constantcommandto ORIGINAL
NAVAIR Ol-Fl4AAD-I
the right wing-sweep actuator that cannot be nulled, since the right wing has no position feedback.In this case,the right wing will travel to the overtravelstop(19” or 69”) in the direction of the last command. The right wing can be positioned in either the 19’ or 69” position only, but not in any intermediateposition since thereis no way to null out the command.A condition similar to a jammed wing-sweep actuator occurs when one hydraulic systemhasfailed in conjunction with a synchronixing shag failure. A temporaryactuatorjam ononesidewhile the wings aresweeping,in conjunction with a broken synchronizing shaft, will result in resumption of operation with asymmetrical wing positions. Symmetrical wing position, within lo, can be achievedagain by commanding the wings full forward or full aft (20” or 68’). The direction to command the wing is dependenton whether the right wing is forward or aft of the left position. The right wing position is displayedby the wing position tapeon the cockpit wing-sweep indicator. If, for example, the right wing is forward of the left wing, the wings should be commandedfull forward to 20”. The right wing will drive to the 19” overtravel stop and remain there until the left wing reaches20”. nulls the command, and hydraulic power is shut off. If the right wing is aft of the left wing, the wings could be commandedfull aft to 68’. The right wing will drive to the 69” overtravel stop and remain there until the left wing reaches68”, nulls the command, and hydraulic power is shut off. Normal symmetrical wing-sweep operation, within la, should follow. Somejeopardy existsduring aft command operation since spoiler control wrll be lost when the left wing obtains 62”. Note A mechanicaljam in the wing-sweepsystem may prevent the wings from being resynchronized.This may be becauseof the failed synchronizing shaftjamming an actuator. The auxiliary flaps/mainflap interlocksarecontrolled by the let?wing-sweepactuator.This meansthat during asymmetric wing conditions, it is possibleto satisfy the interlock requirementswith the left wing and damage aircraft structurewith the off-scheduleright wing. For example, if the left wing is at 20° and the RiH wing is at 35’, the 21’ interlock in the auxiliary flap system is satisfied by the left wing. Lowering the flaps without inhibiting auxiliary flaps will drive the auxiliary flaps through the fuselagein the vicinity of the flight hydraulic system.Pulling the AUX FLAP/FLAP CONTR drcuit breaker (8G3) will remove electrical power to the auxiliary flaps and preventauxiliary flap deployment. ORIGINAL
Note Extending the main flaps with the auxiliary flapsinhibitedwillresuh inalargenosedown trim change. The wing-sweep control drive servo is powered throughWING SWEEP DRIVE NO. 1 (LDI) and WG SWPDRNO.2/MANUVFLAP(LEI)cirouitbreakers. Pulling thesecircuitbreakers inhibits all electrical command paths to the wing-sweep control valve. Manual commandsto the valve are available throughthe emergencyWING SWEEP handle.Pulling the WG SWP DR NO. 2/MANUV FLAP (LEl) circuit breakerremoves power from the maneuverdevicesandinhibits automatic retractionof the maneuverdeviceswith landing gear handleextension.Themaneuverdevicesshottldbecommanded up prior to pulling the WG SWP DR NO. 2MANUV FLAP circuit breaker.It may also be necessary to utilize emergency up on the flap handle to achievefull flap and slat retmction. 11.9.2 Asymmetric Wing-Sweep Flight Characteristics. Asymmetric wing-sweepfailures will be manifested as a wing heaviness accompanied by a WING SWEEP advisory light, indicating a failure ofthe primary wing-sweep channel. A subsequentfailure of the backup wing-sweep channel will illuminate the WING SWEEP warning light. Flight testshaveshown thattheaircraft maybe safely landedwith asymmetric wing sweepas long as spoiler control is retainedfollowing the wing-sweepfaihne. The aircraft is not controllablefor landingwith awing asymmetrysuchasthe left wing aR ofthe spoilercutout angle(62”) andthe right wing forward at 20”. The maximum asymmetrydemonstratedfar landing was20°/600, although tests of 20”/68” at altitude indicate that this configurationis landableif spoilersareoperational(that is, the left wing is at 20” and the right wing is at 68’). The high approach speedscoupled with reduced lateral control authority obtained with asymmetric sweepbecomelimiting factors for aircraft carrier (CV) operations.If at all possible, the flightcrew should attempt to divert for a tieldlanding. In-flightretbelingwas not evaluatedduring flight tests. Cruise configuration flying qualities in the normal refueling airspeedrange (approximately 250 knots) were qualitatively assessed to be suitable for the task. The effects of asymmetric sweeparediminished as airspeedincreases(decreasing angle of attack), so that using a higher than normal tanking speedmay decreasepilot workload.Lateral and directional trim should be utilized to decreaselateral stick force during refueling andcruise flight.
11-28
NAVAIR
Note The use of lateral trim to reducestick force during approach and landing should be avoided, however, because it reduces the amountof spoiler available for roll control. Asymmetric wing sweepis primarily a lateralcontrol problem, increasing in severity as angle of attack increasesandas flap deflectionincreases.The aircraftwill roll toward the afi wing and yaw toward the forward wing. For example, right wing forward of left wing causesleft-wing-down roll and nose-rightyaw. The resultant sideslip angleis favorablefrom a controllability standpointand shouldbe removedwith rudderonly if it is uncomfortableto the pilot. Rudder trim into the forward wing may be utilized, if desired, to increase sideslip angle and generatea restoring rolling moment via dihedraleffect (right ruddertrim for right wing forward of left, and vice versa).Lateral stick force will be accordinglyreduced. Main flaps should be utilized to decreaseapproach airspeedfor asymmetric sweeplandings if both wings are forward of 50” sweep. During flight tests, a flap settingof 20’ to 25“ was found to provide thebestflying qualities in comparisonto the other flap settingstested (OO,10D,359. Safelandingsmay be performed,however, with all the flap configurationsevaluated.In the flaps-up contiguration,undesirableprestallbuffet is experiencedat 16to 16.5unitsAOA for all wing asymmetries. Stall-inducedbuffet is not experiencedin flaps-down configurationsbecausethe leadingedgeslat delayswing stall. Airframe buffet may occur, however, becauseof the turbulent airflow that passesthrough the auxiliary flap holethat impinges on the horizontal tails. This buffet increaseswith increasingflap deflection and is significantly worse with 35’ flaps as comparedto 10” or 20”. In addition to increasedbuffet levels, the 35” flap configuration is prone to lateral PI0 during high-gain taskssuchasclose-inlineup corrections.This is primarily becauseof the increasedspoiler effectivenessobtained with power approachspoiler gearing. The PI0 tendencyis eliminated by selecting flaps 25” or less, which causesa switch to cruise spoiler gearing. All asymmetric wing configurations require precise monitoring ofAOA during lateral maneuveringbecause of the existenceof significant pitch-roll coupling. This is especiallycritical with flapsup. In general,theaircraft tendsto increaseangleofattack when rolling towardthe forward wing anddecreaseangleof attack when rolling toward the aft wing. In order to provide adequatemaneuveringmargin below the stall buffet region, recommended approach AOA is 14 units for all flap-up, asymmetric wing configurationsup to 40“ differential
01-F14AAD-1
split (Figure 11-I 1). A landing with the maximum possible asymmetry of 20”/68” (48” differential split) was not attemptedduring flight tests,but evaluation of this contiguration at altitude indicates that 13 to 14 units AOA will provide adequatecontrol for approachand landingaslong asspoilersareavailable(let?wing at20”, right wing at 689. RecommendedapproachAOA is 15 units for all flap-down,asymmetric wing configurations (Figure 1l-1 1). If the let?wing is positioned aft of the spoiler cutout sweepangle(62’) thespoilersareinoperativeandlateral control is limited to differential tail only. Flight tests indicatethatthe maximum controllableasymmetryat 14 units AOA in this configuration is a 15”differential split. The preferableaction in this caseis to attemptto move the left wing forward ofthe spoilercutoutangleto regain spoiler control. If this is not possible,an attemptshould be madeto commandtheright wing asfar aft aspossible in order to minimize the wing asymmetry, and then perform a slow flight check at altitude to determinethe minimum control speed.The pilot must thendetermine if the configurationprovidesa reasonableapproachairspeed. Sideslip-inducedpitot static system errors may be experiencedwith all asymmetric wing-sweepconftgurations.Accurateairspeed/AOA indicationsmay be obtained by bringing the aircraft to a zero-sideslip condition. A wingman may provide an airspeedcheck prior to landing. 11.10
DUAL HYDRAULIC FAILURES BACKUP FLIGHT CONTROL MODULE FLIGHT CHARACTERISTICS
11 .I 0.1 General. Severalfactorswork in concertto affect the handlingqualities of the F-14 when operating with a dual-hydraulic failure. The first is the total loss of the SAS in all three axes. Since the bareairframe is lightly dampedin both pitch and yaw, gustsand small control inputs result in uncommandedresponsesor oscillations. The pilot’s generalimpressionis that theaircraft is sloppier in all axes and precisecontrol is more difftcult. The pilot doeshave some control over these characteristicsas they arevery dependenton contiguration and airspeed.
The secondfactor is the capabilitiesof the remaining flight control system. The inboard spoilers, speedbrakes,and auxiliary flaps are inoperative,and the inboardspoilersand speedbrakescanbe expectedto Boat. The degreeof spoiler float will be a function of airspeed, AOA, sideslip, flap setting, and the mechanicalcondition of individual spoiler actuators. During flight test, changesin float arevery slow and do not generateany ORIGINAL
NAVAIR Ol-F14AAD-1
FLAPS
MAIN 170
UP APPROACH AIRSPEED (14 UNITS FLATS/SLATS RETRACTED
AOA)
LANDING APPROACH AIRSPEEDS (15 UNITS AOA) FLAPS/SLATS EXTENDED: AUXILIARY FLAPS RETRACTED MAlN FLAPS
Figure 1l-l 1. Asymmetric Wing-Sweep Landing Approach ORIGINAL
11-30
NAVAIR
abruptrolling momentsbut do impose significant lateral trim changes.Outboardspoilersremain fully functional because of the independent nature of the outboard spoiler module, which also servesto power the main flaps and slats via the flap handleor the maneuverflap thmnbwheel. Lastly, only the rudders and horizontal stabilizersare poweredby the BFCM. Becauseof the low outputofthe BFCM, the stabilizersaredramatically reducedin their ability to respondto pilot commands. The stabilizers are rate limited to 10” per second in HIGH and5” per secondin LOW asopposedto a normal rateof 36” per second. This can be a severelimitation to thepilot’s ability to control the aircraft, dependingon the abruptnessof the pilot commands. Eachofthesefactorsinfluencesthehandlingqualities in different regions of the flight envelope. Handling qualitiesat speedsin excessof 200 KCAS areprimarily constrainedby the absenceofpitch SAS andthe limitations of the BFCM. At approachspeeds,the handling qualities areprimarily affectedby floating spoilersand the lossof yaw SAS, althoughrate limiting of the stabilizer can occur. 11.10.1.1 Rate Limiting. The pilot will observe rate limiting both in the feel of the control stick and in the responseof the aircraft. In the F-14 flight control system,the stick is mechanically connectedto the stabilizer. With normal hydraulics, there is virtually no time delay betweenthe pilot’s command and the stabilizer moving in responseto the command. With the BFCM providing significantly less hydraulic flow, at a substantiallyreducedpressure,the stabilizer moves so slowly that it is possiblefor rapid pilot inputs to exceed the stabilizermaximum deflectionrate. When this happens,the pilot will feel an abrupt increasein stick force until the stabilizercatchesup to the pilot’s command. If the pilot feels an abrupt increase in stick forces, the stabilizer is operatingon its rate limit. This can be observedduring the prestartBFCM checks and is most severein LOW.
The pilot’s perceptionofthe aircraft responseis likewise affected by rate limiting becauseof slower responseof the stabilizerto deflectioncommands. If slow control inputs are made, the delay is insignificant, aircraft responseappearsnormal, andcontrol is unaffected. If control inputs areabrupt,however,with many reversalsin direction (suchasmight be requiredto tank, land, or fly close formation), the pilot and the stabilizer can be out of phasewith one another,and a divergent PI0 will developthat resultsin loss of control. This occurs in pitch causedby largerdeflectionsavailable, but may be aggravatedby large lateral or directional flight control inputsthat furtherreducethe flow availableto command the stabilizer and, therefore, increase the
0%F14AAD-1
susceptibility to rate limiting in pitch. LOW mode is extremely limited in its ability to accommodaterapid control inputs,while the HIGH modecan accommodate moderatepilot control inputs. The abruptdegradationthat occurswith rate limiting makesthe handling qualities hazardous. The handling qualities of the aircraft while operatingwith the BFCM in HIGH aregenerallygoodfor moderategaintasks,and it is virtually transparentto the pilot that the flight control systemis degraded.However, when operatingnear the ratelimit of the system,very small increasesin pilot gain will result in an abruptand dramatic lossof control and the taskbeing performed must be aborted(i.e., the aircraft cannotbe controlled adequatelyto continuethe task). Uncontrollablepitch attitudeoscillations of +lO” can developin less than 3 seconds. Regaining control is simply a matter of loosely releasingthe stick, permitting the oscillationsto dampen,andthen smoothly reapplying control to restorethe aircraft to the desiredflight condition. In summary,if the systemis not ratelimited, the handling qualities are good; if the system is rate limited, the aircraft rapidly becomesuncontrollable. 11.10.1.2 Task Performance. There are four variables that the aircrew can control to maximize the probability of successfully completing mission tasks. Selection of an appropriate motor speed is the first controllable variable. Tightly controlled taskssuch as landing,close formation, and in-flight refueling require the control ratesavailable with HIGH mode. Judicious selection of airspeed can also influence successful task performance.With SAS OFF, the sensitivity ofthe aircraft increases significantly with airspeed. The slowerthe airspeed,the slower the response.For tightly controlledtasks,the flight control systemmust be capable of respondingfasterthan the natural dynamic characterof theaircraft, or the pilot must acceptundesirable overshootsand oscillations. The flight control system capabilitieswith the BFCM in eitherLOW or HIGH are very restricted. Part of the solution is to slow down the aircragandits responseasmuch asis practicableto give the flight control system the best chance of keeping aheadof the aircraft. The third variableis configuration, someofwhich are more suitedto specific tasks.Lastly, pilot technique may limit the ability of the aircraft to performsometasks.The slower andsmootherthe input, the less likely rate limiting will be encountered.Flight tests performing each of the following tasks have revealedthe mixture of the abovevariableswherebysuccessfulrecoveryof the aircraft can bestbe ensured, 11.10.2
Low Mode Cruise
and Formation.
Cruise
handling qualities in LOW mode are degradedbut satisfactory.Roll responseis very sluggishand someovershootscan be expectedwhen trying to establisha bank ORIGINAL
NAVAIR
01.F14AAD-1
angle. In pitch, any abrupt pitch input at 250 KCAS or fasterwill result in multiple oscillations when trying to precisely set a pitch attitude. Flying very loose formation is fairly easy, provided tight control is not attempted.Any attemptto finely control vertical elevation relative to a lead aircraft (5 2 feet) will result in rate limiting the stabilizer andloss of control. Control canbe reestablishedby relaxing the grip on the stick, allowing the oscillations to dampen,and then smoothly reapplying control. Slower airspeeds(200 KCAS) provide for more predictable control as discussed in paragraph Il. 10.1.Do not attemptIMC formation, closenight formation, in-flight refueling, or landing while in LOW mode. LOW mode control is satisfactory for the performance of configuration changes such as lowering gear and flaps.
A pitch PI0 will develop if any tight longitudinal control is attempted.Control can easily be regainedby relaxing the grip on the stick, allowing any oscillations to dampen, and then smoothly reapplying longitudinal stick to reestablishthe desired flight condition. Do not attemptIMC formation or close night formation while in LOW mode. Note
Airspeedslessthan 250 KCAS while operating in LOW mode will reducethe susceptibility to rate limiting. 11.10.3
High Mode
Cruise
and Formation.
Up and away flying qualities in HIGH mode are generally excellent, with the only noticeable degradation being a slight sluggishness in roll response.Cruise and formation tasks are very easy,provided that very tight tolerances are not attempted (< il foot). Higher speeds(> 250 KCAS) will increase the probability of rate limiting during parade formation. Close IMC or night formation is possible but not advisable because the divergent PI0 occurs very abruptly with no warning. The F-14 with the hydraulic failure should lead any formation flight except as required for inflight refueling. In-flight refueling can be safely performed but is very dependent on flight condition, configuration, and pilot technique. The best successcan be expected at 180 KCAS with maneuvering flaps and a smooth technique. There are two reasonsfor the strong influence of airspeed.First of all,~@king is easier to perform at slower speeds 11.10.4
ORIGINAL
In-Flight
Refueling.
11-32
becausetheaircraftismuchlesssensitive,thebowwave is considerablyreduced,and the probe position can be morepredictablyandsmoothlycontrolled,reducingthe necessity for aggressiveplays to seatthe probe. Secondly, the BFCM has an easierjob keeping up with aircraftdynamics,decreasingthelikelihoodofratelimiting. Any attempt to tank faster than 200 KCAS will result in loss ofcontrol. Tanking handling qualities are unaffectedby landing gear position and are improved with aft wing sweeps in the event that the wings are trappedaft. Flaps should be selectedto 10” with the maneuverflap thumbwheel, which still functions normally with outboardspoiler module power. Lastly, the influence oftechnique is that the ratelimiting is caused byabruptcontrolinputsandcountercorrections. The2 secondssurroundingcontactarethecriticalphasesince the controls can be three times more active than during theapproachorstabilized refueling. While spottingthe basketis common throughoutthe F-14 community, it is the surestway to place excessive demandson the flight control systemduringthe secondor two prior to contactandprovokea lossofcontrol. Thebest way to avoid abruptinputsis for the pilot to resistspotting thebasketandinstcadrclyontheRlO’sdirectivecommentary. Since the stabilizedrefbeling is easyand requires only moderateflight control activity, the airspeedcan safelybe increasedto 200 KCAS once engagedif additional airspeedis requiredto obtainproperstoreoperation (asmight berequiredwith ram-poweredbuddystoressuch astheD-704or D-301). While not flight tested,avery low gain techniquemust be used at the minimum airspeed attainableby the tankerifthe only resourceis a largebody tankersuchas theKC-IO, for which 180KCAS might be impossible.The pilot must respondto any undesiredmotion by looselyreleasingthestick andallowing theaircraft to dampenitself (,,,,,,,I l
l
Any abruptcontrol input to effect engagement can rate limit the stabilizers and result in loss of control. To avoid rate limiting, the pilot should resist spotting the basketand insteadrely on RIO commcntary to perform engagement. If any undesirablemotions or oscillations occur during or after engagement,the pilot must immediately releasethe stick and permit the motions to dampenbefore resuming active control.
NAVAIR
trolled with appropriateuse of power and smoothpitch inputs, allowing airspeedto vary within the recommended range. Smoothly rotate noseto flyaway attitude on bolter.
Do not attemptin-flight refueling from wingmounted storesof large-body tankers (VC10 Canberra)where nose-to-tail overlap is present.The basketdoestrail adequatelyaft of the tail for KC-130 and airwing assets.
. Carrier landings with a dual-hydraulic failure are very hazardousand shouldnot be attempted becauseof the abrupt and unpredictable nature of rate limiting. Control would most probably be lost between the in-close and at-the-ramppositions when the pilot or LSOs could not avert a catastrophicflight deck mishap.
Note
If the air refueling storedoesnot adequately transferfuel at 180KCAS onceengaged,the airspeed can safely be increased to 200 KCAS to improve the transferrate. Landing handling qualities are primarily affectedby the loss of SAS, inboardspoilers, speedbrakes,auxiliary flaps, andDLC, ratherthanlimitations of the BFCM itself. Longitudinal control is generally good provided no large abrupt pitch changesare attempted.Lateral control is degradedby virtue of the inoperativeSAS and inboard spoilers.Spoiler float and its impact on lateral control is considerablyaggravated by slower airspeeds and increased flap deflections. Consequently,field landings shouldbe performed with the maneuverflaps down, andthe MANUV FLAPANG SWP DR NO. 2 circuit breakerpulled to lock them down (LEl). Airspeed control is degradedbecauseof the dramatically decreaseddrag and low approachpower setting. Any airspeedfrom 15 units to 180 KCAS should be consideredacceptablewith thewings at 20’; waveoff performance is dramatically improved if some additional speedis carried. Fifteen units should be used if the wings aretrappedsignificantly aft. Speedsin excess of 180 KCAS on final should otherwise be avoided becauseof the increasedsusceptibility to rate limiting. Lateral control is degraded but satisfactory, and a straight-in approachto an arrestedlanding should be performed.The very low drag,runway length,long field gear,and length of time while operatingon the BFCM must all be considered in choosing a game plan for handlingbolters. The nosemust smoothly be rotatedto the flyaway attitudeifa go-aroundis elected. Flaps can be selectedto full once on deck to obtain the additional dragfrom the outboardflap panelsandgroundroll braking from the outboardspoilers. 11.10.5
l
0%Fl4AAD-1
Landing.
m Waveoff performancefrom low power settings is very poor. Carrying extra speedduring approach will improve waveoff performancebypermittingsmoothrotationto 15 units AOA to break the rate of descent while enginesare spoolingup. 11.10.6 BFCM Thermal Durability. The thermal behaviorof the BFCM and its isolated hydraulic loop determinethe durability of the system.With the motor operatingin LOW, the temperatureof the motor andthe fluid will stabilizeandthe motor can run indefinitely. In HIGH, however,the motor canheatup within 8 minutes to temperaturesat which it might fail. The motor should be selectedto HIGH only afler theaircraftis on final with intentto land,unlesstankingis required.The motorshould be selectedto LOW oncesafelyairbornefollowing waveoff, missedapproach,or bolter,andthenHIGH reselected on final. The elapsedtime onHIGH mustbe closelymonitored if in-flight rei%elingis required.Once disengaged, LOW mustbe immediatelyselected.
pii-,,,,,,, Operationsof more than 8 minutes total in HIGH may fail the BFCM motor. Extended LOW operation(> 30 minutes)afterin-flight refueling will permit severaladditional minutes of use for subsequentlanding. 11.1 I FLIGHT CHARACTERISTICS AFT CG LOCATIONS
Aggressivenosemovement in close or on bolter canratelimit the stabilizerresulting in low altitude loss of control. Do not use APCS. Glideslope is satisfactorily con-
WITH
11.11.1 Store Effects on Cg Location. The normal NATOPScglimits areexpressedrelativeto areference conditionknown aszerofuel grossweight (ZFGW). This 11-33
ORIGINAL
NAVAIR 0%F14AAD-l
condition known a.3zero t%el gmss weight (ZFGW). Thisconfi~tionisdefinedaswingsat20°,gear and flaps down, zero fuel on board. Adding fuel or raising the gearand/or flaps will move the cg position forward ftom the ZFGW position. The lit for ZFGW cg locations with tunnel-mountedstoresis 17.0-percentMAC. On a typical fleet aim& oneMk 84 2,000-pound bomb placed on station 4 or 5 results in a ZFGW cg afi of 17.0-percentMAC, possibly as far aft as 18.5 to 19percent MAC. lXvo at? hung Mk 84s can produce a ZFGW cg of up to 22-percentMAC. Aft wing sweep canbe usedto move the neutralpoint of theF-14 aft and restore normal static longitudinal stability margin and normal flying qualities evenwith extremely afi cg locations. In-flight actualcg location varies asfuel is burned but remainsrelatively constantat its most forward position between 5,000 to 10,000 pounds. Below 5,000 pounds, the cg moves aft toward the ZFGW position. Wing-mounted AIM-7/9s move the ZFGW cg location slightly forward, while external tankshaveno effect on the cg location. 11.11.2 Wing-Sweep Effects on Stability. Static stability of an aircraft is determinedby the differencein location of the neutral point, where the lift component can be assumedto act, and the cg position. A positive static margin exists as long asthe neutralpoint remains aft of the cg location. As the wings of the F-14 sweep aft, the cg location also moves slightly aft but the greatest change is in the neutral point position that moves further aft as well. Aft wing sweep can be used in conjunction with an aft-cg position to restorethe normal margin betweenthe neutral point and the cg, pmducing the same level of stability and normal flying qualities. 11.11.3 Cruise and Combat Flight Characteristics With Aft Cg. Flying qualities at aft cg locations up to 22-percentMAC with gear and flaps up are only slightly &graded. This degradationwill probably not be apparentto the pilot. No changein flying qualities is noted during dive recoveriesbetween400 and 500 KCAS. Stick force per g remains relatively nominal evenwith 4,000poundsof aft hungbombs. No degradation to any aspect of flying qualities is noted above300KCAS asthe wings remain sufftciently aft on the normal wing-sweep scheduleto producea positive static margin for eventhe most afi cg locations. At 20” of wing sweep, 250 KCAS, and a ZFGW cg of 18.6 percent, the aircraft exhibits some reduction in static stability and is slightly more responsiveto pitch inputs, although this increase in responsivenessmay not be
ORIGINAL
significant enough to be noticed during normal flight operations.Wmg-mounted storesor externaltankshave no adverseeffects on aft cg flying qualities. 11.11.4 Takeoff and Landing Configuration Flight Characteristics with Aft Cg. With the gear and Sapslowered and20’ of wing sweepwith a ZFGW cg locationof 18-percentMAC or greater,thestaticmargin is greatlyreducedtiom nomral andcanbenegativefor the extremelyaft cg locationsproducedby 4,000poundsof bombs on the aft weapon stations. The aircraft is extremely susceptibleto pilot-induced oscillations during closely controlledtaskssuchascloseformation or flying the bail. Loss of control is likely. With a wing sweep of 26’ for ZFGW cg locationsup to 18.6-percentMAC, normal staticmargin is restoredandnormal flying qualities are regained. For ZFGW cg location greaterthan 18.6-percentMAC, 30” of wing sweepis sufficient for normal handling qualities to be regained. Wing-mounted stores and external tanks reduce lateral-directional stability in the takeoff and landing contiguration slightly, although the difference in flying qualities is not significant and may not be noticeable. Once establishedin the optimum wingsweepconfiguration appropriatefor the amount of ordnance hung on the aft stations, normal approach techniques can be used. However, a straight-in approachshouldbe flown aspower requirementsin a turn with aft wing sweepare significantly different thannormal and could produce a severely underpoweredapproach. No abnormalities in aircraft response or performanceam apparentduring landing approachesat 15units, evenwith 4,000 poundsof aft hung ordnance. AFT is not optimixed for aft wing-sweep landingsand shouldnot be used. DLC should not be usedas it adds 8 knots to recovery WOD requirementsand has improper pitch trim responseat aft wing sweep. Expect on-speedairspeed for 25’ of wing sweep to increase 6 knots over the normal DLC on 20° of wing-sweep approachspeed,and 12 knots increaseif wings are at 30”. For CV anestments,the appropriaterecoverybulletin shouldbe consulted. Ashore, a field atrestment is recommended with spoiler brakes dearmed becauseof the large noseup pitch occurring at spoiler deployment. If a field arrestment is not possible, expect to use full forward stick to counter the noseuppitching moment and to maintain forward stick until below 80 KCAS with a resultant longerrollout.
11-34
NAVAIR 01.F14AAD-1
PART V
Emergency
9 STOP
INTRODUCTION
Part V consistsof Chapter 12, GroundEmergencies; Chapter13,TakeoffEmergencies;Chapter14,In-Flight Emergencies;Chapter 15, Landing Emergencies;and Chapter16, Ejection. Thesechapterscover the recommendedproceduresfor coping with emergenciesand malfunctions that may be encounteredduring aircraft operations.Knowledge of the aircraft systemsandemergency proceduresmust be reviewed on a regular basis to ensurethat the flightcrew will take the correctcourse of action underadverseconditions. Each emergency presentsa different problem that requirespositive, specific, remedial action in accordancewith recommendedproceduresand good airmanship. Judgment,precision, and teamwork are essential during emergencies.The flightcrew must weigh all the factors of a given situation and then take appropriate action. As soonas possible,the pilot should notify the RIO, flight leader,flight, andground stationin asmuch detail as possible of the existing emergencyand of the intendedaction. Whenan emergencyoccurs,tbreebasic rulesareestablishedthatapply to airborneemergencies. They shouldbe thoroughlyunderstoodby all flightcrew.
Procedures
READ AND
HEED b. Land as soon as practicable - Extended flight is not recommended.The landing site and duration of flight is at the discretion of the pilot in command. Note l
The ground,takeoff, in-flight, andlanding emergencyproceduresare sequencedas outlined in the EmergencyProceduresTable of Contents.
l
Decision factors (“if” statements) are provided as a guide in selecting certain procedures.
Critical Procedures (Boldface Procedures)
1. Maintain aircraft control.
Proceduresmarked with asterisks(*) are considered critical andarereferredto as“boldface” procedures.The boldfaceproceduresin this part areprovided asa study referenceandarenot intendedto be usedas analternate to the amplified procedurescontainedin Chapters12, 13, 14, 15, and 16 or the abbreviatedprocedurescontained in NAVAIR Ol-F14AAD-IB. Flight crewmembers should be able to accomplish boldface procedures without referenceto the NFM or PCL.
2. Analyze the situationand take properaction.
Warning, Caution, Advisory Lights/Displays
3. Land as the situation dictates.
The warning, caution, advisory lights/displays are listed togetherwith the causeand correctiveaction.
a. Land assoonaspossible - Land at the fmt site at which a safe landing canbe made.
EMERGENCYPROCEDURES Table of Contents Page No. CHAPTER 12 -GROUND 12.1 12.1.1 12.1.2 12.1.3 12.1.4 12.1.5 12.1.6 12.1.7 12.1.8 12.1.9
EMERGENCIES
12-l ON-DECK EMERGENCIES ........................................................................................................ 12-1 Engine Fire on the Deck ............................................................................................................... 12-1 Abnormal Start............................................................................................................................... 12-1 START VALVE Light After Engine Start.................................................................................... UncommandedEngine Acceleration on Deck ............................................................................ .12-l 12-2 Ground EgressWithout Parachuteand Survival Kit.. ................................................................... 12-2 EmergencyEntrance. ................................................................................................................... Weight-On-Off Wheels Switch Malfunction. ............................................................................... 12-2 124 Binding/JammedFlight Controls On Deck.. ................................................................................. 124 Brake Failure at Taxi Speed.........................................................................................................
CHAPTER 13 - TAKEOFF EMERGENCIES 13.1 13.1.1
ABORTED TAKEOFF ............................................................................................................... .13-l 13-l Aborted Takeoff Checklist............................................................................................................
13.2 13.2.1 13.2.2 13.2.3 13.2.4 13.2.5
SINGLE-ENGINE FAILURE FIELD/CATAPULT LAUNCHiWAVEOFF ............................. 13-2 13-2 Angle-of-Attack/BndspeedConsideration..................................................................................... 13-2 Rateof Climb Consideration. ...................................................................................................... 13-2 StoresJettisonConsiderations..................................................................................................... 13-2 Aimew Coordination. ................................................................................................................. 13-3 Single-EngineFailure Field/CatapultLaunchWaveoff.. ..............................................................
13.3 13.3.1 13.3.2
13.3 BLOWN TIRB DURING TAKEOFF.. ....................................................................................... .13-3 Blown Tie During Takeoff, Takeoff Aborted or After Landing Touchdown.. .......................... .13-3 Blown Tii During Takeoff; Takeoff Continuedor After Landing Go-Around .........................
CHAPTER 14 - IN-FLIGHT EMERGENCIES 14.1 14.1.1 14.1.2
14-1 COMMUNICATIONS FAILURE.. ............................................................................................. 14-1 Flightcrew Attention Signals. ...................................................................................................... 14-l COMM-NAV EmergencyProcedures.........................................................................................
14.2
14-1 PITOT-STATIC SYSTEM FAILURES ......................................................................................
14.3
14-2 EMERGENCY JETTISON ...........................................................................................................
14.4
14-4 FIRE LIGHT AND/OR FIRE IN FLIGHT.. ................................................................................
14.5 14.5.1 14.5.2 14.5.3 14.5.4 14.5.5
14-5 ENGINE EMERGENCIES ........................................................................................................... 14-5 CompressorStall. .......................................................................................................................... 14-7 Ahalts. ........................................................................................................................................ .14-11 Single-EngineFlight Characteristics.......................................................................................... .14-12 Engine Overspeed(bI1 or N2 OSP Legend).............................................................................. 14-12 Engine START VALVE Light.. .................................................................................................
Page No.
14.5.6 14.5.7 14.58 14.59 14.5.10 14.5.11 14.512 14.5.13 14.5.14
14-12 Engine Transfer to SEC Mode ..................................................................................................... ..................................................................................... .14-13 UncommandedSEC Mode Rpm Decay 14-15 UncommandedEngine Acceleration Airborne (No Tbrottle Movement). ................................ ..................................... 14-15 ExhaustNozzle Failed (No Nozzle Responseto Throttle Movement). 1615 Stuck/JammedTbrottle(s). .......................................................................................................... 14-16 ...................................................................................................................... AICS Malfunctions ......................................................................................................................... 14-17 INLET ICE Light 14-17 Oil System Malfunction. ............................................................................................................. 14-17 ........................................................................................................... RATS OperationIn Flight
14.6 14.6.1 14.6.2 14.6.3 14.6.4 14.6.5
14-18 FUEL SYSTEM MALFUNCTIONS .......................................................................................... 14-18 Fuel PressureCaution Lights. ..................................................................................................... 14-18 L or R FUEL LOW Light ............................................................................................................ 14-18 .................................................................................................................. Fuel Transfer Failures ................................................................................................................. .14-19 UncommandedDump 14-19 Fuel Leak.....................................................................................................................................
14.7 14.7.1 14.7.2 14.7.3 14.7.4 14.7.5 14.7.6
14-20 ELECTRICAL FAILURE. .......................................................................................................... 14-20 ....................................................................................................................... GeneratorFailure. ii;% Double GeneratorFailure ........ ............................................................................................................... Double Transformer-Rectifier Failure. 14-22 TRANSRECT Light. ................................................................................................................. Electrical Fire. ............................................................................................................................. 14-22 14-24 Total Electrical Failure ................................................................................................................
14.8 14.8.1 14.8.2 14.8.3 14.8.4 14.85 14.8.6 14.8.7 14.8.8
14-25 ECS MALFUNCTIONS/FAILURES ......................................................................................... 14-25 ECS Leak/Elimination of Smoke and Fumes.............................................................................. 14-27 ................................................................................................................. COOLING AIR Light. 14-27 TARPS ECS Lights Illuminate .................................................................................................... SENSOR COND Light Illuminated and/or PUMP PhaseCircuit Breakers Poppedor APG-71 PM Acronym.. .............................................................................................. 14-28 14-28 Cockpit TemperatureControl Malfunction.. ............................................................................... 14-28 .......................................................................................... Cockpit Overpressurixationon Deck CABIN PRESS Light .................................................................................................................. 14-28 14-28 WSHLD HOT Light ....................................................................................................................
14.9 14.9.1 14.9.2 14.9.3 14.9.4
OXYGEN SYSTEM FAILURE ................................................................................................. 14-29 14-29 OBOGS Light .............................................................................................................................. .14-29 B/U OXY LOW Light (Both Cockpits) ..................................................................................... B/U OXY LOW Light (Pilot Only). ............................................................................................ 14-30 14-30 B/IJ OXY LOW Light (RIO Only). .............................................................................................
14.10 14.10.1 14.10.2
14-30 LAD/CANOPY LIGHT AND/OR LOSS OF CANOPY.. ......................................................... CANOPY Light/Canopy LOSS.. ............................................. 14-30 LAD/CANOPY Light With RIO .14-31 LAD/CANOPY Light Without RIO CANOPY Light.. .............................................................
14.11 14.11.1 14.11.2 14.11.3 14.11.4 14.11.5 14.11.6
14-31 HYDRAULIC SYSTEM MALFUNCTIONS ............................................................................ .14-31 Combined PressureApproximately 2,400to 2,600 Psi.............................................................. 14-31 Flight PressureApproximately 2,400 to 2,600 Psi ...................................................................... ............................................................................................................ 14-32 Combined PressureZero.. 14-33 ..................................................................................................................... Flight PressureZero Both Combined and Flight PressureZero ................................................................................... 14-33 Backup Flight Module Malfunction ............................................................................................ 14-35 65
ORIGINAL
.\
.\
\
\\
.\
NAVAIR 01.F14AAD-1
Page No. 14.1,l, .I 14.1.l, .8 14.1.l, .9
Controllability Check ............................................................ ............ .......................................... 14-35 OutboardSpoiler Module Malfunction ....................................................................................... 14-36 Low Brake Accumulator Pressure.................................................. ............................................. 14-36
14.12 14.12.1 14.12.2 14.12.3 14.12.4 14.12.5 14.12.6 14.12.7 14.12.8 14.12.9 14.12.10 14.12.11 14.12.12 14.12.13 14.12.14
FLIGHT CONTROL FAILURES OR MALFUNCTIONS ...................................................... .14-37 14-37 UncommandedRoll and/orYaw ................................................................................................. 14-37 Yaw ChannelFailure .................................................................................................................. Pitch or Roll ChannelFailure ..................................................................................................... .14-37 STAB AUG Transients.......................................................................................... ......................14-38 RudderAuthority Failure.. .......................................................................................................... .14-38 Horizontal Tail Authority Failure................................................................................................ 14-39 14-39 Spoiler Malfunction.. ................................................................................................................... 14-41 FLAP Light.. ................................................................................................................................ , ............................................................... 14-41 Flap and Slat Asymmetry ............................................ W/S Caution Legend.. ....................................................... 14-42 WING SWEEP Advisoty Light and UnscheduledWing Sweep.......................................................................................................... .14-43 CADC Light.. ........................................................................................................................ (......14-43 .14-44 AUTOPILOT Light .................................................................................................................... Weight On-Off Wheels Switch Malfunction ............................................................................. .14-44
14.13 14.13.1 14.13.2 14.13.3
DEPARTURE/SPIN .................................................................................................................... 14-44 14-45 Vertical Recovery ........................................................................................................................ Upright Departure/FlatSpin ....................................................................................................... .14-45 InvertedDeparture&pm............................................... ................................................................ 14-45
CHAPTER 15 -LANDING
EMERGENCIES
15.1
DUAL-ENGINE LANDING, ONE OR BOTH ENGINES IN SECONDARY MODE.. ......................................................................................................... ..15-1
15.2
SINGLE-ENGINE LANDING PRIMARY MODE ..................................................................... 15-l
15.3 15.3.1
SINGLE-ENGINE LANDING SECONDARY MODE.. ............................................................ .15-3 Single-EngineLanding - SEC Mode ......................................................................................... .15-4
15.4 15.4.1 15.4.2
LANDING GEAR EMERGENCIES ............................................................................................ 15-6 Landing Gear EmergencyLowering. .......................................................................................... .15-6 Landing GearMaltunctions.. ........................................................................................................ .15-6
15.5
BLOWN-TIRE LANDING ......................................................................................................... 15-10
15.6 15.6.1 15.6.2
FLAP AND SLAT LANDING EMERGENCIES .................................................... . ................. 15-10 No-Flaps andNo-Slats Landing ................................................................................................. 15-10 Auxiliary Flap Failure .............................................................................................................. 15-10
15.7 15.7.1 15.7.2
WING-SWEEP EMERGENCIES .............................................................................................. .15-11 Aft wing-sweep Landings ......................................................................................................... 15-11 15-11 Asymmetric Wing Sweep............................................................................................................
15.8 15.8.1
AFT HUNG ORDNANCE LANDINGS ................................................................................... .15-16 Lading with Aft Hung Ordnance............................................................................................... 15-17
15.9
FIELD AIWW-MENTS
ORIGINAL
........................................................................................................... .15-17 66
Page No.
15.9.1 15.9.2 15.9.3 15.9.4
Field Arresting Gear .................................................................................................................... 15-17 Short-Field Arrestment ............................................................................................................... 15-18 Long-Field Amstment ................................................................................................................ 15-18 Engaging Speeds.,...,........................,.......,...........,.,.......,.......................................,...............,..... 15-18
15.10
BARRICADEARRESTMENT
15.11 15.12
ARRESTING HOOK EMERGENCY DOWN .......................................................................... 15-21 FORCED LANDING .................................................................................................................. 15-21
CHAPTER 16 -
.................................................................................................. 15-18
EXTREME WEATHER
16.1 16.1.1 16.1.2 16.1.3
EJECTION ..,......,..................................................................,........................................................ 16-1 Ejection Envelope ......... ................................................................................................................ 16-1 Ejection Preparation....................................................................................................................... 16-5 Ejection Initiation ........................................................................................................................... 16-5
16.2
MANUALBAILOUT
16.3 16.3.1 16.3.2 16.3.3 16.3.4 16.3.5
SURVIVAL/FOSTEJECTION PROCEDURES ......................................................................... 16-5 Manual Man&at Separation.................................................................................................... .... 16-8 Survival Kit Deployment ............................................................................................................... 16-8 ParachuteSteering .,........................,............,.............................................................,.................. 16-8 ParachuteLanding Preparation..................................................................................................... 16-8 Raft Boarding.................................................................................................................................16-9
................................................................................................................... 16-5
NAVAIR 0%F14AAD-1
BOLDFACE PROCEDURES BLOWN TIRE CONTINUED
ENGINE FIRE ON THE DECK ‘1.
Both FUEL SHUT OFF handles
‘2. Both throttles
. . . . . Pull
. . . . . . . . . . . . . . OFF
UNCOMMANDED
ENGINE
ACCELERATION
ON
DURING TAKEOFF; TAKEOFF OR AFTER LANDING GO-
AROUND 9.
Throttles
As Required
. . . . . . . . . . .
l 2. Landlng
gear and flaps
. . .
DECK l l. Paddle switch *2. Throttle(s)
. . . . .
. . . . . . . . . . .
=3. ENG MODE SELECT “4 THROTTLE BRAKE
Depress
and Hold As Desired
. . . . . . . . .
MODE switch
SEC
. . . . . . . MAN
AT TAXI SPEED
FAILURE
‘1. ANTI SKID SPOILER BK switch . . . . . . .
Throttles
AND/OR
V. Throttle
SPOILER BK or OFF
. . . . . . . . . . . . . . . . IDLE
FIRE IN FLIGHT
(affected
engine)
. . . . . . . IDLE
l 2. AIR SOURCE pushbutton l 3. OBOGS master switch If light goes cations):
ABORTED TAKEOFF *I.
FIRE LIGHT
Leave a5 Set for Takeoff
off (and
. . . . . . . . . . . . .
no other
‘4. MASTER TEST switch
OFF
BACKUP
secondary
indi-
. . . FIRE DET TEST
If light remalns illuminated, FIRE DET test falls, or other secondary Indications:
. . . . . . . . . . . . . .
EXT
l 6. FUEL SHUT OFF handle (affected engine) . . . . . . . . . . . .
Pull
‘3. Stick
. . . . . . . . . . . . . . . . . .
AFT
l 6. Throttle
OFF
*4. Hook
. . . . . . DN (1,000 feet before wire)
‘2. Speedbrakes
‘5. Brakes
. . . . . . . . . . . . . As Required
l 6. Right engine
. . . . . . .
OFF (If required)
SINGLE-ENGINE FAILURE FIELD/CATAPULT LAUNCHMIAVEOFF *I.
Set IO0 pitch attitude unit5 AOA maximum).
on the waterline
(14
‘2.
Rudder . . . . . . . . . Opposite Roll/Yaw . . . . . . . . . . . . . . Supplemented by Lateral Stick
(affected
l 6. Flreextingulsher
‘4.
Landing
gear
‘5. Jettison BLOWN
TIRE
. . . . . . . . . . . . . . . UP
. . . . . . . . . . . .
If Required
DURING
TAKEOFF
TAKEOFF;
ABORTED OR AFTER LANDING TOUCHDOWN *I.
Nosewheel
steering
pushbutton
*I. Unload aircraft If greater
When
(OSg to 1.0 g).
1.1 Mach:
than
1.1 Mach
. . . . . . . . . . . . . .
. . . . . . . Smoothly
to IDLE
If EGT above 935 “C and/or englne response abnormal: l 4. Throttle
(stalled engine)
. . . . . . . .
OFF
ENGINE FLAMEOUT ‘I. Throttle
. . . . . . . . . . .
l 2. BACK UP IGNITION switch SPOILER BK
MIL
or less:
. . . . . . . . Engaged
‘2. ANTI SKID SPOILER BK switch . . . . . . . . . . . .
. . . Depress
COMPRESSOR STALL
-2. Both throttles
. . . . . . . As Required for Positive Rate of Climb
. . . . . . .
-7 Climb and decelerate.
*3. Both throttles l 3. Both throttles
englne)
IDLE of Above (affected englne) . . . . . . . ON
NAVAIR
If hung
start or no start:
‘3. Throttle If still hung
‘2. Rudder and stick
. . . . . . . or,no
Cycle OFF, Then IDLE (affected engine)
. . . . . . . . . . SEC
is operable,
perform
If both engines flamed crossbleed not possible: ‘5. Airspeed RAMPS
out/inoperative
ELECTRICAL *I.
Land
to below 1.2 TMN. INLET RAMPS switch
. . .
. . . . . . . . . .
SAS or spoiler
l 3. YAWSASswltch
Inputs
ECS LEAKS/ELIMINATION AND FUMES
STOW
OFF
*2. OBOGS master switch
‘4. Canopy
LIGHT LOSS
UNCOMMANDED
ROLL
‘2. Throttles
. . . . . . . . . . . . . BothIDLE . . . .
Opposite
. . . . . . .
OFF
OFF
. . . . . . . BACKUP
If no recovery:
*5. Roll SAS - On; Stick Needle and Aft.
Into Turn Needle
‘6. Controls.
Full Into Turn
. . . . . . . . . . . NEUTRALIZE
*5. Canopy
. . . . . . . . . . . . . . . Jettison
“9. EJECT
. . . . . . . . (RIO Command
INVERTED
l l. Stick . . . . . . . . . . . . . Full Aft/Neutral Lateral, Harness - Lock Throttles
switchDUMP
‘3.
Rudder
. . . . . . . . . . .
OPEN
CANOPY
If recovery
. . . . . . . . . . . . . Both IDLE . . . .
Opposite
Turn Needle/Yaw
Indicated:
*4. Controls.
. . . . . . . . . . . . . Neutralize
“5. Recover at 17 units AOA, thrust
. . . . . . . . . . AND/OR
PILOT
YAW
l l. If flap transltlon: FLAP handle . . . . . . . Prevlous
Posltlon
Eject)
DEPARTURE/SPIN
‘2.
RIO’S
-
arrow
indicated:
35,000 Feet
WITH
Turn Needle/Yaw
If flat spin verified by flat attitude, increasing Yaw rate, increasing eyeball-out g, and lack of pitch and roll rates:
. . . . . . . . . . . BOOST CLOSE (canopy remalnlng)
l 2. EJECT CMD lever
. . . . . . . . . . . Forward/Neutral Lateral, Harness-Lock
. . Pull @Al, LBI)
“3. If smoke or fumes present:
“4. RAM AIRswItch
SPIN
‘7. Recover at 17 units AOA, thrust as required.
OF SMOKE
‘1. AIR SOURCE pushbutton
PRESS
DEPARTURE/FLAT
present:
. . . . . . . , . . . .
a. AltitudeBelow
UPRIGHT
If recovery
l 2. ROLL and PITCH CMPTR AC cb’s
LAD/CANOPY LIGHT/CANOPY
. . . . . . MAX THRUST w WUlM
If yaw rate is steady/increasing, spin flashing, or eyeball-out g Is sensed:
movements.
R generators
b. CABIN
englne
l 4. Stick . . . . . . . . . . . .
UGHT
FIRE
If uncommanded
l 4. Downwlng
l 3. Rudder
‘1. Avoid abrupt throttle
‘3. Affected
or
Roll/Yaw
AOA . . . . . . . . . . . . . Below 12 Unite
l l. Stick.
a crossbleed
. . . . . . . . . . . . . 450 Knots (altitude permitting)
LIGHT/INLET
‘2. Decelerate
. . , . Op~oslte
start:
‘4. ENG MODE SELECT If one engine airstart.
3.
Of-Ff4AAD-1
If spinning
below
10,000
‘6. EJECT . . . . . . . .
as requlred.
feet AGL: (RIO Command
Eject)
NAVAIR
WFl4AAD-I
WARNING/CAUTION/ADVISORY
(WPIRNING( ADVISORY
LIGHTS/DISPLAY
LEGENDS
WARNING LIGHT AND/OR DISPLAY LEGEND (HUD, HUDIMFD, MFD) DISPLAY LEGEND
l-
I
ACTION
CAUSE
LIGHT/LEGEND
VIA tracking radar detected.
4s briefed.
4CLS or autopilot disengagement.
rake control for manual landing approach.
4s briefed.
AAI ZERO (MFD) 4irbome interceptor tracking detected.
4s briefed.
Designated engine anti-ice is on or anttce valve has failed opposite commanded position.
If INLET ICE light on, perform procedure.
I L AIICE R AlICE
If INLET ICE light off, inlet ice may be on though not commanded. Report to maintenance.
(MW
A/P REF (MFD)
appropriate
Selected A/P reference is not engaged.
Depress autopilot reference enoaoe AIP reference mode.
Improper ALQ-165 position.
As briefed.
pushbutton
to
m WW ALQ-165 self-protection overheated.
jammel
Secure ALQ-165.
MD) L AUG R AUG
AB is not available and opposite engine is limited to MIN AB if ATLS is on.
No Immediate action operational impact.
required:
Autopilot or reference failure.
I. MASTER RESET pushbutton - Depress. If light remains illuminated:
MD)
2. PITCH AND ROLL COMPTR AC cb’s (LBI, LAI) - Cycle. Autothrottle
Warning, 0 1RIGINAL \
has been disengaged.
Caution,
Advisory
LlghtslDlsplays
1. Assume manual/boost control. 2. Satisfv APC interlocks. 3. Reengage APC AUTO. (Sheet 1 of 15)
assess
WARNING/CAUTION/ADVISORY LIGHT/LEGEND AUX FIRE EXT
LIGHTS/DISPLAY LEGENDS
CAUSE Low-extinguisher
ACTION
agent pressure.
Report to maintenance.
W”) lerNcs_l
a “o’u’c”T”
Totalizer less than preset value.
Pilot option.
Bleed duct overheat condition or ECS regulating failure.
‘1. AIRSOURCE - OFF. l 2. OBOGS - BACKUP. l 3. If smoke or fumes present: a. Altitude Below 35,000 feet. b. CABIN PRESS - DUMP. l 4. RAM AIR - OPEN. 5. Airspeed - ~300 Knots/O.6 Mach. 6. Nonessential electrical - Secure. 7. CANOPY DEFOG/CABIN AIR lever CANOPY DEFOG. l 6. Land as soon as possible. If electrical fire:
[pEii&l
Operating in auxiliary brake mode, antiskid failure, or parking brake set. Backup oxygen less than 206
psi.
9. Follow electrical fire procedures. I. Turn antiskid off. 2. Cautious brake application. 3. Release emergency brake. E/U OXY LOW light (both cockplts): I. BACKUP OXY PRESS If BACKUP Ox/
Check.
PRESS < 200 PSI:
2. Cabin alt - Less than 10,000 Feet. 3. Oxygen supply - OFF. 4. Oxygen masks - Release One Side. Before landing:
5. Oxygen masks and supply -ON. 6. Emergency oxygen - Activate. If BACKUP OXY PRESS > 200 psk
2. BACKUP OXY PRESS -
Monitor.
B/U OXY LOW light (pllot only): 1. I303 ~~;TFyIu - Check In (7A4). 2. BACKUP OXY PRESS - Check. B/U OXY LOW Llght (RIO Only): 2. BACKUP OXY PRESS Wamlng,
Caution,
Advisory
Lights/Displays
(sheet 2 of 15)
Check.
WARNING/CAUTION/ADVISORY
ACTION
CAUSE
LIGHT/LEGEND CABIN a PRESS
LIGHTS/DISPLAY LEGENDS
Cabin pressure failure.
I. Oxygen mask -
ON.
If below f 5,000 feet:
2. CABIN PRESS CADC failure.
m
Cycle.
1. MASTER RESET - Depress. 2. CADC cb’s (LA2. LB2, LC2. LD2) Cycle. 3. MASTER RESET - Depress. If light still remains illuminated:
4. Remain below 1.5 Mach. ‘I. Canopy - BOOST CLOSE (canopy remaining). l 2. EJECTCMD - PILOT. 3. Airspeed and altitude - Below 200 Knots/15,000 Feet. 4. Seatsandvisora - DOWN. 5. If canopy has departed aircraft, perform controllability check. 6. Land as soon as possible.
Canopy not locked.
m
m
m
Controls and displays hot.
1. Select cabin air. 2. WCS switch OFF.
Improper operation of mnverterInterface unit.
Expect loss of CIU inputs/outputs.
Converter-interface
Pull cb’s 3E7,4El,
VFW CIU HOT
CLSN
unit overheated.
RIO has collision steering selected.
4E2.
Pilot option.
(HUD) Warning,
ORIGINAL
Caution,
Advisory
LlghtdDlsplays
72
(Sheet 3 of 15)
NAVAIR
WARNING/CAUTION/ADVISORY LIGHT/LEGEND COOLING AIR (IN FLIGHT)
01-F14AAD-1
LIGHTS/DISPLAY LEGENDS
CAUSE
ACTION
Indication of possible bleed duct failure forward of the pressure primaly heat exchanger and 400 “F modulating valve.
1. AIR SOURCE - OFF. 2. OBOGS - BACKUP. If associated with any other direct or indirect indication of ECS malfunction:
3. Perform ECS Leak/Elimination of Smoke and Fumes Procedure. If not associated with any other direct or indirect indication of ECS malfunction and operational requirements dictate temporary reselection of mm to regain lost service
systems: 3. 4. 5. 6. COOLING AIR (ON DECK)
inadequate
cooling.
AIRSOURCE - RAM. RAM AIR door - FULLY OPEN. AIR SOURCE - OFF. Land as soon as practicable.
I. AIR SOURCE - Check L ENG. R ENG, or BOTH ENG. 2. Throttles - Advance Without Closing Nozzles. 3. CANOPY DEFOG/CABIN AIR lever - CANOPY DEFOG. 4. ECS - MAN/FULL HOT (CONT). If light goes auf:
5. Throttles - IDLE. 6. ECS - As Desired. If light remains illuminafed:
7. Secure systems. Continuous-wave
emitter detected.
As briefed.
I DEU HOT (MFD) DPI HOT DP2 HOT (MFD) DSS HOT W=W EMERG JETT PUSHBUTTON/ ACK LIGHT
Data entry unit oveheated.
Expect loss of DEU.
Display processor overheated.
Pull cb’s lG2,1G4,1G6,3F4,4F3,4F6.
Data storage set overheated.
Expect loss of DSS.
When depressed with weight off wheels, activates emergency stores jettison signal to the SMS and illuminates light for 5 seconds. Jettison function is disabled with weight on wheels.
None.
Warntng,
Caution,
Advisory
LlghtslDlsplays
(Sheet 4 of 15)
WARNING/CAUTION/ADVISORY
LIGHTS/DISPLAY
CAUSE
LIGHT/LEGEND Low-extinguisher pressure.
ENG FIRE EKT WW
ACTION
agent
Report to maintenance.
Engine mode control in secondary. a
LEGENDS
L ENG SEC R ENG SEC
If engine transfers to set mode: I. Throttle - Less Than MIL. 2. ENG MODE SELECT - Cycle. If PRI mode restored: 3. Maintain constant subsonic airspeed in level flight. 4. Affected L or R AICS cb - Cycle. If engine fwmelfls in SEC: 3. ENG MODE SELECT - SEC. 4. Avoid abrupt throttle movements. 5. Land as soon as practicable.
LFIRE R FIRE
*
Fire/overheat nacelle.
condition in englne
If HUDh4FD message: Message is a repeat of a discrete from the fire detect system. If FIRE warning light is off and FIRE DET TEST checks 4.0, then assume message was incorrect and keep engine on line.
0 (HUD/MFD)
If FIRE warning light and message: ‘I. Throttle (affected engine) ‘2. AIRSOURCE - OFF. l 3. OBOGS - BACKUP.
-
IDLE.
fflight goes OFF and no secondary Indications: l 4. MASTER TEST -
FIRE DET TEST.
If light remains illumlnafed, FlRE DET TEST fails, or other secondary indications: l 5. ‘6. ‘7. l 6. ‘9.
FUEL SHUT OFF - Pull. Throttle - OFF. Climb and decelerate. Fire extinguisher - Depress. Refer to SingleEngIne Cruise Operations. 10. Land as soon as possible. 11. If fire persists - Eject.
Wamlng,
ORIGINAL
Cautlon,
Advlsory
Lights/Displays
(Sheet 5 of 15)
NAVAIR OMl4AAD-1
WARNlf LIGHT/LEGEND
i/CAUTION/ADVISORY LIGHTS/DISPLAY LEGENDS CAUSE
ACTION 1. 2. 3. 4.
Airspeed - Below 225 Knots. FLAP handle Ensure Full Up. MASTER RESET - Depress. While holding MASTER RESET pushbutton depressed, maneuver flap thumbwheel - Full Forward. 5. Check FLAP light out. If after landing/takeoff flap transition, or ~ilfuminatton after above procedures:
Yap position disparity with ommanded position or flap/slat Isymmetry.
1. MASTER RESET - Depress. 2. If light still illuminated, check FLAP handle and indicator position, then proceed with appropriate steps below. Flap handle up and t7aps not fully retracted: 1. Flap handle - EMER UP. Flap handle up and flaps indicaUng full up: 1. Flaps - Cyde. Flap handle down and flaps not f&y extendeti I. Wing sweep - Ensure at 20”. Flap handle down and flaps down: ,I. Wing sweep - Ensure at 20”. 2. MASTERRESET - Depress. Flap and slat asymmetry: Refer to Chapter 14. Check engine gauges. If invalid, report anomaly to maintenance: ff valid petfom
the following:
*I. Throttle - IDLE or Above. ‘2. BACKUP IGNITION switch If hung start or no starl:
WFD)
l 3. Throttle
Warning, Cautlon, Advisory
LlghtdDlspltiya
75
-
ON.
Cycle OFF, Then IDLE.
(Sheet 0 of 15)
ORIGINA
--
\\\\\~\~~\~~~~~~~~~-----.-------
NAVAIR 0%F14AAD.1
WARNING/CAUTION/ADVISORY
LIGHTS/DISPLAY
CAUSE
LIGHT/LEGEND
LEGENDS ACTION
Engine flameout.
If sf/// hung or no start:
giii%J
l 4. ENG MODE SELECT - SEC. If one engine is operable, perfom, a crossbleed airstart.
WW
If both engines flamed crossbleed not possible:
out//noperafive
o
‘5. Airspeed - 450 Knots. 6. OBOGS - BACKUP. When stari complefe: 7. BACKUP IGNITION - OFF. 8. ENG MODE SELECT - PRI. 9. OBOGS - ON. When primary mode restored: 10. Maintain constant subsonic Mach in level flight. il. Affected AICS cb - Cycle.
LL%L
Usable fuel in L and AFT or R and FWD fuselage tanks 1,000 pounds.
1. DUMP switch - OFF. 2. Fuel distribution - Check. If wing ancV0.r e&ma! fuel remaining:
RLF$L lIlIlll
‘PEk
3. WINGIEXTTRANS - ORIDE. 4. Land as soon as practicable. Sump tank boost pump discharge fess than 9 psi.
cz3RPRFEUSESL
1. Both throttles - MILPower or Less. 2. Restore aircraft to 1 .Og flight. If both lights remain on: 3. Increase positive g’s to > l.Og. ,4. Descend below 25,000 feet. 5. Maintain cruise power settings or less. 6. Land as soon as possible. If one light remains on: 3. .No afterburner above 15,000 feet. 4. Fuel distribution - Monitor. 5. Land as soon as practicable.
L GEN R GEN lIlIIIl m
1. Gemmtor - DFF/RESET,ThsnNORM. If generator does not reset:
Generator failure and/or disconected from its ac bus.
2. Generator
-
TEST.
Firing logic met. Pilot’s trigger will Ire weapon when squeezed.
Pilot optton.
Combined or flight pump discharge pressure 2,100 psi or less.
Refer to Chapter 14 for appropriate procedure.
Wamlng,
Caution,
Advisory
Lights/Displays 76
(Sheet 7 of 15)
WARNING/CAUTION/ADVISORY LIGHT/LEGEND HZ TAIL m AUTH
IFF IFF ZERO (MFD)
LIGHTS/DISPLAY LEGENDS
CAUSE
ACTION
CADC fsilure or failure of actuatorsto follow schedule.
1. MASTER RESET -
Depress.
If fight mmalns illuminated: 2. ROLL STAB AUG - OFF. 3. Above 400 knots, restrict lateral control to onequarter throw. 4. ROLL STAB AUG - ON for Landing. 5. Do not select OV SW after landing.
Mode 4 interrogation received; no reply generated. Improper IFF transponder operation.
As briefed.
Inlet guide vanes off schedule.
AICS fail operation mode in use.
m,
As briefed.
Stall margin may be very slightly reduced but still remains satisfactory and greater than that in SEC mode.
WW
High-power thrust may be reduced. IMU WW INS CM=‘) INTEG TRIM
Improper operation of inertial measurement unit.
Secondary navigation mode is in use.
Improper operation of inerttal navlgstlon system.
Secondary navigation mode is in use.
Power loss or discrepancy Input slgnal and posltlon
MASTER RESET.
Computer malfunctton mlsposltlonlng.
between
or ramp
‘1. Avoid abrupt throttle movements. ‘2.. Decelerate below 1.2 TMN. ‘3. Affected INLET RAMPS - STOW. If RAMPS light remains illuminated: 4. Throttle - 80 percent or Less. 5. Affected AICS cb - Pull. 6. Affected INLET RAMPS - AUTO. 7. Land as soon as practicable. If INLET light only illuminated, attempt AICS pivgmm reset: 4. Decelerate betow 0.5 TMN. 5. Affected AlCScb - cycle. If INLET light goes of?? 6. Affected INLET RAMPS - AUTO. If INLET LIGHT remains Mumhated: 6. Affected AlCScb - Pull. 7. Affected INLET RAMPS 6. Remain below 1.2 TMN.
AUTO.
\\\\~~~~~~~-~-~rr--------------------NAVAIR Ol-F14AAD-1
u-
WARNING/CAUTION/ADVISORY
ACTION
Icing condition exists in inlet or ENGlPROBE ANTI-ICE switch is on.
1,. Select ORIDUON. When clear of Mng conditions:
liIIz3
2. ANTI-ICE IPF
IRSTS HOT WW JTID HOT WD) LADI CANOPY cIIzz.2
LADI CANOPY
m LAUNCH BAR (Ground) LAUNCH BAR
LEGENDS
CAUSE
LIGHT/LEGEND INLET ICE
LIGHTS/DISPLAY
-
AUTO/OFF.
JTIDS is failed, a momentary glitch, or 20-percent duty cycle has been exceeded.
Select IPF RESET on JTIDS control panel.
Infrared search and track system overheated.
Secure system.
Possible loss of cooling air or a high JTIDS transmit duty cycle.
Secure system.
With RIO CANOPY light, canopy unlocked.
*I. Canopy - BOOST CLOSE. ‘2. EJECT CMD - PILOT. 3. Airspeed and altitude - Below 200 Knots/15.000 Feet. 4. Seats and visors - DOWN. 5. If canopy has departed aircraft, perform controllability check. 6. Land as soon as possible.
Without RIO CANOPY light, ladder not stowed. Launch bar unlocked, engines less than MIL thrust. Launch bar not locked in up position or cocked nosegear.
(Flight)
1. Airspeed minimum. 2. Obtain in-flight visual check if possible. 3. Land as soon as practicable. As appropriate.
1. Landing gear - Leave Down. 2. Obtain visual inspection. If nosegear cocked, refer to Landing Gear Malfunction guide. If launch bar down or visual inspect/on not available: 3. Request removal of arresting cables for Reid landing. 4. Request removal of cmssdeck pendants I and 4 for CV landing.
L LO THR R LO THR
Designated engine may be producing less than expected thrust.
WW
If associated with RATS check, monitor englnr gauges and FEMS engine data for nomtal rpm FF, and temperatures. If no anomalies message is false alarm triggered by the hook If not associated with a RATS check, recon FEMS data and abort.
Warning,
Caution, Advisory Lights/Displays (Sheet 9 of 15)
78
WARNING/CAUTION/ADV~SORY 1JGHTILEGEND LOCK L MACH # R MACH #
LlGHTS/DlSPLAY
CAUSE
LEGENDS ACTION
Radar locked on target.
Pilot option.
Mach number signal to designated engine has failed.
In flight - Remain below 1 .I TNM. Small throttle reductions below MIL at high Mach can result in engine stall.
WV On deck - Assess operational speed restriction for mission. MACH TRIM
Failure of Mach trim actuator to follow program.
Impact of
1. MASTER RESET. 2. Retrim manually.
WW
i
MASTER CAUTION
a
MC1 MC2
Actuated by any caution light on caution panel.
Push to reset after discrete MSG noted.
Improper operation of mission computer.
Backup operation selected automatically.
Mission computer
Backup operation selected automatically.
M-7 overheated.
MC1 HOT mMC2 HOT WFD)
Engine fan rpm exceeds 106 percent.
1. Throttle - IDLE. Check rpm gauge for N2 and FEMS engine data on MFD for Nf to determine validity of overspeed message. If overspeed continues: 2. ENG MODE SELECT - SEC. If ovwspeed condition persists: 3. Throttle - OFF. 4. Refer to Single-Engine Cruise Operations. 5. Land as soon as practicable.
Engine core rpm exceeds 107.7 percent.
1. Throttle - IDLE. Check rpm gauge for N2 and FEMS engine data on MFD for Nt to determine validity of overspeed message. If overspeed continues 2. ENG MODE SELECT - SEC. If overspeed condition persists: 3. Throttle - OFF. 4. Refer to Single-Engine Cruise Operations. 5. Land as soon as practicable.
L Nl OSP Fl Nl OSP a WFD)
m WW
Warning,
Caution,
Advisoty
Lights/Displays
(Sheet 10 of 15)
WARNING/CAUTION/ADVISORY Nosewheel
LIGHTS/DISPLAY LEGENDS
steering is engaged.
Disengage when approprtate.
NWS ENGAGE
a
&i-iJtJ
Engine oil temperature limits exceeded or high scavenge oil tempemt”m,
On deck: 1. Throttle
-
OFF.
In flight: 1. Oil pressure - Check. 2. Throttle - 85parcantrpm. 3. If after 1 minute, light still Illuminated - Throttle OFF. 4. Land as soon as practicable. 5. Refer to SingleEngine Cruise Operations. 6. Relight engine for landing if necessary. UR OIL LO WD) B
Designated engine oil level Is approximately 2 quarts low Postflight. engine at idle.
Alert ground personnel: :
L or R oil press
servtclng required.
1. Throttle (affected englne)
7
IDLE.
If oil pressure below 15 psi, above 65 psi. or engine vlbtation: If shutdown
feasible:
2. Throttle (affected engine) - OFF. 3. Refer to SIngleEngine Crulsa Operation (Chapter 14). If shutdown
not feasible:
2. RPM - Set Minimum Rpm. 3. Avokl high-g or large throttle movements. 4. Land as soon as practicable. m
Low percent oxygen.
1. BACKUP OXY PRESS -
Channel 1 or 2 inoperative.
If single pitch or roll stab Ilght:
Check.
1. MASTER RESET - Depress. 2. If light remains lllumlnatad No Limitations. If both pitch or roll stab lights: I. 2. 3. 4. 5.
All-speed - Reduce to Stab Limits. Pitch - Not Restricted. Roll - 1.6 TMN. Wait IO seconds for self-test. PITCH CMPTR AC cb or ROLL CMPTR AC ob - Cycle (LA1 or LBi). 6. Recheck lights.
Warning, ORIGINAL
Caution,
Advboty
Lights/Displays
(Sheet 11 of 15)
NAVAIR
WARNING/CAUTION/ADVISORY I 1 LIGHT/LEGEND
1
LIGHTS/DISPLAY
malfunction
or
IRefer
to INLET light.
1. Tailhook - DOWN. ff conditions permit
RATS operation enabled.
RATS
LEGENDS ACTION
CAUSE Computer/mechanical ramp misposittoning.
0%F14AAD-1
2. ANTI ICE CONTR HOOK CONT/ WSHLDIAIR cb - Pull (8C2). ALG-165 identification
RCV
is receiving signal.
threat
14s
briefed. 1. Reduce speed. 2. Check FLAP handle. 3. MASTER RESET.
Flaps fail down, airspeed 225 knots; total temperature 388 ‘F, 2.4 M (HUDNFD) RDP FAN
I
RDR HOT WW
Radar data processor fan failure.
IExpect overheat.
Radar operation on ground is possible.
I?adar POWER switch to STBY (as aapplicable).
Radar system overheated.
select STBY.
Warning or caution message(s) displayed on MFD.
m
I
being
ti appropriate
to displayed massage(s).
I 7 single pitch or roll stab light:
Channel 1 or 2 inoperative.
1. MASTER RESET - Depress. 2. If light remains illuminated Limitations. f both pitch or roll stab lights:
-
No
1. 2. 3. 4. 5.
Airspeed - Reduce to Stab Limits. Pitch - Not Restricted. Roll- 1.6TMN. Wait 10 seconds for self-test. PITCH CMPTR AC cb or ROLL CMPTR AC cb - Cycle (LA1 or LBI). 6. Recheck lights. Warning,
Caution,
Advisory
Lights/Displays
81
(Sheet 12 of 15)
ORIGINAL
WARNING/CAUTION/ADVISORY
1. MASTER RESET - Depress (10 seconds). 2. If light remains illuminated - Above 250 Knots, Restrict Rudder Inputs to < IO”.
CADC failure or failure of actuator to follow schedule.
Improper ALR-67 receiver operation.
m
ACTION
CAUSE
LIGHT/LEGEND
p%FJ
LIGHTS/DISPLAY LEGENDS
radar
warning
As briefed.
WW RWR HOT SAHRS (1
ALR-67 overheated.
Secure ALR-67.
SAHRS not available.
Avoid IFR flight if INS is degraded.
Steady -
As briefed.
Flashing
a
SDU ALARM
Tracking radar detected. -
Missile launch detected.
Improper operation of KY-56.
As briefed.
Overheat or pump loss in radar coolant loop.
1. RADAR COOLING - OFF. 2. RDR - OFF. 3. APG-71 PUMP PH A, 6, C cb - Pull. If other conditions exist that may /nd/cate aI; ECS malfunction, either directly or indirectly, perform ECS leak/elimination 01 smoke and fumes procedures:
WW SENSOR COND
4. Land as soon as practicable. SHOOT SMS HOT MD) m
Target meets LAR requirements. Store management overheated.
As briefed.
system
Symmetric spoiler detctor has locked down spoilers.
If assoc/ated
with abnormal roll andlor yaw:
I. Counter roll with at least I inch of lateral Stick.
2. Visually check spoiler position/ operation. Refer to Chapter 14. Warning,
Caution,
Advisory
Lights/Displays
82
(Sheet 13 of 15)
NAVAIR
WARNING/CAUTION/ADVISORY LIGHT/LEGEND
a
LIGHTS/DISPLAY
CAUSE
LEGENDS ACTION
Starter solenoid air valve open after engine start.
START VALVE
Ol-l=14AAD-1
1. Ensure ENG CRANK 2. AIRSOURCE - OFF. If on deck: 3. Throttle If ainbome:
OFF.
OFF.
3. ENG START cb - Pull (RFI). 4. OSOGS - BACKUP. LSTALL R STALL
*
Engine stall and/or overtemperature.
0 (HUD/MFD)
‘1. Unload aircraft (0.59 to 1 .Og). If greater than f. I Mach: l 2. Both throttles - MIL. When I. 1 Mach or less: ‘3. Both throttles
-
Smoothly to IDLE.
Check EGT and FEMS engine data for TST to determine validity of stall message. If EGT above 935 “C and/or engine response abnormal: l 4. Throttle (stalled engine) - OFF. If EGT normal anNor airstart successful: 5. Perform engine operability L TBT OT R TBT OT m
check.
1. Throttle - IDLE. Check EGT gauge and FEMS engine data on MFD for TBT to determine validity of overtemperature message.
Turbine blade overtemperature.
WW
If still 0verfamperefui-e: 2. Throttle TRANSIRECT
Warning,
Caution,
Advisory
OFF.
1. Generator - OFF/RESET, Then NORM. 2. If both lights remain illuminated, select EMERG GEN on MASTER TESl panel. 3. Land as soon as practicable.
Lack of dc output from either or both T/R.
Landing gear not down with flaps down and either throttle s 85 percent.
-
Lower gear.
Lights/Displays
(Sheet 14 of 15)
AVAIR 0%F14AAD-1
WARNING/CAUTION/ADVISORY
LIGHTS/DISPLAY LEGENDS ACTION
CAUSE
LIGHT/LEGEND
ailure of both wing-sweep pider detent disengaged.
channels OI
\dvisofy light only. no loss of normal wntfoi: 1. MASTER RESET - Depress. MING SWEEP light and W/S legend, 3utomafic or manual control:
WW
nc
1. Airspeed - Decelerate to 0.9 or Less. 2. Check spider detent engaged. 3. MASTER RESET - Depress. I WlNG SWEEP //ght and W/S caut/on legenc Uuminate again: 4. WING SWEEP DRIVE NO.1 and WG SWP DR NO.2 MANUV FLAP cb Pull. 5. Emergency WING SWEEP handle Comply With Schedule. defer to Chapter 14. WING SWEEP WSHLD HOT
:ailure of one wing-sweep
channel.
Advisory light only: I. MASTER RESET -
:enter windshield
temperature
300 “F.
Depress.
1. WSHLDAIR - OFF. ff light remains illuminated: 2. 3. 4. 5.
AIRSOURCE - OFF. OBOGS - BACKUP. RAM AIR - OPEN. Reduce airspeed < 300 knots or 0.8 Mach. 6. Land as soon as practicable. 1. MASTER RESET - Depress. 2. If light remains illuminated Below 1.0 TMN.
%st failure in yaw SAS.
I. YAW STAB - OFF. 2. MASTER RESET - Depress. If light remains illuminated:
second failure in yaw SAS.
3. Decelerate below 1.0 TMN. 4. YAW SAS PWR cb’s - Cycle. 5. If light remains illuminated, remain below 1.0 TMN. If light out: 6. Reset YAW STAB switch. Warning,
)RIGINAL
Caution, Advisory Lights/Displays (Sheet 15 of 15)
84
Stay
NAVAIR Ol-F14AAD-1
CHAPTER
Ground
12
Emergencies
12.1 ON-DECK EMERGENCIES l
12.1.1 Engine Fire on the Deck PILOT
l
* 1. Both FUEL SHUT OFF handles- Pull. l 2. Both throttles - OFF. 3. If conditions permit-Windmill
Note If hot starton deck,windmill engineuntil EGT is below 250 “C before attempting restart. If wet start, continue cranking until tailpipe is clear of fuel.
12.1.3 START VALVE Light After Engine Start Engine.
1. EnsureENG CRANK switch-OFF.
4. BACK UP IGNITION switch - Check OFF.
2. AIR SOURCE pushbutton- OFF. 3. Throttle (affectedengine)- OFF.
Excessive windmilling of engine with oil system failure may increase combustion/ smoking (blue/white) and result in greater difficulty extinguishing, causing further damageto engine.
l
If the starter valve doesnot close during engineaccelerationto idle ‘pm, continued airflow through the air turbine starter could result in catastrophicfailure of the starterturbine.
l
If theSTART VALVE cautionlight illuminatesafterthe ENG CRANK switch is off, or if the ENG CRANK switch does not automaticallyreturnto the off position,ensurethatthe ENG CRANK switch is off by 60-percentrpm andselectAIR SOURCEto OFF to precludestarteroverspeed.
If FIRE light and/orother secondaryindications: 5. Fire extinguisher pushbutton(affectedengine) -Depress. 6. Egress. RIO 1. Notify ground and/ortower.
12.1.4 Uncommanded Engine Acceleration on Deck. Uncommandedengineaccelerationmay or may not be associated with throttle movement. Uncommandedthrottle(s)are characterizedby increasedor decreasedthrottle settingscausedby failuresof thethrottle control system.
2. Egress. 12.1.2 Abnormal Start 1. Throttle (affected engine)- OFF. 2. BACK UP IGNITION switch-Check
OFF.
Uncommandedengine accelerationwithout throttle movement is a result of an AFTC or MEC failure normally associatedwith one engine.Selection of eitherL 12-l
ORIGINAL
0
NAVAIR QI-FI4AAB1
or R ENG select switch to SEC may restore throttle authority. * 1. Paddleswitch - Depressand Hold. ‘2. Throttle(s) - As Desired.
egressdirectly t?om the cockpit, aircrew should grasp the canopyrail with both hands,hang to full body extension,anddropto the ground.A parachute-landingfall maneuvermay be required to minimize risk of injury. Spacing of pitot static probes along both sides of the fonvard fuselagewill allow for an unobstructedegress.
‘3. ENG MODE SELECT - SEC. Note In SEC mode, nozzle is commanded fully closed. ‘4. THROTTLE MODE switch -MAN. If Engine(s) still uncommanded and aircraft is not in catapulttension: 5. Throttle(s) - OFF. 6. FUEL SHUT OFF handle(s)-Pull.
l
Note Approximately 50 pounds of force must be applied to the throttles to override the boost system to ensuredisengagementof APC BIT self-test. The quickest and most reliable method to secureuncommandedthmttles is to revert thethrottle systemto themanualmode and securethe throttle(s).Since manual is, by design,a backupmode, thethrottlerigging may not be the sameasthe boost mode. It maytakeahardsnappingmotiontoposition the throttle into OFF. If throttle(s)am misrigged in manual mode, the OFF position may not securehe1 flow to the engine. Both throttles cannotbe securedsimultaneously; however, reverting to manual mode will allow both throttles to be repositioned to IDLE simultaneously.
\ \
12.1.5 Ground Egress Without Parachute and Survival Kit. Methods and routes of ground egress will vary with the situation. In all cases,kneeling the aircraft (conditionspermitting) via the nosestrut switch will facilitate a safer exit for the aircrew. If sufficient time doesnot exist for groundpersonnelto deploy the boarding ladder,aircrew should egressto the rearof the aircraft, over the horizontal stabilizers or wings, or directly to the deck from the cockpit if the tail is over water. In the caseof fne, the location and intensity of the fne will dictatethe safestescapemute. If electingto
Standingandjumping from the cockpit or attempting to slide down the nose of the aircraft during groundegresscanresult in severeinjury. If the ENG/PROBE ANTI-ICE switch is in the ORIDE position, touching the pitot probeswith bare skin will causeburns. 1. Kneel aircraft (if possible). 2. Canopy-OPEN
or JETTISON
3. Parking bmke - Pull. 4. Ejection seat- SAFE. (Safeby raising the SAFE/ARMED handle) 5. All fittings (Restraintfittings andoxygenhose)Release. Note To retain survival kit, do not releaselapbelt restraintfittings. 12.1.6 Emergency Enfrance. SeeFigure12-1forpmceduresfor enteringthe cockpit for emergencyrescue. 12.1.7 Weight-On-Off Wheels Switch Malfunction. There are WOW switches on the left and right main gearthat interactwith many aircraft subsystemsto provide safetyinterlocks. The interlocks preventoperation of various componentsor systems on deck or in Eight, as appropriate.
Failure of the letI or right WOW switchesto the in-flight mode can causeloss of engine ejecior air to the ID& and hydraulic heat exchangers causing thermal disconnect and/orheatdamageto the generatorsand aircraft hydraulic systems.
I
NAVAIR Ol-Fl4AAD-1
1. PUSHBUTTON TO OPEN DOOR. 2. SQUEEZE T-HANDLE AND PULL TO JETTISON CANOPY.
NORMAL I T E
COCKPIT EN lRANCE I
T
Figure 12-l. EmergencyEntrance
NAVAIR Of-Fl4AAD-I
(,,,,,I
12.1.7.1 Failure Of Weight On-Off Wheels to In-flight Mode INDICATIONS:
With faihne.of the WOW switch to the inflight mode, the following l%nctionsare enabled
1. WOW acronym displayed 2. Approach indexersilluminated. 3. Nozzles may be partially closed at idle rpm. 4. Nosewheel steeringinoperative. 5. Launch bar light illtinatcd >lOO).
(if nosegearturned
6. Ground-roll braking inoperative. 7. Wing-sweep MASTER TEST disabled. 8. Oversweepdisabled. 9. OutboardspoilermoduleonwithFLAPhandleUP (wings less than 62’).
a. Radarcanscanandradiate. b. ALQ-165 can transmit. c. Probeheaterswill be on in AD-TO. d. ALQ-167 can radiate(TARPS).’ e. BOL chatTcan dispense. 12.1.8 Binding/Jammed Deck
1. Holdlightpmssumagaimtbindh@mshictiontothcilitate maintenancetroubleshootingpmce&ma. m
10. Aircraft will not kneel. If two or more of the preceding anomalies are detected,the following action should be taken:
FllgM Controls On
Do not attempt to free controls by force, as further damageto Sight control syatemmay fMllt.
1. Clear runway (if applicable). 2. Generators- OFF. 3. Throttles - OFF (after downlocks arein place).
2. Abort mission. 12.1.9 Brake Failure at Taxl Speed *l. ANTISKID SPOILER BK switch BK or OFF.
SPOILER
2*. NWS - Verify Engaged Failure of the lefl or tight WOW switchesto the in-flight mode can causeloss of engine ejector air to the IDGs and hydraulic heat exchangers causing thermal disconnect and/orheatdamageto the generatorsandaircratt hydraulic systems.
1. RDR switch - OFF.
3.* Parking bmke - PULL (if requhed) (applying parking brake will lock both main wheels.) pi&-) Complete loss of hydraulic fluid throughthe wheelbrakehydraulic lines will render the parking brake ineffective. If brakesstill inoperative: 4. Hook - DN.
NAVAIR Ol-Fl4AAD-l
7 \L
7. Both throttles-OFF
(If required).
If collision imminent, DO NOT delay step7. After lowering the hook,NWS will automatically centerand will remain centereduntil NWS is cycled. 5. Lights-ON. 6. Notify ground and/ortower.
p&G-) During shipboardoperations,aircrew should not delay ejection decision if aircraft departure t?om flight deck is imminent.
NAVAIR 0%F14AAD-1
CHAPTER
13
Takeoff Emergencies 13.1 ABORTED TAKEOFF Emergencies during takeoff are extremely critical andrequirefast analysisandquick decisionby thepilot. The decisionto abortshouldnot bedelayedjust because emergencyarrestinggear is available at the end of the runway. Whether to abort or continue the takeoff depondson the length of runway remaining,refusalspeed, best single-engineclimb speed,and the arrestinggear available.Failure of either engine,a fm warning light, or a blown tire during takeoff dictates an immediate abort if enoughrunway is available. The ejection seats will provide safe escapeat ground level and low airspeeds.Therefore, if a safe aborted takeoff cannot be performedand takeoff is impossible, eject. In an abortedtakeoff, aerodynamicground-roll braking is assistedby simultaneousdeflection of all spoilers (flaps down) or inboard spoilers only (flaps up) to 55” when both throttles are retardedto IDLE. Note Moving flap handledown activatesoutboard spoilersto assistin aerodynamicground-roll braking
Rolling over an arresting wire with brake pressureappliedmay result in blown tires. Ifarresting gearis available,useit to avoid rolling off the runway. Always inform the control tower of your intention to abort the takeoff and engagethe arresting gear,so that aircraft landing behind you can be waved off. Lower the hook in sufficient time for it to Rdly extend (normally 1,000 feet before engagement).Use nosewheelsteeringto maintain directional control and aim for the centerof the runway. At night, use the taxi light to seethe arrestinggear. If off centerjust before engagingthe arrestinggear,do not turn the aircraft but continuestraightahead,parallel to the centerline. If aborting with a blown nosewheeltire, it is likely thateitheror both engineshaveFOD. In the eventof any blown tire during an abortedtakeoff, the flaps should not be moved until they can be inspectedfor FOD. Aircraft control following loss of an engine during the takeoff roll is a function of thrust setting and airspeed.In most cases,anabortedtakeoffwill berequired. Refer to paragraph 11.8 for additional discussion of takeoff configuration, asymmetric thrust flight characteristics.
When securingthe starboad engine, use caution to preventinadvertentshutdownof both engines.If both enginesareshutdown,hydmulic pressureis lost, alongwith antiskid,nosewheelsteering,spoilerbraking, andnormal braking. Full a8 stick is used to augment aetodynamic 13.1.1 Aborted Takeoff Checklist braking.Careshouldbe takenwhile positioningtbe stick a8 to avoid any noserotation.The a&aft’s tendencyto l 1. Throttles IDLE. rotateisaccentuatedwiththeflspsupbecauseofincreased longitudinal control effectiveness,and aft stick must be ‘2. Speedbrakes- EXT. appliedat a slowerrateto avoidrotation. ‘3. Stick-AFT.
Maximum braking effort in aborts initiated nearrotation speedat takeoff grossweights may result in blown tires evenwith antiskid engaged.
Note The stick should be positioned fully at?at a rate that will not causeany noserotation. *4. Hook - DN (1,000 feet before wire) *5. Brakes-As
Required.
NAVAIR Ol-Fl4AAD-1
*5. Brakes-As
Required.
*6. Right engine- OFF (if required). Note Ifperforming no flap/maneuveringflap takeoff, lowering the flap handle slightly during an abort will deploy all spoilersfor groundroll braking if SPOILER BRAKE or BOTH is selected,assisting in decelerating the aircraft. 13.2 SINGLE-ENGINE FAILURE FIELD/ CATAPULT LAUNCHBVAVEOFF Initial aircraft controllability is highly dependenton timely and properrudder usage.Rudder is the primary controlfor counteringyaw causedby asymmetric.thrust sincelateral stick inputs alone will induce adverseyaw in an already critical flight regime. Compounding the situation, visual cues for ascertainingyaw excursions may be absentat night. While roll causedby yaw will always be apparent,yaw excursionsduring night/IFR conditions may be first indicated by the turn and slip indicator and heading indicator if in near wings-level flight. The pilot should be preparedto apply up to and including full rudderat the first indication of an engine failure. Do not rotate aircmt? below 130 knots in any configuration. Refer to NAVAIR 01-Fl4AAP-1.1, Chapter26 for higher rotation speeds.Additional areas for considerationare discussedbelow. 13.2.1 Angle-of-AttacklEndspeed Consideration. Failure to limit AOA will place the aircraft in a regime to reduce directional stability, rudder control, andrate of climb. The aircraft may be uncontrollableat AOA above 20 units. Smoothly rotating to 10” pitch attitude on the waterline and approximately 14 units indicatedAOA provides the best compromise between controllability, good initial flyaway attitude, and adequatesingle-engineperformance.For compromise,normal 15-knot excess endspeed catapult launches (mandatory from catapult No. 4 and highly recommendedfrom catapult No. 3) will place the aircraft in theapproximate 14-unitAOA regime. Zero excessendspeedlauncheson ‘hot days, where single- engineperformance is marginal, will place the aircraft in the approximate 18- unit AOA regime andwill require the pilot to precisely fly the aircraft away Tom the water, avoiding suddenpitch control inputs, 13.2.2 Rate of Climb Consideration. Rate of climb may be increasedby selectingafterburnerwith ASYM LIMITER switch in ON. Only minimum AB is avail-
able.The most adversedrag condition is with the wings level on a constant heading, but techniquesused by traditional multiengine aircraft (suchasraising the dead enginewith 5” angleofbank) areapplicablefor theF-14. Airspeed and angle of hank control will also greatly affect rate of climb (refer to NAVAIR 01-F14AAP-1.1 for all of theseeffects). Under normal circumstances,180knots is usedasthe flaps up speed. However, if during a single-engine takeoff the aircraft has achieveda safeflying speedand a positive rateof climb but has difficulty achieving flap speed,moving the flaps up in incrementsprior to 180 knots will enhanceaccelerationand climb capabilities. 13.2.3 Stores Jettison Considerations. If an acceptablerate of climb caIlnotbe maintainedor deceleration cannot be counteredby thrust alone, jettison should be selected.The benefits of an instantly lighter aircraft and lower drag configuration always produce positive effects on performance. Separation characteristics of the externaltanks in this configuration,however, have never been verified by flight tests and consequentlymay result in stores-to-aircraftcollision with unknown consequences.The use of ACM jettison, which will selectively bypassnonselectedstores,could be utilized but does not offer the same gross weight reductionand requires the additional interlocks of gear handleplus ACM guardup. 13.2.4 Aircrew Coordination. Each launch must be made with the aircrew preparedfor the worst case. Even when mentally preparedto handlethis emergency, the F-14 crew facesa difficult task in executinga safe flyaway. Of paramountimportance is a knowledgeable understandingby both pilot and RIO of what to expect when confrontedwith an enginefailure during launch. Both must have already determinedduring a preflight briefing the points to be considered,that is, controllability, AOA/pitch attitude, engine,rate of climb, and jettison considerations.The pilot will probably be the only one to know if an enginefails during launch. The RIO will probably be the only one in a position to successfully initiate ejection prior to departingthe ejection envelope. 13.2.5 Single-Engine Failure Field/Catapult LaunchMlaveoff *l, Set 10“ pitch attitude on the waterline (14 units AOA maximum). ‘2. Rudder -Opposite Roll/Yaw SupplementedBy Lateral Stick
I
NAVAIR Ol-F14AAD-1
*3. Both throttles-As Climb
Requiredfor Positive Rateof
*4. Landing gear- UP.
Do not delayengagingnosewheelsteering in orderto centerrudderpedals.
‘5. Jettison- If Required.
Aircraft should have ground locks installed and enginessecuredbefore moving aircraft.
6. If bannertow, hook - DOWN. 7. If unable to control aircraft - Eject. 8. Establish IO-unit AOA climb. 9. Climb to safealtitude. 10. Flaps - UP. 11. Refer to Single-Engine Cruise Operations,Chapter 14. 13.3 BLOWN TIRE DURING TAKEOFF If a tire blows during the takeoff roll and an abort is impossible,do not raisethe landinggearor flaps.Leave the landing geardown to avoid fouling the blown tire in the wheelwell. Leavethe flaps down; they may be damagedby piecesof rupturedtire. Also, climbing with the gear and flaps down is an optimum flight attitude for emergencyfuel dumping. 13.3.1 Blown Tire During Takeoff; Takeoff Aborted or After Landing Touchdown * 1. Nosewheelsteering- Engaged. *2. ANTI SKJD SPOILER BK switch - SPOILER BK.
Note Antiskid will sensea constantreleaseon a draggingblown tire. 13.3.2 Blown Tire During Takeoff; Takeoff Continued or After Landing Go-Around
\ \ \
* 1. Throttles - As Required. ‘2. Landing gearand flaps - LeaveAs Setfor TakeOff.
\ \
m Blown tire(s) can causeengineFOD and/or structuraldamage.
\
\
3. HYD ISOL switch - FLT. \ Note This will requirebendingthe cam on the gear handle in order to move the HYD ISOL switch to FLT.
\ \
4. Refer to BLOWN TIRE LANDING procedures \ paragraph 15.5. \L
I
NAVAIR
CHAPTER
In-Flight 14.1
COMMUNICATIONS
0%Fl4AAD-1
14
Emergencies 3. Attempt home baselocation by radarmapping or DR to best known position. Attempt marshalpattern location by APX-76 interrogation.
FAILURE
1. Check mikes and earphoneplugs. 2. Checkoxygen mask connectionsandoxygenhose disconnect.
4. Drop fourbundlesofchaffat 2-mile intervals,then complete series of four standardleft-hand 360” turnsat 20-secondintervals.
3. RIO checkconsoleconnectoradjacentto shoulder harnesscontrol lever. Pilot checkconsoleconnector aft of g valve.
5. Ifno chaff, fly minimum oftwo triangularpatterns to left with l-minute legs.
4. Increase ICS volume and attempt B/U and EMERG positions.
6. Repeatpatternsat 20-minute intervals.
5. Attempt intercommunications with VHF/UHF transceiver.
7. Conserve fuel throughout and facilitate radar pickup by maintaining highest feasible altitude consistentwith situation.
6. If cockpit altitude is safe, oxygen mask can be removedsothatwhenhelmet earmuff is heldopen, verbal communicationscan be maintained. 14.1.1 Flightcrew Attention Signals. When no other method of communicating exists, the following signals shouldbe used:
14.1.2.3
3. Acknowledgmentwill be thumbs-up,high on lefthand side of cockpit, and future communications will be conductedby visual hand signals using HEFOE code.
14.1.2.1
Emergency
Aids
Aids
But
No Radio
(With
Navigation
Aids)
1. Proceedto alternatemarshal. 2. EnergizeID function at least onceeachminute. 3. Commencepenetrationor letdown at EAC. If not givenEAC, commenceapproachat estimatedtime of arrival.
Procedures
Lost (Without Navigation Radio Receiver)
Lost (Without Navigation With Radio Receiver)
1. Sameas without radio, but make turns to right.
2. RIO will attractpilot by shouting“.... #,@,&,!”
COMM-NAV
9. Afterjoining, communicatewith appropriatehand or light signals. 14.1.2.2
1. Pilot will attractRIO by rocking of wings.
14.1.2
8. Be alert for aircraft attempting to join.
or
4. Be alert for aircraft vectoredto join.
1. Pilot selectrunning lights on FLASH.
14.2
2. RIO squawk mode 3 Code 7600.
If the altimeter and Mach airspeedindicatorsare erroneous, pitot pressure, static pressure, and total temperatureinputsto the centralair datacomputer may 114-l
PITOT-STATIC
SYSTEM
FAILURES
ORIGINAL
NAVAIR
01-F14AAD-1
also be inaccurate. Placing the ANTI-ICE switch in ORIDE/ON or AUTO/OFF may restoreoperationif the malfunction was causedby icing. Note
. Pitot-static system failures becauseof icing may input an erroneousMach number to the AICS programmer, which will result in the ramps being in the wrong position for the actual Mach number (engine stall may result). If this erroneousMach number is outside 0.3 to 0.9 band, the AICS anti-ice positioning featurewill be overridden. l
With known or suspectedpitot-static malfunctions,do not exceed0.9 TMN.
If it is apparentthat icing is not the problem,use the AOA indicator in place of airspeedfor flight conditions as shown in Figure 14-1.Descendto an altitude below 23,000feet.When cabin altitude stabilizesat 8,000feet, aircraft altitude will be approximately 23,000 feet. Below 23,000 feet, aircrafi altitude can be determinedby dumping cabin pressureand using the cabin altitude indicator above 5,000 feet. Below 5,000 feet, use the radaraltimeter. Reduceairspeedandsetwing sweepto 20° using the emergencywing-sweep mode. The landing should be without the autothrottleengaged.If the mission computer computationsare affected,the RIO can manually enterestimatedwind direction andvelocity throughthe computer addresspanel or the DEU. 14.3
EMERGENCY
JETTISON
All storesincluding externalfuel tanks(stations2 and 7). but excluding Sidewindermissiles (AIM-g), arejettisoned in a fixed interval between sequencedstations to avoid store-to-aircraftcollision. SeeFigure 14-2 for externalstoresjettison table. piGi-1 l
l
With landing flaps and slatsdown, do not tire Sidewinder missiles. If jettisoned during takeoff emergency, external fuel tanks may collide with the aircraft because of their unstable characteristics.
l. EMERG STORES JETT pushbutton-Depress.
ANGLEOFAlTACK UNITS
FLIGHT CONDITION CATAPULT (15 KNOTS EXCESS) MRT Transition From Catapult AB
14.0 13.0
MILITARY POWER CLIMB All Drag Index Sea Level Combat Ceiling
6.0 9.5
MAXIMUM POWER CLIMB All Drag Indexes Sea Level Combat Ceiling
5.0 0.0
CRUISE AT ALTITUDES BELOW 20,000 FEET (All Gross Weights) Drag Index = 6 Drag Index = 100
6.0 9.0
CRUISE AT OPTIMUM ALTITUDE All Drag Index
0.0
MAXIMUM ENDURANCE All Drag Indexes, All Altitudes
10.0
IDLE DESCENT 250 KCAS Maximum Range
9.0 10.0
GEAR AND FLAPS EXTENSION Safe Gear Extension (Flaps UP) at 260 KIAS Safe Flap Extension (Gear DN) at 225 KIAS
6.5 9.0
I\PPROACH CCAlGCA Pattern; 220 KCAS; Gear UP; Flaps UP; 54,000 pounds. Final ON SPEED Approach (Gear DN): Two Engines (All Flap Configurations) Sinole Enaine/PRI: FULL FtiR DLC ENGAGED FULL FlaF: DLC STOWED NO FLAP Single Engine/SEC: FULL FLAP (CV ONLY) NO FLAP (FIELD ONLY) DRAG INDEX 0 100
9.0 15.0
15.0 14.0 14.0 13.0 15.0
CONFIGURATION (4) AIM-7 (6) AIM-54 (2) 267-gallon
external tanks
Figure 14-1. Airspeed Indicator Failure
NAVAIR
($1
iMERGENCY (PILOT)
1/
(*) ACM (PILOT)
v
v
SELECTIVE (RIO)
v
0%F14AAD1
VERIFY ON DURING LTS CHECK PRESTART - PILOT
SEQUENCE JETTISON SELECTED STATIONS
v NOTE
l
FUZING SAFED IN ALL JElTISON MODES. (DOES NOT PRECLUDE INADVERTENT ARMING OF MECHANICAL FUZES.)
l
SIDEWINDER
CANNOT BE JE’ITISONED.
INTERLOCKS WEIGHT OFF WHEELS (EITHER RIGHT OR LEFT MAIN GEAR)
(*) STATIONS
JETTISON
SEQUENCE
1 B, 88,2,7, -4D, -5D, -4A, -5A, -4C, -5C, 48, -58, -3D, -6D, -3A, -6A, -3C, -6C, -38, -6B
NOTE 0
0
@
0
LANDING GEAR HANDLE UP . THE TIME INTERVAL BETWEEN STATIONS INDICATED BY (-) IS 100 MS. MASTER ARM SWITCH ON
ACM COVER UP
STATION SELECT
0 SUBSTATIONS A, B, C, AND D OF RAIL ARE NUMBERED CLOCKWISE, LOOKING DOWN AT RAIL WITH A THE LEFT REAR STATION ON EACH RAIL. . STATIONS lB, 8B,2, AND 7 ARE JETTISONED SIMULTANEOUSLY.
NAVAIR
01-Fl4AAD.1
Note l
The EMERG STORE JETT function is disabledwith weight on wheels.
. The EMERG STORES .lETT and ACK lights illuminate when emergencyjettison is activated. l
A weight-off-wheels signal from the left or right main wheel is sufficient to enable emergencyjettison.
.. A complete emergencystorejettison sequencecan take 1.7seconds. If step 1 fails, proceedwith ACM jettison. ACM jettison will releaseall storesselectedexcept Sidewindermissiles. 1. LDG GEAR handle- UP. 2. DEU STA SEL -As 3. ACM guard-UP
Required. (coverup).
4. ACM JETT - Depressand Hold (at least 2 seconds). Note . ACM jettison follows the samesequence as emergencyjettisoning but requiresindividual selection of stations to be released.Stationnot selectedis skipped. . Whenjettisoningbombsfrom stations3,4, 5, and 6, the interval betweensequenced stationsis automaticallydesignatedat 100 milliseconds to avoid store-to-storeand store-to-aircraftcollision. 14.4
FIRE LIGHT AND/OR
2. Intermittent bursts of white sparksin the vicinity of the aft edgeof the overwing fairing. 3. Sparksturning to flames. 4. Continuousyellow sparksin anareaof increasing size. 5. Flames and/or smoke spreadingforward to wing pivot point andencompassingtheareaof theoverwing fairing. 6. Flames,smoke,and/orheatcrossingthecenterline of aircraftandexiting in theotheroverwing fairing area. Theseindicationsmay or may not be accompaniedby a FIRE light anda HUD/MFD legend.This midship passageof heatandflamescouldbe throughtheareacontaining the flight controlsystemcontrol rods,which run fore andafl throughthe back of the aircraft.Heat and flames progressingthroughthis areawould impingeon thelongitudinalandlateralcontrolrodscausingpossibledistortion or failure. Loss of aircrafi may follow. The flightcrew facedwiththis typeoffue in flightmust reactimmediately. Note
If the FIRE warning light is off and a HUD/MFD legendis displayed,verify FIRE DET TEST checks 4.0. Assume message was incorrect and keep engineon line. The legendis a repeatof a discrete from the fire detectionsystem. * 1. Throttle (affectedengine)- IDLE. *2. AIR SOURCE pushbutton- OFF. *3. OBOGS master switch - BACKUP.
FIRE IN FLIGHT
Fire may be accompaniedby other indications such as explosion,vibration, smoke,or fumes in the cockpit, trailing smoke,or abnormalengineinshumentindications. A fire in flight precipitatedby a failwe in the engine canbe catastrophicin anextremely shortperiod oftime. The shrapnelgeneratedby the engine can rupture fuel and/or hydraulic lines, resulting in a raging tire. The sequenceof events for the failure could include all or some of the following: 1. A low-amplitude vibration and noise.
Oxygenbreathingtime on BACKUP is limited and requires immediate mission planning. See OBOGS emergency procedure. See Figure 2-80 for oxygen breathing time remaining. Note
When ECS service air to the OBOGS concentratoris shut off, theaircrew hasapproximately 30 secondsbefore depletingresidual OBOGS pressureand mask collapse.
Note Restorationof service air (selecting RAM) will return OBOGS to operation. Iflight goesoff (and no other secondaryindications): Note Fire detection test is not available on the emergencygenerator. $4. MASTER TEST switch - FIRE DET TEST If light remains illuminated, FIRE DET test fails, or other secondaryindications:
c. IncreasingEGT d. Rpm rollback and/orthrust loss e. Lack of throttle response f. Inlet buzz (supersoniconly) g. Fireball emanating from the exhaust and/or intake. *I. &load aircraft (0.5g to l.Og). If greaterthan 1.1Mach: *2. Both throttles- MIL
*5. FUEL SHUT OFF handle (affected engine) Pull. *6. Throttle (affectedengine)- OFF. *7. Climb and decelerate. *8. Fire extinguisherpushbutton- Depress. Note EnsureBACK UP IGNITION switch is OFF. 9. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2. 10. Land as soonas possible. 11. If fire persists- Eject. 14.5 ENGINE EMERGENCIES 14.51 Compressor Stall. A compressorstall is an dynamic disruptionofthe airflow throughthecompresSOT.Compressorstallsmay occurat any altitude/airspeed combination,includingsupersonic,andcanbeidentifiedby anyoneor a combinationof thefollowing indications. Note The loss of Mach number signal from the CADC resultsin the lossofboth airflow limiting and idle lockup functionsof tbeAFTC. This may result in pop stalls at supersonic speeds(ona cold day) athigh power andinlet buzz, resulting in pop stalls at idle power. a. Loud bangsor vibrations b. Rapid yaw or noseslice
When 1.1Mach or less: *3. Both throttles- Smoothly to IDLE. Note If above1.1Mach, monitor minimum rpm to ensureproper functioning of idle lockup to avoid inducing a stall. If EGT is above 935 “C and/or engine response is abnormal: ‘4. Throttle (stalled engine)- OFF. If EGT normal and/orairstartsuccessful: 5. Perform engineoperability check. Note After any stall, throttle movement shouldbe minimized until engine operability checks areperformed.Engines should be exercised at 10,000feet in cruiseandthen at approach speeds,oneat a time, to ensurestall-freeperformanceis available for landing. If engine performanceis abnormal,set power as necessaryand avoid further throttle movement. Land as soonas practical. Flight test operationshave not producedany fully developedenginestalls. Pop stalls have beenobserved and were self-clearingwith no adverseoperationalimpact. Engine ground testing has shown that a hard stall (characterizedby loud bang) can result in substantial damage to the IGV system. The damage resulted in completedetachmentof the IGV from the externallinkage.There was no FOD.
NAVAIR Ol-F14AAD-1
When the IGV linkage breaks, the IGVs assumea fixed aerodynamic trailing position. This position is near normal for MIL or AB power settings, but is too far open at lower throttle positions. This reduces fan stall margin with the greatestreduction halfway between IDLE and MIL. Airborne, a hard stall may result in similar damage and will likely have been the result of an AICS malfunction and/or fuels/engine control system failure. If a stall occurs during AB operation, the asymmetric thrust limiting circuit should reduce the good engine to minimum AB. Asymmetric thrust may produceadverseflying qualities under low airspeed and/or high AOA conditions. I,,,,,,,1 Do not delay securingan overtempedengine. Undue delay will greatly increasethe likelihood of severeturbine damageanddecrease the chance for a successfulairstart. If both enginesareovertemped,one enginemust be securedimmediately to provide maximum potential for a successfulairstart. Note Airspeedandaltitudewill determinewhether both enginescan be safely shut down (with dual compressor stalls), or whether one should be securedand relit prior to shutting down the other. If airspeedis insufficient to provide windmill ‘pm for hydraulic pressure, one engineshould be left in hung stall. There is a threefold dangerpresentwhen one engine has experienceda compressorstall. The most serious dangermanifestsitselfat slow airspeedsandhigh power settings,where the suddenthrust asymmetry (a stalled engineyields negligible thrust)will induceor aggravate a departureandmay producesufficient yaw rateto cause a flat spin if properrecoverycontrols arenot used. The othertwo dangersfrom a compressorstall arethat thestalledenginemay sufferovertempemture damageand that the goodenginemight also stall. Although the emergencyprocedures aredesignedto addressall threedangers, thepilot must understandthat aircraftcontrollabilitytakes priority over engine considerationsand involves both throttle position and flight controls.Referenceto the engine instrumentswill probablybe requiredto determine the stalledengine.If the aircraft has departedcontrolled flight, this shouldnot be attempteduntil the pilot hasensuredthatthrust asymmetryhasbeenminimized andthat yawrateandAOAare undercontrol.Therationalefor each individual stepin the emergencyprocedureis as follows:
Step 1: Unload the aircraft (0.5g to 1.Og)- Unloading theaircraftreducesthelikelihood of a departure, while providing a more normal engineinlet airflow. It is not intendedthat the pilot push full forward stick or inducenegativeg, but merely that any g load on the aircraftbe reducedto as near1.Ogaspossible.In the nose-high,slow-airspeedcase,thepilot may temporarilylosecontrol effectiveness.This shouldnotbe causefor alarm and thepilot shouldhe able to expeditiouslyestablish a wings-level,nose-lowattitudeas long as step2 is followed immediately. Step2: If speedis 1.1 Mach or greater,both throttles - MIL. Setting the throttlesto MIL will both help reduce the asymmetric thrust developed during the stall andpotentially help the engine recover from the stall. It is not recommended to retard the throttle to below MIL until the aircraft is below 1.1 Mach. The engine may automatically switch to SEC mode,anda tbrottie setting below MIL may result in inlet buzz (idle speedlockup is lost in SEC mode) compounding the stall problem and potentially inducing a stall in the operatingengine. Step 3: Throttle(s)- If speedis 1.1Mach or less,retard smoothlyto IDLE. During a deparhue,retarding both throttlesto IDLE will help recoverthe aircm&by minimizing theasymmetricthrust.In the case of a violent slicing departureinvolving asymmetricthrust,reductionof throttlesto IDLE is themost critical stepandmustbe doneimmediately.Ifcontrol ofthe aircraftis not in question, thereis no needto retardthethrottleon theoperating engine.Retardingonly the stalledengine throttlereducestheremoteprobabilityof inducing a dual-enginestall. In addition, thrustfrom theoperatingenginemay berequiredduringlowaltitude emergencies.Minimizing asymmetric thrust at high AOA and low airspeedshall be accomplished wheneverpossible. Obviously, there are situations (landing pattern, catapult launch, low altitude,and airspeed)where idle power is unacceptable,and emergencyprcceduresmust be temperedby pilot judgment. Step 4: Stalled engine,throttle off- When an engine stalls, the combustor flame does not extinguish. Airflow throughthe engineand cooling flow to theturbine bladesareseverelyreduced, andtheturbinebladesmay sufferovertemperature damage. Securing the stalled engine to OFF extinguishes the combustor flame, thereby reducing the turbine blade temperature.
1451.1
Supersonic
Airspeed.
Supersonic
com-
pressorstalls will produceinlet buzz. This resultsin a rnugh,bumpy ride (+2.5gto -1g at six cyclesper second). The propertechniqueto recoverfrom a supersoniccompressorstall is to smoothly retardthrottlesto MIL, keep feet on the deck, and control any wing-drop tendencies with lateral stick.
known at this point; however, it is possible that the secondstall may have beeninducedduring the throttle transient to IDLE. Leaving one engine in hung stall minimizes the likelihood of total loss of hydraulic and electricalpower (emergencygenerator). pi-z--l
14.5.1.2
Dual Compressor
Stall
pi&--I l
l
l
l
During recoveryfrom a dual-enginecompressor stall (with both engine-driven generatorshaving droppedoffline), flight control inputs may temporarily reducethe combined hydraulic system pressure.If combined hydraulic system pressure dropsto between2,000 and 1,100psi, the emergency generatorwill automatically shift to the l-kVA mode and power only the essentialNo. 1buses.If the combined hydraulic pressurecontinues to fall, the essentialNo. 1 buses will drop offline, resulting in a total electrical failure. Complete loss of electricalpower will result in loss of ICS, OBOGS, backupoxygen (below 10,000 feet MSL), engine instruments, spin direction indicators (spin arrow andturn needle),anddisplays. If combinedhydraulic systempressurerecovers, the emergency generatorshould automaticallyreestablish1-kVA power to the essentialNo. 1 buses.The emergency generatorswitch must be cycled through OFF/RESET to NORM to regain the 5-kVA mode to the essentialNo.2 buses. Engine instruments are powered by the essentialNo. 1 bus but may not be automatically restoredwith the l-kVA mode. It may be necessaryto cycle the emergencygeneratorswitch throughOFF/RESET to NORM to regain lost engine instruments.
If both enginesare stalled after retardingthrottles to IDLE, at least one engine must be immediately secured to prevent turbine damage and provide maximum potential for an airstart. If possible, securethe enginethat did not initiate the event(the secondengine to stall). The causeof the first engine stall may not be
Leaving one enginein hung stall may catastrophically damagethe turbine. It is, therefore, imperative that the pilot expeditiously secureand relight one engineto preventtnrbine damage.Attentionshouldbe givento the remainingstalledengineassoonaspossible. 14.52 Airstarts. Tbemost likelyreasonstoperform an airstartarethat the enginehas shutdown becauseof control systemfailure, hardwarefailure, fuel feed failure, FOD, or enginestall. The augmenterfan temperaturecontrolcontainsdiagnosticlogic to identify primary (PRI) enginemode failures and automatically transfers to secondary(SEC) mode when required. If the shutdown was not pilot commanded,the enginemay switch to SEC mode automatically. The first airstart attempt should be made in the engine mode selectedby the AFTC(eitberPRIor SEC). Ifan initialPRImodeairstart is unsuccessful, the ENG MODE SELECT switch shouldbe in SEC for any subsequentairstartattempts.
If an engineflamesout, the automatic relight feature will attemptto restartthe engineimmediately; however, ifrpm is decayingbelow the throttle-commandedlevel, spooldownairstartproceduresshouldbe initiated immediately. If engine flames out becauseof an automatic shutdowncausedby an overspeedgreaterthan 110percent, there will be no automatic relight. To regainfuel flow, the throttle must be cycled to OFF then to IDLE. Note An overspeedcondition in excessof 110percent will result in momentary loss of ‘pm indication until Nz rpm falls below 110h.5 percent.EGT andFF indicatorswill continue to function normally. There are three airstart phases:spooldown, crossbleed, and windmill. Spooldown is the first phaseand providesthebestopportunity for a rapid start.Windmill is the lastphaseandis availableonly in very high-energy conditions. Spooldownairstartsshouldbe initiated immediately when it is apparentthat anenginehaslost thrustandthat rpm will decay below the throttle-commandedlevel.
-
NAVAIR
-
-
Ol-Fl4AAD-1
High ‘pm, high airspeed,and low altitude increasethe likelihood of a successfulspooldown start. SeeFigure 14-3. The bestconditions for both PRI and SEC mode spooldown starts are below 30,000 feet, above 300 knots,andwith ‘pm greaterthan30 percent.Spooldown airstartsthat light-off with rpm aslow as 30 percentcan takeup to 90 secondsto accelerateto idle and20 seconds when initiated at 50 percentor greater. When initiating a spooldown airstartto cleara stall, cycle the throttle OFF then to IDLE with the enginein either PRI or SEC mode. EGT and rpm indications should rapidly decreasewhen the throttle is OFF confirming throttle position. If OFF is selectedto clear an enginestall, thethrottle shouldremain in OFF for a few secondsuntil the stall clears. Typically, airstarts are characterizedby a rapid light-off and initial EGT rise with a slow initial increasein ‘pm, In thelow-rpm range, it may take up to 10 secondsto observean apparent increasein ‘pm. The ‘pm display should be flashing if the ‘pm is increasing. Hung startsare characterizedby the ‘pm stagnating below idle. The currentengineindicating system(EIG) will stop flashing if the next higher segment is not reachedwithin 10 seconds.A low-range (less than 45 percent)hung startcanbe overcomewith the assistance of crossbleedair. A midrange hung start at subidle rpm (50 to 60 percent)canbe correctedby cycling thethrottle OFF then to IDLE. Above 45 percent,the starterwill not engage.At the completion of the start sequencethe engine correspondsto actual throttle position. 14.5.2.1 Dual-Engine Airstart (Or Airstart of One Engine With the Other Engine Secured).
Dual-engine redundancyand automatic relight makes this situation extremely unlikely. Dual enginewindmill airstart proceduresafter unsuccessful automatic and manual spooldown airstart attemptsshould be consideredtertiary and performed with seriousconsideration given to airspeedaltitude and safeejection limitations. Flight test data indicate nominal windmill airstart airspeedrequirementsto be in the vicinity of 450 knots. Dependingon airspeedandaltitudeavailableat windmill aircraftprofile commencement,a dive angleof up to 45” may be requiredto achievenominal airstartairspeeds. pi&-I Dive angle should not exceed45”. At 7,500 feetAGL andlessthan450knots,commence a smooth, 2g pull converting airspeedto altitude and eject when less than 350 knots,
Once establishedat 450 knots, approximately 20” nose down is required to maintain constant airspeed. While attempting airstarts, flight control authority is critical. As ‘pm decreases,sufficient hydraulic pressure for smoothflight control inputs shouldbe availablewith oneenginewindmilling above18percentor two engines windmilling above 11percent.At 450 knots, 15”dive, a 2g pullup should be initiated at 2,000 feet. Once the windmill airstart is consideredto be unsuccessful,the aircraft shall be deceleratedto less than 350 knots and ejection performedbefore controllability is lost. pzzji=J When advancingboth throttlesfrom OFF, cycle the right throttle first to a position aboveIDLE, to avoid thethrottlequadrant locking pin feature.
l
Main generatorsdropoff at55-percentrpm. The emergencygeneratorwill drop off at 1l-to 12-percent‘pm. Engineignition will not be availablebelow 10percent.
l
Oxygen breathing time on BACKUP is limited and reqttires immediate mission planning. SeeOBOGS emergencyprocedure. SeeFigure 2-81 for oxygen breathing time remaining.
l
Note
When ECS serviceair to theOBOGS concentrator is shut off, the aircrew has approximately 30 secondsbefore residual OBOGS pressureand mask collapse.
l
l
14.5.2.2
Airstatt canbe performedon both engines simultaneously. Engine
Flameout
‘1. Throttle - IDLE or Above (affected engine). *2. BACK UP IGNITION switch - ON. Note
Spooldown airstarts can take up to 90 seconds to reach idle rpm if light-off occurs at low ‘pm, low airspeed,andhigh altitude. If hung start or no start: *3. Throttle (affected engine) IDLE.
Cycle OFF, Then
Figure 14-3. Airstart Envelope 14-9
ORIGINAL
IAVAIR
01-Fl4AAD-1
Istill hung or no start:
9. OBOGS masterswitch - ON.
‘4. ENG MODE SELECT - SEC. Foneengineis operable,perform a crossbleedairstart, aragraph14.5.2.3. rboth enginesflamed out/inoperativeor crossbleednot ossible:
‘m Ensure ECS service air is available to OBOGS prior to selectingthe OBOGS master switch ON. When primary mode is restored: 10. Maintain constantsubsonicMach in level flight.
l
A dual-enginecompressorstall may result in a total electrical failure, renderingthe ICS, OBOGS, backup oxygen (below 10,000 feet MSL), engine instruments, spin direction indicators (spin arrow and turn needle),and displays inoperative.
a If sufficient hydraulic pressurerestores the I-WA mode of the emergencygenerator,it maybe necessaryto cycle the emergency generator switch through OFF/ RESET to NORM to regain lost engine instruments. l
l
l
Ejection above 350 knots is hazardous; the decisionto exceed350knots restswith the aircrew. Sufftcient hydraulic pressurefor smooth flight control inputs should be available with one engine windmilling at 18percent rpm or two enginesat 11percent. Dive angles should not exceed 45”. At 7,500 feet AGL minimum, commence a smooth2g pullup to a 20” dive, maximum. At 2,000 feet AGL minimum, pull up to level flight. If the airstatt is unsuccessful, convert airspeedto altitude and eject at 350 knots or less before controllability is lost.
*5. Airspeed - 450 Knots (altitude permitting). 6. OBOGS masterswitch - BACKUP. men start is completed: 7. BACK UP IGNITION switch - OFF. 8. ENG MODE SELECT - PRI.
11. Affected L or R AICS cb - Cycle (LF 1, left or LG 1, right). p-K-1 If WMG SWEEP advisory light is illuminated,cycling L AICS circuit breaker(LFl) may causeunintentional wing sweepunless WING SWEEP DRIVE NO. 1 (LDl) and WG SWP DR NO. 2iMANUV FLAP (LEl) cb’s arepulled. 1452.3
Crossbleed
Airstart
1. Throttle (had engine)- OFF. 2. FUEL SHUT OFF handle- Check In. 3. Throttle (good engine)- SO-PercentRpm (minimum). 4. BACK UP IGNITION switch - ON. 5. ENG MODE SELECT - PRI. 6. ENG CRANK switch (badengine)- ON. 7. Throttle (bad engine)- IDLE Immediately. Note
Quickestlight-offs areachievedwith throttle to IDLE at less than lo-percent ‘pm. If hung start: 8. Throttle (bad engine)- OFF Then IDLE. If still hung: 9. ENG MODE SELECT - SEC.
NAVAIR Ol-Fl4AAD-1
When start is completed: 10. BACK UP IGNITION switch-OFF.
asan apparentloss of thrustand/ortheinability to obtain a successfulairstart.For confirmed mechanicalfailures, the engineshouldbe securedandtheFUEL SHUT OFF handlepulled.
11. ENG MODE SELECT - PRI. When primary mode is restored: 12. Maintain constantsubsonicMach in level flight. 13. Affected L or R AICS cb - Cycle (LFl, left or LGl , right). [W/\RNING( If WING SWEEP advisory light is illuminated,cycling L AICS circuit breaker(LFl) may causeunintentional wing sweepunless WING SWEEP DRIVE NO. 1 (LDI) and WG SWP DR NO. 2IMANUV FLAP (LEl) cb’s arepulled. 14.5.3 Single-Engine Flight Characteristics. Single-engine flight characteristicsare dependenton gross weight, configuration, angle of attack, wing sweep, and maneuvering requirements. In the cruise configuration, with one engine operating at military/ high power settings, rudder deflection and/or trim is requiredto preventyaw toward the failed engine.However,single-engineperformancecapabilitiescan be significantly restricted by adverse flying qualities in approachpower configuration,particularly at high gross weightsin turning flight becauseof the effects of thrust asymmetry at normal approach speed.This degrades with turnsinto the failed enginesuchthatmdderrequiremeritsto maintain level flight can exceedavailable rudder control. Flight in this configuration should be plannedto avoid turns into the failed engine with bank angleslimited to 20” maximum andAOA limited to 12 units. The aircraft design is such that no one system (flight control, pneumatic,electrical,etc.) dependson a specific engine. Therefore, loss of an engine does not resultin lossofany completesystemas long astheHYD TRANSFER PUMP is operative.Refer to NAVAIR OlF14AAP-1.1 for single-engineperformancedata. 14.5.3.1 Single-Engine Failure During Flight. It is uncommon to encountercompressorstalls that require immediate engine shutdown. Occasionally, mechanical failure of FllO engine componentsresults in enginefailure. These failures may be obvious as when accompaniedby severeenginevibration or may be subtle as indicatedby a lack of engineresponseto throttle changes.Turbine failure for example,may appearonly
If an engine fails or a mechanicalmalfunction has been determined, the respective FUEL SHUT OFF handle shall be pulled immediately afterengineshutdownto reduce the possibility of fire or fuel migration. Note ECS serviceair pressuremay be inadequate for OBOGS when operatingon a single engine at idle. Increasingthe throttle position for the operating engine above IDLE will increasepressure.This will also close the nozzle, increasingdescentrange. 14.5.3.2 Single-Engine Cruise Operations 1. FUEL SHUT OFF handle engine).
Pull (inoperative
2. If on final approachor landing, refer to single engine landing procedures, paragraphs 15.2 and 15.3. When eitherfuselagetapereaches4,500poundsof fuel or less: 3. WING/EXT TRANS switch - OFF.
The WING/EXT TRANS switch automatically returns to AUTO if the REFUEL PROBE switch is placedto ALL EXTEND, DUMP is selected,or there is 2,000pounds remaining in the low side.The WMG/EXT TRANS switch canbe reselectedto OFF after a 5-seconddelay, the REFUEL PROBE is retracted,or DUMP is secured. 4. FEED switch - OperatingEngine Side. When pilot workload permits close monitoring of tie1 distribution: 5. FEED switch -Inoperative Engine Side.
w--w------
NAVAIR
Ol-F14AAD-1
If the fuselagequantity on the inoperativeengine side beginsto increase: 6. FEED switch - Immediately Move to Operating Engine Side.
14.5.5
Engine
START
VALVE
Light
1. EnsureENG CRANK switch - OFF. 2. AIR SOURCE pushbutton-OFF. Note
An increasein fuel quantity on the inoperative engine side indicatesthat the sump tank interconnectvalve is not open.Fuel available is limited to the quantity on the operating engineside. If the fuselagefuel quantity on the inoperativeengine side beginsto decrease: 6. FEED switch-Remain
On InoperativeEngine.
7. WING/EXT TRANSFER switch - AUTO. 8. Refer to appropriatehydraulic systemfailure, 14.54
Engine
Overspeed
If operational necessity dictates, AIR SOURCE L ENG or R ENG may be selected provided the START VALVE light remains out.Crossbleedairstartsmay not beavailable to the affected engine after a START VALVE light illuminates, becauseof possible overspeeddamage. If on deck: 3. Throttle (affected engine)- OFF. If airborne: 3. ENG START cb - Pull (RF]). 4. OBOGS master switch-BACKUP.
(Nq or N2 OSP Legend)
1. Throttle (affectedengine)- IDLE. If overspeedcontinues: 2. ENG MODE SELECT-SEC. light illuminated.
Verify ENG SEC
If overspeedcondition persists:
Oxygen breathingtime on BACKUP is limited and requires immediate mission planning. See OBOGS emergency procedure. See Figure 2-81 for oxygen breathing time remaining. Note
3. Throttle (affected engine)- OFF.
. When ECS serviceair to theOBOGS con-
centrator is shut off, the aircrew has approximately 30 seconds before depleting residual OBOGS pressureand mask collapse.
Note l
l
Fuel flow is automatically securedwhen ‘pm reaches110 percent.To regain fuel flow, the throttle must becycled OFF then to IDLE. An overspeedcondition in excessof 1IO percent will result in temporary loss of ‘pm indication until N2 falls below 110 A.5 percent.EGT and FF indicators will continue to function normally.
4. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2. 5. Land as soon as practicable.
. Restoration of service air (selecting
RAM) will return OBOGS to operation. 14.5.6
Engine
Transfer
to SEC Mode
In SEC mode, idle lockup protection is lost. Deceleratebelow 1.1 TMN beforeretarding throttle to IDLE to avoid supersonic inlet buzz andpossible compressorstall.
NAVAIR
Note l
Engine ac generatorfailure, indicated by loss of ‘pm andnozzle gaugeindications, will shift the engineinto SEC mode without illuminating theSEC light. Main highenergy ignition will be inoperative. Backup ignition is requiredfor airstarts.
. SEC mode transferwhile in AB may result in pop stalls. Nonemergencymanual selectionof SEC mode airborneshouldbe performedin basic enginewith the power set above85-percent‘pm. If enginetransfersto SEC mode: 1. Throttle (affectedengine)- Less Than MIL. 2. ENG MODE SELECT-Cycle. If PRI mode is restored: 3. Maintain constant subsonic airspeed in level flight.
1456.1
Transfer
to SEC Mode
Ol-F14AAD-1
Results
1. SEC mode transfer from AB may result in pop stalls. 2. Nozzle folly closed(higher taxi thrust). 3. Stall warning is inoperative (engine overtemp warning still available). 4. No nozzle position indication. 5. No AB capability. 6. Decreasestall margin at low rpm. 7. 65 to 116 percent basic engine thrust available (seeFigure 14-4). 8. Main engineignition continuouslyenergized. 9. No idle lockup protection. 10. IGV fixed full open(lower windmill airspeed). 11. RATS inoperative. 145.7
If WING SWEEP advisory light is illuminated,cycling L AICS circuit breaker(LFI) may causeunintentionalwing sweepunless WING SWEEP DRIVE NO. 1 (LDI) and WG SWP DR NO. Z/MANlJV FLAP (LEI) cb’s arepulled. 4. Affected L or R AICS cb - Cycle (LFL, left or LGI, right). If engineremains in SEC: 3. ENG MODE SELECT - SEC.
Uncommanded
SEC Mode
Rpm Decay
Enginewill flameout iftransfer is delayedto below 59-percent‘pm. 1. ENG MODE SELECT - PRI (greaterthan 59percentrpm). If PRI mode is restored: 2. Maintain constant subsonic airspeed in level flight.
4. Avoid abruptthrottle movements. 5. Land as soonaspracticable.
Landing in SEC mode may increaselanding roll becauseofloss ofnozzle reset.Ifrunway length or braking conditions warrant, make an arrestedlanding.
pii-1 If WING SWEEP advisory light is illuminated,cycling L AICS circuit breaker(LFl) may causeunintentional wing sweepunless WING SWEEP DRIVE NO. 1 (LDl) and WG SWP DRNO. 2/MANUV FLAP (LEl) cb’s arepulled. 3. Affected L or R AICS cb - Cycle (LFl, left or LG 1, right).
NAVAIR
Ol-F14AAD-1 % OF PRIMARY
THRUST
FllO-GE-400
ENGINE
_
35
i 85 -
I
\
-\
I
30 j
I
-.
I’
: I’
/ __---
_-
0 0
0.1I
0.2I
I 0.3
I 0.4
I 0.5
MACH
I 0.6
I 0.7
-I 0.8
--
92 I 0.9
1.0
NUMBER
0.FSOD-21
Figure 14-4. SecondaryMode Thrust Levels ORIGINAL
14-14
2-c
NAVAIR Ol-FlI)AAD-1
14.58 Uncommanded Engine Acceleration Airborne (No Throttle Movement). Uncommandedengineaccelerationis characterizedby an increasein thrust without throttle movement as a result of an AFTC or MEC failure normally associatedwith one engine.Selection of the ENG MODE SELECT switch(es)to SEC may restorethrottle authority. 1. EN0 MODE SELECT -
SEC.
If dual engineuncommandedaccelerationis associated with CADC failure, normal primary mode may be regained by reselectingPRI mode with the gear handle down. If engineis still uncommandedand engineshutdownis necessq: 2. Throttle (affectedengine)- OFF. 3. Refer to Single-Engine Cruise Operations,parsgraph 14.5.3.2. 14.5.9 Exhaust Nozzle Failed (No Nozzle Response to Throttle Movement). Nozzle position is hydraulically operatedby engineoil from a separate compartmentin the oil storagetank. A rupture in this systemcould renderthe nozzles inoperativeandwould generally cause the nozzles to blow open. This could result in engine mislight, AB blowout, and low thrust. Exhaust nozzles failed closed could result in engine stallsif afterburneris selected,andexcessresidualthrust will be presenton landing rollout. An exhaust nozzle electrically failed openmay be closedby selectingSEC mode. 1. Monitor engineoil pressure/rpm. 2. Throttles - Basic Engine Only (use minimum power required). Note . SEC mode transfer while in AB may result in pop stalls. Nonemergencymanual selection of SEC mode should be performed in basic enginewith the power set above85-percentrpm. . If the fan speedlimiter circuit has failed, enginerollback may occur with the selection of SEC mode. In the event of engine rollback, PRI mode must be reselected above59-percentrpm or flameoutwill occur and an airsWt will not be possible. 3. ENG MODE SELECT - SEC.
Note In SEC mode,nozzleindicatoris inoperative. 4. Obtain visual inspection. If nozzle is openin SEC mode or abnormalresponse: 5. ENG MODE SELECT - PRI. 6. Assume mechanical failure and land as soon as practicable. If nozzle is closedor a visual inspectionis not possible: 5. ENG MODE SELECT- Remain in SEC. 6. Assume electrical failure and land as soon as
practicable. 14.510 Stuck/Jammed Throttle(s). One or both throttles may becomejammed in the afterburnerrange becauseof misadjustmentsor FOD within the throttle quadrant. Selection of SEC mode may be required to control rapid fuel consumption and airspeed and/or altitude. Ifthe problem cannotbecorrected,engineshutdown with the fuel shutoff handlemay be necessaryto abort a takeoff, to control a stalledengine,or to effect a safe landing. If the afterburnerdetent lever is misadjusted, the right throttle may not move inboardthrough the AB detentinto the basic enginerange. An additional failure mode has been identified that may causeone or both throttles to becomestuck in the basic engine range. If a large idler bearing in either electromechanicalrotary actuator fails, it can jam the geartrain andcreateside loadson themechanicalclutch sufficient to lock it and prevent further throttle movement. Failure may occur at any power settingbetween idle andmilitary and is mom likely to be observedwhen throttlesareretarded.While failure will preventaffected throttle from being retardedany further, it may be possible to move it forward. 14.5.10.1
Stuck or Jammed Afterburner
Throttle(s)
In
Note . Spoiler brake will be inoperative with either throttle stuck aboveidle. l
Speedbrakeand DLC will be inoperative with either throttle stuck abovemilitary.
1. L ENG MODE SELECT and/or R EN0 MODE SELECT -SEC.
I I
NAVAIR 01-FI4AAD-I
2. Apply maximum inboard force on throttles and retardas required.
I If throttle(s)will not retardbelow minimum AB: I
If WING SWEEP advisory light is illuminated,pulling L AICS circuit breaker(LFl) may causeunintentional wing sweepunless WING SWEEP DRIVE NO. 1 (LDI) and WG SWP DRNO. 2/MANW FLAP (LEI) cb’s are pulled.
3. Match throttles.
I
4. Relax aft pressureon throttles. 5. While forcing throttlesapart laterally:
5. Affected L or R AICS cb LGl, right).
a. Pull throttlesstraight at?to MIL detent. b. Move throttles inboardand aft.
6. Affected INLET RAMPS switch-AUTO.
6. Do not reselectafterburner.
7. Land as soonas practicable.
If right throttle will not retard: 7. Right FUEL SHUT OFF handle required). 8. Right throttle-MAX
Pull (LFl, left or
If INLET light only is illuminated, attempt AICS programmer reset:
Pull (if
4. Deceleratebelow 0.5 TMN.
AB (after shutdown). p&G-,,,,,,,
i
I I
Failure to move theright throttle full forward may limit theleft throttle to 88 percentor less after it is retardedbelow the MIL stop.
If WING SWEEP advisory light is illuminated, cycling L AICS circuit breakerLFl may causeunintentional wing sweepunless WING SWEEP DRIVE NO. I (LDl) and WG SWP DRNO. 2MANW FLAP (LEl) cb’s are pulled.
9. Refer to single-engineprocedures(Chapter 15). If left throttle will not retard:
5. Affected L or R AICS cb - Cycle (LFl, left or LGI, right).
10. LetI FUEL SHUT OFF handle-Pull (if required). Il. Refer to single-engineprocedures(Chapter15).
If INLET light goes off:
14.5.11 AICS Malfunctions 14.5.11.1 RAMPS Light/INLET Light
6. Affected INLET RAMPS switch-AUTO. If INLET light remains illuminated:
* 1. Avoid abrupt throttle movements. ‘2. Decelerateto below 1.2TMN l 3. Affected INLET RAMPS switch - STOW.
If WING SWEEP advisory light is illuminated,pulling L AICS circuit breaker(LFI) may causeunintentional wing sweepunless WMG SWEEP DRIVE NO. 1 (LDI) and WG SWP DR NO. 2lMANW FLAP (LEI) cb’s arepulled.
A RAMPS light should alwaysbe accompanied by INLET light when the landing gear handle is UP. If RAMPS light remainsilluminated:
6. AffectedLorRAICScb-PPull(LFI,lefiorLGl, right).
4. Throttle (bad engine)- 80 Percentor Less, ORIGINAL
14-16
7. Affected INLET RAMPS switch-AUTO.
3. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2.
8. Remain below 1.2 TMN. If shutdownis not feasible: 14.512 INLET ICE Light 2. Rpm - Set Miimum Rpm. 1. ANTI-ICE switch - ORIDWON. 3. Avoid high-g or large throttle movements. When clear of known icing conditions: 4. Land as soon aspracticable. 2. ANTI-ICE switch -AUTO/OFF. 14.5.13.2 L or R OIL HOT Light p&G-) Ice may form on inlet and ramp surfaces without any other visual indications, which may causecompressorstalls and/orFOD. 14.5.13 Oil System Malfunction. Malfunctions in the oil system are indicated by an L or R OIL HOT light, OIL PRESS light, or by oil pressurebelow or abovenormal. If oil pressure.is over 65 psi, retardpower until pressure is within the normal range.If pressurecannot be reduced,the engine should be shut down to avoid rupfaring oil lines. If oil pressureis lessthan 15psi, bearing wear canbe minimized by maintaining a constantthrottle settingandavoidingmmecessaryaircraftmaneuvers. Bearing failure is normally characterizedby vibration, increasingin intensity with bearingdeterioration.When vibration becomesmoderateto heavy, engineseizureis imminent if engine is not shut down. Continuedopemtion of an engine with oil pressureless than 15 psi is likely to result in illumination of OIL HOT light or an engine seizure.If conditions permit, it is advisable to shut down the engineto reducedamageand to save it for emergencyuse. 14.5.13.1 OIL PRESS Light and/or Abnormal Oil Pressure 1. Throttle (affectedengine)- IDLE. If oil pressureis below 15 psi, above 65 psi, or engine vibration: If shutdownis feasible: 2. Throttle (affectedengine)- OFF.
Illumination of an OIL HOT caution light may be an indication of abovenormal gearbox scavengeoil temperatureor high supply temperature.Continuous engine operation will result in reducedgearboxlife and lubrication degradation. Note On deck OIL HOT light may be causedby underservicingor by excessivetemperature on deck In the event of OIL HOT light on deck position throttles to OFF. 1. Oil pressure- Check 2. Throttle (affectedengine)- 85-PercentRpm. 3. If after 1 minute light is still illuminated, throttle - OFF. 4. Land as soonaspracticable. 5. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2. 6. Relight engine for landing, if necessary. 14.5.14 RATS Operation In Flight 1. Tailhook-
DOWN.
If conditionspermit: 2. ANTI ICE CONTR HOOK CONTiWSHLD/AIR cb -Pull (8C2).
Illumination of both lights may be indicative of a total motive-flow failure. Zeroor negative-gflight shouldbe avoided.
. Pulling the ANTI ICE CONTR HOOK CONT/WSHLD/AIR cb (8C2) disables RATS. Inform CV of increased windover-deckrequirementsand grossweight settingsfor a non-RATS arrestment.
Complete loss of motive flow will result in the sump tank interconnectand the engine feedcrossfeedvalveremainingin the closedposition, isolating the forward and aft systems.Consequently,single-engine operationwill causefuel on the opposite side to be unavailable.
. With the circuit breakerin andRATS operating, there is reducedthrust available for approachand use of afterburnermay be requiredto arrestsink rate.
If one light remains on:
pzFjzJ
3. No afterburnerabove 15,000feet.
ANTI ICE CONTR HOOK CONT/ WSHLD/AIR circuit breaker(8C2) must be in prior to hook transition.Avoid icing conditions and rain with circuit breakerpulled.
4. Fuel distribution - Monitor (balanceif required). piGi-1
Note IfRATS secureswhen thehook is raisedwith no other weight-on-wheelsindication, failure is internal to the RATS circuitty.
If the sump tank interconnect valve has failed, selecting AFT or FWD on the fuel feed switch could result in fuel migration to the inoperativeside. If fuel migration occurs after selecting AFT or FWD on the feed switch (as indicatedby a lOO-to 300-pound per minute increaseon the inoperativeside), immediately return the feed switch to NORM.
14.6 FUEL SYSTEM MALFUNCTIONS 14.6.1 Fuel Pressure Caution Lights. Afterburner operationsplace an extremedemandon the enginethe1 feedsystem. Aircraft maneuversin the zero to negative 0.5gflight regimeaggravatethe effectandmay generate a situationwhereafterburnerblowout andengineflameout occur. The first indication of this condition may be a fuel pressurelight.
5. Land as soonas practicable. 14.6.2 L or R FUEL LOW Light
14.6.1.1 L and/or R FUEL PRESS Light(s) On
1. DUMP switch - OFF.
1. Both throttles- MIL Power or Less. 2. Restoreaircraft to l.Og flight.
2. Fuel distribution - Check (balanceif required). If wing and/orexternal fuel remaining:
If both lights remain on:
3. WMG/EXT TRANS switch - ORIDE.
3. Increasepositive g’s to greaterthan l.Og.
4. Land as soonas practicable.
4. Descendbelow 25,000feet.
14.6.3 Fuel Transfer Failures
5. Maintain cruisepower settingsor less.
14.6.3.1 Wing Fuel Does Not Transfer
6. Land as soon aspossible.
ORIGINAL
1. WMG/EXT TRANS switch - ORIDE.
14-18
NAVAIR
Onewing still doesnot transfer: 2. FEED switch - Select High FuselageTape Side. If wing fuel doesnot decreaseafter 2 minutes or wing fuel transfercomplete: 3. FEED switch -NORM. 14.6.3.2
External Transfer
Tanks Fail To Transfer Slowly
Ol-F14AAD-1
14.6.5 Fuel Leak. In the absenceof actualvisual detection, a fuel leak resulting from a malfunction or failure of a fuel system componentwill usually result in a split in the fuel quantity tapesor feeds.The flightcrew must determine from available instruments(tie1 flOW and total fuil quantity) whether the aircraft is losing more fuel thanthe enginesindicate they areusing.Carrectivestepsarebasedonconfirmation ofthe leak.Upon confirmation of abnormal decreasein fuel quantity:
or
1. Land as soonas possible.
1. WING/EXT TRANS switch - ORIDE. If fuel continues to transfer improperly or does not transfer: 2. REFUEL PROBE switch - All Extend, Then Retract. 3. Apply cyclic positive or negativeg’s. 4. AIR SOURCE pushbutton-OFF Then ON (below 35,000 feet, lessthan 300 knots).
Use of afterburnerwiih fuel leak shouldbe limited to emergencyuseonly. 2. WING/EXT TRANS switch - OFF. Ifabnonnal fuel quantity decreaseceases,fuel leak is in wing/wing pivot or attachment points for auxiliary tanks: Note
pi&-,,,,,,, CV arrestment,CV touch andgo, or normal field landings with full or partial fuel in the external tanks is not authorizedbecauseof overloadofthe nacellebackupstructure.Only minimum descentratelandingsarcauthorized. 14.6.3.3
Wings Switch
Fuel With Switch
@El).
Note Enough time shouldbe allowed for quantity tapes/feedsto develop split so that leak can be isolated to left or right feed group. Affectedside will be low side.
2. WING/EXT TRANS switch - OFF. Wings Accept EXTD Position
If leak is not stopped,it is in engine/nacellearea.proceedimmediately with next step. 3. FUEL FEED/DUMP cb -Pull
Do Not Accept Fuel With in ALL EXTD Position
1. REFUEL PROBE switch - FUS EXTD.
14.6.3.4
This cannotbe determineduntil the fuel level hasdecreasedto below the sourceofthe leak. Do not proceedwith the below stepsprematurely.
in FUS
4. Throttle (affectedside)- OFF.
1. WING/EXT TRANS switch - ORIDE.
5. Conditionspermitting, allow rpm to decelerateto windmill ‘pm.
Note
With AIR SOURCE OFF pushbutton selected,externalfuel tanks will not transfer. 14.6.4
Uncommanded
Dump
1. DUMP switch - Check OFF. 2. FUEL FEED/DUMP cb - Pull @El).
6. FUEL SHUT OFF handle(affectedside)- Pull. 7. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2. Settingthe WING/EXT TRANS switch to OFF stops motive flow to thewings andinhibits externaltanktransfer and fuselagetank pressurization.Pulling the FUEL
NAVAIR
Ol-F14AAD-I
FEED/DUMP circuit breaker (REI) isolates the right andforwardsystemandthe left andaft fuel system.This aids in determiningthe location of the leak andprevents loss of fuel from the good sidevia the fuel systeminterconnects,The circuit breakeralso deactivatesthe function of the FEED switch, the automatic balance functions, and the fuel dump system. Securingthe engine and, if necessary,pulling the FUEL SHUT OFF handle shouldstopmost engineleaks.
If generatordoesnot reset:
14.7
14.7.1.2
ELECTRICAL
FAILURE
Generator Failure. Amechanicalgenerator failure or an overheatingautomatically causesthe CSD unit of the generatortransmissionto decouplefrom the engine. Once disengaged,the CSD cannot be reconnectedin flight. 14.7.1
Either generatorby itself is capableof supplying the electricalrequirementsof theaircraft. Even doublegeneratorfailure will notcausetotal loss ofelectrical power; the5-kVA emergencygeneratorwill automaticallypick up the load for the essentialac and dc busesNo. 1 and No. 2, and the AFCS bus. If the bidirectional pump is operating and ptessure drops to bctwcen 2,000and 1,100psi (dependentupon the load placedon the generator),the emergencygenerator will automatically shift to the l-kVA mode and power only the essentialac and dc No. 1 buses.If combined systemhydraulic pressuresubsequentlyrecovers, the emergencygeneratorswitch must be cycled through OFF/RESET to NORM to regainthe essentialNo. 2 ac and dc buses.Figure 14-5lists the equipmentavailable with only the emergencygeneratoroperating. With both engines inoperative, windmilling engine(s)provide(s)hydraulic pressurefor both the flight controls and the emergency generator.However, the flight controls have first priority and may cause the emergencygeneratorto loiter when low airspeedsreduceenginewindmilling ‘pm. Approximately450 knots mustbe maintainedto ensureadequateenginewindmilling rpm for hydraulic pressure. 14.7.1.1
L or R GEN Light
1. Generator (affected generator switch) RESET, Then NORM.
OFF/
Note If the generatorfault is corrected,the generatorwill be reconnectedandthe cautionlight will go off.
2. Generator(affected generatorswitch) - TEST. If the light goes off with the switch in TEST, the fault is in the respectiveelectrical distribution system. If light remains illuminated, thegeneratorhas beendisconnectedautomatically andthe fault is in IDG or generatorcontrol unit. L or R GEN and TRANWRECT
Lights
1. Generator (affected generator switch) - OFF/ RESET, Then NORM. 2. If L GEN and TRANS/RECT lights remain illuminated,selectEMERG GEN on MASTER TEST panel. Note
With R GEN and TRANS/RECT lights illuminated, ac essentialpower is supplied by the L GEN. Selecting EMER GEN on the MASTER TEST panel (with R GEN and TRANSlRECT lights) will not provide any additional power but may causean interrupt as the supply is transferredfrom the L GEN to the EMER GEN. 3. Land as soon as practicable. 14.7.2
Double
Generator
Failure
1. Both generatorswitches-Cycle. If operatingon emergencygenerator,the following important systemsare inoperative: 1. Emergencyflight hydraulics 2. Outboard spoiler module and emergency flap activation 3. OBOGS concentratorheater (OBOGS may still function at a reducedbut adequatelevel). If temporary loss of combined system pressurecauses emergencygeneratorto shift to 1 kVA mode (to drop No. 2 essentialbus): 2. EMERG generatorswitch-Cycle. 3. Land as soonas practicable.
NAVAIR
ESSENTIAL AICS RAMP STOW ANGLE OF ATTACK IND ALTITUDE LOW WARNING BACKUP CONTR/B/U
OXY LOW
BACKUP IGNITION BACK UP OXY PRESSURE IND BAROMETRIC ALTIMETER CONSOLE LIGHTS (PILOT) DC ESSENTIAL NO. 1 FEEDER DC TEST ENGINE INSTRUMENT ENGINE INSTRUMENT WHITE LIGHTS ENGINE START
GROUP GROUP
BUSES NO. 1 (1 KVA MODE)
FIRE EXTINGUISHING FLOOD LIGHTS FUEL QUANTITY INDICATOR HYDRAULIC PRESSURE INDICATION ICS IFWSIF INSTRUMENT BUS FEEDER INSTRUMENT LIGHTS JElTlSON (EMERGENCY) MAIN LANDING GEAR SAFETY RELAYS OBOGS CONTR
ESSENTIAL AFCS AFCSBUSFEEDER AICS AICS LOCKUP POWER AIR SOURCE CONTROL ALPHA COMPUTER ALPHA HEATER ANNUNCIATOR PANEL POWER ANTI-ICE CONTROL ANTI-ICE PROBE ANTI-SKID POWER ARMAMENT GAS ARRESTING HOOK CONTROL AUTOMATIC DIRECTION FINDER AUXILIARY FLAP/FLAP
BINGO POWER
RADAR ALTIMETER RUDDER TRIM STANDBY ATTITUDE STORE MANAGEMENT PROCESSOR TAIL/RUDDER/FLAP
INDICATOR
TURN AND SLIP INDICATOR VHF/UHF RADIO 1 8.2 VOICE SECURITY EQUIPMENT WHEELS POSITION INDICATIONS WING POSITION INDICATIONS
OBOGS CONCENTRATOR PITCH/ROLLTRlM PROBE LIGHT
FIRE DETECTION
CONTROL BDHI
0%FI4AAD-1
BUSES NO. 2
BLEED AIR LIGHT
ENGINE STALL TONE
BLEED DUCT CABIN PRESSURE CADC CANOPY LIGHT
EXHAUST NOZZLE EXTERIOR LIGHTS CONTROL FLAP/SLAT CONTROL SHUTOFF
CIU CURSOR CONTROL DC ESSENTIAL NO. 2 FEEDER DEKI LIGHTS DISPLAY PROCESSORS ECS TEMPERATURE CONTROL EJECTION COMMAND INDICATOR EMERGENCY GENERATOR TEST ENGINE AFTC ENGINE ANTI-ICE
FLIGHT CONTROL AUTHORITY FUEL DUMP FUEL FEED FUEL MANAGEMENT PANEL FUEL PRESSURE LIGHT FUEL TRANSFER OVERRIDE FUEL VENT VALVE FUEL LOW LIGHT GENERATOR LIGHTS GROUND ROLL BRAKING INDICATOR HUD
ENGINE ANTI-ICE VALVES ENGINE OIL COOLING ENGINE SECONDARY MODE
Figure 14-5. EmergencyGeneratorDistribution (Sheet 1 of 2)
14-21
ORIGINAI
NAVAIR Ol-FI4AAD-I
HYDRAULIC PUMP SPOILER
MISSION COMPUTER NO. 2
ROLL COMPUTER
CONTROL HYDRAULIC VALVE CONTROL INBOARD SPOILER CONTROL INSTRUMENT LANDING SYSTEMS (ARA-63)
MOTIVE FLOW ISOLATION NOSE GEAR STRUT LAUNCH BAR LIGHT NOSE WHEEL STEERING OIL HOT LIGHTS
RUDDER TRIM SENSOR CONTROL SPEED BRAKES ENABLE SPOILER INDICATOR STARTER VALVE LIGHT
INS INS SYNCH JTIDS LADDER LIGHT
PEDAL SHAKER PILOT ANNUNCIATOR (AUX POWER)
TAXI/FORMATION LIGHT TRANSFORMER/RECTIFIER LIGHTS
MACH TRIM MAIN LANDING GEAR RELAYS MFD NO. 1 MISSILE POWER HUD TEST
PITCH COMPUTER PITCH-ROLLTRIM PITOT HEAT RADAR BEACON (AN/APN-154)
PANEL
ENABLE
UTILITY LIGHTS WINDSHIELD AIR WINDSHIELD DEFOG CONTROL YAW SAS POWER SUPPLY
Figure 14-5. EmergencyGeneratorDistribution (Sheet2 of 2) 14.7.3 Double Transformer-Rectifier Failure. The 5-kVA emergencygeneratorwill automatically activate and power the essentialac and dc No. 1 and No. 2 and AFCS buses.SeeFigure 14-6 for listing of inoperabledc-poweredequipment. 14.7.4 TRANSIRECT Light. The TRANSIRECT light will illuminate if eitheror both T/R malfunction. If oneT/R fails, the operatingT/R will assumethe dc load. If both TiRs fail, the emergencygeneratorwill go on the line and tie to essentialdc busesNo. 1 andNo. 2. Land as soonas practicable. Poppedcircuit breakersshouldnot beresetmore !han once or be held depressedunlessthe associatedequipment is absolutely an operationalnecessity.A popped circuit breaker indicates an equipment malfunction or an overloadcondition. Repeatedresetsor forceddepressionsofpopped circuit breakerscan result in equipment damageand/or seriouselectrical tire. The lossof onegeneratorandfailure to tie the acmain buses will illuminate the affected GEN light. The TRANYRECT light will also illuminate bccausc the affected generator’sassociatedT/R is not receiving ac power to convert. Upon observing a TRANWXECT light, the pilot can check that the aircrafl is actually experiencinga T/R failure and not a bus tie failure. If the seatadjust,white floods, or instrumentlights arestill operative with the R GEN light illuminated, the bus is tied. If the throttles are operatingon the boostedmode with a L GEN light illuminated, the bus is tied.
If thehydraulictransferpump is operatingandpressure dropstobehvecn2,000and 1,100psi (dependent uponthe load placedon the generator),the emergencygenerator will automaticallyshift to the 1-kVA modeandpoweronly the csscntialac anddc No. 1bttscs.If combinedhydraulic pressuresubsequentlyrecovers,the EMERG generator switch must be cycledthroughOFF/RESETto NORM to regaintheessentialac and dc No. 2 andAFCS buses. 14.7.5 Electrical Fire. Electrical tires may be indicatedby visual or audible arcingor an ozoneodor in the cockpit and popping circuit breakers.Electrical tires producedby 400 “F air leaks can result in any one or combination of the following: 1. Pinballing caution/advisorylights and instrument indications. 2. CADC associatedcaution/advisorylights. 3. Uncommanded movement of electrically controlled components (SAS, spoilers, wing sweep, throttles). 4. Complete electrical failure. 5. Smoke, fumes,and/or heatin the cockpit. The most effective methodto extinguishanelectrical fire is to secureall electrical power. However, some conditionsmay not permit securingtheemergencygeneratorafterboth main generatorsaresecured.Night/IFR flight or ECS-duck-leak-induced electrical fires are caseswheresecuringall electrical power is not feasible.
NAVAIR
ACM LIGHT AIRBORNE SELF-PROTECTION JAMMER AIR SOURCE CONTROL ALE-39 CHAFF/FLARE ALR-67 AMC BlT ANIAWW-I ANNUNCIATOR PANEL DIM CONTROL ANTENNA LOCK ANTENNA HYDRAULIC SERVO ANTI-COLLISION LIGHT ASW 27 AUTO THROTTLE BEAM PS BOL CHAFF DISPENSERS BRAKE ACCUMULATOR SHUTOFF VALVE COUNTING ACCELERATOR DATA LINK DATA PROCESSORS DATA STORAGE SET DEHYDRATOR DEU DIGITAL DISPLAY ENABLE ELECTRICAL COOLING
EMERGENCY GENERATOR COOLING FLIGHT HYDRAUUC BACKUP GROUND POWER COOLING INTERLOCK GROUND TEST GUN POWER HUD CAMERA HV POWER SUPPLY IFF AIR-TO-AIR INS BAllERY POWER INTERFERENCE BLANKER INTEGRATED TRIM INlERRUFllON FREE DC BUS IRST JTlDS DATA PROCESSOR AND BATTERY HEATER LEFT/RIGHT AICS HEATER LEFT MAIN TRANSFORMEWRECTlFlER LIQUID COOUNG MASTER ARM MASTER TEST MISSILE POWER RELAY UNlT MISSION COMPUTER NO. 1 MONlTOR BUS CONTROL MULTI-FILTER ASSEMBLY
Ol-F14AAD-1
MULTI-FUNCTIONAL DISPLAYS 2AND3 NFO CONSOLE LIGHT OUTBOARD SPOILER CONTROL AND PUMP POSITION LIGHTS RADAR COMPONENTS RECONNAISSANCE EQUIPMENT RIGHT MAIN TRANSFORMER RECTIFIER RIGHT DC TEST SAHRS SEAT ADJUST SOLENOID POWER SUPPLY STATION 1.1 A, AND B AIM-9 COOLING POWER STATION 1, 3, 4, 56, AND 8 DECODER RELAY POWER STEADY POSITION LIGHTS STORES MANAGEMENT PROCESSOR STORM FLOOD LIGHTS SUPPLEMENTAL POSITION LIGHTS TELEVISION CAMERA SET
Figure 14-6. Failure of Both Transformer-RectifiersEquipment InoperativeList *l. L and R generators-OFF. Note
If associatedwith any other direct or indirect indication of ECS malfunction, perform ECS Leak/Elimination of Smoke and Fumes procedure,paragraph14.8.1
OBOGS concentratorheater power will be lost. OBOGS may still function at a reduced but adequatelevel. If uncommandedSAS or spoiler inputs are present: *2. ROLL and PITCH CMPTR AC cb’s -Pull &Al, LBI).
An electrical tire may affect the CADC and AICS systems causing random movements of the wings andramps. If conditionspermit: fTzjziJ
Ground-roll braking is inhibited with LA1 andLB1 cb’s pulled. 83. YAW SAS switch - OFF.
OBOGS will shut down if all electrical power is lost. BOS will be activated above 10,000 feet MSL but will not be available below 10,000feet MSL.
The following systemsare still available: 1. Airspeed indicator Oxygenbreathingtime onBACKUP is limited andrequiresimmediatemissionplanning.See OBOGS emergencyprocedure.SeeFigure 281 for oxygenbreathingtime remaining. 4. EMERG generatorswitch - OFF.
2. Altimeter 3. Cabin pressurealtimeter 4. Vertical velocity indicator 5. Arresting hook
Securing all electrical power while airborne causesthe ECS to go full cold. If causeof fire can be isolated: 5. Pull cb’s of affected equipment, 6. All generators-NORM. If causeof tire cannot be isolated: 5. Secureall unnecessaryequipment, 6. EMERG generatorswitch - NORM.
6. Standbyattitude gyro (3 minutes) 7. Emergencywing sweep 8. Landing gear 9. Main flaps/slats 10. Standbycompass 11. Backup oxygen system (above10,000feet MSL). (,,,,,,,I
7. Land as soonas possible. fiEjizJ Do not operateengineson the groundwithout electricalpower. Groundcooling fansare shut off, causinghot bleedair to cook off oil andhydrocarbonsin theECS ducting,resulting in smoke in thecockpit andpossibledamage to the ECS turbine compressor. 14.7.6
Total Electrical
Failure
1. Descendor climb to known VFR conditions. Note
The standby attitude gyro is capable of providing reliable attitude information (within !?‘) for up to 3 minutes after a complete loss of power. Cabin pressurewill be lost and ECS will go full cold. 2. Attempt to contactradarfacilities or otheraircraA by handheldsurvival radio. 3. Make arrestedlanding as soon aspossible.
Ground engine operation without electrical power supplied by either the generatorsor external power may cause20-mm ammunition detonationbecauseof excessiveheatin the gun ammunition drum.
OBOGS will shut down if all electrical power is lost. BOS will beactivatedabove 10,000feetMSL but will not beavailable below 10,000feet MSL. Oxygen breathing time on BACKUP is limited and requires immediate mission planning. SeeOBOGS emergencyprocedure. SeeFigure 2-81 for oxygen breathing time remaining. Do not operate engines on the ground without electrical power. Ground cooling fans are shut off, causinghot bleed air to cook off oil and hydrocarbonsin the ECS ducting, resulting in smoke and possible damageto the ECS turbine compressor.
NAVAIR
If warning or caution systemsdo not function, the first indication of an ECS leak can vary. The presence and order of appearanceof indications dependon the size and location of the leak.
Note l
Total electricalfailure will causethe sump tank interconnect,engine crossfeed,and motive flow isolationvalves to close, fully isolating both tank systems.Wing andexternal fuel will transferinto the fuselage.
Direct and indirect indications are listed below in a representativeorder of appearance;however, they can appearin any sequence.The presenceof any one direct indicationorany two indirect indicationsshallbe treated as an ECS leak.
a Ifpossible, a sectionIFR descentshouldbe conductedto VFR conditionsfor landing. All other normal system and cockpit cues are not available. When all electrical power is shut off, the cockpit dumpvalve closesandthe environmentalcontrol system suppliesonly cold air to thecockpit andforcedaircooled avionics. Pressurizationwill slowly bleed off. If operational necessityprohibits immediate descent,maintain cockpit altitude at the highestpracticable level to conserveBOS. Otherwise, descendto a cabin altitude less than 10,000feet. If the system failure occurs in the day or night VFR environment,immediatereturn to baseand an emergencylanding shall be accomplished.In the day or night IFR environment,ascendor descendto known VFR conditions.(Extreme careshouldbe exercisedbecauseof partial panel environment.)Reducepower setting to maximum endurance.Contact nearestground facility by handheldsurvival radio. Once positive radar identification is made, follow controllers’ directions to landing. 14.8
ECS MALFUNCTIONS/FAILURES
14.8.1 ECS Leak/Elimination of Smoke and Fumes. Bleed air leaks,hot air leaks,and ECS turbine
failureshavesimilar indicationsand resultsand shall be treatedas one failure, ECS leaks. All can causeunsurvivahle damagewhen not recognizedand correctedexpeditiously. Bleed air leaks in the enginecompartment illuminate the appropriate FIRE warning light, and FIRE light proceduresapply. Bleed air leaks outsidethe enginecompartmentilluminate the BLEED DUCT caution light. Hot air leaks also illuminate the BLEED DUCT caution light. Illumination of the appropriate caution/warninglight shouldhe the first indication ofan ECS leak. ECS turbine failures can causehot air leaks. After a compressor-sidefailure, catastrophicthermal damagecan be causedby heatgeneratedduring turbine winddown. Wire bundles, flight control rods, and SMDC lines are in the vicinity of the ECS turbine and hot air manifold. Both turbine andcompressor-sidefailuresmay causea whining noise emanatingfrom below andbehind the right side of the RIO cockpit, and other indicationsof an ECS air leak follow.
Direct indications: 1. BLEED DUCT caution light 2. FIRE warning light 3. Smokeor fumes in the cockpit 4. Heat emanating from behind aft right comer of RIO cockpit 5. Complete loss of ECS airflow. Indirect indications: 6. Audible pop or squealfrom ECS 7. Rapid drop in cockpit airflow 8. Electrical tire indications 9. Any ECS advisory light (SENSOR COND or COOLING AIR). When an ECS duct leak is indicated or ECS turbine whine is heard,AIR SOURCE should be immediately selectedOFF. ECS leaks may melt wiring splice junctions andcreateconditions that may induceanelectrical tire. Ifan associatedelectricaltireoccurs, smoke,fumes, heat, and damageto the surroundingaircraft structure may intensify. Since electrical fire proceduresare not compatible with measures to eliminate smoke and fumes,canopyjettison may becomenecessaryas a lastditch procedure. (WARNING1 Failure to immediately selectAIR SOURCE OFF upon indication of an ECS leak may result in severeaircraft damageand loss of aircraft.
14-25 _-------
----
Ol-Fl4AAD-1
ORIGINAL _------------a-
,\\\\\\\m
I
NAVAIR 0%Fl4AAD-1
1 WARNING
*4. RAM AIR switch -OPEN. Note Ram air door may take up to 50 secondsto fully open.
1
Selectionof AIR SOURCE to RAM alloys bleed air to circulate throughoutthe 400 “F manifold system.
5. Airspeed-Below
300 knots/O.8Mach.
6. Nonessentialelectrical equipment-Secure.
Oxygenbreathingtime on BACKUP is limited andrequiresimmediatemissionplanning.See OBOGS emergencyprocedure.SeeFigure 281 for oxygenbreathingtime remainiig.
7. CANOPY DEFOG/CABIN AIR lever - CANOPY DEFOG. 8. Land as soonas possible. If electrical tire:
Note When ECS serviceair to theOBOGS concentrator is shut off, the aircrew has approximately 30 secondsbefore depleting residual OBOGS pressureand mask collapse.
9. Follow ElectricalFire procedures,paragraph14.7.5. m The EMERG generatorswitch shouldbe let? in NORM unlessthereareoverridingconsiderationsthat mandateturning the emergency generatoroff. Note a SelectingAlR SOURCE OFF eliminates pressurizationto the servicesystem(canopy, g-suit, external fuel tanks, pressure/ ventilation suit, andairbagseals).Rain mmoval, defog, OBOGS, and heating systems are also eliminated. Judicious reselectionof AIR SOURCE to BOTH or RAM to regaincritical SupporVsetvice systems is predicatedon severityof ECS malfunctionandoperationalrequirements.
Restoration of service air (selecting RAM) will return OBOGS to operation. * 1. AIR SOURCE pushbutton- OFF. *2. OBOGS master switch-BACKUP.
Oxygen breathingtime on BACKUP is limited and requires immediate mission planning. See OBOGS emergency procedure. See Figure 2-8 1 for oxygen breathing time remaining.
l
l
a If ECS airflow continues, ensure AIR SOURCE CONTROL cb (RDZ) is in. If cb RD2 haspopped,ECS control is lost.
Note When ECS service air to the OBOGS concentrator is shut off, the aircrew has approximately 30 secondsbeforedepleting residual OBOGS pressureand mask collapse.
l
Restoration of service air (selecting RAM) will return OBOGS to operation.
*3. If smoke or fumes are present: a. Altitude - Below 35,000Feet. b. CABIN PRESS switch -DUMP. 14-26
Securingall electricalpowerwhile airborne closescockpitdump valve andcabinhot air valve, opensbleed air shutoff valves and dualpressureregulator,andtheram air door remainsat its lastcommandedposition(tam air door takesup to 50 secondsto open). This resultsin full cold air to the cockpit, uncontrolledbleed air to circulate,andthe lossofnormal cabindumpcapability.Minimize low- speed(lessthan0.25 Mach) and ground operationsas the heat exchanger cooling fan will be inoperative and ECS overheatcondition will result.
NAVAIR
Ol-FI4AAD-1
Note
Elimination of smokeor fumes without electrical power may be accomplishedby ECS airflow. To obtain maximum smoke/ fume removal capability under this condition, fly below 8,000 feet MSL and set the throttle to maximum practical position. This will open the cabin regulatorvalve for maximum ECS airflow. If smoke or fumes are not eliminated,it is most probable that smoke/fumes arebeing regeneratedby an ECS air leak. As a last resort,jettison the canopy. 14.8.2 14.8.2.1
COOLING
Oxygen breathingtime on BACKUP is limited and requires immediate mission planning. See OBOGS emergency procedure. See Figure 2-81 for oxygen breathing time remaining. Note
. WhenECS serviceair to theOBOGS concentratoris shut off, the aircrew has approximately 30 seconds before depleting residual OBOGS pressureand mask collapse.
AIR Light
On Deck
1. AIR SOURCE pushbuttonENG, or BOTH ENG.
. Restoration of service air (selecting RAM) will return OBOGS to operation.
Check L ENG, R
2. Throttles - Advance Without Closing Nozzles.
If associatedwith any otherdirect or indirect indication of ECS malfunction:
3. CANOPY DEFOG-CABIN AIR lever - CANOPY DEFOG.
3. Perform ECS Leak/Elimination of Smoke and Fumes procedure,paragraph14.8.1.
4. ECS -MAN/FULL
HOT.
If not associatedwith any other direct or indirect indication of ECS malfunction and operational requirements dictate temporary reselectionof RAM to regain lost service systems (external fuel transfer, OBOGS, cabin pressure,rain removal, engineanti-ice, etc.):
If light goesout: 5. THROTTLES -IDLE. 6. ECS -As Desired.
3. AIR SOURCE pushbutton-RAM.
If light remains illuminated:
4. RAM AIR door switch-Full
5. Securesystems. 14.8.2.2
Increase.
5. AIR SOURCE pushbutton-OFF (when service systemis no longerrequired).
In Flight
6. Land as soonas practicable.
1. AIR SOURCE pushbutton- OFF.
14.8.3
pii-,,,,,,,
TARPS
ECS Lights
Illuminate
1. TARPS sensors- OFF.
Failure to immediately selectAIR SOURCE pushbuttonOFF upon indication of an ECS leak (bleed air or hot air leak indication) or upon hearingECS turbine whine may result in an uncontrollable electrical fire, catastrophic ECS componentfailure, and/orloss of flight controls.
2. SYSTEM switch -OFF. 3. Pull TARPS cb’s:
a. RECON ECS CONT DC (9El) b. RECON ECS CONT AC (2G4)
2. OBOGS master switch - BACKUP.
c. RECON HTR PWR PH A (2Bl) d. RECON HTR PWR PH B (2Dl) 14-27
ORIGINAL
NAVAlR
61.FI4AAD-1
e. RECON HTR PWR PH C (2Fl)
4. AIR SOURCE pushbutton 35,000feet).
RAM (below
f. RECON POD ( 1E2) 5. RAM AIR switch-OPEN (selectamountof ram air desiredfor Eightcrew comfort).
g. RECON POD CONTR (9E2) h. RECON POD DC PWR NO 2 (9E3) i. RECON POD DC PWR NO l(9E4)
High-cockpit temperatureand smokeduring groundoperation indicatesECS cooling fan shutdown. This will occur with an external air source(start cart) without electric power on the aircraft. This results in an overtemperaturecondition causedby operatingwithout ground cooling fans.
4. Ask for visual check of pod by wingman. 5. Land as soon as practicable. 14.8.4
SENSOR COND Light Illuminated or PUMP Phase Circuit Breakers Popped or APG-71 PM Acronym
and/
1. RADAR COOLING switch-OFF. 2. RDR switch - OFF. 3. APG-71 PUMP PH A, B, andC cb’s - Pull (2G3, 2G6,2G7). If other conditions exist that may indicate an ECS malfunction, either directly or indirectly, perform ECS Leak/Elimination of Smoke and Fumes procedure, paragraph14.8.1.
14.8.6
Cockpit
Overpressurization
on Deck.
Cockpit overpressurizationis sensedby the aircrewand verified by lower than normal cockpit altitude on the cabin pressurealtimeter. This condition could be caused by a faulty cabin pressurecontroller or regulator. 1. AIR SOURCE pushbutton- OFF. 2. CABM PRESS switch-DUMP. 3. Canopy- OPEN (when cockpit pressurealtimeter equalsthe field elevation).
4. Land as soon aspracticable. 14.8.5
Cockpit Temperature Malfunction
pii-1
Control
The canopy may explosively leave the aircraft upon unlocking of the canopysill locks if cockpit overpressureis not reduced.
1. TEMP mode switch - MAN. 2. TEMP thumbwheel -As
Desired.
If temperaturecontrol is not regained: 3. VENT AIRFLOW thumbwheel- OFF.
14.8.7
CABIN
PRESS
Light
1. Oxygen mask - ON. If below 15,000feet: 2. CABIN PRESS switch - Cycle.
Reduceairspeedto 350 knots or 1.5 Mach, whichever is lower, to preventram air attemperatureabove110OFfrom enteringaircraft. After ram air flow is stabilized,airspeedmay be increased as required for flightcrew comfort or to increase flow to electronic equipment.
14.8.8
WSHLD
HOT Light
1. WSHLD AIR switch - OFF. If light remains illuminated: 2. AIR SOURCE pushbutton-OFF (below 35,000 feet).
NAVAIR
01-F14AAD-1
Note
If light remains illuminated after air source is off, the indication is faulty. Turn ECS on and land as soonas practicable.
The aircrew will not have any indication of a failure of the monitor. If the aircrew suspects the onset of hypoxia at any time, immediately select BACKUP. The monitor maybe testedoncethe aircrafthasdescended to a cabin altitude of 10,000feet or lessand the ON position on the OBOGS master switch has beenreselected.
3. OBOGS masterswitch - BACKUP.
Oxygen breathingtime on BACKUP is limited and requires immediate mission planning. See OBOGS emergency procedure. See Figure 2-81 for oxygen breathing time remaining.
Oxygen breathingtime on BACKUP is limitcd and requires immediate mission planning. See Figure 2-81 for oxygen breathing time remaining.
Note l
l
When ECS serviceair to theOBOGS concentratoris shut off, the aircrew has approximately 30 seconds before depleting residual OBOGS pressureand mask collapse.
14.9.1
OBOGS
Light
1. BACKUP OXY PRESS - Check.
Restoration of service air (selecting RAM) will returnOBOGS to operation.
4. RAM AIR switch - OPEN. Oxygen breathingtime on BACKUP is limited and requires immediate mission planning. See Figure 2-81 for oxygen breathing time remaining.
5. Reduce airspeed to less than 300 knots or 0.8 Mach. 6. Land as soonaspracticable. 14.9
OXYGEN
SYSTEM
FAILURE
If operationalnecessityprohibits immediatedescent, maintaincockpit altitude at the highestpracticablelevel to conserveBOS. Depressurizingthe cabinwill increase the durationof the backupand emergencyoxygensopply. If fuel is not a problem andflight conditionspermit, descendbelow 10,000MSL. BOS will not beavailable; therefore,it will be necessaryto releaseone side of the oxygenmask in orderto breatheunlessemergencyoxygen is used. Emergency oxygen can be shut off and reactivatedas required.It is recommendedthat emergencyoxygenbe reservedfor final approach,permitting the aircrew to refastenoxygen masks.
14.92
B/U OXY LOW Light
(Both
Cockpits)
1. BACKUP OXY PRESS- Check. If BACKUP OXY PRESS is less than 200 psi: Note
Preparefor mask collapse. Breathing time can vary from 2 to 4 minutes, depending upon cabin altitude. 2. Cabin altitude-Less
Than 10,000Feet.
3. OXYGEN SUPPLY valves-OFF. 4. Oxygen masks- ReleaseOne Side,
NAVAIR
01-F14AAD-1
Before landing: 5. Oxygenmasksand OXYGEN SUPPLY valves -
ON. 6. Emergency oxygen-Activate. If BACKUP OXY PRESS is greaterthan 200 psi: Note
Failure ofthe BN OXY LOW pressurerelay will illuminate both pilot andRIO B/U OXY LOW light. BACKUP OXY PRESS indicator remainsfunctional anddisplaystrue BOS reserve. 2. BACKUP OXY PRESS -Monitor. Note
Emergencyoxygen canbe shut off andreactivated as required. 14.9.3
B/U OXY LOW Light
(Pilot
Only)
1. BOS CONTRiBRT OXY LOW cb (7A4).
Check In
speedincreasesabove 300 knots. ICS and RIO VHF/ UHF communications will probably be impossible above200 knots,althoughthe pilot will be ableto effectively utilize V/UHF at airspeedsup to approximately 400 knots. After lowering the seat,the RIO shouldlean forward to take advantageof the wind blast protection provided by the detail display and instrument panel, while the pilot deceleratesthe aircraft by utilizing idle power, speedbrakes,and moderateg. The RIO should deselectHOT MIC ICS to prevent interferencewith VNHF communications causedby wind blast across the oxygenmask microphone.Helmet losswill resultin severedisorientationbecauseof a total lossof communicationsand vision impairment causedby wind blast. If canopy loss is experiencedat high speed,or if helmet loss.appearsto be possiblebecauseof wind blast or buffeting, retain the helmet by pulling down on the visor cover (keepingarms close to the body). The pilot LAD/CANOPY caution light may be activated by a mispositioning of either the boardingladder or the canopy.If both the pilot LAD/CANOPY andthe RIO CANOPY lights are illuminated, thenthe problem is with thecanopysystem.If the RIO CANOPY light is working but not illuminated, then the problem is with the boardingladder.
2. BACKUP OXY PRESS - Check. m Note
FailureoftheBOSCONTR/B/UOXY LOW circuit breakerwill illuminate only the pilot B/U OXY LOW light. BACKUP OXY PRESS indicatorremainsfunctional anddisplays true BOS reserve. 14.9.4
B/U OXY LOW Light
(RIO Only)
Note
I. BACKUP OXY PRESS -Check. 14.10
LAD/CANOPY OF CANOPY
If both the pilot and RIO caution lights are illuminated, indicating a canopy problem, a later problem with the boarding ladder will not activatetheLAD/CANOPY or theMASTER CAUTION lights.
LIGHTANDIOR
LOSS
In the event of canopyloss in flight, the pilot will be adequatelyshieldedby the forward windscreento maintain control of the aircraft. Vision may be impaired briefly by dust in the cockpit, and moderateheadbuffet may occur, which canbe alleviatedby lowering the seat and/or leaning forward. The RIO will be exposedto a significantly more hazardousand disorienting environment, which will include vision impairment, loss of communications,wind blast injury, andbreathingdifficulties. The degreeto which thesewill be experienced is directly relatedto airspeedandseatheight,In addition, the possibility of helmet loss becomes greateras air-
Ifthe RIO CANOPY light is not illuminated, ensurethat it is operating by selectingIND LT on the RIO TEST panelbeforeassuming a boardingladder problem. 14.10.1
LAD/CANOPY Light With RIO CANOPY Light/Canopy Loss
* 1. Canopy- Boost Close (canopyremaining). *2. EJECT CMD lever-PILOT. 3. Airspeedandaltitude-Below200Knots/ Feet. 4. Seatsandvisors -Down.
15,000
NAVAIR
5. If canopyhas departedaircraft, perform controllability check.
01-FI4AAD-I
6. L INLET RAMPS switch -AUTO. 7. DLC - Do Not Engage.
6. Land as soonas possible. 14.10.2
LAD/CANOPY Light CANOPY Light
Without
RIO
8. EMERG FLT HYD switch committed to landing).
HIGH (on final,
9. Land assoon as possible. 1. Airspeed - Minimum SafeOperating. 2. Obtain in-flight visual check if possible. 3. Land as soonas practicable. 14.11
HYDRAULIC
14.11.1
SYSTEM
Combined Pressure 2,400 to 2,600 Psi
MALFUNCTIONS Approximately
pii-
If hammering (cavitation) is experiencedin the hydraulic system, componentrupture is imminent. Turn the hydraulic transferpump switch (BIDI) OFF.
. Loss of combined pressuremay indicate impending fluid loss. Without fluid in the combinedsystemrehrn line, the in-flight refueling probe will not extend with the handpump.Early extensionof therefueling probeat the first indicationof a combined system malfunction is recommendedin a carrierenvironment. . Monitorremaininghydraulicsystempressuresince the MASTER CAUTION and HYD PRESS lights will not illuminate if the remaining systemsfail. Note
1. HYD ISOL switch - FLT. Note
Monitor AUX BRAKE PRESSURE gauge. Tap wheelbrakes to seat priority valve if pressureis decreasing. 2. In-flight refueling PROBE switch - EXTD (in carrier environment).
To extendor retracttherefueling probeusing thehydraulic handpumprequiresthe landing gear handle to be in the up position, combined system fluid in the system return line, and essentialdc No. 2 electrical power. Extension of the in-flight refueling probe requiresapproximately 25 cycles of the pump handle. 14.11.2
3. Wing sweep-
Set at 20”
4. L INLET RAMPS switch-STOW Mach).
(lessthan 1.2
5. Left AICS cb - Pull (LFl).
If WING SWEEP advisory light is illuminated,pulling L AICS cb (LFl) may cause unintentional wing sweep unless WING SWEEP DRIVENO. 1 (LDl) andWG SWP DR NO. 2/MANUV FLAP (LEl) cb’s are pulled.
Flight Pressure to 2,600 Psi
Approximately
1 WARNING
2,400
1
If hammering (cavitation) is experiencedin the hydraulic system, componentrupture is imminent. Turn the hydraulic pump switch (BIDI) OFF. 1. Wing sweep- Set at 20”, 2. R INLET RAMPS switch - STOW (lessthan 1.2 Mach). 3. Right AICS cb - Pull (LGI).
NAVAIR
Ol-Fl4AAD-1
4. R INLET RAMPS switch-AUTO. 5. EMERG FLT HYD switch committed to landing).
l
HIGH (on final,
Monitor remaining hydraulic system pressure since the MASTER CAUTION and HYD PRESS lights will not illuminate if the remaining systemsfail. The following important equipment is inoperative: a. NORMAL HOOK - Restoredby weight on wheels. Hook handle restowed. Note Arrested landing will require emergency hook extension.
l
Do not return to AUTO (LOW) mode once module is selected on (HIGH or LOW) with operatingflight hydraulic system. When operatedin conjunction with zero combined pressure, some backup module fluid will be expelledby thermal expansion.The module will remain fully servicedand operatenormally as long as elevated temperatures are maintained. Onceoperating,the module shouldnot be tmned off in flight without combinedsystem pressureavailable to reserviceit. Doing so would result in fluid contraction andan underservicedcondition that could preventsubsequentpump operation.
Loss of combined pressurewith landing flapsdown may allow the auxiliaryflaps to cycle,causingmoderatepitch oscillations.
6. Land as soonas possible. l
14.11.3
Combined
Pressure
Zero
1. HYD ISOL switch - FLT. 2. HYD TRANSFER PUMP switch - SHUTOFF.
Monitorremaininghydraulicsystempressure since the MASTER CAUTION and HYD PRESS lights will not illuminate if the remaining systemsfail.
The following important equipmentis inoperative:
3. REFUEL PROBE - EXTD (in CV environment).
a. LAICS
4. Wing sweep- Set at 20”.
b. Nosewheelsteering
5. EMERG FLT HYD switch-LOW.
c. Gun drive d. Inboardspoilers
pii-
e. Hook extend(emergencyactuationavailable) l
l
Ifthe INLET RAMPS switch is not placed in STOW prior to the pressurereaching zero, do not place it in STOW after complete loss of pressure.Trapped fluid may be the only thing holding the affected ramp in position.
f. Flapsandslats(emergencyactuationavailable) g. Landing gear(emergencyactuationavailable) h. Wheelbrakcs(emergencyactuationavailable) i. Refueling probe (emergencyactuation available if fluid remains in return line)
An outboard spoiler module failure with flaps extended,below 180knots, andwith a combined hydraulic failure rendering the inboardspoilersinoperative,canresult in asymmetric spoiler float such that the aircraft may not be flyable at normal approach airspeeds. A small amount of spoiler float cansignificantly increaseappreachspeeds.
ORIGINAL
j. Emergencygenerator k. Auxiliary flaps I. DLC
14-32
NAVAIR
Ol-F14AAD.1
m. Speedbrakes
b. RAICS
n. Normal hook.
c. Normal hook-Restored by weight on wheels. Hook handlerestowed.
6. Hook - EMERG DN. 7. EMERG FLT HYD switch committed to landing).
HIGH (on final
4. EMERG FLT HYD switch committed to landing).
HIGH (on final,
5. Land as soon aspossible. 8. LDG GEAR handle- EMERG DN. Note
9. AUX FLAP/FLAP CONTR cb - Pull (8G3). 10. Flaps (no awiliq
Arrested landing will require emergency hook extension.
flaps) - DN.
14.11.5
11. Brake accumulator(handpump)- Check.
Both Zero
Combined
and Flight
Pressure
12. ANTI SKID SPOILER BK switch -SPOILER BK (OFF for CV).
1. EMERG FLT HYD switch-LOW.
13. Make arrestedlanding as soon aspossible.
2. Do not attempt CV recovery.Divert if possible. fTjG,jJ
After landing: 14. Do not taxi out of arrestinggear. l
15. Engines- OFF. 14.11.4
Flight
Pressure
Zero
1. HYD TRANSFER PUMP switch - SHUTOFF.
l
2. Wing sweep- Set at 20’. l
3. EMERG FLT HYD switch-LOW. pik-) If the INLET RAMPS switch was not placed in STOW prior to pressurereachingzero,do not place it in stow after complete loss of pressure.Trappedfluid may betheonly thing holding the affectedramp in position.
l
If any undesirablemotions or oscillations occur, immediately releasethe stick and permit the motions to dampenbeforeresuming active control. Do not attempt IMC or closenight formation flight while in the LOW mode. Operations of more than 8 minutes in HIGH may fail the BFCM motor. The LOW mode should be selectedas soonas practicablefollowing a waveoff or bolter andthe HIGH modereselectedon thesubsequentapproach. Inboardspoilers can be expectedto float, causing uncomfortable lateral stick requirementsfor level flight. Do not trim out lateral forces.
3. Reduceairspeedbelow 250 knots if practicable. H Note Airspeedsless than 250 knots while operating in LOW mode will reducesusceptibility of exceedingmaximum stabilizer deflection rate.
Monitor remaining hydraulic system pressure since the MASTER CAUTION and HYD PRESS lights will not illuminate ifthe remaining systemsfail.
The following importantequipmentis operativein flight:
The following important equipmentis inoperative:
a. Horizontal stabs(significantly reducedrate)
a. ACLS 14-33
ORIGINAL
\\\\\\\mmmm== NAVAIR
01.Fl4AAD-1
9. Maneuverflaps-Retract.
b. Rudders(slightly reducedrate) c. Main flaps and slats (reduced rate, via thumbwheel or flap handle)
Field recovery: 10. Landing gear- EMERG DOWN.
d. Outboardspoilers 11. Maneuverflaps-Extend With Thumbwheel. e. Hydraulic handpump
12. MANEWER
f. Landing gear(emergencyactuationavailable) Es Hook extend (emergencyactuationavailable)
FLAPS cb - Pull (LEI).
13. Hook - EMERG DOWN. 14. Brake accumulator -Check.
h. Refueling probe (emergencyactuation available, if fluid remains in return line)
Establishedon final, committed to landing:
i. Wheelbrakes(emergencyactuationavailable).
15. EMERG FLT HYD switch - HIGH.
If in flight refueling rt:fueling required:
pL-1
4. Deceleratewith tanker to 180knots. 5. Maneuver flaps-Extend. 6. EMERG FLT HYD switch moving to precontact).
HIGH (prior to
Aggressivenosemovement in close canrate limit the stabilizers,resulting in low altitude loss of control. Do not use APCS.
7. Avoid abruptcontrol inputs during contact.
Any abruptcontrol input to affect engagement can rate limit the stabilizersand result in loss of control. The pilot must resist spotting the basketand rely on RIO commentary to perform the engagement. ExtendedLOW operation(greaterthan30 minutes) after in-flight reheelingwill permit several additional minutes in HIGH mode for subsequentlanding. Tanking horn largebody tankers(KC-130, KC-IO, KC-135) is hazardousand should not be attempted. Note If the air refueling storedoesnot adequately transferfuel at 180knots, once engaged,the airspeedcan besafely increasedto 200 knots to improve fuel transferrate. 8. EMERG FLT HYD switch-LOW once clear of tanker). ORIGINAL i mm’pAwmm~~~m mYlF.‘pAw
(immcdiatcly
Waveoff performancefrom low power settings is very poor. Carrying extraspeedduring IMC approach will improve waveoff performanceby permitting smooth rotation to 15 units AOA to breakthe rateof descent while the enginesareaccelerating. If wings are20”: 16. Fly straight-inapproachat 15units and I80 knots. If wings aregreaterthan 20”: 17. Fly straight-inapproachat I5 units. Note
Control in LOW mode is satisfactoryforperforming transition to dirty configuration. Pitching moment becauseof flap transition is easilycounteredwith electricaltrim caused by very slow extensionrate. 18. Make arrestedlanding as soonas possible.
NAVAIR
After landing: 19. Do not taxi out of arrestinggear.
6%FI4AAD1
Even though the aircraft may possesssignificantly differentor evenhazardousflying qualities,thepilotand RIO havenumerouscues available to them to warn of potential problems.Some of thesecuesinclude:
20. Throttles -OFF.
1. Turn needleandball position 14.11.6
Backup
Flight
Module
Malfunction 2. AOA 3. Buffet
Prolonged use of the backup flight control module in the high mode may result in a failure of the module.
4. Yaw string position 5. Flight control positions 6. Trim settings
1. FLT HYD BACKUP PH A, B, and C cb’s - In (2A1,2Cl, 2El).
7. Rolloff
2. Land as soonas possible.
8. Rateof descent.
14.11.7 Controllability Check. There are several malfunctions that may significantly affect the handling characteristicsin the cruise and landing configurations. For example,theseinclude,but arenot limited to:
1. Spoiler malfunction 2. Flap/slatasymmetry 3. Structuraldamage 4. UncommandedSAS inputs 5. Ruddermalfunction (hardover)
All cues should be very closely monitored, as they tell the pilot what the aircraft is doing or is aboutto do. Stall/departurerecovery proceduresshould be discussedprior to any controllability check. In the eventof a stall, NATOPS proceduresshouldbe appliedimmediately. Flapsshouldbe left down, if alreadythere.A rapid increasein airspeedcanbe attainedthroughjudicialuse of forward stick and military power. After a thorough controllability check, the aircrew must makethe decisionas to whetherthe aircraft canbe safely landedaboardthe carrier or shouldbe diverted.
6. Wing-sweepasymmetry 7. Jammedflight controls. It is absolutelyimperativethatthe aircrew thoroughly and safely evaluate the degraded handling characteristics of damagedor malfunctioning aircraft prior to continuedflight and landing. These guidelines do not take priority over existing emergencyprocedures.
If aircratl stalls or departsin dirty contiguration, immediately unload and place throttles at military. Do not raiseflaps until recovered. (If during flap/slat transition, follow uncommandedroll/yaw procedures.) 1. Climb to 10,000feet AGL minimum.
Upon encounteringa problemthat altersthe handling qualities of the aircraft, the aircrew should realize that the aircraft may no longer be a stable airframe, especially in thelanding configuration.In addition, the flight characteristicsmay rapidly degradeor evenbecometmcontrollablewhen normal configurationchangesareintroduced or during airspeed changes. Increased awarenessof flight parametersshouldprevail following a malfunction until the aircraft is safely on deck.
2. Obtainvisual check ifpossible. 3. Decelerategradually to 200 knots if feasible. 4. Dirty aircraft time.
One configuration changeat a
5. Slow-fly aircraft to determineapproachhandling characteristics.
NAVAIR
0%Fl4AAD-1
6. Fly simulated
approachwith lineup corrections, power changes,and waveoffbolter.
7. For landing, use minimum safe control speedbut no slower than optimum AOA.
2. Evaluateflaps-downlateral control characteristics at safealtitude. If unacceptable: 3. Make flaps-uplanding.
8. If CV landing is not possible-Divert. 14.11.9
pi-1
tention and awareness of the aircrew.
The
aircrew must be preparedto encounterunusual handling characteristicssince aerodynamic properties of the aircraft may be significantly changed.Stall speedand characteristicsmay be drastically different from normal. Outboard
Pressure
Spoiler
Module
1. HYD ISOL switch - T.O./L,DG. If pressuredoesnot recover: 2. LDG GEAR handle- DN. 3. BYD BAND PUMP-Recharge Accumulator. Note
Malfunction l
l
An outboard spoiler module failure with flaps extended,below 180knots, and with a combinedhydraulic failure renderingthe inboard spoilers inoperative, can result in asymmetric
Accumulator
In flight:
A controllability check requiresthe total at-
14.11.8
Low Brake
spoiler float such that the air-
craft may not be flyable at normal approach airspeeds.
Monitor AUX BRAKE PRESSURE gauge.Tap wheelbrakes to seat priority valve if pressureis decreasing. Approximately 13 to 14 differential pedal applications of auxiliary brakes are available.
If accumulatorcannotbe recharged: 4. Make arrestedlanding as soon aspracticable. 5. Parking brake- Pull (to lock wheels).
If outboatdspoilersfail with airspeedgreater than225knotsandwingsweepislessthan62”, limit lateralstick to one-halfpilot authority. 1. OUTBD SPOILER PUMP cb -Check
(2B3).
a. If OUT - Attempt Reset.
(,,,,,,,I
Complete lossof hydraulic fluid throughthe wheelbrakehydraulic lines will renderparking brakeineffective.
b. If IN and outboard spoiler module flag indicatesOFF -Pull. The following important equipment is inoperative: (1) OutboardSPOILERS (2) FLAP and SLAT BACKUP (3)
ACL.
Maximum airspeedfor wheelbrakeapplication is 165knots at a grossweight of46,OOO poundsand 145knots at 5 1,000pounds.
NAVAlR 0%F14AAD-1
14.12 FLIGHT CONTROL FAILURES OR MALFUNCTIONS
c. Spoiler malfunction d. Bardovermdder
f4.12.1 Uncommanded Roll and/or Yaw e. Stmctumldamage l
Note If uncommandedroll and/or yaw occurs during high AOA maneuvering(above 15 units), assumedeparturefrom controlled flight and apply appropriate departure and/or spin recovery procedures.Gtherwise, perform appropriate procedures below.
a. Engine failure
14.12.2 Yaw Channel Failure. Failure of a single yaw channeldoesnot affect yaw stabilization since the system is triply redundant.Single channelMute is indicatedwhentheYAW STAB OP light illumina@while the STAB AUG switch remains ON. A second yaw channelfailure is indicatedwhen the YAW STAB OUT light illuminates. The YAW STAB switch is not automatically positioned to OFF. CV landings with total YAW SAS failure require increasedattention to yaw oscillations in turbulence and/or adverseyaw during lineup corrections.
b. Stuck up spoilers
14.12.2.1 YAW STAB OP Light
. Failuresthat may causeuncommandedroll and/oryaw include, but are not limited to the following:
c. Asymmetric flaps and slats
1. MASTER RESET pushbutton- Depress.
d. Uncommanded differential stabilizer and/or rudder automatic flight control system inputs caused by abnormal power transients.
2. If light remains illuminated -MN.
e. Rudderhardoverfrom yaw SAS (19O)). * 1. Iftlap transition FLAP handle- previousPosition. *2. Rudderand stick - OppositeRoll/Yaw.
I
9. Slow-fly aireraft to determine controllability at 10,000feet AGL minimum.
Note For spoiler malfunctions, use lateral stick as primary lateral control and rudder only as neededto maintain balancedflight.
*3. AOA - Below 12 Units.
*4. Downwingengine-h&4XTHRUST(iimquired). 5. Roll SAS -ON. 6. Roll trim - Opposite Stick (if required). 7. Out of control below 10,000feet -EJECT. 8. Control regained climb and investigatefor:
Stay Below 1.0
14.g2.2.2 YAW STAB OUT Llght 1. YAW STAB switch-OFF. 2. MASTER RESET pushbutton-Depress. If light remains illuminated: 3. Deceleratebelow 1.0TMN, 4. YAW SAS PWR cb’s-Cycle
(LB3, LC3, LD3).
5. If light remains illuminated, remain below 1.0 TMN. If light out: 6. ResetYAW STAB switch. 14.12.3 Pitch or Roll Channel Failure. Failure of a single pitch or roll channeldamperis indicatedby that channelSTAB cautionlight The remaining channel provides50 percentof the scheduledgain and damping authority. The affected STAB AUG switch remains in ON if only one channelfails.
a. Flap andslat asymmetry b. SAS malfunction
Failure of two channelsilluminates both STAB lights ofthe affectedsystem.The affectedSTAB AUG switch
---~
NAVAIR gl-Fl4AAD-1
is automatically positioned to OFF. If the stability augmentation system self-test circuit can isolate the faulty channel,the remaining channellight will go out; however, the STAB AUG switch must be resetto the ON position. CV landings with either or both PITCH and ROLL SAS failures can be accomplishedwith some degradationin normal approachhandling qualities. 14.12.3.1 Single PITCH or ROLL STAB Light 1. MASTER RESET pushbutton-
Depress.
2. If light remains illuminated -No
Limitations.
14.12.3.2 Both PITCH or Both ROLL STAB Lights fzlJ+-J
Note Pitch SAS loss may result in lossof outboard spoilers.Roll SAS loss may result in loss of inboard spoilers. 14.12.5 Rudder Authority Failure. Schedulingof allowable rudder deflection is computed in the CADC asa function of dynamic pressure.If the command signals and position feedback do not agree,power is m moved, stopping further movement and the RUDDER AUTH light illuminates. Directional authority is never less than 9.5’ of rudder. 14.12.5.1 RUDDER AUTH Light 1. MASTER RESET pushbutton secdnds).
Depress (10
2. If light remains illuminated - Above 250 Knots, RestrictRudderInputs to LessThan 10’.
With both PITCH and ROLL lights illtinated,ground-roll braking may be inhibited. 1. Airspeed -Reduce to StabLimits. 2. Pitch-Not
Restricted.
l
With rudder authority stops failed open, excess rudder authority is available and could result in structural damage above 250 knots.
l
Atler landing,nosewheelsteeringauthority may be restrictedto 1O0(with neutraldimctional trim) and differential braking is requiredcoming out of the arrestinggear.
3. Roll - 1.6 TMN. 4. Wait 10 secondsfor self-test. 5. PITCH CMPTR AC cb or ROLL CMPTR AC cb -Cycle (LA1 or LBl). 6. Recheck lights:. a. If one STAB light off Switch, No Limits.
Reset STAB AUG
b. If both lights remain illuminated- LeaveAppropriateSTAB AUG SwitchesOFF, Stay Below Stab Limits. 14.12.4 STAB AUG Transients 1. Paddle switch - Depress. 2. Airspeed- DecelerateBelow 1.OTMN. 3. STAB AUG switches-All
OFF.
4. MASTER RESET pushbutton- Depress. 5. STAB AUG switches - RESET (resetindividually to isolate failure).
14.12.5.2 Runaway Stabilizer Trim. A runaway trim failure is sensedby the pilot by both uncommanded stick motion and by changesin aircraft pitch and load factor. This failure state causesthe horizontal tail to move alongthe normal stick-to-tail gearingcurvefor the hands-offcondition. Aiicrat? responseto a runawaystabilizer trim, even in the high-speedconfiguration, is slow enough(about 1” per secondstabilizer change)to be recoveredf?om safely. The most critical steady-statetrim conditions are those for which the greateststick force is required.A field or carrierlandiig with either a Rollnoseupor nosedown runaway stabilizer trim requiresan averagestick force of 14 to 19 pounds to maintain longitudinal control. If pilot fatigue becomes a factor with full noseup trim, stick forcesmay be significantly reducedby placing the wings aft of 21” and lowering the FLAP handle causingthemain flaps to extendwhile theauxiliary flaps remain retracted.This overrides the wing sweep 21’ interlock and the FLAP light will be illuminated. This
NAVAR 01.F14AAD-1
contiguration is not recommendedfor landing. At approach speed,the worst nosedown trim condition requiresa maximum stick pull of 27 poundswithout DLC engagedand approximately 24 pounds with DLC engaged.A tit11noseuprunawaytrim requiresa maximum of 17 pounds of stick push without DLC engagedand 23 poundswith DLC engaged. Note With abnormalstabilizer trim response,continuing to trim may precludeability to retrim to a neutralposition. 1. SPD BK/P-ROLL TRIM ENABLE cb -
Pull
Wm.
2. Decelerateto below 300 knots. 3. Use AFCS, if available, in cruiseconfiguration to reducepilot workload. 4. Minimum stick forcesare achievedunderthe following conditions: a. Runaway nosedown- flaps up. b. Runawaynoseup- flaps down. 5. Straight-in approach. Note Forcerequired(pushor pull) may be asmuch as 30 pounds. 14.12.6 Horizontal Tail Authority Failure. Lateral stick inputsare limited by control authority stopsscheduled by the CADC as a function of dynamic pressure. Failure of the lateral stick stopsis indicatedby the IU TALL AUTH cautionlight. Failure of the stopsin the fully closedpositiondoeslit low-speedrolling performanoe, but ampleroll controlis availablefor all landingconditions and configurations.Failure in the open condition, witb SAS on,requitesthepilottomanuallylimitstickdefleetion to preventexceedingfuselagetorsionalload limits. 14.12.6.1 HZ TAIL AUTH Light 1. MASTER RESET pushbutton seconds).
Depress (10
If light remains illuminated: 2. ROLL STAB AUG switch-OFF. 3. Restrict lateralcontrol inputsabove400 knots/O.9 Mach to one-quarterthrow. 14-39
4. ROLL STAB AUG switch - ON for Landing. Note At low airspeeds,lateral control effective nessmay be reduced. 5. Do not selectOV SW after landing. 14.12.7 Spoiler Malfunction. The inboard and outboardspoilersare poweredand controlled by separate hydraulic and electrical command systemsand are protectedby separatespoiler failure detectioncircuits. The pitch computerandoutboardspoilermodule control the outboard spoilers, and the roll computer and the combinedhydraulic systemcontrol theinboardspoilers. It is highly unlikely that both spoilerpairs on one wing would fail up/float, but if this situation occurred,controllability would be marginal to impossible. The severity of a spoiler failure is influenced by spoiler position and deflection, aircrafi contiguration, and flight conditions. The rolling moment generated from a deflectedspoiler variesfrom the inboardto most outboardspoiler. The moment generatedby the No. 4 spoiler is approximatelytwice asgreatasthat ofthe No. 1 spoiler. Sweepingthe wings aft reducesthe effect of a deflectedspoilerby decreasingthe moment arm of the spoiler and its aerodynamic effectiveness.A fully deployed No. 4 spoiler at 200 knots and20,000feet in the cruise contiguration generates25Oper secondroll rate with the wings at 22’, and a 4” per secondroll rate with the wings at 62”. In the cruise contiguration, the increasein rolling moment is essentiallylinear with increasingspoilerdeflection angle,whereasin the landing con@uration,the increasein rolling moment is nonlinearwith increasing spoiler deflection angle (approximately 50 percent of total rolling moment is generatedin the fmt loo of spoilerdeflection).Flap position hasa verypronounced effect on rolling moment. With the flaps down in the high-lift (landing) contigumtion, a deflectedspoiler reduces litI considerably more than with the flaps up. Consequently,a failed-up spoiler causesa significantly higher rolling moment with the flaps down than with flaps up. Selecting flaps up with a failed-up spoiler greatly reducesthe amount of lateral stick required to maintain a wings-level attitude. The same lateral stick position of 6“ differential stabilizer will balance55Oof No. 4 spoiler deflection with flaps up, and only go of No. 4 spoiler deflection with flaps down. The use of lateraltrim to reducestick forcesmay result in a reduction of availableopposite-wingspoiler deflection.Trimming in the direction of stick forces (normal pilot reaction)reduceseffective spoiler authority from 55Oto approximately25“ at full lateral trim. ORIGINAL
r
NAVAIR 0%F14AAD.1
\L The control capability remaining with a failed-up ipoileris influencedby wing-sweepangle,flap position, ~011 SAS operation,AOA, airspeed,sideslip, and availibility of the remaining spoiler set. Spoilersareconsidxably more effective with Saps down than with flaps up.Any single fully deflected, failed-up spoiler is consollable evenwith the flaps down and the roll SAS off if the remaining spoiler set is operating,airspeedis below 180 KCAS, and sideslip is minimized. With flaps down and at slightly negative true AOA (less than 5 units),dihedral effect reverses(i.e., right ruddercauses a lefl roll); therefore, combinations of bight sidelsip angle and high airspeed/low AOA (above 180 KCAS and/or below 5 units AOA) should be avoided in the flaps-downconfiguration.Ifuncommanded roll is experienced in the landing pattern, comply with uncommanded roll and/or yaw emergency procedure (coordinatedstick and rudder inputs) to arrestroll and yaw rates.Onceconfirming a stuck-upspoiler, the pilot should control the aircraft using primarily lateral stick, applying only small rudder inputs to maintain balanced flight, andremain at or below 180KCAS in preparation for raising the flaps (if practicable) to reduce lateral control requirements.
In the eventof a subsequentfailed-up spoiler on the samewing, the aircraft may be uncontrollable in the flaps-down configuration. 14.12.7.1 Spoiler Malfunction/Spoiler
A stuck-up failure of a secondspoiler panel on the same wing will further increaselateral control requirements and may necessitatecoordinating rudder inputs and sideslip angleto maintain control. The pilot should use as much lateral stick as possible to minimize the required sideslip angle and avoid high airspeed/low AOA if the flaps aredown. Raise flaps assoon aspracticable to improve lateral controllability. With the SPOILER FLR ORIDE switches in the ORIDE position, all spoilers on the “good” wing are available to counter rolling moment induced by the failed, stuck-up spoiler(s).Ample lateral control exists in this configuration to opposefailed spoiler moments regardlessof flap position. Note that with the SPOILER FLR ORIDE switches in the ORIDE position, the SPOILERS light will not illuminate in the event of a spoiler failure. Detecting a failed-up spoiler following uncommandedroll is letI up to the aircrew.Oncea stuck spoiler is confmed, counterroll primarily with lateral stick and avoid excessiverudder inputs and/or sideslip. It is preferableto divert (to shore)an aircraft that is experiencingcontrol problemsbecauseof a spoilermalfunction. If the decision is made to land aboard the carrier, a straight-in, no-flap approachshouldbe flown. If conditions do not permit a no-flap CV landing, the aircrew should slow-fly the aircraft at a safealtitude to determinethe flaps-down controllability and minimum controllable airspeed.
14-40
Stuck Up
Note . Spoilers caution light will not illuminate with SPOILER FLR ORIDE switchesin the ORIDE position. l
Use lateral stick as primary control and rudder only as neededto maintain balancedflight.
1. Perform checks at a safe altitude in flaps-up con@guration. 2. Affected SPOILER FLR ORIDE switch NORM (guarddown). 3. Counterroll with at lease 1 inch of lateral stick. Note Stick deflection of over 1 inch enables spoilerasymmetry logic andelectrically fails all affectedspoilersdown. Spoilerslight will illuminate. 4. If spoiler(s) fail down, failed SPOILER CONTF cb -Pull (8G9 INBD, 9C5 OUTF3D) (go to stel 13). 5. If spoiler(s) remain up or floating, affecter SPOILER FLR ORIDE switch - ORIDE. 6. MASTER RESET - Depress. 7. Failed SPOILER CONTR cb -Pull 9C5 OUTBD).
(8G9 INBD
8. If spoiler(s)fail down, go to step 13. Note a Outboard spoiler position indicators will indicate down with cb 8C5 pulled. a With circuitbreakers 8G9and9C5pulled, ground-roll braking is inhibited.
NAVAIR 01-Fl4AAD-1
Note Allow up to 60 secondsfor spoilersto return to trail. 9. If spoiler(s)remain up, malfunction was mechanical. Failed SPOILER CONTR cb - Reset(8G9 INBD, 9C5 OUTBD). 10. Slow-fly aircraft in the flaps-up configuration to determineminimum control speed. 11. Verify full remaining spoilerauthority is available by trimming laterally oppositeof stick deflection. 12. Fly straight-in,flaps-upapproachaboveminimum control speed. ;f spoiler(s)fail down: 13. Slow-fly aircraft at a safe altitude in Saps-down configuration to determine minimum control speed. 14. If controllability is satisfactory,perform full-flap, straight-in landing. If controllability characteristics are not satisfactory,perform a no-flap or maneuvering-flapstraight-inlanding. 14.12.6 FLAP Light 14.12.6.1 Not After Landing/Takeoff Transition
14.12.6.3 FLAP Handle Up and Flaps Not Fully Retracted 1. FLAP handle- EMER UP. If FLAP handleor flaps will not respondor FLAP light remains illuminated, refer to Flap and Slat Asymmetry procedures,paragmph 14.12.9. 14.12.6.4 FLAP Handle Up and Flaps Indicating Full Up 1. Flaps - Cycle. If FLAP handleor flaps will not respondor FLAP light remains illuminated, refer to Flap and Slat Asymmetry procedures,paragraph14.12.9. 14.12.6.5 FLAP Handle Down and Flaps Not Fully Extended 1. Wing sweep- Ensureat 20”. Flaps will not respondor FLAP light remainsilluminated,refer to Flap andSlat Asymmetry pro !dures,paragraph14.12.9. 14.12.6.6 FLAP Handle Down and Flaps Down 1. Wing sweep-Ensure at 20”.
Flap
1. Airspeed - Below 225 Knots. 2. FLAP handle-Ensure Full Up. 3. MASTER RESET pushbutton-Depress. 4. While holding MASTER RESET pushbutton depressed,maneuver flap thumbwheel - Full Forward. 5. Check FLAP light out (light can take up to 10 secondsto reilluminate). 14.12.9.2 After Landing/Takeoff Flap Transition, or Reillumination After Above Procedures 1. MASTER RESET pushbutton-Depress. 2. If light still illuminated, check FLAP handle and indicator position, then proceedwith appropriate stepsbelow.
2. MASTER RESET pushbutton-Depress (allow 10 secondsfor auxiliary flaps to extend). Note If FLAP handle or flaps will not respondor FLAP light remainsilluminated, referto Flap and Slat Asymmetry procedures,paragraph 14.12.9. 14.12.9 Flap and Slat Asymmetry. Flap and slat asymmetrycan occur with failure of an asymmetrysensor and subsequentfailure of the flap and slat drive mechanismforonewing. The pilot’s only indicationwill be an uncommandedroll followed by a FLAP light approximately 10secondslater.The flap indicatordoesnot indicate actual flap position, but the position to which the flap and slat control box has beendriven. The slat indicator showsup, down, or transition(barberpole) for the starboardslat only. The port slatposition is not monitored.Asymmetric flaps causeanimmcdiate roll. Asymmetric slats may not be apparentuntil just beforewing stall. Asymmetric slats can causerapid rolloff above 15 units AOA. Slat position muat be monitored by the RIO during transition.
NAVAIR gl-i=l4AAD-1
6. Cliib above 10,000feet AGL. 7. AUX FLAP/FLAP CONTR cb -Pull The we of lateral trim to reducestick force will reducespoiler control significantly. An uncontrollable situation can develop if lateral trim is out of neutralbefore flap andslat asymmetry or ifthe pilot trims laterally in the neutral direction (opposite the roll) during flap and slat transition.This situationwill be aggravatedandrecoverymay not bepossible with roll SAS off becauseof reduceddifferential tail authority.OnceasymmetryOCCUTS, do not trim out stick forces.If lateral control is marginal, trim opposite to the natural direction until 111 spoiler deflection is avaiiable.For example,stick to theright, trim let?. If a roll is encountered during flap and slat transition or if RIO notes asymmetric slat extension or retraction: Note Uncommanded roll/yaw procedures take precedenceif appropriate. Otherwise perform the proceduresbelow. 1. FLAP/SLAT CONTR SHUT-OFF cb - CheckIn
wx
Lack of asymmetry protection (RA2 circuit breakerout) may causeuncommandedroil and/oryaw during flap or landing gearhandle movement. Handle With Flaps Position.
3. Obtain visual check if possible to ascertainposition of ail flap and slat surfaces.
I
(,,,,,,,I Failure to complete step 6 before the subsequent steps can result in large uncommanded pitch trim changes because of auxiliary flap movement. 8. FLAP/SLAT CONTR SHU’T-OFPcb-Pull @X2). 9. Slowly move FLAP handlein dim&ion to minhnii asymmetryand/orlateralcontrolrequirements. 10. Stop flap and slat travel before reachingfull up or down. 11. FLAP/SLAT CONTR SHUT-OFF cb -
wb
Reset
(,,,,,,,I
Asymmetric slats may not be apparentuntil just before wing stall. Asymmetric slats can causerapid rolloff above 15 units AOA. 12. If asymmetry has been corrected,land using 15 units AOA.
I,,,,,,,(
2. FLAPS -Match
(8G3).
4. Slow-fly aircrafi in approachconfiguration at or above 10,000 feet AGL to determine approach characteristics,conditions permitting. 5. Land as soon as practicable if aircraft is controllable and minimum approachairspeedis within shipboardarrestinggear limits. Ifasyrnmeny is so largeasto make landingimpossibleor minimum safeapproachspeedis aboveshipboardarresting gearlimits with no possibledivert field available:
13. If asymmetry has not been corrected, flaps and slatsdid not respondto aboveprocedure,or lateral control problems exist, land using maximum safe AOA if landing is elected. 14.12.10 WiNG SWEEP Advisory Light and W/S Caution Legend 14.12.10.1 Advisory Light Only - No Loss of Normal Control 1. MASTER RESET pushbutton-Depress. 14.12.102 WING SWEEP Light and W/S Caution Legend - No Automatic or Manual Control 1. Airspeed - Decelerateto 0.9 Mach or Less. 2. Check spider detentengaged.
NAVAIR Of-F14AAD-1
3. MASTERRESETpushbutton-Depress(wait secondsto determinesystem status).
15
6. Land as soon aspracticable.
If WING SWEEP light and W/S caution legendilluminateagain:
l
4. WING SWEEP DRIVE NO. 1 and WG SWP DR NO. 2/ MANUV FLAP cb -Pull (LDl, LEl). 5. Emergency WING SWEEP handle with below schedule:
Comply
l
Note After a wing-sweep malfunction, the WING SWEEP advisory light and the W/S legend may take I5 seconds to illuminate/display. FLAP light will be illuminated with cb LEl pulled.
14.12.12 CADC Light
a. < 0.4 Mach - 20°. b. < 0.7 Mach - 25”.
1. MASTER RESET pushbutton- Depress.
c. < 0.8 Mach -50”.
2. CADC cb’s (LA2, LB2, LC2, LD2) -Cycle.
d. < 0.9 Mach - 60”.
3. MASTER RESET pushbutton- Depress. If light still remainsilluminated:
e. > 0.9 Mach - 6S”.
4. Remain below 1.5 Mach. One or mom of the following systemsmay be affected by CADC malfunction that illuminates only the CADC light.
Avoid ACM and aerobatics. 14.12.11 Unscheduled Wing Sweep
a. Maxiium safeMach
1. EmergencyWING SWEEP handle - Raise and Hold.
b. Autopilot c. Idle lockup function of AFTC d. Wing-sweepindicator e. Cockpit cooling less than Mach 0.25
Unscheduled wing sweep at supersonic speedmay causestructuraldamage.
f. HUD Display.
2. Airspeed - Decelerateto 0.6 TMN or Less in Ig NonmaneuveringFlight. l
3. Emergency WING SWEEP handle Forward.
Full
If wings do not move till forward: 4. EMERGENCY WING SWEEP handle-Match With Actual Wing Position. 5. WING SWEEP DRIVE NO. 1 andWG SWP DR NO. 2MANUV FLAP cb - Pull (LDl, LEl) (refer to aft wing-sweeplanding).
Note ErroneousMach inputs to the AFTC may causeuncommandedaccelerationof both enginesto near-military valuesin the PRI enginemode.
a If illumination of the CADC light is accompanied by other caution or advisory light(s), refer to the appropriate procedurethat will dictate the most restrictive limitation.
14.12.13 AUTOPILOT Light 1. MASTER RESET pushbutton-Depress. Do not move both throttles to IDLE unless ANTI SKID SPOILER BK switch is set to OFF if weight on-off wheels switch is suspectedbecauseof loss of lift causedby spoilers deploying.
If light remains illuminated: 2. PITCH and ROLL COMPTR AC cb’s - Cycle (LBl, LAl). 14.12.14 Weight On-Off Wheels Switch Malfunction. Formostsystems,f&lureofboththelefland right WOW switchesis requiredto causethe systemsto revert to the on-deckmode. Should such failures occur, the following anomaliescan result:
2. ANTISKID SPOILER BK switch - OFF. 3. Land as soon aspracticable.
1. Approach indexersare inoperative. If we&t on-offwheels switch failure is suspected, cocked up, high sink rate landing with throttles at idle can result in damageto the afterburner.
2. AFT will not engage. 3. Outboardspoiler module is inoperative(flaps up). 4. Nozzles may go fit11open(with LDG GEAR handle down, throttles IDLE)
14.12.14.2 RIO 1. MLG SAFETY RLY NO. 1 andNO. 2 cb -Pull (7F5,7F4).
5. Ground-roll spoiler braking (throttleaIDLE). 6. Radarwill not scan.
Note Circuitbreakerscanbcresetaftertouchdown to enableground-roll braking, antiskid, nozzles openat idle, andnosewheelsteering.
7. Autopilot cannOtbe engaged. 8. BOL chaff will not dispense. 9. At high altitude, ground cooling fans may overspeedand shutdown, causing smokein cockpit. 10. RATS will be enabledairbornewith the hook handle down or the hook out of the stowedposition. piGiWith RATS enabled airborne, military power provides 20 to 25 percent less thrust than normal, resulting in less than optimum waveoff and bolter performance. lftwo or more of the aboveanomaliesare detected,the Followingaction should be taken. 14.12.14.1 Pilot 1. Throttles - Any Position Except IDLE.
ORIGINAL
14.13 DEPARTURE/SPIN Successful recovery from out-of-control flight requires correct situation analysis,timely and correct ap plication of procedures, crew coordination, and recognition of recovery. Departure from controlled flight shouldberecognizedandtheappropriaterecovery proceduresinitiated aa soon as the aircraft begins uncommandedmotion. Throttles should be immediately placed to IDLE to ensuremaximum stall margin and prevent asymmetric thmst from delaying recovery. If recovery is not immediately apparent,instrument cues must be cross-checked.Full departures/spinsare indicatedby peggedAOA (30 units for upright, 0 units for inwrted), low airspeed(less than 150 knots), and sustained yaw rate as indicated by the tum needle and/or spin arrow. The spin arrow is the best indicator of yaw direction if it is available. If the above indications are not present,neutralixethe controlsand fly the aircraft as airspeedincreases.Recoverycontrols shouldbeapplied
14-44
and maintained until recovery is indicated minimum altitudereached,or anincreasein eyeball-outgthreatens aircrew incapacitation.The most positive indication of recovery is a break in AOA as yaw rate is reduced, followed by an incresse in airspeedand g load in the direction commanded by longitudinal stick. To minimize altitudelossfor recovery,pull out at 17units AOA. Crew coordinationis essential.The RIO must be able to analyzethe situation andprovide timely andaccurate information and proceduralbackup to the pilot without excesscommunication. The RJO should use airspeed, altitude remaining, and the spin srrow as cues.Lateral stick applicationcanbe confirmed by observingspoilers deflectedup on the wing pointed to by the spin arrow. Ejection in an out-of-contml flight situation canbestbe accomplishedby the RIO after consultation with the pilot. A thorough understandingof Chapter 11, Flight Characteristics,is requiredof the aircrew when dealing with thesehigh task emergencies. 14.13.1 Vertical Recovery 1. Above 100 knots, use longitudinal stick to pitch the nosedown. At extremenose-highattitudes,aft stick facilitates recoverytime and will avoid prolongedengineoperationwith zero oil pressure.
$3. Rudder- OppositeTurn Needle/Yaw. If no recovery: *4. Stick-Into
If yaw rate is steady/increasing,spin arrow is flashing, or eyeball-outg is sensed: I *5. Roll SAS - ON Stick - Full Into Tum Needle andAft. If recoveryis indicated: *6. Controls-Neutralize. *7. Recoverat 17 units AOA, thrust as required. If flat spin verified by flat attitude, increasingyaw rate, increasingeyeball-outg, and lack ofpitch androll rates: *8. Canopy-Jettison. ‘9. EJECT -RIO
2. Below 100 knots, release controls and wait for aircraft to pitch nose down. This preventsdepletion ofhydraulic pressurein the eventboth engines arelost andprovides quickestrecovery.
l
4. Use longitudinal control asnecessaryto keepnose down and accelerating. 5. Above 100knots, pull out,using 17units AOA. 6. Recovery to level flight from point of pitchover cannormally be completedin lessthan 10,000feet.
l
14.13.2 Upright Departure/Flat Spin
‘2. Throttles -Both
IDLE.
Command Eject.
Ejection guidelinesarenot meant to prohibit earliercanopyjettison and/orejection. If insufficient altitude exists to recover from departed flight, the flightcrew should not hesitateto eject.
3. If roll and/oryaw develop,wait until aircraft is in a nosedownattitude and acceleratingbefore correcting with rudderor lateral stick
* 1. Stick - Forward/Nemral Lateral Harness- Lock
Tmn Needle.
Note At high yaw rates where eyeball-outg is sensed,atl stick and full lateral stick into the tmn needlemay arrestthe yaw rateand increase the possibility of recovery. At theseyaw rates,the additional differential tail provided by roll SAS on will also incressethe possibility of recovery. It may be necessaryto center stick laterally momentarily to engageroll SAS.
1413.3 inverted Departure/Spin l
1. Stick - Full AFT/Neutral Lateral Harness-Lock.
I
*2. ‘hottles -Both
IDLE.
piEjEJ
*3. Rudder- OppositeTurn NeedWYaw. If recovery is indicated: *4. Controls -Neutralize. 5 Recoverat 17 units AOA, thrust as required. If spinning below 10,000feet AGL: l 6. EJECT -
RIO Command Eject.
Dual compressorstalls may be expectedin an inverted spin. Note If pedal adjustment antior pilot positioning (becauseofnegativeg forces)is suchthat fall rudder pedal travel cannotbe obtained, 111 lateral control opposite the tom needle/yaw may provide an alternaterecovery method. AA longitudinal stick should be relaxed enoughto allow full lateralstick auulication.
NAVAIR Ol-Fl4AAD-1
CHAPTER
Landing
15
Emergencies
15.1 DUAL-ENGINE LANDING, ONE OR BOTH ENGINES IN SECONDARY MODE With either one enginein secondarymode (theother enginein primary) or both enginesin secondarymode, a straight-in approachshould be conducted with slats and flaps fully extended,15 units AOA, DLC engaged, and speedbmkesextended.Approachescan be accomplished safely up to the normal gross weight limits of theaircraft. Throttle position in secondarymode will be 5” to 10” higher than in primary mode for the same amountof thrust.Thrust responsein secondarymode is nonlinearand very sluggish. Engine accelerationtime can be as much as three times longer than in primary mode. Secondarymode MIL power thrust levels can vary from as little as 65 percent to as much as 116 percentof primary mode MIL thrust.
For shipboard landing, the LSO and tower must be informed ifthe landing is to be made with both enginesin secondarymode to ensurewind-overdeckrequirements aremet as RATS is not operativein secondarymode. During flight tests with one engine in secondary mode, optimum resultswere obtainedby matching the enginerpm’s prior to commencing final approachand maintaining the throttle split when making power corrections.Use of DLC to make small glideslopechanges will improve lineup control by reducingthrottle activity and and the associatedyaw excursions.Waveoff and bolter performanceis essentially the same as in dualengineprimary mode except for a slight yaw into the secondarymode engine. With both enginesin secondarymode, expect very sluggishpowerresponseand throttle positions 5” to IO“ more forward than in primary mode. Extreme care shouldbe taken to avoid an underpoweredcondition as
this will significantly degradewaveoff performance. The LSO should move the waveoff window such that only minor glideslope/lineup corrections are required from in the middle position. [WARNING) Waveoff performancewith both enginesin SEC mode may be severely degraded.Extreme careshouldbe usedto avoid an underpowered,high-rate-of-descentsituation. 15.2 SINGLE-ENGINE LANDING PRIMARY MODE Perform a straight-in approachwith flaps and slats extended and speedbrakesretracted (to reduce thrust required). External tanks have a negligible effect on thrustrequiredandneedto be droppedonly ifnecessary for grossweight considerations.If operatingon the left engine,DLC is availableandis recommended.DLC can be usedto aid in the control of glideslope,therebyminimizing requiredpower changesandthe resultantlateral/ directional deviations. The 8-knot increasein airspeed with DLC engagedresultsin more control authorityand improved waveoff andbolter performance.Flight in the power approachconfiguration is critical. Turns should be made away from the failed engineusingbank angles that do not exceed20”. Remain below 12 units AOA until established on final approach. Final approach shouldbeconductedat 15unitsAOA with DLC engaged/ 14 units with DLC stowed (DLC is not availablewhen combined hydraulic system is pressurizedby the BIDI pump). Small rudderinputs shouldbe madein conjunction with power changesto reducethe amount of yaw. Waveoff and bolter (with RATS) may be accomplished up to normal grossweight limits of the aircraft. Test resultshaveshown that MIL powerprovides satisfactorywaveoffperforance. Minimum AB (ATLS on) reducesaltitude loss when waveoff occurs from a high rate of descent.The use of maximum AB is prohibited.
NAVAIR
0%Fl4AAD-1
No significant differencein altitude lossduring waveoff was noted between minimum AB and maximum AB. The aircraft is extremelydifficult to control in maximum AB and largebank anglesinto the operatingengineare requiredto maintain centerline.Late or inadequatecontrol inputs during a maximum AB waveoff canresult in largelateral flightpath deviations.Waveoff techniqueis to select MIL or minimum AB (ATLS on), maintain approachAOA until a positive rate of climb is established, then accelerateand climb out at the airspeed indicatedin the Climb PerformanceAAer Takeoff (Single Engine) Chartsin NAVAIR 0 1-F 14AAP- 1.1.
Use of maximum AB during waveoff or bolter is prohibited. If unableto control yaw rate (possible ATLS failure), immediately reducepower to MIL. During single-engine operations at fuel states above 4,000 pounds,a fuel split will develop betweenthe aft/ let?and forward/right sides. When either cell No. 2 or cell No. 5 thermistor is uncovered (at approximately 2,000 poundson either tape),or when FWD or AFT is selectedon the FEED switch, the motive flow isolation and sump tank interconnectvalves open, making wing and fuselagefuel onboth sidesavailableto the operating engine.However, if the sump tank interconnectvalve fails to open,fuel will migrate to the wing and fuselage tanks on the inoperative engine side and will not be available to the operating engine. Under these conditions, themaximummigrationratecouldreach300ppm. If the FUEL SHUT-OFF handle on the inoperativeengine is not pulled, an additional migration path could exist throughthe enginecrossfeedvalve. During singleengine operation,the following procedureswill minimize meI migration if the sump tank interconnectvalve fails to open.
Note Altitude loss during a single-enginewaveoff is minimized by maintaining approachAOA until a positive rate of climb is established. Avoid overrotating in close as this will increasethechanceof anin-flight engagement. Minimum AB (ATLS on) will improve waveoff performance (minimize altitude loss) from high sink rates. The bolter maneuveris affectedby selectingMIL or minimum AB (ATLS on) and slight aft control stick until the desiredflyaway attitude is established.During a bolter following a DLC stowed approach,nose rotation will be more sluggish than normal (becauseof the slower approachspeed)requiring a slightly more aggressiveaft control stick input.
1. FUEL SHUT OFF handle(inoperativeengine) Pull. If not on final approach: The use of excessivebackstick on a bolter may causethe tail surfaceto stall, delaying aircraft rotation and causing the aircraft to settle off the angle deck.
2. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2.
As power is advancedduring a waveoff or bolter, simultaneouslyapply rudder(approximatelytwo-thirds to three-fourthsof full deflection) to counterthe asymmetric thrust and prevent lateral drift, Rudder may be supplementedwith small lateral stick inputs.If yaw rate develops into the dead engine, immediately apply full opposite rudder to arrest the yaw rate and then reduce the rudder as required to track centerline.If unable to control yaw rate during AB waveoff (possible ATLS failure), immediately reducepower to MIL.
ORIGINAL
If after commencing final approach or in landing pattern:
15-2
2. ATLS -
CheckON.
IfATLS is inoperative,the useofafterbumer is prohibited.
NAVAIR
01-Fl4AAD-1
Note
Altitude lossduring waveoff is minimized by maintaining approach AOA until positive rateof climb is established.Avoid overrotating in close as this will increasethe chance of an in-flight engagement.Minimum AB will improve waveoff performance (minimize altitude loss) from high sink rates. Maximum AB provides little or no improvement over minimum AB and is prohibited.
If combined hydraulic pressureis zero, do not returnto AUTO (LOW) mode oncemodule is selectedon. If module is shut off after operationcommences,it may not restart. 14. For landing patternuse 12 units AOA for pattern airspeedand do not attempt turns greaterthan 20’ angleof bank. Avoid turns into the deadengine.
3. Afterburner operation(airspeed> 170 knots, fuel permitting, and full rudder authority) (RUDDER AUTH light out) - Stageto Verify Proper Operationof ATLS. 4. Wing sweep -
If hammering (cavitation) is experiencedin the hydraulic system, component rupture is imminent. Turn the HYD TRANSFER PUMP switch (BIDI) off. 5. Hook -
Extreme caution must be exercised when performing turn into deadengine.Decaying airspeed/increasingAOA can rapidly result in a situation wherethere is not enoughrudder authority to return the aircraft to level flight, and insufficient altitude to affect a recovery.
Set at 20” (EMER).
15. Final approachairspeed: DLC engaged- 15Units AOA. DLC stowed - 14 Units AOA.
As Required.
pii-1
6. Reducegrossweight/minimize lateral asymmetry into the inoperativeengineas required. 7. Speedbrakes-
Military power climb performance during heavy waveoffs may not adequatelyarrest high-sink-rate conditions. Use of AB provides an increasein climb performance.Up to full ruddermay be requiredto counterAI3 asymmetric thrust yawing moment during waveoff or bolter. Do not exceed 14 units AOA during waveoff or bolter.
RET (on final approach).
8. LDG GEAR handle - DN (ifcombined hydraulic pressurezero - EMERG DN). 9. Check SAS -
I
ON.
10. If combined pressure is zero FLAP/FLAP CONT Cb (8G3). 11. Flaps -
Pull AUX
DN.
12. DLC (if operating on right engine) Engage.
Do Not
If operatingon the left engine and 3,000 psi combined pressure- Engageon Final. 13. EMERG FLT HYD switch committed to landing).
HIGH (on final,
15.3
SINGLE-ENGINE LANDING SECONDARY MODE
Approachesin single-enginesecondary(SEC) mode are consideredextremely hazardous.Engine military (MIL) power thrust levels can vary from as little as 65 percentto asmuch as 116percentofprimary modeMIL thmst. Although the majority ofenginesproducegreater than90 percentof primary mode thrust (at MIL power), the possibility exists that in the full-flap contiguration, a low-thrust enginewill not provide enoughthrust for level flight. Engine accelerationtimes also vary andcan be as much asthreetimes longer than in primary mode. Aircraft in this configuration should recover shore based.Shipboardlandings shouldbe attemptedonly as
a last resort and only if performance is adequate.For example, 72 percent of primary mode MIL thrust is consideredthe minimum required for a safe CV approachwith a 48,000-poundaircraft with no stores. To accomplish the performancecheck,configure the aircraft at 2,000 feet AGL or greaterand 10units AOA with the maneuvering flaps down (if available) and leavethe landing gearup. With the engineat MIL thrust, establish a constant airspeedclimb (i5 knots) at the airspeedcorrespondingto 10units AOA. The minimum changein altitude required in 30 secondsis as follows:
powerresponseresultinginanunderpoweredcondition. Waveoffcapability is dependenton enginethrust/thmst response,aimtaft rate of descent,and power setting at waveoff initiation. Waveoffs should be conductedby rotating toward 14 units (maximum) AOA until a positive rateofclimb is attained,then slowly reducingAOA to 10 units AOA to achieve maximum rate of climb. Bolters should be conductedby rotating to 10” pitch attitudenot to exceed 14 units AOA. Avoid increasing AOA, as performancewill degradeand wing drop will occur at 16.5to 17.5 units AOA. pi&-,,,,,,,
CHANGE
IN ALTITUDE
-
FEET
MANEUVER FLAPS DN
MANEUVER FLAPS UP
2,000 feet
950 feet
900 feet
4,000 feet
800 feet
750 feet
8,000 feet
700 feet
650 feet
Waveoff performance from high rates of descent in SEC mode may be severely degraded.Extreme care should be used to avoid anunderpowered,high rate-of-descent situation. Shipboardlandings in single-engineSEC mode are not recommendedand should be attempted as a last resort (divert not available) and if the performance check is successful.Jettison all external storesand reduce fuel weight asmuch aspracticableto reducegross weight and drag. Configure ihe aircraft for landing no lower than 2,000 feet AGL. Approachesshouldbe conducted with the flaps and slats fully extended,speedbrakeretracted,and DLC stowed.
Note Climb performancewill improve by 20 feet in a 30-secondclimb for every l,OOO-pound grossweight reduction. If the test is passedbasedon predictedgrossweight, do not lower the landing gear and flaps until the predicted gross weight is reached.If the performancetest is passedand divert is not possible,a CV approachmay be attempted.The minimum performanceis requiredfor optimum conditions (day, VMC, steady deck, experienced aircrew, normal wind over deck, etc.). For degradedconditions, theminimum performanceshouldbe increasedbasedonjudgment, If the minimum perfomrante test is not passed,and all other options are exhausted (stores jettisoned, gross weight minimized, divert not possible),eject under controlled conditions. For shore-basedlandings, conduct a straight-in approachwith flaps up and speedbrakesretracted.If conditions warrant a full-flap landing, conduct a performancetest and proceedas in the caseof a shipboardlanding. Grossweight shouldbe reducedasmuch as practicableto improve flyaway performance.Maintain 10 units AOA in the pattern slowing to 15 units AOA at touchdownwhen a safe landing is assured.Use extreme caution when working off a high and/or fast situation, avoiding any large power reductions. The natural tendencywill be to underestimatethe sluggish ORIGINAL
’ 15-4
Conduct a straight-in approach.Any turns shouldbe madeaway from the deadengineusing bank anglesthat do not exceed20”. Maintain 10units AOA until established on final, at which time the aircraft should be slowed to 13 units (maximum) AOA. Extreme care should be used when working off a high and/or fast condition, as any large power reductionscould result in an underpoweredsituation.A high and/orfast condition should be correctedusing only small power reductions. Upon detection of a decelerationor settle, immediate selectionof MIL power may be requiredto correct the situationin’s timely manner.To minimize the chanceof a hook-skip bolter, it is important to maintain aA stick pressureon touchdown.Waveoffs shouldbe conducted by rotating the aircraft to 14 units (maximum) AOA until a positive rate of climb is attained, then slowly reducingAOA to I I to 12 units to achievea maximum rate of climb. Bolters should be conductedby rotating to IO0pitch attitude not to exceed14 units AOA. 153.1 Single-Engine
Landing -
SEC Mode
1. FUEL SHUTOFF handle (inoperative engine) - Pull.
NAVAIR
2. In CV environment -
Divert.
3. Refer to Single-Engine Cruise Operations,paragraph 14.5.3.2,and EngineTransferto SEC Mode procedures,paragraph14.5.6. If not preparingfor CV approach:
01.F14AAD-1
ante criteria are basedon optimum conditions (day, VMC, steadydeck, experienced aircrew, normal wind over deck, etc.) and shouldbe increasedfor degradedconditions basedon judgment. 5. If minimum performancecriteria are not passed and all options are exhausted(storesjettisoned, minimum gross weight, and divert not possible), eject undercontrolled conditions.
Seestep6. If divert is not possible:
If configuredfor landing: 4. Throttle Engine thrust and thrust responsecan be severely degraded such that level flight cannot be maintained in the full-flap landing configuration. DO NOT configure for landing until the performancetest has been accomplished.
MIL.
5. Ensurea minimum of 500~fpmrateof climb at 14 units AOA available for CV approach. When preparingfor landing:
If not configured for landing: 4. Perform constantairspeedclimb (i5 knots) at 10 units AOA, landing gear up, maneuvering flaps down (if possible), above 2,000 feet. Minimum climb requiredin 30 secondsis as follows:
Shipboard recovery in single-engine SEC modeis consideredextremely hazardousand shouldbe conductedonly as a last resortand if the performancecheck is successful. 6. RUDDER AUTH light -
CHANGE
IN ALTITUDE
MANEUVER FLAPS DN
-
FEET
7. Wing sweep -
Out, Check.
Set at 20”.
MANEUVER FLAPS UP
2,000 feet
950 feet
900 feet
4,000 feet
600 feet
750 feet
6,000 feet
700 feet
650 feet
If hammering (cavitation) is experiencedin the hydraulic system, componentrupture is imminent. Turn the HYD TRANSFER PUMP switch (BIDI) off. 8. Hook -
m
As Required.
9. External stores Recovery.
Ifminimumperformance testis passedbased onpredictedgrossweight, do not lower landing gear and flaps until predicted gross weight is reached.
Jettison for Shipboard
10. Fuel - Dump or Burn (reduce as much as practicable). 11. Speedbrakes-
RET (on final approach).
Note
Climb performancewill improve by 20 feet in a 30-secondclimb for every 1,OOO-pound grossweight reduction. Minimum perfotm-
12. LDG GEAR handle - DN (ifcombinedhydrautic pressurezero - EMERG DN).
NAVAIR 0%Fl4AAD-1
1. Airspeed -
Less Than 280 Knots.
2. LDG GEAR handle Shore-basedlandings should be conducted with flaps up. If conditions warrant a fullflap landing, conducta performancetest and proceedas in the caseof shipboardlanding. 13. CheckSAS I
ON.
14. If combined pressure is zero FLAP/FLAP CONTR Cb (8G3).
Pull AUX
DN.
The LDG GEAR handle should be pulled with a rapid and continuous55-poundforce until the handle is loose (fore and aft) in its housing as an indication of complete extension of the handle.
15. Flaps - DN (shipboardrecovery),As Required (field landing).
3. PushLDG GEAR handlein hard,turn it 90” clockwise, pull, andhold.
16. DLC -
4. Gearposition indication -
Do Not Engage.
17. EMERG FLT HYD switch committed to landing).
HIGH (on final,
5. Make arrestedlanding if available.
l
If combined hydraulic pressureis zero, do not returnto AUTO (LOW) modeoncemodule is selectedon. If module is shutoff after operationcommences,it may not restart.
l
18. For landing pattern,use 10units AOA for pattern airspeedanddo not attempt turns greaterthan 20” angle of bank. 19. Final approachairspeed - 13Units (CV), (field landing slow to 15units, no flaps at touchdown). Note l
l
Waveoff shouldbe conductedby rotating to 14 units (maximum) AOA until a positive rate of climb is attained. Bolters shouldbe conductedby rotating to 10” pitch attitude not to exceed 14 units AOA.
Check (12 seconds).
l
l
Note The nosegear cannot be confirmed as locked by visual observation.If both the indicator and transition light indicate unsafe, assumethat the downlock is not in place. If thereis disagreementbetweenthe indicatorandlight andthegearappearsdown, the malfunction may be because of a faulty contact on the nosegeardownlock microswitch. Use of emergencygear extensionresults in loss of nosewheelsteering. To facilitate in-flight refueling probe extension when the gear has been blown down, raise the LDG GEAR handle to give priority to the refueling probe system.
If any geardoesnot come down: 6. Increaseairspeed.Do not exceed280 Knots.
15.4 LANDING GEAR EMERGENCIES
7. Apply positive and negativeg to force geardown.
15.4.1 Landing Gear Emergency Lowering. Use emergencylowering of the landing gear only as a last resort. Once this system is used, the gear cannot be retracted;therefore,the landing must be made in whateverconfiguration you have at that time. Ifa long flight is necessaryto make a field landing, it will have to be made with the geardown (seeFigure 15-1).
8. Obtain visual in-flight check if possible. 9. Refer to Figure 15-1(as appropriate). 15.42 Landing Gear Malfunctions 1. Remain below 280 knots.
I
NAVAIR
.
FIELD
NOTES
GEAR AVAILABLE NOTES
iNDING
NO ARRESTING GEAR AVAILABLE 1 NOTES
ARRESTING FINAL
CARRIER
LANDINGS
CONFIGURATION >ocked Nose Gear
Land
;ide-Brace ‘lace
Land
Not In
lose Gear JpAJnsafe Down
Land
1,8,11
Arrested Landing
8, 8, 9, 11,12, 13
1,&E,
11
No Arrested Landing
3, 637, 8, 11
1,2,4, 8, 11
No Arrested Landing
4, 6.8, 9,10,11
01-F14AAD-1
Land
Land
16, 9, 11
6, 89,
10,ll Land
6, 8.9,
10,ll Eject
-,,
Pilot Option Eject Or Land
5, 6, 8, lO,ll, 13
Pilot Option Eject
dains One Or Both
Eject Pilot Option To Land tf Tanks 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13.
Pilot Option Eject
Divert it possible Hook down barricade engagement Minimize skid and drift rollout Remove all arresting gear Land off center to gear down side Minimum rate of descent landing (488 fpm ma%) Gradual symmetrlcal braklng Retain empty drop tanks Lower nose gently prior to fall through Secure engines at airframe contact External ordnance -SEL Jell If required. Activate emerg landing gear lowering to enable ratsIng gear handle for SEL or ACM JEtT Hold damaged gear off deck until pendant engagement. Engage NWS if operable, use as required.
Figure 15-l. Landing GearMalfunction EmergencyLanding Guide 15-7
ORIGINAL
NAVAIR
Ol-Fl4AAD-1
2. Combined hydraulic pressure-
Check.
3. If lessthan 3,000psi, refer to combinedhydraulic failure proceduresin Chapter 14. 15.4.2.1
Landing Gear Indicates Unsafe Gear Up or Transition Light Illuminated
1. LDG GEAR handle -
DN.
If safe gear down indication is obtainedand transition light out: 2. Landing gear -
Leave Down.
3. Obtain visual check of gearcondition.
A hyperextended main strut, whether because of a broken piston or overextended piston barrel and/ormain strut with a cocked wheel, will likely result in a combined hydraulic system failure while airborne and a shearedstrut upon touchdown. A hyperextendedmain strutis evidentto a wingman by full vertical extensionofthe scissorsandbroken brake lines and to the tower or LSO by onemain gearhangingnoticeablylower than the other.When either of thesesituationsoccurs, landing proceduresfor a stub (MLG) mount must be followed. 4. Land as soonas practicable.
If associated with LAUNCH BAR light, leave geardown and obtain visual check. 2. Landing gear Ifcondition still exists: 3. Obtain visual check ifpossible. 4. Make normal landing. 15.4.2.3 Landing Down, Transition
15.4.2.2 Landing Down, Transition
Gear Indicates Unsafe Gear Light Out. This indicationmeans
a failure in oneof thedual-poledownlockmicroswitches. 1. Transition light bulb -
Check (LTS TEST).
Gear Indicates Unsafe, Gear Light Illuminated. Nosegear
unsafeindicatesthat the downlock pin throughthe drag braceis not in place.Visual determinationofnosegearunlocked statusis assistedby a red bandpaintedon the landingnosegearbraceoleo. However,a positive check for locked nosegearis not possible visually. Main gear unsafe should be verified by visual inspection. If the drag brace is fully extended,the main gear should be down and locked. 1. Obtain visual check if possible.
a Visual determination of nose landing gear-unlockedstatusis assistedby a red band painted on the nose landing gear dragbrace.If red is visible, the nosegear is not locked. l
If landing gear indicatesunsafeafter rctraction and a down-and-lockedindication can be obtained,the brake pedalsshould be depressedfor 60 secondsto ascertainwhether brake hydraulic lines have been severed.If brake hydraulic lines are severedanda combined hydraulic failure occurs,refer to combined hydraulic systemfailure proceduresin Chapter14.
Cycle.
During an airborne visual inspection of the main landing gear (even if the paint stripe acrossthe drag brace kneepin appearsto be straight),the possibility exists that the downlock actuatorhas failed and the gear may not be locked in the down position.
2. LDG GEAR handle -
Cycle.
If still unsafe: 3. Increaseairspeedto 280 knots, pull positive g’s and yaw aircraft. If main landing gearis still unsafego to step5.
If nose landing gear indicates unsafe, transition light illuminated, continue wifh step 4: 4. LDG GEAR handle Less Than 2 Seconds.
15.4.2.4 Landing Down, Transition
Gear Indicates Light Illuminated.
Safe
Gear
This indication can be causedby a malfunction of the following:
Cycle UP then DN in a.
pi&-(
Half of the dual-pole micro in the nosegear downlock.
b. Half of the dual-pole micros in either of the main geardownlocks.
Failure to place the LDG GEAR handle to DN immediately after selectingUP may allow the main landing gear doorsto receive the signal to close with main gear struts extended,causingdamageto the doors and inducing a possible combined hydraulic or brakesystemfailure. Do not reselectUP with the LDG GEAR handle after the doors attempt to close, as indicated by an unsafe main mount or visual inspection. Note
c. The proximity micros in the sidebraces. d. Failure of the LDG GEAR handle position micro. e. If a visual checkconfirms the gear is extended and both sidebracesare in place, a malfunction of one of the transition light micros is indicated. 1. LDG GEAR handle -
Use of the aboveprocedureshould be done at the intended point of landing or within rangeofan acceptabledivert field exercising a gear-downbingo profile. 5. LDG GEAR handle - EMERG DOWN (refer to landing gearemergencylowering). Note
Use of the emergencygear lowering procedurewill result in lossof nosewheelsteering. If still unsafe and visually confirmed unsafe, or gear position cannotbe confirmed: 6. Refer to Figure 15-I.
Cycle.
If associated with LAUNCH BAR light, leavegeardown and obtain visual check. If transition light remainson: 2. Obtain visual check. 3. Gear/sidebraces appear in place Landing.
Normal
Sidebracesconfirmed not in place: 4. Refer to Figure 15-1. 15.4.3
LAUNCH
BAR Light
1. Landing gear -
Leave Down.
When landing with nosegear unsafedown indication, anticipatepossible nose landing gearcollapse.
If nosegearcocked,seeFigure 15-1.
Do not attemptto tow aircraft by nosegear until gearis securedin down position.
If launch bar is down or visual inspection is not available:
Nose landing gear ground safety pin installation will not prevent nosegearcollapse.The noselanding gearstrut must be restrainedagainstforward rotation.
2. Obtain visual inspection.
3. Request removal of arresting cables for field landing. 4. Requestremoval of cross-deckpendantsNos. 1 and 4 for CV landing.
NAVAIR
15.5
01-F14AAD-1
BLOWN-TIRE
Note
LANDING
Blown-tire landings shouldbe performedinto arresting gearwheneverpossible.Rollout is extremely rough on blown tires. If go-aroundis elected,do not apply full aft stick in attempt to rotatethe aircraft before reaching flying speed.The drag from full-up deflection of the stabilizersis largeand significantly delaysacceleration. Blown tireswill frequentlyresult in damagedmainlanding gear hydraulic lines. Anticipate possible combined hydraulic system failure and attendant committal to gear-downbingo following a blown tire.
FLAP AND SLAT EMERGENCIES
LANDING
No-Flaps and No-Slats Landing. Anoflaps and no-slats landing is basically the same as a normal landing except that the pattern is extendedand theapproachspeedis approximately 15knots fasterthan a full-flap approach.Field arrestinggearshouldbe used ifnecessary.CV arrestmentsarepermitted. Consult applicable recoverybulletins for WOD requirements. 15.6.1
2. Flaps -
UP.
Note If outboardspoilers are neededfor groundroll braking, FLAP handle must be set to DN.
Do not allow the aircraft to roll backward after the arrestment.The downlock actuatormay havebeendamagedby tire failure and rearward movement of the aircraft could causethe gear to collapse.
3. Fly !anding pat!em sligh!ly wider than normal or make straight-in approachat 15units AOA.
1. Obtain in-flight visual check ifpossible.
3. HOOK -
15.6
1. Grossweight - Reduce(weight consistentwith existing runway length and conditions).
Blown tire(s) can cause engine FOD and/orstructuraldamage.Leaveflaps and slats as set. Aircraft should have ground locks installed andenginessecuredbefore moving aircraft.
2. ANTI SKID SPOILER BK switch BK (OFF for CV).
Antiskid will sensea constantreleaseon a draggingblown tire.
4. Use normal braking technique.
SPOILER
DN. .
Maximum airspeedfor wheelbrakeapplication is 165 knots at a gross weight of 46,000 pounds and 145 knots at 51,000 pounds.
.
Use of full aft stick during landing in this configurationcanresult in tailpipe ground contact.
.
Avoid slow approaches.Wing drop and increasedsink rate may occur at 16.5 to 17.5units AOA.
4. Make carrier or short-field fly-in arrestedlanding as soonas practicable. 5. HYD ISOL switch -
T.O./L.ND (on final).
If arrestinggear is not available: 6. Land on centerline. 7. Nosewheel steering -
Engaged.
m
156.2 Auxiliary Flap Failure. A no-auxiliaryflaps landing is basically the sameas a normal landing exceptthattheapproachspeedis 6 knots fasterthanwith auxiliary flaps extcndcd,and the longitudinal stick position during the approachis further aft. CV arrestments are permitted; consult applicable recovery bulletin for WOD requirements.
Do not delay engagingnosewheelsteeringin order to centerrudderpedals.
ORIGINAL
15-10
c------
NAVAIR
1. Wing sweep -
Ensureat 20”.
2. AUX FLAP/FLAP CONTR cb 3. Approach -
4. Maneuvering flaps Pull (8G3).
15Units AOA. If maneuvering flaps are used, ensurethat maneuver flap thumbwheel is not actuated during the approach.
With AUX FLAP/FLAP CONTR cb pulled, wings will not sweepaft.
5. DLC and APC WING-SWEEP
15.7.1
Extend.
pi&-(
Note
15.7
Ol-Fl4AAD-1
Do Not Engage.
EMERGENCIES
Aft Wing-Sweep
Landings.
CV arrest-
merits arepermitted with up to 40” of wing sweep,and emergencybarricade engagementsare permitted with up to 35” of wing sweep. Shipboard aft wing-sweep landingsshouldbe conductedat 15units AOA. Field aft wing-sweeplandingsmay be conductedat AOAs up to 17 units when wings are stuck aft of 50” to minimize approachairspeedfor normal landings or remain within publishedfield arrestinggearlimitations for short-field arrestedlandings.Main flaps andslatsshouldbeutilized to reduceapproachspeedwith aft wing sweepsup to 50’. Maneuver flaps may be utilized if main flaps and slats fail to extend. If wings are determinedto be stuck aft of 20” position:
6. Slow-fly aircraft at a safe altitude to determine approachairspeed(up to 17 units AOA for field landings with wings aft of 50”) and to evaluate handling/stall characteristics and waveoff performance. Note
s Referto emergencyfield arrestmentguide for maximum engagementspeedif field arrestmcntis desired. l
Referto Figure 1l-l for approachairspeeds.
7. Fly straight-inapproachat 15units AOA (up to 17 units for field landingswith wings aA of 50’).
1. Emergency WING SWEEP handle - Match Captain Bars With Actual Wing Sweep Position Tape. Nozzle clearanceis reducedat elevatedapproachAOA. Ensurethat a maximum of 17 units is maintainedat touchdown. Note
Closely monitor wing-sweep movement whenattemptingto matchhandlewith wingsweepposition. Ifabnormal movementis noticed, immediately returnhandleto previous position. 2. Grossweight -
Maximum airspeedfor wheelbrakeapplication is 165 knots at gross weight of 46,000 poundsand 145knots at 51,000pounds. 15.7.2 Asymmetric Wing Sweep. Refer to Chapter 11 for asymmetric wing-sweep design limitations and flight characteristics.
Reduceas Required.
If wings < 50”: 3. Main flaps -
With asymmetric wing-sweepemergencycondition, divert field landing is prcfcrableto CV landing attempt. Aircrew must fully considerapproachspeedandaircrag controllability characteristicsprior to attemptingCV arrestmcnt. See Figure 15-2 for recommendedapproach airspeedfor 14 or 15units AOA with asymmetricwing configurations.
FULL DN. Note
Main flap/slat extension with the wings aft of 20” will result in a large nosedownpitch transient. If main flaps areinoperative:
15-11
ORIGINAL _--
NAVAIR
01-F14AAD-1
FLAPS
MAIN 170
UP APPROACH AIRSPEED (14 UNITS FLATS/SLATS RETRACTED
AOA)
LANDING APPROACH AIRSPEEDS (15 UNITS AOA) FLAPS/SLATS EXTENDED: AUXILIARY FLAPS RETRACTED
Figure 15-2. Asymmetric Wing-SweepLanding Approach Airspeed ORIGINAL
15-12
NAVAIR
01.F14AAD-1
b. Assessspoiler function by controlled left- and right-stick inputs. To preclude potential damage to aircraft, avoid all wing-sweep commands prior to performing steps1 through 9. Limit maneuvering envelopeto 350 knots and 1.5g.s.
Aircraft controllability in approachcontiguration with spoilers inoperative and a large wing-sweepasymmetrywill rangefrom difficult to impossible dependingon split.
1. Leavewings and flaps as set. 2. Altitude AGL.
Climb/Remain Above 10,000 Feet
3. Airspeed AOA.
250 Knots/Do Not Exceed 12 Units
c. Landing gear -
4. Maneuver devices Retract.
Down.
d. Leave flaps as set until further determinations arecomplete.
Thumbwheel Manual
e. Slowly increaseAOA to no more than 15units (attemptto maintain 0” sideslip).
5. WING SWEEP DRIVE NO. 1 and WG SWP DR NO. 2/MANUV FLAP cb’s - Pull (LDl, LEl).
f. Make small lateralstick inputs to simulatelineup corrections.
6. ALPHA COMP/PEDAL SHAKER cb WI). 7. All SASS -
Pull
Ifaircraft controllability is questionablefor safelanding, perform Asymmetric Wing Sweep Unacceptablefor Landing procedure,paragraph15.7.2.2.
ON.
Note If roll SAS will not’engage,accelerateand attemptto resetat approximately20-knotintervals. Stick may have to be releasedlaterally in order to reengageroll SAS. 8. Confirm let?and right wing position. Note
Wing-sweeptapeindicatesactualright-wing position. All other cockpit wing position indicationsmay beunreliable,including wingsweep handle position. Visually verify left-wing position. If leftwing is at?of 57”/62” spoilercutoutandright wing is 20°, perform Asymmetric Wing SweepUnacceptable for Landing procedure,paragraph15.7.2.2.
If aircrafi controllability is safe for landing, perform Asymmetric Wing SweepAcceptable for Landing procedure,paragraph15.7.2.2. 15.7.2.1 Asymmetric Wing Sweep Acceptable for Landing. Establish final landing configurationas
follows: 1. AUX FLAP/FLAP CONTR cb -
Pull (8G3).
Note Pulling the AUX FLAP/FLAP CONTR cb (8G3) with the emergencyWING SWEEP handle at the 20” position disables wingsweepcommands. Ifboth wings are forward of 50’: a. Airspeed -
Below 225 Knots.
9. Perform preliminary controllability check as follows: a. Trim away from forward wing (oppositestick force) to ensurethat maximum spoiler dcflection is available.
Extendingthemainflaps witheitherwingaft of 50” could result in damage to both the flaps and the aft fuselage. b. Flaps -
Lower Incrementally 20” to 25O.
-------------
2. Emergency WING SWEEP handle - Leave in Position that Established Satisfactory Controllability. When flaps are set greaterthan 2.5”,lateral pilot-induced oscillations arelikely and may result in wingtip damage at touchdown and/orhard landings.
4.
DLC -
Reduceas Required.
Stowed.
5. Autothrottles (APC) -
Note The 25’ flap position can be establishedby first noting when the spoiler position indicators switch to the drooped position during flap extension.An uncommandedbut controllable roll transient because of spoiler gearing change will also occur. Upon observing either event, retract the flaps to just lessthan 25”. The roll transientwill occur in the opposite direction as the flaps pass through 25”. Main flap extension without auxiliary flaps will requiregreaterthan normal atI stick trim. c. Approach airspeed -
3. Grossweight -
15 Units AOA.
Note Indicated AOA is subject to a I- to 2-unit sideslip-inducederror. Verify proper AOA at zero sideslip.
Do Not Engage.
6. Confirm flight characteristicsby flying simulated landing approachat safealtitude,to include lineup corrections,power changes,and waveoff.
Full spoiler authority will be required for landing with large wing-sweep asymmetry. Before attempting actual approach, trim away from the forward wing (oppositestick forces) to ensuremaximum spoiler deflection is available. 7. Fly straight-in approach to arrestedor normal landing.
If either wing is aft of 50”: a. Flaps -
UP.
b. Approach airspeed -
1 \ \ \L
I; \
14 Units AOA.
Wing rock andwing stall may occur at 16to 16-l/2 unitsAOA duringflaps-upapproaches. Rapid lateral stick inputs will result in pitch coupling.Excessivedescentratesmay develop and/orwingtip damageat touchdownmay occur. PreciseAOA control and smoothlateral controlinputs arerequired. Note Indicated AOA is subject to a 1- to 2-unit sideslip-inducederror. Verify proper AOA at zero sideslip.
\L
ORIGINAL
Avoidrapidlateral stickinputs,assigniticant pitch-roll coupling may result in roll ratcheting, pitching motion, and lateral PI0 tendency; an excessive descent rate may develop and/or wingtip damage at touchdown may occur. Note . A crosswind from the swept-wing side is favorable while a crosswind from the forward-wing side is unfavorable. . To reduce lateral stick force, the landing approachcan be flown with rudder trim into the forward wing, allowing aircraft to yaw into the forward wing. Sideslip should be reducedwith rudderjust prior to touchdown.
NAVAIR 01.F14AAD-1
l
l
Note If desired,sideslip can be reducedto zero with rudder at the beginning of the approach and held to touchdown. Lateral stick force increasesassideslipis reduced. Method of approachis at pilot’s option. In theeventof bolter or go-around,asairspeed increases,the aircraft will roll toward the swept wing andyaw toward the forward wing.
sequentwing-sweep commandsmay not move the right wing. If spoilersare operational: a. Emergency WMG SWEEP handle a Small Forward Command. If spoilersarenot operational: a. Emergency WING SWEEP handle a Small At? Command.
a Maximum airspeedfor wheelbrakeapplication is 165 knots at gross weights of 46,000 pounds and 145 knots at 51,000 pounds.
3. Note movementof left andright wings andattempt to regainwing-sweepasymmetryby using thefollowing wing-sweepcommands.
a. Airspeed -
Efforts to improve controllability by attempting to minimize or eliminate wingsweep mismatch could result in an acceptable condition becoming unacceptable. Note Once spoiler operation is assessed,stick forcesmay be trimmed to reducepilot workload during transit to field or CV. The useof lateral trim to reducestick forcesduring actual approachand landing shouldbe avoided as this reducesthe spoiler deflection available for roll control.
b. EmergencyWING SWEEP handle -
68’.
c. EmergencyWING SWEEP handle -
20’.
CONTR cb -
Pull
e. Repeat preliminary landing controllability check (step9 of paragraph15.7.2). Ifboth wings aremoveableandright wing is forwardof left wing: a. EmergencyWING SWEEP handle b. AUX FLAP/FLAP (8G3).
20”.
CONTR cb -
Pull
c. Repeat preliminary landing controllability check (step9 ofparagraph 15.7.2).
In (8G3).
a At any point during the following procedures, if wing-sweep symmetry is regained at aft wing-sweep position and runway length/approach speed permit, aircrew may elect to perform Aft WingSweep Landing emergency procedure, paragraph15.7.1.
300 Knots.
d. AUX FLAP/FLAP (8G3).
UP.
2. AUX FLAP/FLAP CONTR cb -
Input
If both wings are moveableand left wing is forward of right wing:
15.7.2.2 Asymmetric Wing Sweep Unacceptable for Landing
1. Flaps -
Input
If right wing is jammed and left wing is moveable: a. Airspeed -
300 Knots. Note
If right wing is jammed atl of spoiler cutout angle,matching let? wing will result in loss of spoiler control. If this reducedlateralcontrol is undesirable,left wing shouldbe commandedjust forward of spoiler cutout to regainspoiler control.
a If letI wing is jammed, wing-sweep command can result in right wing driving to either 19” (forward command) or 69” (aft command) actuatorovertravel stop. Sub-
15-15
ORIGINAL
NAVAIR 0%FWiAD-I
b. EmergencyWING SWEEP handle I& Wing to Right-Wing Position. c. AUX FLAP/FLAP (8G3).
light when the hung station is selected.Obtain a visual check if possibleto validate this checkas failures of the stores-aboardswitch regularly occurred during flight test and will indicate hung storeswhen none actually exists.
Match
CONTR cb -
Pull
d. Repeat preliminary landing controllability check (step9 of paragraph15.7.2). If left wing is jammed and spoilers areoperational: a. EmergencyWING SWEEP handle b. AUX FLAP/FLAP (8G3).
CONTR cb -
20’. Pull
c. Repeat preliminary landing controllability check (step9 of paragraph157.2). If left wing is jammed aft of spoiler cutout wing-sweep angleand spoilers are inoperative: a. Airspeed -
3OOKnots.
b. EmergencyWING SWEEP handle c. AUXFLAP/FLAPCONTRcb
-
68”.
Pull(8G3).
d. Repeat preliminary landing controllability check (step9 of paragraph15.7.2).
In-flight actualcg location variesas fuel is burnedbut remainsrelatively constantat its most forward position between5,000to 10,000pounds.Below 5,000pounds, the cg moves aft towards the ZFGW position. Landing shouldbe accomplishedat 5,000poundsof fuel or more if possible.Wing-mounted AIM-7/9s move the cg location slightly forward and have no adverseeffects on flying qualities.External tanksproduceno changeto the cg location and also have no adverseeffects.Combinations of forward andaft storeswill producea cg change slightly less than consideringthe difference ashung on the aft stations alone (i.e., the cg location with 2,000 pounds forward and 4,000 pounds at?will be slightly more forward than 2,000 poundsaA alone). Flying qualitiesat aft cg locationswith gearandflaps up are only slightly degraded.This degradationwill probably not be apparentto the pilot. Stick force per g remainsrelatively nominal even with 4,000 poundsof aft hung bombs. No changein flying qualities is noted during dive recoveriesbetween400 and 500 KCAS. At 20” of wing sweepwith the gearand flaps down andan aft cg, the aircraft is extremely susceptible to pilotinducedoscillationsduring closely controlledtaskssuch as flying the ball. Loss of control is likely.
If final wing configuration is unsafefor landing: a. Preparefor and executecontrolled ejection. 15.6 AFT HUNG ORDNANCE LANDINGS The normal NATOPS cg ZFGW limit for tunnelmounted stores is 17.0 percent.On a typical fleet aircraft, one Mk 84 2,000-poundbomb placed on station No. 4 or 5 results in a ZFGW cg aft of 17.0 percent MAC, possibly as far aft as 18.5to 19.0percentMAC. Two ti hung Mk 84s can producea ZFGW cg of up to 22 percentMAC. Theseall cg locations reducethe normaI static stability of the F-14, producing a marked degradationin landing flying qualities. Aft wing sweep can be used to restore the normal static longitudinal stability margin, regainingnormal flying qualities even with extremely aA cg locations. Aircrew may have difficulty detecting aft hung ordnancefollowing bomb release.The only cockpit indication of an unsuccessfulreleasewill be a hot trigger light that remains illuminated following the intendedrelease of all selectedstations.With MA ARM ON, individually selecting stations will illuminate the HOT TRIG ORIGINAL
The transitionto landing contigumtion shouldbeperformed in straight-and-level flight to allow handling qualities to be evaluated in benign conditions. Wings should be swept to the desiredposition beforethe gear andflaps arelowered.The AUX FLAP/FLAP CONTR (8G3) cb should be pulled in caseof a wing/flap interlock failure and alsoto preventthe auxiliary flaps from deploying if 20” of wing sweep is inadvertently selected. Sweeping the wings with auxiliary flaps retracted results in significant pitch-trim changes.A straight-inapproachshould be flown as power requirements with aft wing sweep in a turn are significantly different than normal and could producea severelyunderpoweredapproach.Onceestablishedin the optimum wing-sweepconfiguration appropriatefor theamountof ordnancehungon theat?stations,normal approachtechniques can be used. No abnormalities in aircraft response or performance are apparent during landing approachesat 15 units, even with 4,000 poundsof aft hung ordnance.APC is not optimized for aft wingsweeplandingsandshouldnot be used.DLC shouldnot be used as it adds 8 knots to recovery WOD requirements andhas improper pitch trim responseat atl wing sweep.Expect onspeedairspeedfor 25” of wing sweep
15-16
NAVAIR
to increase6 knots over the normal DLC on, 20” of wing-sweepapproachspeed,and a 12-knot increaseif wings are at 30’. For CV arrestments,the appropriate recovery bulletin should be consulted. Ashore, a field arrestment is recommended with spoiler brakes dearmed because.of the large noseup pitch occurring at spoiler deployment.If a field arrestmen1is not possible,expect to use full forward stick to counter the noseuppitching moment and to maintain forward stick until below 80 KCAS with a resultant longerrollout. 15.8.1
Landing
with Aft Hung
Ordnance
1. Determine location of hung stores.Obtain visual check if possible. 2. Wing sweep - Set at 25” if c 2,000-Pounds Hung AA; Set at 30” if > 2,000PoundsHung AA. 3. Perform transition to gear-downconfiguration in straight-and-levelflight. 4. AUX FLAP/FLAP CONTR cb 5. Flaps -
Pull (8G3)
FullDN.
6. Fly straight-in approachat 15 units AOA. Do not engageAPC or DLC. CV approach: 7. Perform CV arrestmentin accordancewith applicable recoverybulletin. Field approach: 7. Spoiler brake -
OFF.
8. Perform field arrestment.
0%Fl4AAD-1
Expect a significant nose pitchup during landing rollout as spoilers deploy. Full forward stick may be required to avoid a tail strike. 15.9
FIELD ARRESTMENTS
15.9.1 Field Arresting Gear. The types of field arrestinggearin useinclude the anchorchain cable,water squeezer,and Morest-type equipment. All require engagementofthe arrestinghook in a cablependantrigged acrossthe runway. Location of the pendantin relation to the runway will classify the gearas follows:
1. Short-field gear - Located 1,500 to 2,000 feet past approach end of runway. Usually requires prior notification in orderto rig for arrestment. 2. Midfield gear - Locatednearthe halfway point of the runway. Usually requiresprior notification in order to rig for arrestment in the direction desired. 3. Abort gear - Located 1,500to 2,500 feet short of thedepartureendof theduty runway andusually rigged for immediate use. 4. Overrungear - Locatedshortly pasttheupwind endof the duty runway. Usually rigged for immediate use. Some fields will have all types of gear,othersnone. For this reason,it is imperative that all pilots be aware of the type, location, and compatibility of gear in use with the aircraft, and the policy of the local air station with regardto which gearis rigged for useand when. As variousmodifications to the basic typesof arresting gearare made, exact speedswill vary accordingly. Certain aircraRservice changesmay also affect engaging speedandweight limitations.
Note Refer to emergency arrestment guide for maximum engagementspeed. If arrestinggear is not available. 8. If field arrestmentis not available, spoiler brake - BOTH.
15-17
An engagementin the wrong direction into chain gearcan severelydamagethe aircraft.
ORIGINAL
NAVAIR 01-Fl4AAD-1
In general,arrestinggearis engagedon the centerline at as slow a speedaspossible.Burn or dump down to an acceptablelandingweight. Conditionspermitting, make practice passesto accurately locate the arrestinggear. Engagementshould be made with feet off the brakes, shoulderharnesslocked, andwith the aircraft in a threepoint attitude. After engagingthe gear, good common senseandexisting conditionsdictatewhetherto keepthe enginesrunning or to shut down and egressthe aircraft. In an emergencysituation, first determinethe extent of the emergency by whatever means are available (instruments,other aircraft, LSO, RDO, tower or other ground personnel).Next, determine the most advantageousarrestinggearavailableandthetype of arrestment to be made under the conditions. Wheneverdeliberate tieldarrestmentis intended,notify controltowerpersonnel as much in advanceaspossible and stateestimated landing time in minutes. If gearis not rigged, it will probably require 10 to 20 minutes to prepare.If foaming of the runway or areaof arrestmentis requiredor desired,it shouldbe requested by the pilot at this time. If fuel is streamingfrom the bottom of the aircraft, a field arrestedlanding is not recommendedbecauseof thehighprobabilityofsparksandheat from thearresting hook igniting the streaming fuel and air mixture. If an arrestedlanding is mandatedbecauseof the lack of adequatebraking or runway conditions,an effort shouldbe made to foam the runway in the runout areaof the arresting gear. 15.9.2 Short-Field Arrestment. If at any time before landing a directional control problem exists or a minimum rollout is desired, a short-field arrestment should be made and the assistanceof LSO requested. The LSO shouldbe stationednearthe touchdownpoint andequippedwith aradio. Inform theLSO of thedesired touchdown point. A constant glideslope approachto touchdown is permitted (minor or Fresnel lens landing aid) with touchdown on centerlineat or just before the arrestingwire with the hook extended.The hook should be lowered while airborne and a positive hook-down check should be made. Use midfield gear or Moresttype, whenever available. If neither is available, use abort gear.Use an approachspeedcommensuratewith the emergencyexperienced.Landing approachpower will be maintained until arrestment is assured or a waveoff is taken. Be preparedfor a waveoff if the gear is missed.AAer engagingthe gear,retardthe throttlesto IDLE or secureenginesandabandonaircraft,depending on existing conditions.
15.9.3 Long-Field Arrestment. ‘Ihelong-tieldarrestment is used when a stopping problem exists with insufficient runway remaining (that is, abortedtakeoffs, icy or wet runways, loss of brakes after touchdown, etc.). Lower the hook, allowing sufftcient time for it to extend Mollybefore engagement(normally 1,000 feet before reaching the arresting gear). Do not lower the hook too early and weakenthe hook point. Line up the aircraft on the runway centerline. Inform the control tower of your intentionsto engagethe arrestinggear,so that aircraft landing behind you may be waved off. If leaving the runway is inevitable, securethe engines. 159.4 Engaging Speeds. The maximum permissible engagingspeed,gross weight, and off-center engagement distance for field arrestment are listed in Figure 15-3.The datain the long-field landing columns may be used for lightweight abortedtakeoff where applicable; data in the aborted takeoff columns may be used for heavy grossweight landings. As variousmodifications to the basictypes of arresting gear are incorporated,engaging speedsor grossweight limitations may change.For this reasonand for more detailedinformation, the applicableaircratlrecovcry bulletin shouldbe consulted. 15.10 BARRICADE ARRESTMENT 1. External stores - Jettison (except AIM-7 or AIM-54 on fuselagestationsif wing is at full forward sweep). 2. External tanks - Jettison(empty tanks retained only for landing gearmalfunction). 3. Fuel -
Dump or burn (reduceto 2,000pounds).
4. HOOK - DN (Lower to permit engagementof a cross-deckpendant,which will minimize barricadeengagementspeedand damageto aircraft). 5. Fly normal patternand approach,on-speed,angle of attack,centerline,andmeatball. Note Anticipate lossof meatball for a shortperiod of time during the approach.Barricadestanchions may obscurethe meatball. Upon engagingthe barricade: 6. Throttles -
OFF.
7. Evacuateaircrag as soonas practical. ORIGINAL
15-18
~~\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\
NAVAIR
MAXIMUM
ENGAGING
SPEED (KNOTS) (D)
GROSS WEIGHT X 1,000 POUNDS
TYPE OF ARRESTING GEAR
LONGFIELD LANDING IM)
SHORT-FIELD LANDING (K)(L) 1 40
1 44
t 48
1 51.8 1 54
E-28
176 (W
180
179
178
E-28 (G)
176 (‘3
178
160
160
0%F14AAD-1
ABORTED
MAXIMUM OFF-CENTER ENGAGEMENT (FT)
TAKEOFF (4
1 57
1 60
1 64
1 68
1 69.8
72
177
176
175
174
172
172
171
40
160
160
158
145
145
145
145
40
113
10
118
30
(J)
50
160
30
160
40
(A)
Data provided in aborted takeoff column may be used for emergency
(B)
Maximum
(C)
Dual BAK-12 limits are based on 150- to 300-foot span, 1-l/4-inch cross-deck pendant, 50,000-pound weight setting, and 1,200-foot runout. No information is available regarding applicability to other configurations.
(D)
Maximum
engaging
(E)
Off-center
engagement
(F)
Before making an arrestment, the pilot must check with the air station to confirm the maximum engaging speed because of a possible installation with less than minimum required rated chain length.
(G)
Only for the E-28 systems at Keflavik and Bermuda with 920-foot tapes.
(H)
Standard BAK-12 limits are based on 150-foot span, l-inch cross-deck pendant, 40,000-pound weight setting, and 950-foot runout. No information is available regarding applicability to other configurations.
(J)
Engaging speed limit is 96 knots at 59,000 pounds. Because of runout limitations, gear not be engaged at weights greater than 59,000 pounds.
(K)
Maximum
(L)
Consult appropriate
(M)
engaging
speed limited by aircraft limit horizontal-drag
high gross weight arrestment.
load factor (mass item limit “9”).
speed is limited by arresting gear capacity except as noted may not exceed 25 percent of the runway span.
of 3.0’ glideslope. section for recommended
approach speed
Flared or minimum rate of descent landing.
Figure 15-3. EmergencyField Arrestment Guide (Sheet1 of 2)
15-19
it it recommended
this
AIRCRAFT ENGAGING SPEED LIMITS FOR E-5 EMERGENCY ARRESTING GEAR \IRCRAFT:
F-14 D SHORT-FIELD
IANDING
LONG-FIELD LANDING 100 POUNDS
ARRESTING 1
ABORTED TAKEOFF 60,100 TO 72,000 POUNDS
HEAVY CHAIN
STANDARD CHAIN
E-51 I I
E-5-3
-H-
NOTES (E) AND
HBAW CHAIN
COL.8
COL.9
38 CD) ‘14 (‘2 51 0)
38 (‘J) 44 P) 51 CD)
COL. 1c COL.11 33 (0) 39 (W 44 0
102 (D)
102 (0)
s2 (0)
109 (D) 117(D)
109 (D) 117(D)
67 CD) 93 (4
125 (D) 133(D) 140 (D)
125 (D) 133(D) 140 (D)
98 (‘3 104(D) 109 (D)
148 (D) 150 (D)
148 (D) 156 (D)
115 (D) 120 (D)
(F) APPLY
Figure 15-3. EmergencyField ArrestmentGuide (Sheet2 of 2)
E-5 E-5-2
E-51 E-5-3
COL.12
COL.13
33(D) 39 CD) 4‘1(‘3
M(D) 49 CD) 47 0)
34(D) 49 (0) 47 (0)
49 (0) 55 (0)
53 (0) 59 P)
53 0) 59 (0)
60 03
66 0)
66 (0)
85 (‘J) t 71 (0)
73 (D) 79 (‘J)
73 (0) 79 0)
82(D) 87(D) 93(D)
93(D) 100(D) 107(D)
93(D) 100(D) 107(D)
NAVAIR Dl-Fl4AAD-1
If light is illuminated and hook visually is checkedup: 4. HOOK handle Weight limits for barricadeengagementare asfollows: a. Wings at 20” IllUm).
51,800 pounds (maxi-
b. Wings > 20’ < 35’ (maximum). c. Wings 35’ -
46,000 pounds
Not permitted.
15.11 ARRESTING HOOK EMERGENCY DOWN
Restow in Down Position.
5. HYD VALVE CONTR cb ter 5 Seconds(8E5).
Pull andResetAf-
If light is illuminated and hook visually is checked down: 6. WSHLD AIR/ANTI-ICE HOOK CONT cb Pull (8C2). Note Cb 8C2 also controls windshield air and anti-ice.
1. HOOK handle -
DN.
15.12 FORCED LANDING
2. HOOK handle -
Pull, Then Rotate.
Landing the aircrafi on unpreparedsurfacesis not recommended.If it is necessaryto do so, landing with the landing gear down, regardlessof the terrain, will assistin absorbingthe shock of ground impact and reduce possibility of flightcrew injuries. External stores shouldbe jettisoned in a safe areaprior to touchdown. External tanksshouldbe jettisoned if they contain fuel, but retainedto absorblanding shock if they are empty. If time permits, dump fuel to allow touchdown at the slowestpossiblespeedwith full flaps.
Note Pull handle aft approximately 4 inches and turn counterclockwise. This will mechanitally releasethe uplatch mechanismand allow hook to extend. 3. Hook transition light -
Check OFF.
15-21 (Reverse Blank)
I
UAVAIR 0%FMAAD-I
CHAPTER
16
Ejection 16.1 EJECTION Responsibility for the decisionto ejectshall be determined andbriefed before Sight Thereafterthe decision to abandonthe aircraft shall rest with the crewmember assignedresponsibility for that particular situation. The decision should be made before sink rate, altitude, and attitude conditions jeopardixe safe ejections for both occupants.In flight, the aircraft must be abandonedby meansof the ejection seatssince them is no provision for manual bailout. Prior to ejection from a flyable or controllableaim&, it is the pilot’s responsibility to do everythingreasonableto ensurethat the abandonedaircraft will intlict the leastpossible damageon impact. Ejection may be necessaryas a result of fire, engine failure, structural failure, midair collision, or when the aircraft becomesuncontrollable.In eachcase,the pilot must decide when to eject, using the following as a guide: 1. Ejection is mandatory underthe following conditions except when unusual circumstancesclearly indicate to pilot that cause of safety to self and otherswill be betterservedby a flameout approach thanby ejection. a. Serious,uncontrolled fire. b. Ifaircrafiis inuncontrolled flight at 10,OOOfeet AGL or below. c. When dual-engine flameout occurs below 1,500feet AGL and 250 knots. d. If repeatedrelight attemptsare not successful between 30,000 and 10,000 feet, eject by 10,000feet AGL. e. If still on first or secondrelight attempt when passing through 10,000 feet AGL and it appears that a relight is likely, airstart attempt may be continuedto a minimum of 5,000 feat AGL.
2. If dual-enginetlameout occursbelow 10,000feet, zoom to convert excessairspeedto altitude. Attempt airstart as time permits. If peak altitude is above 5,000 feet AGL and airstart attempt is not successful,eject no lower than 5,000fret AGL. If peakaltitude is below 5,000feet AGL andairsmt attempt is made during xoom and thereis no evidence of a relight, eject at peak altitude. If no airstartattempt is made, eject at peak altitude. 3. If decision to abandon aimrat? is made at high altitude, the recommendedminimum altitude for ejection is 10,000 feet AGL, or higher, if conditions so indicate. Under any circumstancesandif at all possible, ejection should be accomplished prior to descendingbelow 2,000 feet AGL. 16.1.1 Ejection Envelope. Figure 16-1 shows minimum ejectionaltitude for a given airspeedand sink rate, bank angle, and dive angle. For all ejections,it is mu~mmendedthat akspeedbe reducedas slow aspmcticable;however,inuncontrolled situations,donot delay ejection becausethe aircmfi is not within the published safe escapeenvelope.For ejection at low altitude, it is recommendedthat a climb be initiated to convertexcess airspeedinto altitude. Although the escapesystem is capableof zero-zeroejection,it shouldbebornein mind that a combination of low airspeedand high rate of descentat low altitude can present a condition more severethan zero-zero.Ejection sequencesareshown in FO-16andFO-17. Fordetailsofejectionseatme&anical operation,seeparagraph2.38. The escapesystem will Rmction up to 600 knots; however, human liitations are more restrictive as indicatedbelow: l.Zeroto35Oknots probable).
-
Safe Ejection (injury im-.
2. 350 to 450 knots - HazardousEjection (injury may be sustained).
NAVAIR 01.Fl4AAD-1
MINIMUM
EJECTION
ALTITUDE
AIRSPEED AND SINK RATE EFFECTS
z /
I
I
F-14D LEGEND 130 KNOTS ---
- 250 KNOTS _____________ 400 KNOTS ---
600 KNOTS
/: , s’ /
IOC I
81
AIRCRAFT SINK RATE (FEET PER MINUTE) NOTES 1. MINIMUM EJECTION HEIQHTS ARE BASED ON INITIATION OF THE ESCAPE SYSTEM, AND THE TIME REQUIRED FOR A COMPLETE DUAL SEDUENCED EJECTION IS INCLUDED. 2. PILOT REACTION TIME IS NOT INCLUDED. 3. EJECTION ALTITUDE IS BELOW 5,000 FEET MSL.
Figure 16-l. Minimum Ejection Altitude (Sheet 1 of 3) ORIGINAL
16-Z
3
10. 00
----___
\\\\\\\\\\\a\ NAVAIR
MINIMUM AIRSPEED
EJECTION
0%F14AAD-1
ALTITUDE
AND BANK ANGLE
EFFECTS
-__------- 400 KNOTS __________ --
00
20
-
600 KNOTS
40
AIRCRAFT
60
80
BANK ANGLE
100
120
140
(DEGREES)
NOTES 1. MlNlMUM MlNlM”,., EJECTION HEIGHTS ARE BASED ON INITIATION OF THE ESCAPE SYSTEM, AND THE TIME REGUIRED FOR A COMPLETE DUAL SEQUENCED EJECTION IS INCLUDED. 2. BANK ANGLE DATA IS FOR COORDINATED FLIGHT. YAW OR SLIP WILL INCREASE THE HEIGHT REQUIRED FOR RECOVERY. 3. PILOT REACTION TlME IS NOT INCLUDED. 4. EJECTION ALTITUDE IS BELOW S,OOO FEET MSL.
Figure 16-l. Minimum Ejection Altitude (Sheet2 of 3) 16-3
160
180
MINIMUM EJ,ECTlON ALTITUDE AIRSPEED AND DIVE ANGLE EFFECTS 3200
-
130 KNOTS
- - - 250 KNOTS
----_.--. 400 KNOTS ---
600 KNOTS
AIRCRAFT
DIVE ANGLE
FROM HORIZONTAL
(07 TO VERTICAL
NOTES: 1. MINIMUM EJECTION HEIGHTS ARE BASED ON INITIATION OF THE ESCAPE AND THE TIME REQUIRED FOR A COMPLETE DUAL SEOUENCED EJECTION 2. PILOT REACTION TIME IS NOT INCLUDED. 3. EJECTION ALTITUDE IS BELOW 5,000 FEET MSL.
SYSTEM. IS INCLUDED.-
(909
NAVAIR 0%Fl4AAD-1
3. Above 450 knots - Extremely Hazardous(serious injury highly probable). Usually, there will be enough time to do several thingsto preparefor a successfulejectionprior to pulling the seat firing handle. However, when the emergency condition requiring ejection is such that ejection must bemadewithout hesitation,simply graspthe handleand pull forcibly to the West extent until the seatejects.If the seat fails to eject, immediately pull again. If the handlewill not move, ensurethat the ground safetypin hasbeenremoved and that the ARMED/SAFE handle is at ARMED beforetrying again.Ejection throughthe canopy is an automatic backup. There is no provision for manual bailout.
l
7.
Properbody position is a critical factor in preventingejection injuries.
Assumeproperejectionposition(seeFigure W-2). a. Headpressedback againstheadrest. b. Chin slightly elevated(10’ up). c. Back straight. d. Hips againstseatback. e. Thighs flat on seatsurvival kit. f. Outsideof thighs pressedagainstside of seat.
16.1.2 Ejection Preparation g. Elbows and arms pressedfirmly againstbody. h. Feeton rudderpedals,heelson deck.
pi&-) Never pull the manual override handle before ejection. Pulling the handlereleasesthe crewmember from the seat and moves the ARMED/SAFE handle to SAFE, making it impossible to initiate ejection from the seat. Further, if ejection is initiated by the other crewmember,results could be fatal. Time permitting, perform all or as much as possible of the following: 1. Place aircraft in safe envelope and attitude for ejection. 2. Warn othercrewmember. 3. EJECT CMD lever 4. IFF/SIF -
EMERG/
5. Position report -
Select (RIO). (RIO).
i. Visor down, oxygen mask tightened,helmet secure. 16.1.3 Ejection Initiation. ejection initiation.
See Figure 16-3 . ,r
After the seattiring handleis pulled: 1. The harnessretraction unit retractsthe shoulder harnesspulling theoccupantto anuprightposition. The leg gartersareretractedas the seatmoves up the rail. 2. Ejection through the canopy is a backup method only; therefore,canopyis jettisoned aspart ofnorma1ejection sequence.Ejection through the canopy or out of the aircraft occursafter a delayifthe normal sequencefails. 3. Seatseject individually and in oppositedirections (pilot right, RIO left).
Transmit. 16.2 MANUAL BAILOUT
6. Check altimeter. pih-) a Positioning the legs aft prior to ejection will causethe spine to flex and will increasethepossibility of spinal injury, and will also increaselikelihood of seat/thigh slapwith attendantleg injury.
There is no provision for manual bailout. Ejection throughthecanopyis anautomaticbackupifthe canopy fails to jettison or the safeand arm unit fails to fire. 16.3 SURVIVAUPOSTEJECTION PROCEDURES Figure 16-4describesstep-by-stepproceduresfor inflation of the LPA configuredwith beadedhandlesand the 35-gramCO2 cylinder.
PROPER
BODY
POSITION
Figure 16-2. ProperEjection Position
Figure 16-3. Ejection Initiation
16-6
lMMEDlATELY FOLLOWlNG OPENlNG SHOCK. CHECK CONDlTlON OF PARACHUTE. IF THERE IS NO DAMAGE, MALF”NCTlON.
3.
PULL BEADED HANDLES DOWN A, STRAIGHT OUTTO INFLATE.
NAVAIR 01.F’I4AAD-l
Note LPA inflation may not be desirable over land. Theparagraphsthat follow provide proceduresapplicable to the NACES seat. Additional post-ejection/ survival proceduresare to be found in the NATOPS Survival Manual, NAVAIR OO-SOT-101. phiiEjection at low altitude allows only amatter of secondsto preparefor landing.Over water, inflation of the LPA is the most important step to be accomplished. Release of the parachutequick-releaseflttings as the feet contact the water is the secondmost important stepto prevententanglement in the parachute shroud lines.
l
Q When ejectionis in the immediatevicinity of the carrier, parachute entanglement combined with wake and associatedturbulencecan rapidly pull a survivor under. The deployed seat survival kit may contribute to shroud-line entanglement.The survivor must be preparedto cut shroud lines that are dragginghim down. l
The crashed aircraft may release large quantitiesofjet fuel and fumes that could hamperbreathingandcreatea tire hazard if smoke or flare marker is present.The emergencyoxygensystemmay be invaluable in this caseand discarding the seat panwould terminateits use.However, totally discarding the seatpan may be appropriate after considering weather, sea conditions,and rescuepotential. Note The variety andcomplexity ofconditions encountered during the time-critical movements following a low-altitude, overwater ejectionmake it impossibleto formulateproceduresto cover every contingency.
16.3.1 Manual Man/Seat Separation. If below 14,000feet and man/seatseparationhave not occurred,the procedurewill haveto be initialed manually. Locate the manual override handleon the right side of the seatbucket, depressthe handle releasebutton and
pull handlesharplyupward asfar aspossible.This fues a cartridgeto activatethe parachutedeploymentrocket andreleasethe upperand lower harnesslocks. Man/seat separationoccurs when the main parachute is extracted and deployed. 16.3.2 Survival Kit Deployment Note Survival kit deploymentis not recommended in an overlandejection situation.The kit can be openedafter landing by removing the closurepins from the cones. With either hand, locate one of the deploymenthandles at the rearof the seatkit. Firmly pull on the handle until it is free of the kit and the survival packagefalls away on its dropline. The packageremains attachedto the kit lid by the dropline. At fall dropline stretch,the liferatl is inflated automatically. 16.3.3 Parachute Steering. A gentle pull of approximately 6 inches on the 1eAor right steeringline (attachedto the riser) will rotatethe canopy to enable steering.Pulling on the left line steersleft. The canopy will continue to rotate for a time after the steeringline is released,so it is necessaryto compensatefor this lag by releasingthesteeringline beforethe desireddirection is reached. 16.3.4 Parachute Landing Preparation. Preparationsover land and over water are essentially the same except that over land the visor should be kept down, the gloves worn, and the survival kit should not be deployed. In low-level, overwater situations, the mask and regulator should be retainedsince they provide an underwaterbreathingcapability. If thereis time beforea water landing, the glovesmay be removedand stowed safely. This may make it easierto operatethe canopy releases. Try to determine the direction of the wind at the surfaceusing white caps,smoke from the wreckage,or known surfacewinds in the vicinity. Nom that surface winds may be quite different from those at altitude. When nearing the surface, steer into the wind and assumethe properbody position for landing: 1. Feet together, knees slightly bent, toes pointed slightly downward. 2. Eyes on the horizon. 3. Grasp canopy risers and tuck elbows in prior to water entry.
NAVAIR Ol-Fl4MD-1
4. On water entry, releasethe canopy manually. The SEWARS releaseswill operatethe canopyrelease fittings on saltwaterentry as a backup. 16.3.6 Raft Boarding
l
l
Note If the life& has not inflated automatically, pull on the red operatinghandleon the dropline to inflate. If the survival packagehas not been deployed before water entry, first pull the yellow deployment handle then the red operatinghandle.
Whenclearofthe canopy,retrievetherat?by locating thedroplineandpulling theraft to you. The raft retaining lanyardis in a pocket next to the CO2 cylinder. Attach
the end of the lanyard securely to the gatedhelo hoist ring on the harness,then ensurethat the oxygenhoseis disconnectedfrom the kit lid and releasethe laphelt quick-releasefittings, releasingthe kit lid. Bring theraft aroundfor entry from the small end (stem); grasp the stem, and forcibly push under LPA waist lobes. Using the boardinghandles,pull into the raft and turn into a comfortable, balanced, seated position. Locate the dropline andretrieve the survival package.
Do not attempt to retrieve the kit lid. Any attempt to do so could capsizethe raft. Close the canopy and orally inflate the canopy and floor. An integral baler is provided to bale the raft as necessary.
16-9 (Reverse Blank)
NAVAIR 0%F14AAD-1
PART VI
All-Weather
Operations
chapter 17 - Instnlment Procedures Chapter IS-Extreme
Weather
85 (ReverseBlat&
ORIGINAL
NAVAIR Ol-F14AAD-1
CHAPTER
Instrument
17
Procedures
17.1 AUTOMATIC CARRIER LANDING SYSTEM
pendentglideslope error signals from the AlWSPN-41 instrumentlanding system may also be displayed.The pilot may take control at any time and continue the landing via Mode II.
ACLS approachesapply to properly configured aircraft utilizing carrier or shore-basedAN/SPN-10 or AN/SPN-42 ACLS radar facilities. Three primary modesof operationand two submodesare available.
17.12 Mode II. The control of the aircraft remains with the pilot along the entire glideslopeto touchdown. Glideslope error signals are transmitted to the aircraft for cockpit displays from the ANBPN-41 or the AN/SPN-42. The pilot flies the aircmtl to null the error andto keep the vertical and lateral crosshairscentered. During a Mode II T approach,the final controller provides a Mode III-type talkdown to assist the pilot in flying his needlesor for controller tmining.
1. Mode I approach automatically controlled to touchdown 2. Mode IA approachautomatically controlled to a minimum of 200 feet and one-half mile; manual control remainderof approach
17.1.3 Mode Ill. The pilot flies the aircraft in responseto voice radio commandsfrom the final controller to keep the aircraft on the proper glideslope.From the radarazimuth and elevation displays,the final controller determinesthe aircrafiposition withrespectto the desiredglidepath and gives guidanceto the pilot.
3. Mode II approach manually controlled using ANBPN-41 or AN/SPN-42 vertical display indicator and/or heads-up display presentation for glideslopeand lineup information 4. Mode III approach manually controlled using only CCA-controller-supplied information 5. Flight director approachmanually controlled using HUD flight directorpresentationderived from AN/SPN42/46 information and navigation system data for glidepathinterceptand following. 17.1.1 Mode I. Mode 1 provides a fully automatic, hands-off landing capability, called automatic carrier landing or all-weather landing. The landing radarsystem (AlVSPN-42) tracks the aircraft and comparesits position with the desiredposition. The aircraft position is correctedto fly the desired glidepath by commands t?omthe naval tactical datasystemusing the radarcomputer. These commandsare transmitted over the UHP datalink to the aircraft, wherethe automatic flight control systemexecutesthe pitch andbank commands.Additional ramp input commandstailored to eachspecific ship or field are applied at the proper time to assistthe aircraft throughthe burble. In addition to control of the aircraft, discretewords and glideslopeerror signals are transmittedfor cockpit displays to show the pilot where his aircraft is in relation to the desiredglideslope.Inde17-l
17.1.4 Flight Director. The pilot flies the aircraftso that the FPM stays inside the flight director symbol on the HUD. The flight director symbol provides glideslope and centerline steering information computed by the mission computer using navigation system parameters and data-link information from the SPN-42/46 ACLS system.The box with the threedots provides the pilot with optimal glidepath intercept and following when the flightpath marker is inside the flight director box and the three dots are aligned with the wings and the tail of the flightpath marker. The horizontal deviation of the flight director symbol from the FPM representsthe error between the commanded and actual bank angle. The. vertical deviation representsthe error between the commanded vertical rate. The flight director symbol also rotatesan amount corresponding to the error between the bank command and the bank attitude to give an indication of the size of the bank correction required (primarily usefirl for following large bank commands during centerline captures).The vertical deviation is scaledon theHUD ORIGINAL
NAVAIR 0%Fl4AAD-1
beenselected(in this case,ACL), but not engaged.The pilot engagesACL through the referenceengageswitch on the stick grip, at which time the A/P REF advisory goesout.
so that it gives an indication of the vertical flightpath angle correction required. 17.2 AIRCRAFT SUBSYSTEMS
Note If a pitch parallel actuatorforce link disconnect occurs prior to an ACLS approach,the A/P REF advisorymay goout whencoupling is attempted,but the aircraft will not respond to SPN-42 commands and the aircraft will uncouplewhen the first pitch commandsare received.
Mode I (automatic) landings arepossible only if the ACLS installation, including data link, AFCS, radar beacon and augmentor, inertial navigation system, and ACLS displays (MFD and/or HUD) are all fully operational. The approachpower compensatorshould be used during the coupled portion of the approach. Mode II (manual) landings can be made using displayed crosspointer information from either the data link or the AN/ARA-63 receiver decoder, or both (providing dual displays). 17.2.1 Data Link. Data-link (link 4A) messagesare receivedandtransmittedby aUHF frequency-shift-keymodulated radio link. Data link receives control messagesin serial form from the NTDS andprocesseseach messageas necessary.For ACL, the position error information is furnished to the MFD and/or HUD ACL steeringindicator, discretemessagesappearon MFDs 1 and3, andcontrol information is providedfor the AFCS. Reply messagesare transmitted to the NTDS with detailed information on aircraft heading, speed,altitude, Ihe1quantity, weapons,stores,and autopilot status. The shipboarddatalink continuouslytransmitsa universal test message and a monitor control message. When in operation,the UTM or MCM is used by the aircraft asa self-test feature.The aircraft data-link system self-testis performedby selectingAWL steeringon the MFD. Only the pilot can deselectAWL steering from the MFD VDI format once selected.
Following ACL engagement,the pilot can take control of the aircraft by simply overriding the data-link commandswith his control stick. This causesimmediate disengagement, and the AFCS will again revert to STAB AUG. Refer to paragraph2.24.4.7, Automatic Carrier Landing, for further information on ACL. 17.2.3 Radar Beacon (ANIAPN-164). The radar beaconenhancesaircraft tracking (rangeand accuracy) by ship and/orground-basedI-bandradarsfor precision vectoring.Pulsed(coded) I-bandsignals transmittedby the surfaceradarstation arereceivedby the beaconand decoded;if they match the mode (six available)selected by the RIO, the beaconrespondswith a return pulse to the radar site. The reply signal, considerably stronger thana normal radarecho,enhancesthe radaracquisition and tracking capability of the surfacestation.
Note AWL steering is only available in the TLN mode. In A/A and A/G, the AWL pushbutton selection on the MFD VDI format is removed. 17.2.2 Automatic Flight Control System. The AFCS performs two functions: stability augmentation and autopilot. Stability augmentation(STAB AUG) providesadded stability to the aircraft and is, in general,necessaryfor effective aircraft control. The autopilot ACL mode can be engagedonly after engagingall STAB AUG axes and then by placing the AUTO PILOT ENGAGE switch in ON. Selection of ACL on the AFCS control panel arms the mode and displays the A/P REF advisory on the pilot MFD No. 1. A/P REF indicates that an AFCS pilot relief mode has ORIGINAL
17-2
17.2.4 ACLS Beacon Augmentor (R-1623). The beaconaugmentoris a crossbandreceiver that extends the tracking capability of the ANISPN-42 shipboardradar with the capability of operatingwith either or both channelsof the AN/SPN-42 without interference. The beaconaugmentoreliminates radarscintillation by providing a large sourceof reply energy from one point on the aircraft. The beacon augmentorreceives interrogationsfrom the AN/SPN42 carrier-basedradar in the Ka-bandat 33.0 to 33.4GHz, processesthem, and retransmitsmodulated I-band pulsesat 8.8 to 9.5 GHx to the AN/SPN-42, which has an I-band receiving system mounted contiguous with the basic Ka-bandradar transmittingantenna.The uniquefeatureof theaugmentor is that it usesthe AN/APN- 154beaconas its I-band transmitter.This is accomplishedby coupling theoutput of the augmentorto the AN/APN-154 and triggering its modulator and transmitter. During the landing phase,it is necessaryto manually place the radarbeaconMODE switch to ACLS. In this mode, the AN/APN-154 receiver is disabledto ensurethatI-bandsignalsin thearea will not trigger the AN/APN-154 transmitter during landing.
NAVAIR 0%Pl4AAD-1
17.2.4.1 Beacon Controls. The RADAR BEACON panel (Figure 17-1) is on the RIO right console. POWER or STBY can be used for radarbeaconwarmup; to precluderesponseto a prematureor unintentional interrogation,the STBY (ACLS not selected)position shouldbe used. There are no cockpit displays for the beacon, althoughthe ACLS TEST button will be illuminated ifthe beaconis respondingduring an ACLS approach.Aselfcheck of the beaconACLS mode is accomplished by depressingthe ACLS TEST or performing anon-board check. Either of thesetwo use the receiver video processingcircuits of the augmentorin the same manneras a Ka-band input from the ANKPN-42. If operationof thereceiveris normal, theACLS TEST pushbuttonlight on theRADAR BEACON panelwill illuminate. A BAG acronym will be displayed when performing an OBC andintheeventofabeaconaugmentorfaihue. Theradar beaconhasa minimum warmup time of 5 minutes.During this time, failure indications will be displayed and self-test results should be regardedas inconclusive A NO GO light during OBC shouldbeverified by depressing the ACLS TEST pushbutton.If the ACLS test light illuminates, the system is functioning regardlessof the NO GO light indication. [,,,,,,,I If the aircraft is parkedon the flight deck at? of the island, the radar beaconshould be in either OFF or STBY with ACLS not selected. With ACLS selected,stray energy can trigger beacon responseand may seriously degradeperformanceor precludelockon of aircraft attemptingACLS approaches. After shipboardarrestmentand upon clearing the landing area,the radarbeaconpower switch should be turned to OFF to prevent possible beacon signal interference with other aircraft.
functioning APC shouldhold theaircraft on-speedM.5 unit throughoutthemajority ofthe approach.At tipover, the aircraft may accelerateto asmuch astwo units faster but should correct to on-speedwithin 5 seconds.The APC shouldbe checkedfor satisfactoryoperationprior to coupling. If the performanceof the APC does not meet the abovecriteria, the approachshouldbe downgradedto Mode II. 17.2.6 ACLWILS Displays (MFD and HUD). ACLS and instrumentlanding systemsteeringinformation can be displayedon any MFD and the HUD (Figure 17-Z). When the AWL pushbuttonis depressed,final determination of the display submodeis governedby the HUD andMFD pushbuttonson the MFD when in AWL steering, which provide for separateILS andACLS selection for both the HUD and MFD VDI format. This enables any mix of ILS (ANN/SPN-41/AN/ARA-63), ACL (AN/SPN-42/data link), or no displays at the pilot’s option. The ILS andACL displaysdiffer in thatthe ILS errors are displayed by needlesand the ACL errors are displayedwith the ACL steeringindicator.The ACL steering indicator (Figure 17-2) represents where the intersectionof ACL needleswould be ifpresented.Azimuth and glideslope deviation are representedby the relationship of the velocity vector to the needles/ACL steering indicator. Two different means of displaying ILS and ACL steering are used to allow the option of displaying both sourcesof information simultaneously on either display (MFD or HUD). Both displays in the ACL mode display a command headingmarker. This marker, during AN/SPN-42 approaches,indicates final bearing.
Note Do not depressthe ACLS TEST pushbutton aftercoupling on aMode I approachasit will causethe groundstation to breaklock.
The ILS steering displays approachinformation in the form of precision coursevectors. A vertical vector is used for azimuth steeringwhile the horizontal vector is for elevation. The pair form a crosspointerand are displayedon the HUD and MI presentationssimultaneously. Full-scale deflection limits of the HUD and VDI vector symbols are2’ and 1.5inches,respectively. The vectors are limited to this deflection to ensurethe displayedsymbol will always havean intersection.Full scaledeflectionlimits correspondto 6” of lateral deviation from centerlineand 1.4’ of vertical deviation from glideslope.
17.2.5 Approach Power Compensator Performance. For successful Mode I and Mode IA ACLS approaches,it is essentialthat the APC be functioning satisfactorily. Sluggish APC performanceor its inability to maintain on-speedaccuratelyduring the approachwill result in degradedcontrol on the glideslope and unacceptabletouchdown dispersion. A properly
The ACL submodeusesthe ACL steeringindicator that is driven by the datalink insteadofthe AN/ARA-63 receiver decoder. Any combination of ILS needles, ACL steering indicator, or neither is available for the HUD or VDI presentations.Selection of each is controlled by the pushbuttonscontainedon the MFD once AWL steeringis selected.
17-3
ORIGINAL
NAVAIR
01.Fl4AAD-1
NOMENCLATURE a
MODE switch
SINGLE -
Limits beacon response to single pulse of any code group received.
DOUBLE -
Beacon response set to one of ftve double-pulse Intenogatlons.
ACLS -
Enables augmentor operatlon. piiiz-WARNINO( ACLS shall not be selected on the flight deck when the power switch Is In STBY or PWR, or during the 5-minute beacon warm up period.
0
ACLS TEST PUSH Ilghtlpushbutton
On (green) - Indicates a ANI.SPN-42 lockon In ACLS mode; when pressed with radar beacon mode selector In ACLS, indicates a satisfactory self-test of ACLS mode only. Flashing -
Indicates ANISPN-42 locked on.
Is sweeping through alrcraft but has not
lntermlttent (or no Ilght) - During self-test Indicates a fault In the ACLS mode only.
Figure 17-I. RadarBeaconPanel (Sheet 1 of 2)
ORIGINAL
17-4
NAVAIR NOMENCLATURE 0
Power switch
01-F14AAD.1
FUNCTION PWR -
With radar beacon mode selector in ACLS, enables l-band replies to Ka-band interrogations.
STBY -
Used tar warmup with radar beacon MODE switch in SINGLE or DOUBLE. Note The beacon will warm up with the switch in either posltlon STBY or PWR. To prohibit response to premature or unintentional Intenogations, warmup should be accomplished in STBY For optimum performance allow 5-minute warmup.
OFF -
Turns off all power to radar beacon.
Figure 17-l. RadarBeaconPanel (Sheet2 of 2) Additionally, certain ACLS commands that are uplinked to aircraft via the data-link system are displayedto both aircrew on MFD No. 1 and No. 3. Note For more detailed information on the data link symbology, refer to NAVAIR OlFl4AAD-IA. The ACLS andILS systemsprovide angularsituation information (ILS needlesand ACLS tadpole) of glidepath errorsthat requiresthe pilot to determinethe corrections neededto eliminate those errors, resulting in higher workload and possible degradedapproachperformance(overshootsandoscillations).The flight director display provides the optimum glidepath steering information (ascomputedby the mission computer using navigation system parametersand data-link information from the SPN-42/46ACLS system) to intercept andfollow the glideslopeandcenterline,which reduces pilot workload and improves approachperformance. The flight directorsymbol canbe selectedfor display on the HUD by boxing the FLT DIR pushbuttonon thepilot AWL VDI MPD format. 17.2.7 Instrument Landing System (ANIARA-63). The aircraft ILS usesthe AN/ARA-63 receiverdecoder to process ANElPN-41 confirmation. This system is usedfor manual instrumentlanding approachesor asan independentmonitor during final approach with the
17-5
ACLS. TheAN/ARA-63 decoderpanel(Figure17-3)is locatedon the pilot right-side outboardconsole. The aircraft systemreceivesand decodesglideslope azimuth and elevation signals that are convertedinto command fly-to indications in the ClU and displayed via VDI and/orHUD in the TLN mode (Figure 17-2).If the ILS or ACL landing submodesselectedon the pilot display control panel becomesinvalid, the invalid submodesymbology will be removed.A computermessage informing the aircrew which submodebecameinvalid will be postedon MFD No. 1 andNo. 3. As a backupto the display subsystem,ILS steeringindicationsam also displayeddirectly on thepilot standbyattitudeindicator vertical andhorizontal needles. Note
The ILS has a minimum warmup time of 1 minute. During this time, a failure indication shouldbe disregarded. The ILS performs a self-test when the BIT pushbutton on AN/ARA-63 decoder panel is depressedand held. Responseto the ILS self-testis displayed,providing ILS or BOTH is selectedon HUD and MFD. The correctILS landing mode display on the HUD andMI display during system checkoutshowsthe vertical pmcision coursevector symbol slowly oscillating on the right side of the display, then on the left side. The horizontal precision coursevector symbol remainsstationary in the centerof the display.
ORIGINAL
NAVAIR 0%Fl4AAD-1
L
(AT)&F50D-343-0
NOMENCIATURE
FUNCTION
! HUD Symbology
-TLN Gear Up Basic Format
0
Command Marker
0
ILS Precision Course Vectors
Consists of two independent vectors (vertical and horizontal) that form a cross pointer. The horizontal vector responds to ILS glide slope error and the vertical vector responds to ILS localizer error. Null/center indications are provided to enable the pilot to null the error and keep the vertical and horizontal needles centered.
ACLS Tadpole
Provides ACL Steering commands
Waveoff
A large “x” will appear flashing in the center of the display to indicate a waveoff.
g~;yg”dding
Indicates the selection of AWL Steering.
Tacan Range
Indicates distance to the tacan station.
0 @ @
@
Heading
indicates ACL data link final bearing. Where final bearing is beyond display scale limits the marker will be pegged at the edge nearest to the final bearing.
driven by the SPN-42
Figure 17-2. ACLWLS Steering(Sheet 1 of 3)
17-6
data link.
NAVAIR
NOMENCLATURE
0%F14AAD-1
FUNCTION
I VDI Symbology
-AWL Steering Mode
0
Command Marker
0
ILS Precision Course Vector
Consists of two independent vectors (vertical and horizontal) that form a cross pointer. The horizontal vector responds to ILS glide slops error and the vertical vector responds to ILS localizer error. Null/center indications are provided to enable the pilot to null the error and keep the vertical and horizontal needles centered.
0
ACL Steering Indicator
Provides ACL Steering commands
Waveoff
During carrier landings, a large “x” will appear flashing in the center of the display to indicate a waveoff.
@
Heading
Positioned relative to the magnetic heading scale to indicate ACL data link final bearing. Where final bearing is beyond display scale limits, the marker will be pegged at the edge nears& to the final bearing.
driven by the SPN-42
data link.
Figure 17-2. ACLSiILS Steering(Sheet2 of 3)
17-7
ORIGINAL
NAVAIR gl-F14AAD-I FUNCTION
NOMENCLATURE @
The flight director symbol provides glide slope and centerline steering information computed by the mission computer using navigation system parameters and Data Link information from the SPN-42/46 ACLS system. The flight director provides the pilot with optimal glide path intercept and following when the flight path marker is inside the flight director box and the three dots are aligned with the wings and the tail of the flight path marker. The same procedures are used whether the flight path marker is caged or uncaged. The flight director symbol is removed from the HUD when the FLT DIR pushbutton on the VDI is unboxed. The pushbutton is removed from the VDI if the Flight director is not available for display (for example, a/c vector or ACL data link mode is not selected).
Flight Director
Permits option to display AWL (both ACL and ILS), ACL, ILS or NO STEERING information on the MFD. Initial selection of the AWL steering mode on the basic VDI format displays both ACL and ILS steering information on the MFD. This will be indicated by AWL in the box adjacent to the MFD legend. Successive depression of the pushbutton cycles AWL, ACL, ILS and NO STEERING information on the MFD in that order. Permits option to display AWL (both ACL and ILS), ACL, ILS, or NO STEERING information on the HUD. Initial selection of the AWL steering mode on the basic VDI format displays both ACL and ILS steering information on the HUD. This will be indicated by AWL in the box adjacent to the HUD legend. Successive depression of the pushbutton cycles AWL, ACL, ILS, and NO STEERING information on the HUD in that order. Note The RIO is inhibited from deselecting once selected from any MFD.
AWL steering
Figure 17-2. ACLSfiLS Steering(Sheet3 of 3) 17.3 SURFACE SUBSYSTEMS 17.3.1 Automatic Landing System (ANK3PN-42). The ANISPN-42 radar uses a conically scanning antennabeam of Ka-band energy,which is receivedat the aircraft in diit proportion to its position within the antennacoveragearea. This microwave energy is received as amplitude modulation of the pulsed carrier and, by meansof the beaconaugmentor,the AM is put on the I-bandbeaconfor retransmissionback to the ship as an active radar signal. The AM on this retransmitted signal is thereforeidentical to the AM received at the aircraft. By relating the amplitude of the returnedsignal to the ANjSPN-42 antennaposition within its conical scanningarea,the system knows the exact location of thb aircraft in relation to the axis of the conical scan, which is thedesiredglidepath.From this information,the system LXUgeneratecorrectionsto bring theaircraftto the d&i glidepath.Additional rampinputpitch commands, td~red to eachspecificship or field by theNaval Air Test Canter during Mode I certification, are applied at the propertime to assisttheaircraftthroughtheburble. ORIGINAL
17-8
To satisfy the system capability and landing-raterequirements,the shipboard subsystem landing control central AN/SPN-42 has a dual-channelconfiguration. This provides increasedsystem reliability through rcdundancy.At full operationalcapability, both channels are in use, controlling two aircrafi on the glideslopeat the same time. Two aircrafi are normally spacedapproximately 60 secondsapart along the glideslope. In addition, the three operating modes act as backupsfor eachother should partial system failure occur. 17.3.2 Instrument Landing System (ANk3PN-41). The aircraft ILS usescarrier or shore-basedANISPN-41 (C-scan) transmitters. The system operatesin the Kband, between 15.4 and 15.7 GHz, on any of 20 channels. The transmitted azimuth signal produces a 2” beam,which is scanned+20” from the deck centerline. The transmittedelevation signal producesa 1.3’ beam with a scanpatternfrom 0” to 10’ abovethe horizon. A proportionalazimuth angle for steeringis 6’ right or left of centerline;proportional elevation angle for steering is 1.4” from the referenceglideslope(aboveor below).
NAVAIR QT.F14AAD-1
NOAllENCLATURE 0
CHANNELselector
FUNCTION l’wnty possible channelselectionsby rotation of selector knob.
0
Bri PRESS-to-test bulton
Depresslngbuttonactivates BTTtest circuitry. Landlngsymbols available on HUD ariaor MI lf AWL oi ILS display option is selected, and on pilot’s standby attitudeIndicator.
0
POWERswitch (lock-lever)
ON-
Activates receiverdecoderfor all-weather carrierlandlng.
OFF -
mrns system off. Lock-lever switch must be lifted to OFF.
@
Ughts when ANIARA-63 Is on. lndlcatorIlgM QlgMIs removedwlth AVC 2460)
Figure 17-3. ANIARA-63
17-9
Decoder Panel
ORIGINAL
NAVAIR gl-Pl4AAD-1
Gpemting rangeis approximately20 nauticalmiles. The signal is transmitted in J-bandon a carrier frequencyof 15.4to 15.7 GHx. The AN/SPN-~~ can be usedto guide the pilot to the window of the AN/SPN42 radar for an ACL Mode I approachand as an independentglideslopeand azimuth displayduringaModeIapproach.ShouldtheAN/SPN-42 radarsystem fail, the ANEPN-41 canbe usedfor Mode II approaches.
2. Tacan 3. AWL. All are directly selectableon the VDI format of the MPD. Switching between submodesrequiresa choice betweenDATA LINK, TACAN, and AWL steering.If a submodeselectedbecomesinvalid, the steeringinformation will cease.The oilothas the oution of reaelectinn will also info& thd &crew of invalid~s&ing
17.4 ACLS PROCSDURES The succe.ssfuIcompletion of a Mode I or Mode IA ACLS approachis dependenton theproperperformance and complex interaction of a variety of shipboardand aircmfl systems.It is the responsibility of the aircrew to verify that all ACLS-related aircratl systems are fimctioning properly andthatproperproceduresarefollowed in order to ensurea safe coupled approach. 17.4.1 Preflight. During the exterior preflight, the aircrew should ensurethat both beaconantennasarc in good repair and not painted. The receive antennais located on the lower starboard fuselagejust aft of the radome and is mounted flush with the fuselage. The transmit antennais a blade antennalocated on the aft portion of the chin dome (IKTV pod). Poor condition of these antennaswill seriously degradebeaconperformanceandwill result in degradedtracking capability by the ANEPN-42 system. 17.4.2 Poststart Checks. Following start, the aircrew should verify proper operationof the beaconand data-link systemsalongwith associatedlights and advisories and indications by performing the prescribed built-in tests. In addition, the pitch parallel actuator should be checked during OBC to make sure that the force link is not totally or partially disconnected.If any of thesesystemsarenot functioning properly, a coupled approachwill not be possible. 17.4.3 Approach Phase. In ACL, the purposeof the approachphaseis to getthe aircraft to theacquisition window (Figure 174). At the marshalingarea,some20 miles asternof the carrier, the abaft about to land are stackedaccording to fuel statusand other relevantparameters that determine landing priority, the ILS (AN/AKA-63) systemis energized,andthe properchannel and displays are selected.The pilot, in concurrence with the controller,hasthe option ofchoosing from three display submodesto aid him in reaching the radar acquisition window: 1. Data-link vector
ORIGINAL
During the letdown from marshaling,an ANEPN-42 channelis assignedto the aircratl and a computer program of aircraft control parametersis selected.A datalink discrete message (the first of a series to be transmitted),LANDING CHBCK, is sentto the aircraft to initiate communicationswith CATCC andto indicate. to thepilot that anANjSPN-42 channelis available.The aircraftwill usually alreadybe in a landingconfiguration upon receiptof LANDING CHECK. 17.4.3.1 Data-Link Vector Approach. When DATA LINK is selected,theDiL vector display is added to the basic landing display. Command headingrelative to theheadingtaneis addedto the HUD andVID disolav and iefi side of the MI display. Data-link vector information is available only for the approachphase(i.e., to theradaracquisition window). When the aircraft is vectored (D/L vector commands) to the acquisition window, the pilot hasto make a new submodeselectionfor the descentphase.This is not the case with the tacan submode,as tacan information is available throughout landing, from marshalingto touchdown. 17.4.3.2 Tacan Approach. The course deviation indicator is used for tacandeviation along with a manually set command heading indicator on both the HUD andVDI display. 17.4.3.3 AWL Approach. ILS information from the ANEPN-41 is available during both the approach anddescentphase.SelectionofAWLontheVDIdisplay enablesvertical and lateral glideslope enor display. Final determinationof the AWL&CD mode is governed by the ILS/ACL selection,which provides for separate HUD and VDI selection. Additionally, the pilot may independentlyselectHUD flight director for display by boxing the FLT DIR pushbuttonon the AWL MI. The normal ACLS approachmode will display the ACL tadpolesituation information, theILS needlessituation information, and the ACL flight director steering information on the HUD. If the pilot intendsto make a Mode I approach,he must advisethe ground controller
17-10
NAVAIR 01.F14AAD-1
BEFORE REACHING 6-MlLE DME FIX MARSHAL 1. ARAa3 SET 2. Plum DISPLAY CONTROL PANEL a. MODE . . ,... ., TLN b. HUDDECLUTTER NORM c. WDAWL AWL d. “DIMODE .,..,.,....... AWL
4. AFCS STAB AM a, PITCH Il. ROLL c. YAW
3. APN-la4 1. MODE awITCH.. .NOT ACLS b. POWER SWITCH .STBY c. ALLOW 6 MINUTE WARM. UP PERIOD. d. POWER SWITCN STBY OR PWR I). MODE awITCH.. .ACLS
\ v-
&MILE
DEPARTING MARSHAL 1. DESCENT AT 4.000 ‘thin KNOTS 2. REPORT: a MODEX b. COMMENCINO c. STATE
ON ON ON
PLATFORM 5.000 FEET 1. SLOW DESCENT TO 2,000 ft,min 2. AlRSPEED 250 KNOTS 3. REPORT: a. MODEX b. PLATFORM IO-MILE DME FIX 1,200 FEET 1. AFT-154 STaYORPWR 2. REPORT: 8. MODEX b. I&MILE GATE 3. TRANSlTlON TO LANDING CONFlG
AND 250
DME FIX 1,200 FEET
CCCENGAGED AFCSAND ALTITVDE HOLD
ACQUISITION
WINDOW
FINAL REPORT FEET--112MILE REPORT: “SIDE NUMBER COMMANDCONTROL”
170° RADIAL
’
\ La*
I,““”
I-CSI
TOUCHDOWN
-?!A
170° RADIAL \
TOUCHDOWN
BDLTRl?tWAVRDFF
1. APC DISENGAGES AUTOMATICALLY. 2. SELECT MRT BOTH THROTTLES AND RETRACT SPEEDBRAKES. 3. ANTlClPATE BOLTER.
PROCERDASINCU CAaR Ill Pm-raw.
Figure 17-4. ACLS Mode I and II Approaches ORIGINAL
NAVAIR Ql-F14AAD-1
ofhis intentions.The groundcontroller will thendisable the flight director commands and enablethe autopilot commands. Until this is done, the pilot will not have the capability to couple the autopilot to the ACLS commands. The only information that is displayed on the HUD during Mode I approachesis theACLS tadpole situation information and the ILS needles situation information.
The landing system (CATCC) (Figure 174) generatesa coupteravailabrediscretethat illuminates the A/P CPLR advisoryandindicatesthatthepilot hasthe option of coupling the AFCS to data-link commandsof pitch andbank.At this time, theaircraft shouldbe in alanding configurationwith APC, DLC, AFCS, andaltitudehold engaged. Note TheradarshouldbeinSTY orPULSEsearch to avoid beaconinterferenceproblems.
17.4.4 Landing Phase. As theaircraft continuesits approachand passesthrough the 4-nm ACLS radaracquisition window, a smooth transition, not requiring pilot action, occurs. If tacan information has previously been selected(for the approachphase),the pilot could use this information to land. Assume, however, that AWL. has been selected,ILS and ACL information is being displayed on the HUD and VDI. At the radaracquisition window, the AIKSPN-42 radar acquiresthe aircrag with the aid of the airborneradar beaconaugmentor,and the system automatically sends a discrete indicating radar lock-on that illuminates the ACL READY advisory. Transmission of vertical and lateral glidepath errors and flight director commands, derived by the AN/SPN42/46 radar, commences.The glidepath error signals drive the ACL tadpole on the VDI andHUD. The flight directorsymbol is selectedfor display by boxing the FLT DIR pushbuttonon the AWL VDI MFD format. ‘Ihe flight director display information is computedby the mission computer usingnavigation system parameters and data-link information, if desired.If the pilot intendsto make a Mode I approach, he must advise the ground controller of his intentions. The groundcontroller will then disablethe flight directorcommandsandenablethe autopilotcommands.Until this is done, the pilot will not have the capability to couple the autopilot to the ACLS commands.The only information that is displayed on the HUD during Mode I approachesis the ACLS tadpolesituation information and the ILS needlessituation information. The HUD and VDI symbology has thus beendetermined for the landing phaseand no further pilot selection is required (unless a system malfunction occurs). The mode of operationfor this phaseof the landing is a function of the type of equipment used. In particular, there are thnx modes of landing applicable: Mode I, Mode II, and Mode III. 17.4.4.1 Mode I Landing Sequence Note Refer to paragraph2.24.4.7,Automatic Carrier Landing (ACL), for further information on ACL. ORIGINAL
The AFCS should be armed in the ACL relief mode with the A/P REF advisory on, indicating that a pilot reliefmode (in this case,ACL) hasbeenselectedbut not engaged.The pilot can couplethe AFCS to the datalink by meansof the autopilot engagebutton on his control stick, at which time, ifthe AFCS is functioningproperly andthe ACL interlock is true, the AP REF advisorywill go out. The pilot should report coupled; at which time, the controllerwill senda discretecommandcontrolmessagethat illuminates the CMD CONTROL advisory. The NTDS begins transmitting data-link and pitch and bank commandsto the aircraft. The autopilot (AFCS) actuatesthe appropriatecontrol surfaceto executethe desiredcommand, while the autothrottle(APC) maintains approachangleof attackby controlling thethrottle setting. Wheneverthe aircrafi exceedsthe Mode I flightpath control envelope,the system automatically sendsa signal to uncouple the AFCS (A/P CPLR advisory goes out). The approachmay be continued in Mode II or Mode III. If the flightpath error increasesto the point wherea largemaneuveris requiredto bring the aircraft back on course,the controller will senda waveoff messagethat is displayedon the HUD andVDI andturnson the WAVEOFF advisory. This discretealsodisconnects the autopilot (if engaged)and the AFCS revertsto stability augmentation.The controller then transfersthe guidanceof the aircraft to the bolter/waveoff controller, who directsthe pilot back into the landing sequences. If the information stored in the data link is not updatedwithin any 2-secondperiod during thedescent,the TLT advisorygoeson (missedmessage)and the AFCS automatically disconnectsand revertsto STAB AUG. The pilot can continue the descentin Mode II or Mode III. At 12.5 seconds from touchdown (approximately 2,200 feet from the touchdownpoint), the 10 SECOND advisory goeson, indicating deck motion dataarebeing addedto the glidepath commands.This information is in the form of a slight increase(or decrease)in aircraft altitude to adjust for the movement of the touchdown
17-12
NAVAIR Ol-FlhAD-1
point caused by the ship’s motion (roll, pitch, and heave).Between 12.5and 1.5secondstirn touchdown, the CATCC sendsan automatic waveoff if any part of the carrier-basedequipment fails and up to S seconds tbrm touchdownif the aircraft exceedsthe AN6PN-42 flightpath control envelope.Waveoff signals also may be issuedby the final controller (betweenlock-on and touchdown) and the landing signal offtcer between 1 mile andtouchdown.Approachesmust be waved off at weatherminimums (200-feetaltitude and In-mile visibility) if the pilot cannotseethe meatball. At 2 secondst?om touchdown, the landing system freezesthe pitch and bank commands and the AFCS holdstheaircraft’s attitudeto touchdownunlessthepilot electsto override the AFCS either by maneuveringthe control stick or by manually disengagingthe AFCS and assumingcontrol. If the aircraft bolters or if the pilot decidesto go around,the AFCS is disengagedautomatically by meansof overriding the control stick, and the pilot entersthe bolter/waveoff pattern.
Use of paddleswitch to disengageAFCS for Mode IA landing is not recommendedsince DLC, pitch SAS, and roll SAS will also be disengaged. 17.4.4.2 Mode II Landing Sequence. The early phasesof a Mode II descent(Figure 17-5)are identical to a Mode I descentsequence.The aircraft to be recoveredis directed through the marshaling area, received LANDING CHK, and arrives at the ACLS radaracquisition gate.When the lock-on discrete (ACL READY) messageis received,thepilot continuesto fly theaircraft
manually (using APC as desired) in responseto VDI and/orHUD displays. Ifthere is anequipmentfailure, the system(CATCC) will senda voice discretesignalthatturns on theVOICE advisory, and the ANKPN-42 error information displayedwill be invalid and thus removed.The pilot then expectsto receive standardvoice commands and will probably use the redundantILS information or switch to tacansteering. As long astheaimrat?is locatedwithin theAN/SPN42 flightpath control envelopefor Mode II, the descentis continueduntil visual contact is made with the Fresnel lens optical landing system meatball. All waveoffs in Mode II are given by the final controller of the LSO. Approachesareterminatedat weatherminimums (200feet altitude and l/2-mile visibility) if the pilot cannot seethe meatball. At any time before 12.5secondsfrom touchdown,the pilot can switch from a Mode II manual to a Mode I automatic flightpathcontrol, providedthecoupleravailable discreteis being receivedand the ACL interlock is true. 17.4.4.3 Mode Ill Landing Sequence. Mode III descentsfollow the same general sequenceas that of Modes I and II, but Mode III approachesare talkdown landings; that is, all flightpath correctionsareprovided by voice andno computerizeddiscretesignalsare sent. The useofAPC is optional. Approachesareterminated at the weatherminimums ifthe FLOLS (meatball)is not visible to the pilot for continuing the landing.
17-13
ORIGINAL
PLATFORM 5.000 FEET “GLINFIGHTER 401” “PL*TF*RW
DE”IATvJN SYMBOLS ON H”DNDI,. FOR EXAMPLE. “GUNF,O”TER 401 FLY UP. FLY RIGHT-.
STEER COMMAND - AWL ~-MILE DME FIX 1,200 FEET APC ENOAOED IIF DESIREDI DLC
APPROXIMATELY
ENGAGED m
1 70° RADIAL
NEEDLES
SHOULD
CENTERED, BEGIN
4
3 MILES 1,200 FEET BE
3500 RADIAL
.
BASE RECOVERY COURSE
Figure 17-5. SPN-41 ILS Approach ORIGINAL
17-14
NOTE ENS”.% BEFORE
THAT DLC DISENOAGE RAISING FLAPS.
r
NAVAIR 01.Fl4AAD-1
CHAPTER
Extreme
Weather
10.1 ICE AND RAIN
The primary concernwith flying in icing conditions is ice accumulation sufficient to causeengine damage. Ice accumulationon engineprobeslocatedbetweenthe engine guide vanes and above the number three inlet ramp is not detectablefrom the cockpit. Aircraft maneuversor landingimpact candislodgeaccumulatedice and cancausesevereFOD to the engine.Visual detectionof icing on exterior surfacesand/or illumination of the pilot’s INIET ICE caution light should be treatedas indicationsofthe potentially more seriousproblemsdescribed above. The following precautionary action should be taken immediately in known or suspected icing environments:
[-GE-( Icing conditions can causeheavy ice accumulation in the inlet ramp areasor on engine probesandthe compressorface.Aircratlmaneuversand arrestedlandingsmay dislodge this accumulation and cause extensive engine FOD or failure. A straight-in field landing is preferred. Minimum power setting after landing is recommended.
ORIDHON.
2. CABIN AIR DEFOG lever 3. Engine instruments -
Operations
of icing conditions. If inadvertent or unavoidableoperation in known or suspectedicing conditions hasoccurred, an effort should be made to eliminate the ice before landing by remaining well below the freezing level for an extendedperiod of time.
18.1.1 Icing. Icing conditions should be avoided wheneverpossible.Before flight, check freezinglevels and areasof probableicing from weatherservice.
1. ANTI-ICE switch -
18
FWD DEFOG.
Monitor Frequently.
Carefully monitor ‘pm and EGT indications. A reductionof rpm or an increasein EGT accompanied by a loss of thrust is an indication of engine icing. 4. Avoid clouds and other areasof visible precipitation. 5. If unable to avoid precipitation, adjust aircraft Mach or altitude asnecessaryto remain outsideof the icing zone shown in Figure 18-l. Extended operations in icing conditions should be consideredan emergencysituation.If time and fuel permit, a descentbelow thefreezing level is recommended. If unable,altitudesaboveapproximately 25,000feet or ambient temperaturesbelow -30 “C are generally free 18-l
Operationof main flaps/slatsandmaneuvering devices increases the likelihood of a flap/slat lockout becauseof shearingof the torque tube. Attempt to descendbelow the freezing level for 20 to 30 minutes before operatingmain or maneuveringflaps/slats. 18.1.2 Rain. Whenever rain is encountered, turn ANTI-ICE switch to AUTO/OFF. Note In heavy rainfall, maintain a minimum engine power setting of 70-percentrpm. This will assureadequateaccelerationmargin and preventpossibleengine speedhangup. 18.1.2.1 Takeoff in Rain. Takeoffs performedwith standing water on the runway may result in unstable engineoperationbecauseof water ingestion.
ORIGINAL
NAVAIR 0%Fl4AAD-1
LloTE cRossHmcmEouIEI mmcAlEs*REIm wtocn ENGINE lcms IOUE TO wer eoouN0, CAN OCCUR WTmolJT ExrEmos su%Aes lemo.
Figure 18-l. Icing DangerZone 18.1.2.2 Landing in Rain. Selecting ON with the WSHLD AIR switch controls a blast of air that blows rain off the windshield. Be awareof the possibility of flameout in a heavy rain and of reducedbraking action becauseof a wet runway. 18.2 HYDROPLANING Operationson wet or flooded runways may produce fourconditionsunderwhichtimtractionmaybereduced to sn insignificant value. 1. Dynamic hydroplaning 2. Viius 3.
hydroplaning
Dynamic hydroplaningis insensitiveto vertical load changes(weight),but is greatly affectedby tire inflation pressureand tire wear. Since the fluid cushion is incapableof developingany appreciableshearforce,braking and sideforcecoefficients becomealmost nonexistent.
Revertedrubber skids
4. Combined viscous and dynamic hydroplaning. Note Hydroplaning has been experiencedin the F-14 at speedsdown to 40 knots.
18.2.2 Viscous Hydroplaning. Viscous hydroplaning occurs when the tires are separatedfrom the runway surfaceby a thin film. Viscous fluid pressures in the tire-ground contact zone of rolling tires build up with speedto the dangerlevels requiredfor hydrophming only when water-coveredpavementsaresmoothor smooth acting, as when contaminants considerably more viscousthanwater coatthepavements.Sincea tire
18.2.1 Dynamic Hydroplaning. Dynamic hydroplaning is a condition in which a fluid separatesthe tires from the Iunway surface.When standingwater on a wet ORIGINAL
tunway is not displacedby the tire fast enoughto allow contactover the complete footprint areaof the tire, the tire rides on a wedge (or film) of water over all or part of thefootprint area.Total dynamic hydroplaningoccurs when the pressurebetweenthe tires andthe runway lifts the tires off the runway surfaceto the extentthat anonrotating tire will not spin up (landing) or a rolling, unbraked tire will slow in rotation and may actually stop (takeoff). Total dynamic hydroplaning speedis representedby the following mathematicalformulas: 9 times thesquareroot of the tire inflation pressurefor a rotating tire (as in takeoff); 7.7 times the squareroot of the tire inflation pressurefor rt nonrotatingtire (as in landing).
18.2
NAVAIR
01.F14AAD-1
operatingon a surfacewith rubberdeposits,paint, fuel, or oil canonly partially displacethe nappedwater film, considerablyhigher hydroplaningpressureswill be developedin thetire footprint areawith thesemoreviscous fluids. Even slight amountsof precipitation, for example, aheavydew that coatsthe pavementwith a thin film of fluid, can producethis effect. Becausethe tire footprint separatest?omtherunway with lessfluid depthand at a lower relative groundspeedthan dynamic hydroplaning speed,viscoushydroplaningis potentially more dangerousthandynamic hydroplaningandisnot greatly affectedby changesin vertical tire load or tire inflation pressure.Grooved tires offer a greateradvantagethan smooth tires in reducing the effects of viscous hydroplaning.The runwaypavementsurfacetextureis also an important factor in combatingviscous hydroplaningeffects. 18.2.3 Combined Dynamic and Viscous Hydroplaning. Lossoftire hiction with increasingor decreas-
ing speedon wet or flooded runway pavementscan be causedby the combinedeffectsof viscous anddynamic hydroplaning.Figure 18-2 shows a pneumatic tire rolling at medium speedacross a flooded pavement in a partial hydroplaningcondition. The first zoneshowsthe traction of the tire footprint that is supportedby bulk water (dynamic); the second zone, the fraction supported by a thin film of water (viscous); and the third zone, the fraction essentially in dry contact with the peaksofthe pavementsurfacetexture.The lengthof the first zone representsthe time requiredfor a rolling tire in this speedcondition to expel bulk water from under the footprint; correspondingly,the length of the second zonerepresentsthe time requiredfor the tire to squeeze out the residual thin water film remaining under the footprint after the bulk water has beenremoved. Since fluids cannotdevelopshearforces of appreciablemagnitude,it is only in the thiid zone(essentiallydry region) that friction can be developedbetweenthe tire and the pavementfor steering,decelerating,and acceleratinga vehicle. The ratio of the dry contactarea(thud zone)to thetotal tire footprint area(zones1,2, and3) multiplied by the coefficient the tire developson a dry pavement, yields the friction coefftcient the tire develops for this flooded pavement and speed condition. As speed is increased,a point is reachedwhere the third zone disappearsand the entire footprint is supportedby either bulk water or a thin film. This speedcondition is called combined viscous and dynamic hydroplaning. As speedis furtherincreased,a point is reachedwherebulk water penetratesthe entire footprint; this condition is called dynamic hydroplaning. If the runway is not flooded (no bulk water), such as on a runway covered with heavy dew, it is possible for the secondzone to cover the entire footprint as speedis increasedor decreased.The pavement would have to be smooth or la-3
Figure 18-2.Combined Viscous andDynamic Tii Hydroplaning smooth acting, as in the casewhere contaminantsare present,for this to take place; this is called viscous hydroplaning. 18.2.4 Reverted Rubber Skids. Arevertedrubber hydroplaning condition (also called reverted rubber skid) takesplacewhen a wheel skid hasstartedon a wet runway and enough heat is produced to turn the entrapped water to steam. The steam in turn melts the tubber in the tire footprint. The molten rubberforms a sealpreventingthe escapeofwater and steam.Thus,the tire rides on a cushionof steamthat greatly reducesthe coefftcient of friction. On inspection of the portion of the tire involved, a patch of rubberwould show signsof reverting to its uncured state and hencethe name, revertedtubber.Onceestablished,this conditionmaypersist to very low groundspeeds.The characteristicmarks on a pavementfor the revertedrubberskid arewhite, as opposedto the black marks left on the pavementduring a dry skid. Thesewhite marks are associatedwith the cleaning processof super-heatedsteam and high pressuresthat are presentin the skid. The revertedrubber condition tends to make all runway surfacessmooth acting. Pavementsurfacetexture,which has a large effect on traction lossesfrom dynamic andviscoushydra planing, hasbut little effect for the revertedrubbercase with the possibleexceptionof groovedsurfaces.NASA researchconfirms the theory that the reverted rubber ORIGINAL
NAVAIR
0%Pl4AAD-1
skid is the most catastrophic for aircraft operational safetybecauseof the low-braking friction and the additional fact that tire cornering capability drops to zero when the wheels rotation is stopped.
3. AUTO PILOT switch 4. Loose equipment -
OFF.
Secured.
5. Tighten lapbelt and lock shoulderharness. 18.2.5 Landing On Wet Runway. te.r 7 for landing discussion. 18.3
TURBULENCE
Refer to Chap6. Cockpit lights -
AND THUNDERSTORMS
Unlessthe urgency of the mission precludesa deviation t?om course, intentional flight through thunderstorms should be avoided to preclude the high probability of damageto the airtiame and components by impact of ice, hail, and lightning. Flameoutsbecause of water ingestionor compressorstalls causedby rapid changesin flight attitudescould also occur. Radarprovides a means of navigating between or aroundstorm cells. If circumnavigatingthe storm is impossible,penetrate the thunderstormin the lower third of the storm cell, away from the leading edgeof the storm cloud, if possible. It is recommendedthat the AFCS be disengaged.Structuraldamagecould resultwith the automatic functions operating. 18.3.1 In the Storm. Maintain a normal instrument scanwith addedemphasison attitude displays.Attempt to maintain a constantpitch attitude and, if necessary, accept moderate altitude and airspeedfluctuations. In heavyprecipitation,a reductionin enginespeedmay be necessarybecauseof theincreasedthrustresulting from water ingestion. If compressorstalls or engine stagnation develops,attemptto regainnormal engineoperation by momentarily retarding the throttle to IDLE then advance to the operatingrange.If the stall persists,shut down the engine and attempt to relight. If the engine remains stagnatedat reduced power and the EGT is within limits, maintain reduced power until clear of the thunderstotm.While in the storm, the longitudinal feel trim, angle-of-attack, total temperature, windshield overbeat,static pressurecorrection,and cabin pressurization systemsmay experiencesome abnormalitiesbecauseof rain, ice, or hail damage.No difficulty should be encouuteredin maintaining control of the aircraft; howevcr, the rapid illumination
of numerous warning
lights may be somewhatdistracting to the pilot if he is not prepared. 18.3.1.1 storm:
If Necessary
to Penetrate
a Thunder-
ORIGINAL
7. Fly attitudeandheadingindicatorsprimarily while in extremeturbulence,becausealtimeter and airspeedwill fluctuate. Note During severeicing conditions,the pilot can expectto lose airspeedindicationsevenwith the pitot heat on. Ground-controlledintercept stations,.if available, can aid the pilot with tracking assistancethrough thunderstorm areas. Severeturbulent air at high altitudes may causethe inlet airflow distribution to exceedacceptablelimits of the engine,therebyinducing compressorstalls.To avoid compressorstalls during flight becauseof turbulentair, maintain 275 to 300 KIAS at all altitudes. 18.4
COLD-WEATHER
OPERATIONS
A careful preflight will eliminate many potentialhazards found in cold-weather operations.Inspect engine intakes for accumulation of ice and snow. If possible, preheattheenginefor easierenginestarts.When removing ice and snow from the aircraft surfaces,be careful not to damagethe aircraft. Also, useprecautionsnot to stepon any no-stepsurfacesthat could be coveredwith ice or snow. Check the pitot-static tube for ice as well asthe fuel pressurizationram/air intakes,andyaw,pitch, and angle-of-attacktransducers. Moisture in the fuel systemgreatly increasesoperational problemsin cold weather.At lower temperatures, the water-dissolvingcapacity of fuel is greatly reduced andwill result in considerablymore water accumulation (asmuch as severalgallons of water to 1,000gallonsof tie]). If the water separationoccurs at below freezing temperatures,the water will crystallize on the fuel drain andinternal valves. Any water accumulationwill settle to the bottom of the tanks and freezeup the fuel drains. Normal operatingproceduresas outlined in Chapter 7, Shore-BasedProcedures,should be adheredto with the following additions andexceptions.
1. Slow to between275 to 300 KIAS. 2. ANTI-ICE switch -
On Bright.
AUTO/OFF.
18-4
NAVAIR 0%F14AAD1
18.4.1 Preflight
shouldnot be delayedto ensurecompleteexternal tank transfer.
1. Check entire aircraft to ensurethat all snow, ice, or Gost is removed.
Note If externaltransferdoesnot initiate or is incomplete,flight below the freezing level for 20 to 30 minutes will allow frozen valves to thaw permitting externaltransfer.
Snow, ice, and frost on the aircraft surface are a major flight hazard.The result of this condition is a loss of lift and increasedstall
In severelycold weather,allow a short time for warmup beforeincreasingrpm out of the idle range.If oil pressureis low or fails to comeup in a reasonablelength of time, shut down. Attempt anotherstart atIer heating the engines.
SptXdS.
2. Shock struts and actuation cylinders Ice andDirt. 3. Fuel drain cocks densation 4. Pitot tubes -
Free of
piEi-1
Free of Ice and Drain Con-
If abnormalsoundsor noisesarepresentduring starting, discontinue starting and apply intake duct preheatingfor 10to 15 minutes.
Ice andDirt Removed.
5. Exterior protective covers -
Removed.
18.4.3 Taxiing. Avoid taxiing in deepor rutted snow since frozenbrakeswill likely result.
18.4.2 Engine Start. Be sure that the aircraft is adequatelycheckedbefore enginestart. When operatingin subfreezingtemperatures,moisture in the air enteringthe aircraft from the startingunit may freeze,causingECS malfunctions. Starting the aircraft with the AIR SOURCE in OFF will prevent the problem. The AIR SOURCE in BOTH ENG should be selectedafter both engineshave been startedand the starterair disconnected.ECS malfunctions after engine startmay still occur becauseof moisture internally presentin the aircraft. If this occurs,select: 1. TEMP mode selectorswitch 2. TEMP control thumbwheel 3. WSHLD AIR switch -
MAN. Full Hot (14)
To ensuresafestoppingdistanceandpreventicing of aircraft surfacesby melted snow and ice blown by jet blast of a precedingaircmft, increasespacingbetween aircraft while taxiing at subfreezingtemperatures. 18.4.4 Takeoff. When operating Born runways that are coveredwith excessivewater, snow,or slush,highspeedabortsmay result in engine flameout becauseof precipitation ingestion. The probability of flameout is highest when throttles are chopped. With a double flameout, normal braking, anti-skid and nosegearsteering will be lost as hydraulic pressuredecreaseswith engine spool down. Check applicable takeoff distance chartsin NAVAIR 01-Fl4AAP-1.1. Thrust available will be noticeably greaterin cold temperaturesduring the takeoff run.
ON.
4. With both enginesat IDLE, the ECS should thaw in about 20 minutes. During this warmup period, leave all avionics andradaroff. Before initial takeoff roll, ensurethat all instrumentsare sufftciently warmed up. After takeoff, cycle landing gear a few times to preventthe possibility ofthe gearfreezingin the wheelwells.
If externalfuel tanks areinstalled: 5. MASTER TEST switch -
FLT GR UP.
Advancethrottlesasnecessaryto 80percentmaximum to check for GO light and positive external transfer. Once airborne, external fuel transfer
18.4.5 Landing. Frozen downlock microswitch a~tuatots,becauseof moisture combinedwith extremely 18-5
ORIGINAL
NAVAIR 0%FUAAD-1
2. Engine ground operationshould be minimized as much as possible.
cold temperatures,can causespuriousunsafedown indications when landing gear is extended.Use antiskid during the landing roll.
18.51 Taxiing. While taxiing in hot weather, the canopiesmay be opened,if necessary,to augmentcrew comfort.
Note Bard braking on ice or a wet runway, even with ANTISKID on, could result in dangerous skidding. 18.4.8 After Landing. During operationswherethe temperatum is below freezing with heavy rain, or expectedto drop below freezing with heavy rain, the aircraft may be parkedwith wings forward (20’) andflaps in the full down position.
Do not operatethe enginesin a sandor dust storm, if avoidable. Park the aircraft crosswind andshut down the enginesto minimize. damageCorn sandor dust.
18.4.7 Before Leaving Aircraft. Weatherpermitting, leave the canopy partially open to allow for air circulation. This will helu ureventcanonvcrackinufrom
18.5.2 Takeoff. The required takeoff distancesare increasedby a temperatureincrease.Checkthe applicable rakeoffdistancech;utsinNAVAIROI-F14AAP-1.1.
18.5 HOT-WEATHER AND DESERT OPERATIONS Do not attempt takeoff in a sand or dust storm, if avoidable, to prevent sand or dirt from blowing into the intake ductsand causing enginedamage.
Checkfor accumulationof sandor dust in the intakes. Normal startingprocedureswill be employed. Normal operatingproceduresaaoutlinedin Chapter7, Shore-BasedProcedures,shouldbe adheredto with the following additions and exceptions: 1. Expect higher temperaturesthan normally obtained in operatingranges.
ORIGINAL
18.5.3 Landing. Anticipate a slightly longer landing distance and the possibility of turbulence becauseof thermal action of the air close to the ground. Use the defoggingsystemif necessary,in warm, humid weather.
18-8
PART VII
Communications-Navigation and Procedures
Equipment
chapter19- communicatioIls Chapter20- Navigathn Chapter21- Identification
I
87(Reverse Blati)
ORIGINAL
NAVAIR 91.Fl4AAD-1
CHAPTER
19
Communications betweenthe upperand lower seekinga strongersignal. SeeChapter20 for tacanoperation.
19.1 COMMUNICATIONS AND ASSOCIATED EQUIPMENT
19.1.3 Mutual Interference. Mutual interference amongthe ViUHF communication radios and between the V/UHF communication radios and D/L. can OCCUI: In the UHF band, minimize mutual interferenceby selecting opposite antennasor a !?equencysepamtion Of at least55 MHZ betweenradios if both are being used. When D/L is in use, mutual interferencecan be miniOperationof electronic equipmentfor more mized by using VHF channelsfor voice c~mmunicethan5 minuteswithout adequatecooling will tions. If this is not possible, frequency separatioo of at permanentlydamagethe equipment. least 55 MHz and selection of opposite antennasfor voice and DiL. arerecommended.If necessary,V/UHF 19.1.1 Communications Antennas. Four ViUHF/ 1or2 canbe shutoff. UHF communicationsinterference L&and, dual-bladeantennasprovideomnidirectionalcovwith D/L may causethe TILT computer messageto eragefor V/UHF voice, JTIDS voice, UHF D/L, JTIDS appearand the autopilot ACL or VECPCD mode to Link 16,tacan,andIFF/SIF transponder operation.VAJHF disengage.D/L interferencewith the radios may cause 2,lTIDSvoiceanddata,andtacanshamonesetofantennas; audible chirping at theD/L messagereply rate. theupperisimmediatelyatIofthecanopyturtlebackandthe lowerisembeddedintheleftventral~.TheVNHFl,D/L, In the VKF band,both radios should not be operated and lFF/SIF shamthe secondset; the upperis the second simultaneouslyat VHF frequencies. antennaaft of thecanopyturtlebackandtheloweris emheddedin theright ventraltin. Eachsystemis connectedto the JTIDS will not interferewith any ofthe V/UHF comappmpriateportionof anupperandlower antennathrough munication radios or date link becauseit usesa higher a coaxial switch and diplexer.For information on the frequencyband. Tacan compatibility, which is in the AN/ASW-27 DL (Link 4), and JTIDS (Link 16),refer to same frequencyband(L-band) asJTIDS, is performed NAVAIROI-F14AAD-IA. internally by JTIDS. Figure 19-l lists the CNI equipmentassociatedwith the aircraft/weaponssystems.
The AF’X-76 IFF interrogatorantennais an integral partoftheradarantenna.SeeFO-1andFO-2 forantenna locations. 19.1.2 Communications Antenna Selection. Selectionof the upper or lower antennafor use by the two communication radios and the D/L or JTIDS is manual and is controlled by switches on the RIO ANT SEL panel (Figure 19-2). The D/L is always on the oppositeantennafrom V/UHF 1. Antennaselection for theIFF/SIF canbe eitherautomaticor manual.The ANT switch on the IFF control panel controls antennaselection and is describedin Chapter21. Tacanantennaselection is completely automatic. If a signal is lost or is too weak to maintain receiverlockup, the tacan cycles 19-1
19.2 INTERCOMMUNICATIONS The KS provides normal, backup, or emergency communications between crewmembers.It also combines and amplifies audio signals received from other electronicreceivingequipment(ECM, Sidewindertone, IFF/SIF, radaraltimeter, and voice radios,etc.). Identical ICS con&o1panels(Figure 19-3)areon the pilot and RIO left-side consoles.The KS includes four amplifiers, two at eachcockpit station, that permit duplex operationduringnormal operation.Ifone amplifier fails, it may be bypassedby selecting either the BiU (backup) or EMER (emergency)position on the ICS control panel.This permits continuedICS operation. ORIGINAL
NAVAIR OI-l=MAAD-I TYPE AND DESIGNATION NTERCOM [LS-46OB)
I FUNCTION Provides voice communications between crewmembers and between cockpit and groundcrew, also amplifies various warning and weapon tones, and voice communications.
RANGE Within the aircraft and groundcrew cersonnel
3PERATOR 3oth, and Foundcrew lersonnel
LOCATION OF CONTROLS I‘ilot and RIO left :onsole and in I :he nosewheel \ Nell
JTIDS [AN/URC-107)
Provides jam-resistant, cryptographically secure digital voice and data, navigation, relay, and tacan.
.ine of sight (LOS) up to 300 nautical niles.
30th
I‘ilot left console, I310 right and left ,:onsoles
rACAN :AN/ARN-116(V)) [ANIURC-107)
Navigation aid provides bearing and distance information to local stations.
LOS up tc 390 nm, depending on altitude.
30th
I‘ilot and RIO left ,:onsole
JHF DATA LINK [AN/ASW-27C)
Provides two-way digital message communication.
LOS up to 160 nautical miles.
30th
IIO right console
d/UHF 1 COMMUNICATIONS SET [AN/ARC-182(V))
Provides two-way voice and tone communication.
LOS up to 200 nautical miles.
30th
IPilot left console
$/UHF 2 COMMUNICATIONS SET [AN/ARC-162(V))
Provides two-way voice and tone communication.
nauticalmiles.
v/UHF DIRECTION FINDER (OA-6697/ARD)
Provides bearing lnformatlon to selected stations.
LOS up to 160 nautical miles.
30th
IPilot and RIO left tconsole
UHF VOICE SECURITY EQUIPMENT (KY-56)
Cryptographic encoding and decoding of UHF voice communications.
Same as radio in use.
310
ILeft console
?I0
IRight console
I
IFF TRANSPONDER (AN/APX- 100)
1Resoonds to interrooations by &her aircraft org&und stations.
LOS.
IFF INTERROGATOR (ANIAPX-76B)
Requests identification I other aircraft.
LOS.
from
I710 left console
LOS up to 200
IDD and right console
RECEIVER DECODER (AN/ARA+SA)
Provides glideslope signals for carrier landing system.
LOS up to 20 nautical miles.
Pilot
IRight console
RADAR ALTIMETER (AN/APN- 194)
Displays height above earth’s surface.
0 to 5,000 feet.
Pilot
Pilot’s instrument panel
RADAR BEACON (AN/APN - 164)
Aids in tracking by ship and ground-based x-band radars. Provides down link for automatic carrier landing system.
LOS.
Figure 19-l. Communicationsand AssociatedEquipment ORIGINAL
19-2
Right console
NAVAIR
1 LWR
NOMENCLATURE @
0 0
.J;ftantenna
select
V/UHF-l DL antenna select switch
V/UHF-2 antenna select switch
0%FI4AAD-4
/b’\UPRJI
FUNCTION
I AUTO -
Enables JTIDS to transmit on the upper antenna and to receive on either the upper or lower antenna depending upon signal strength.
LWR -
Enables JTIDS to transmit and receive on the lower antenna.
UPR -
Enables JTIDS to transmit and receive on the upper antenna.
BOTH -
Enables JTIDS to transmit and receive on both the upper and lower antenna. 200 watt output power is equally divided between the upper and lower antenna, 100 watts each.
UPWLWR - Selects upper V/UHF 1 and lower D/L antenna. LWR/UPR -
Selects lower V/UHF 1 and upper D/L antenna.
UPR -
Selects upper V/UHF 2 antenna.
LWR -
Selects lower V/UHF 2 antenna.
Figure 19-2. Antenna Select Panel
19.3
ORIGINAL
NAVAIR OI-F’l4AAD-I
FUNCTION
NOMENCLATURE 0
Pilot’s COMM switch
ICS -
I 0
VOL control
Permits intercommunication when COLD MIC is selected on function selector. Overrides V/UHF communications.
JTIDS -
Keys the JTIDS terminal for voice communications.
V/UHF 1 -
Keys ARC-182
V/UHF 2 -
Keys ARC-1 82 radio for operation.
radio for operation.
Controls intercommunication audio level at that cockpit station. Audio level at other station not affected; however in EMER volume is controlled by other station.
Figure 19-3. Intercommunication Controls (Sheet 1 of 2)
ORIGINAL
NAVAIR
NOMENCLATURE 0
@
01.t=l4AAD-1
FUNCTION
Amplifier selector
B/U -
(Backup) used to bypass a fault amplifier and uses a backup output amplifier at own station.
NORM -
(Normal) used when all amplifiers are functioning
EMER -
(Emergency) uses the backup amplifier at own station, and makes use of input amplifier of other station over the emergency line. Volume is controlled by other station.
properly.
RADIO OVERRIDE - Attenuates non critical radio audio to emphasize intercommunication when urgent.
Function selector
HOT MIC -
Intercommunication
wfthout keying.
COLD MIC -
Intercommunication only when pilot actuates COMM switch on inboard throttle or RIO actuates keying switch on left foot rest.
0
RIO’s ICS button (left foot rest)
Permits intercommunication if COLD MIC is selected on the function selector control. Overrides V/UHF communications.
@
RIO’s MIC button (right foot rest)
Permits transmission on V/UHF 1, V/UHF 2, or BOTH radios as well as JTIDS as selected on the radio frequency channel indicator (RFCI).
Figure 19-3. IntercommunicationControls (Sheet2 of 2) Note
If two amplifiers fail at the same station, intercommunicationis impossible. The external interphone connection is in the nose wheelwell. When the pilot’s COMM switch is set to HOT MIC, groundpersonnelcancommunicatewith the cockpit stations.
With the front cockpit KS amplifier selector knob in the EMER position, engine stall/ overtemperatureand Sidewinder tones will not be available to the pilot, Note l
Audio warning signalsfrom the weaponsystem are available to either or both crewmen through the ICS. Each signal has a distinct tone. A visual display accompaniesmost audio signals so that the flightcrew can expect the tone and interpretits meaning.Most audio signalsmay be attenuatedorturnedoff ifnot required,allowing the flightcrew to concentrateon more critical tones. Critical warning tonescannotbe attenuatedby any mode of ICS operation. 19.2.1
Audio
Warning
Signals.
19-5
l
Selectionof EMER via the KS amplifier selectorknob in eithercockpit allows use of the other cockpit’s input amplifier. The RIO can obtain a Sidewinderand engine sta1Vovertemperahu-e tone by selecting EMER on his ICS panel.This allows the RIO to usethe pilot’s input amplifier.
Figure 19-4 provides a glossary of audio warning signals available within the aircraft weapon systems. Two 28-Vdc circuit breakers,ICS NFO (7F3) and ICS PILOT (7F2), control power to andprovide circuit protection for the ICS. Power to both circuit breakersis ORIGINAL
NAVAIR
0%FMAAD-1
TONE
POSITION
CONTROLS
FUNCTION
CHARACTERISTICS
IDEWINDER
Pilot
TONE* VOLUME/TACAN CMD panel
Missile aCqUiSitiOn
High fr8qU8nCy.Chang8S to indicate miSSil8 self-track.
LR-67
Pilot and RIO
TONE VOLUME/TACAN panel (PILOT) RADAR WARNING RCVR panel (RIO)
Indicates a missile alert, missile launch, critical threat, and/or status change.
Low to high frequency, determined by scan rat8 and PRF of threat radar. Low- to high-frequency warble when missile launch is detected.
qadar Altimeter
Pilot and RIO
Radar altimeter indicator (pilot)
Low-altitude warning
1,000 Hz tone, modulated at 2 pulses per Second, lasting 5 seconds or until altitude is increased/limit bug is lowered.
.PX-100
RIO
IFF control panel
Valid mode 4 interrogation
PRF of interrogation pulse 2,000 and 6,000 Hz.
acan
Pilot and RIO
Tacan control panel
Station identification
International morse code with three-letter designation.
,N/ARC-182
Pilot and RIO
V/UHF control panel
Other aircraft direction find (DF) reception.
International voice.
:NGINE STALL/ )VERTEMPERATURE
Pilot
None
Engine stall detection and/or EGT overtemperature warning.
Modulated 320 Hz for 10 seconds maximum or until fault is removed, whichever comes first.
Figure 194. Glossaryof Tones ORIGINAL
19-6
morse code,
NAVAIR 91.F’l4AAD-I
from dc essentialbus No. 1. Approximately 1 minute of warmup is requiredin orderto achievenormal operating temperature.
5. Frequency select switches Frequency.
Slew to Desired
6. Fmquencymode control - LOAD (he+ency is storedin memory for CH 1).
19.2.2 Pilot Tone VolumelTacan Command Panel. The TONE VOLUMEITACAN CMD panel (Figure 19-5)on the pilot left consolehas two volume controls for regulating audio signals from the ALR-67 and Sidewindermissile lock-on.
7. Frequencymode control quencyDisplay.
19.3 V/UHF RADIO (AN/ARC-182)
8. Enter frequency in quick referencedirectory for CH 1 (if desired).
The ARC-182 radio providesmultimode, multichannel, air-to-air/air-to-surface voice, tone, and antijam (Have Quick) communications. The ARC-182 control panel (Figure 19-6) is located on the pilot and RIO left console.Frequencyrangeextendsin four bandsfrom 30 to 87.975, 108 to 155.975, 156to 173.975,and 225 to 399.975MHz on any of 11,960channels(separatedby 25 kHz). Transmission and reception are available in AM or FM bands.The modulation is selectedautomatically by the radio except in the 225 to 399.975band, which is reservedfor antijam use. There are 40 preset channelsavailable. Channels1 through 30 areused for normal voice communications.Channels31 through40 areuscdforantijamHaveQuickcommunications.Guard frequencyof eachbandmay bemonitoredsimultaneously with any othertiequencyselected.The mdio is usedwith theOA-8697IAROto provideautomaticdirectionfmdiig to the transmitting station.The ARC-182 operateswitb securevoice equipment(KY-58). Upper and lower antenna installations provide reliable line-of-sight communications to 200 nm (depending on altitude and atmosphericconditions).A radio frequency/channelindicator (Figure 19-7) on the pilot and RIO instrument panel displays the frequency or channel selected.A separateVOLUME control panel (Figure 19-8) for the pilot is locatedon the pilot left console.
Transmissionson bothV/UHF 1 andV/UHF 2 radios, while operatingon the same tiequency,maymsuhinasqueal.Thisisanormal condition causedby RF interactionbetween thetwo radiosoperatingon thesameRequency in closeproximity to eachother.
T/R or T/R&G.
2. Frequencymode control 3. CHAN SEL switch -
Reset.
SelectChannel 1.
4. Frequencymode control -
9. Repeatsteps2 through8 for subsequentchannels. 19.3.2 Built-In Test. BIT isolatesfaults in the RT to one module, two modules, and three modules. BIT shouldbe initiated anytime the FREQ/(CHAN) display blanks or indicates an erroneousreadout. Proceedas follows: 1. MODE selector 2. BRT control -
TEST.
As Required.
3. BIT requires approximately 10 seconds;observe FREQ/(CHAN) display. a. No fault is indicatedby 888.888. b. Faults areindicatedby a numberthat identiftes the module or modulesat fault. Note If readouts061 or 651 display, select other antennaand key transmitter for 5 seconds, thenrepeatsteps 1 through 3. Figure 19-9 lists the most common BIT fault codes andtheir respectivemodule failures. 19.3.3 Have Quick (Antijam) Mode. Have Quick is a tactical antijam systemthat utilizes frequencyhopping, a method where frequenciesare changedmany times per second. The frequency hopping patterns, storedin memory and frequencytables,are selectedby word-of-day,netnumbers,anda given date.The antijam mode of the ARC-182 is enabled by selecting a net numberandby placing theNORM/A.7 switch to AJ once all the variables have been enteredinto the radio. For two or more radios to successfully communicate on a Have Quick net, eachradio must have the sameTOD, WOD, and operatingnet.
19.3.1 Preset Channel(s) Load 1. MODE selector -
READ, Verify Fre-
The ARC-l 82’s Have Quick II systemis compatible with older Have Quick I systems.
Read. 19-7
ORIGINAL
.NAVAlR
Ol-FUAAD-1
1
1
TONE ALU-67
0
VOLUME
TACAN
0
ALR-67
0 2
FUNCTION
volume control
SW (Sidewinder) volume control
:lockwise rotation increases tone in pilot’s headset. Provides threat alert, it&us and warning tones representing received threat radar signals. Iockwise rotation increases missile tone in pilot’s headset. :ounterclockwise rotation turns tone to low. lluminates when selected PLT or NFO, indicating acan.
Figure 19-5. Pilot TONE VOLUMBTACAN
ORIGINAL
I
I
SW
NOMENCLATURE a
CMD
IQ-8
crewman
CMD Panel
in command
of
NAVAIR
NOMENCLATURE 0
0
0
@
0
Of-l=14AAD-f
FUNCTION
VOL corltml
Ad).@@level of audio signal. Clockwise rotatlonincreasesaudio level. RIO’s adjustmentsmade only vla the RFCI.
Squelch switch
SQL-
Squelch &cult Is operationaland backgroundnoise Is removed by reducingreceivergaln.
OFF-
Disables squelch circuit restorlngreceiverto full galn.
Frequenoy Wlect
Fourfrequencytunlng switches are used to tuna transceiverwhen the tunlng selectorwit@ Is set to MAN (manual). The spring-loaded switches Inuease the frequency In the up position and decreasefrequfnxy In the down poslon. The left switch controls the hundredsand tens dlgits, the second switci~controls units, the thlrd switch controlstenths, and the right w&h controls hundredthsand thousandths.
Fl?EQ/(CHAN)display
Dlsplays Incandescentdlgilal readoutsof selectedfrequencyor channel. In TESTmode lndlcates receivertransmitteffault locatlons.
UHF mode selector
Operationalwhen tuned to frequenciesIn the 225.000to 399.ooOMHz band.
swltohes (sprtngreturn)
AM-
Selects amplitude modulatlonsignals. Varieswith atmospheric conditions, susceptibleto electromagneticInterterence.
FM-
Selects frequencymodulationslgnals. Reduceselectromagnetic Interference.
Figure 19-6. AN/ARC-182 V/UHF Control Panel(Sheet 1 of 2) 19.9
ORIGINAL
NAVAIR 0%F14AAD-l NOMENCLATURE ____.. -.__-..-~~~
t8
3
@
@
@a
FUNCTION
I
BRT control
Varies the FREQ/(CHAN) display light intensity. intensity.
MODE swttch
OFF -
Secures V/UHF radlo, unless frequency
T/R -
Energizes transmitter and main receiver.
T/R&G -
Energizes transmitter, main, and guard recetvers.
DF-
Provides automatic
TEST -
lndlcates built-in-test (BIT) RT, displayed on FREQ/(CHAN) indicator. Refer to Built-In-Test this chapter. Generates lo#) Hz unattenuated tone.
Rcv-
Allows reception of TOD messages
SEND -
Allows transmlsslon selected.
NORM -
Used for normal V/UHF communlcatlons.
AIJ-
Provides @II reslstant communlcatlons.
243-
Turns on the receiver-transmitter (takes precedence over operational mode controt) and causss the transmitter maln receiver, and guard receiver to tune to 243.ooO MHz (UHF guard frequency). All functions except VOL, SQL and BRT are disabled.
MAN -
Permits manual selectlon of an operating frequency using me frequency tuning switches. Ttansmttter and mcelver ara d&bled during a frequency change.
G-
Tunes me receiver-transmitter to me guard frequency to which me RT was last tuned.
TOD switch
NORM/Al
switch
Frequency mode switch (outer dlat)
Clockwlse maximum
mode switch Is set to 243.
dlrectlon flndlng from 108 to 399.975 MHz.
on preset channel selected.
of TOD messages
on preset channel
In the band
PRESET - Allows selection of any 1 of 40 present operatlng frequencies wltf CHAN SEL switch. Selected channel Is dlsplayed In the two center diglt readouts of the FREC/(CHAN) dlsplay. Channels 31 through 40 are for Have Quick (antIJam) use.
0
CHAN SEL swlt& dial)
(JnnH
READ -
Dlsplays me frequency selected.
WAD -
Automatlcally places the dlsplayed me selected preset channel.
(rather man channel) of preset channel
frequency
Into the memory for
Enables any 1 of 49 preset channels when the frequency mode svdtch tS Set to PRESET.
Figure 19-6. AN/ARC-182 VKJHF Control Panel (Sheet2 of 2)
1910
NAVAIR 01.Fl4AAD-1
a
NOMENCLATURE VHF/UHF-i and -2 frequency/channel indicator
FUNCTION Displays information
for each radio (pilot and RIO) as follows:
l
Left most LCD indicates secure voice selection : C (cypher) or P (plain)
l
Right most LCD indicates whether radio is in use for transmission reception (R)
l
Displays frequency, channel number, or WOD channel number
l
With anti-jam
selected, the net number is prefixed by an A
l
F is displayed
if the RFCI fails periodic BIT
l
If there is bad or no V/UHF data for 3 seconds, displays only a decimal point.
(T) or
Displays channel selected (0 - 127) for JTIDS-1 and JTIDS-2 voice links ;E;;;,ai;;;;:;with alpha designator indicating transmit (l) or receive (R)
0
TEST button
Activates IO-second maximum internal test of the RFCI. On successful completion of the test, the LCDs show the test display. If the TEST button is held for more than 10 seconds the display will automatically return to the display prior to test.
Figure 19-7. Radio Frequency/ChannelIndicator (Sheet1 of 2)
19-11
ORIGINAL
NAVAIR 0%F14AAD-1 “n.reUP,
cn,mE
,.“,.,~m.Y~m”m.-
FUNCTION . _.__.. -._
VOL control
Enable RIO to adjust level of audio signal. audio level.
XMTR SEL buttons
Enables RIO to select desired radio for voice communications JTIDS).
@
0
I
Clockwise rotation increases
(V/UHF or
Note When JTIDS voice communications is selected V/UHF plain voice communications are inhibited. If V/UHF encrypted voice communication is selected, both V/UHF (encrypted) and JTIDS will transmit simultaneously.
Figure 19-7. Radio Frequency/ChannelIndicator (Sheet2 of 2) 19.3.4 Have Quick Load instructions. Have Quick antijam voice communications entry usespresetchatinel40. The contentsof presetchannel40 designatesthe loadingmodein which thennit is operating.The following loading codes are used tc operateand load in Have Quick II:
2. TRAINING
a. 00 -
HaveQuickITmining.
b. 25 -
Have Quick II Training.
c. 50/75 -
1. 220.000 2. 220.025
-
MWOD load mode.
3. 220.050
-
MWOD erasemode.
4. 220.075
-
FMT load mode.
If the aircrew desiis to enter Have Quick without loading or verifying, 220.000shouldbe loadedinto preset channel 40 using the procedures in paragraph 19.3.4.13.otherwise, Have Quick I processingis used. 19.3.4.1 Net Selection. Have Quick I andII usethe samemethodof netselection.A net is a six-digit number that selectsthe frequencytable that will be hoppedon. Net numbers are in the form of AXXXYY, where A indicatesa Have Quick net, X is a number Tom 0 to 9 deftig thenet,andW is either00,25,50, or 75, which determinesthe combat or training operational mode. The operationalmodes am 1. COMBAT a. 00 -
Qperatein Have Quick I.
b. 25 -
Have Quick II NATO.
c. 50 -
Have Quick II Non-NATO.
d. 75 -
Not Used.
ORIGINAL
Not Used.
Qperatein Have Quick II. The 1,000combat nets range t?om 000 to 999. The variablesin thesenet numbersrefer the radio to specific frequenciesand algorithms within the radio’s memory. There are five Have Quick I tmining nets displayedas AOO.XOO,where X is 0 to 4. There are 16 Have Quick II training netsdisplayedasAOXX25, whereX.X is 0.0 to 1.5. The variables in thesetraining net numberstell the radio the training thequencyon which to begin hopping. Training nets are activated by a special WOD (300.0X39 in segment one of the WOD used for that dsy. The lasttwo digits determinethehoprate.The same applies tc the last two digits of the fmt segmentof combat WODs. 19.3.4.2 Word of Day/Multiple Word of Day. A WODiMWOD is a transmissionsecurityvariable.Have Quick I radiosusea WOD consistingof six segmentsof six digits each.Have Quick II radiosuse a MWOD that addsa seventhsegmentcontaining a two-digit datetag and live more MWODs for 6 days of operationwithout reloadingWODs. The WODMWOD is loadedinto the radio to key the Have Quick system tc the properhopping pattern,dwell time, and hop rate. The hop rate is included in the fast segment of each WODMWOD. XXXXYY, where YY is 00,25,50,75, denotingslow to fast hop rates. When operating with Have Quick I systems,only oneofthe six MWODs is used.SeeFigure 19-10.
19-12
NAVAIR
JTIDS
7
NOMENCIATURE 3
3
01.F14AAD-1
FUNCTION
JTIDS SEL switch
Selects JTIDS 1 or 2 voice channel for pilot’s voice transmissions. channels are always selected to receive.
JTIDS-1, V/UHF-2 control
Clockwise only).
JTIDS-2, volume
rotation increases audio level of received transmission
Both
(Pilot
Figure 19-8. Pilot VOLUME Control Panel
19-13
ORIGINAL
NAVAIR
01.Fl4AAD-1 FAULT RMT or RT
INTERPRETATION SELECT TEST MODE
LOW PWR
SELECT TEST MODE
RMT CTRL
DEFECTIVE CONTROL
TEST
680.000
NONE
RT AND CTRL OK
TEST
465
RT
MODULES 4,5, OR 6 SAD
TEST
061
VSWR
RT OR ANTENNA SYSTEM
TEST
651
FWDPWR
RT OR ANTENNA SYSTEM I
TEST
157
MODULES 1,5, OR 7
RT I
TEST
333
MODULE 3 SAD
RT
I
Figure 19-9. Common BIT Indications 1 .l
269.950
2.1
295.850
3.1
290.450
4.1
275.950
5.1
270.450
6.1
300.050
1.2
299.000
2.2
289.600
3.2
279.000
4.2
269.300
5.2
259.000
6.2
249.000
1.3
298.100
2.3
288.000
3.3
276.600
4.3
268.000
5.3
256.600
6.3
246900
1.4
297.000
2.4
287.900
3.4
277.400
4.4
267.000
5.4
257.600
6.4
247.100
1.5
296.000
2.5
286.300
3.5
276.500
4.5
266.700
5.5
256.000
6.5
246.100
1.6
295.000
2.6
285.300
3.6
275.100
4.6
265.500
5.6
255.500
6.6
245.200
1.7
11
2.7
12
3.7
13
4.7
14
5.7
15
6.7
16
5.1 = OPERATIONAL DAY 1 .l through 1.6 are WOD 1 segment
numbers.
1.7 is the date tagfor WOD 1. 2.1 through 2.6 are WOD 2 segment numbers 2.7 is the date tag for WOD 2. 3.1 through 6.7 is the same as above for WOD’s 3 through 6. 6.1 is the current Operational
Day, which should match one of the date tags.
Note: (1) If the current operational day was 11 (MWOD location I), Have Quick II Combat net would be used with a hop rate of 50 (included in the last two digits of segment 1 .l). An appropriate Have Quick II operatlonal net should be chosen. (2) If the current operational day was 16. Have Quick II Training Net would be used because the first segment of MWOD location 6 (6.1) is the special training segment. The hop rate would be 50 (last two digits of first segment). An appropriate Have Quick II Training Net number should be chosen.
Figure 19-10. Example ofan ARC-182 Have Quick Il MWOD Fill ORIGINAL
19.14
NAVAIR 01-F14AAD-1
19.3.4.3 Time of Day. TOD is a signal that synchronizes Have Quick radios to a common time for antijam operation. There are two ways to enter TOD. One methodinvolves receivingUTC over the air on a manually selectedUHF frequencyafter powerup. The second method involves using the self-start (emergencytime start)mode, which is usedwhen acting as masterclock to transmit that time to other Have Quick systems. Within this TOD signal is the operationalday. This is transmittedwith the TOD or loadedmanually as in the self-startprocedure.Refer to paragraph19.3.4.12,TOD Load. The codeword for TOD is “Mickey.”
6. Repeat steps 1 through 5 to load remaining MWODs. Note The desiredfrequenciesare loadedin segments1through6ofeachMWOD.Thedate tag for eachI?WOD is loadedinto thesoventhsegmentandis atwo-digit numbercorrespondingto theoperationalday on which thatMWODistobeused.Itcanbeloaded or changedusingthe two middle frequency selectswitches and the MWOD segment loadingproceduresabove.
19.3.4.4 MWOD Load Entry 1. Frequencymode control 2. CHAN SEL switch -
The crew may not enter an out-of-range WOD frequency, segment, or date tag. When two identical date tags are loaded, the last date enteredis valid and the old dateis setto zero.Ifthe old dateis viewed, 00 will be displayed.
Preset.
SelectChannel40.
3. Frequencymode control 4. Frequencyselect switches 5. Frequencymode control -
READ. Select 220.025.
‘Ike MWOD is not enteredinto the memory of the unit until the datetag is loaded. Thus, if a segmentof an MWOD hasbeen changedafter the MWOD was initially entered,the datetag must be reenteredto acceptthe MWOD change.
LOAD.
Note If MWODs are being loaded to replace existing ones, the old MWODs should be erasedusing the procedures in paragraph 19.3.4.9. This procedure will erase all MWODs in the radio’s memory.
19.3.4.6 MWOD Load Exit 1. Frequencymode control ceive TOD).
MAN (ready to re-
19.3.4.5 MWOD Load 1. Frequencymode control displayed).
Note When manual is selectedon the frequency modecontrol to exit a load mode,the codeto operatein Have Quick II antijam without enteringaload mode(220.000)will automatically be loadedinto presetchannel40.
Preset (1.1 will be
2. Frequency select switches - Select Desired WOD and MWOD SegmentUsing Middle Two FrequencySelect Switches. 3. Frequencymodecontrol - READ (displayshows frequencyindicatingdesiredWOD segment). Note If the MWODs were erased using the MWOD erase procedure in paragraph 19.3.4.9,the display will show 000.000indicatingthat they had beenerased. 4. Frequencyselectswitches quencyWOD Segment.
19.3.4.7 Operational Date Load. The operational dateis the calendardateof the mission day. The range is 1 through3 1.The MWOD that is usedby theunit for frequency hopping is the MWOD whose date tag matchesthe operationalday.Thus, if an operationalday is enteredor receivedvia TOD transmissionandno date tag exists for that operational day, an error will occur and be displayed. The operational day is loaded as follows:
SelectDesiredFre-
5. Frequencymode control - LOAD (desired&equencyloadedinto memory). 19-15
1. Perform steps 1 through 5 of paragraph19.3.4.4. Step 1 is not requiredif alreadyin MWOD Load. 2. Frequencymode control - PRESET (last WOD and segmentselectedwill be displayed). ORIGINAL
NAWAlR
0%F14AAD-l
3. Frequencyselectswitches -
Select8.1.
4. Frequency mode control - READ (last operational date or 00 is displayed). 5. Fmquency select switches Date.
SelectedDesired
6. Frequencymode control - LOAD (Operational dateis loadedinto memory). Note
Out of range (cl or >31) operationaldates may not be entered.
1. Frequencymode control -
Verify. The aircrew may view the MWODs at any time for verification by reading the
19.3.4.8
MWOD
MWOD locations by using steps 1 through 3 in paragraph 19.3.4.5. The following procedure enablesthe aircrew to eraseall MWODs storedin the nonvolatile memory. This procedureis recommended before reloadingall MWODs with new hquencies. 19.3.4.9
MWOD
Erase.
1. Frequencymode control 2. CHAN SEL switch -
PRESET.
SelectChannel40.
3. Frequencymode control -
RBAD.
4. Frequencyselectswitches - Select220.050To Initiate MWOD EraseFunction. 5. Function mode control - LOAD (display will go blank indicating MWODs havebeenerased). 19.3.4.10
FM1 Training
Frequency
Load.
The
Have Quick II FMT training net operatessimilar to combat Have Quick II, as both the date tag and operational day t%nctionsare used. The FMT net, however, hops on its own set of 16 frequenciesloaded into a separatetraining WOD. Additionally, a specialMWOD segmentfor FMT (300.0xX, whereXX is the hop rate) is loadedinto thefast segmentofthe MWOD beingused (usually 1.1,but any of the six MWODs can be usedas long asthe datetag for the MWOD whosefmt segment contains 300.0xX matches the operational day). The frequenciesactually hopped on, however, are loaded into a separateFMT WOD that canbe accessedwith the FMT loadcodeloadedinto presetchannel40:Once the 16 training kequencies
(7.01 through 7.16) m.
loaded,
it is not necessaryto reload them. Additionally, it is not necessaryto reload the special FMT MWOD segment once it is loaded,as long as the datetag used is within the sameMOOD asthe special FMT segment.If using ORIGINAL
theself-startmethodof TOD, the operationaldayaswell asthe datetag must be loadedinto segments8.1 and I .7 (or the seventhsegmentof whichever MWOD is being used),respectively. Thus, combat Have Quick II and FMT can be used interchangeablysimply by loading one or more of the MWOD fmt segmentswith the special training WOD segment.On every day that the operationalday matchesthe datetag of theMWOD with the specialFMT segmentloaded into its fmt segment, the unit will hou on the FMT trainine tiuencies. re gardlessofthe &tents ofthe otherse&en& within’that MWOD. SeeFigure 19-10,Note 2.
19-16
2. CHAN SEL switch -
PRESET.
Select Channel40.
3. Frequencymode control -
READ.
4. Frequencyselect switches 5. Frequencymode control -
Select220.075. LOAD.
6. Frequencymode control - PRESET (fat FMT frequencysegment7.01 is displayed). 7. Frequencyselect switch Segment.
SelectDesiredFMT
8. Frequencymode control -
READ.
9. Frequency select switches FMT Training Frequency.
Select Desired
10. Frequency mode control - LOAD (desired FMT training frequencyis storedin memory). 11. Repeatsteps6 through 10 to load remaining desiredFMT training frequencies.The load fbnction is exited by placing the frequencymodecontrol to MAN. 19.3.4.11 FMT Nat Operation. Once the training frequencieshave been loaded or verified, Have Quick II FMT net can be operatedas follows:
1. Perform steps1 through 5 of paragraph19.3.4.4. 2. Frequencymode control -
PRESET.
3. Frequency select switches - Select Segment 1 of Desired MWOD To Be Used (1.1, 2.1, 3.1, etc.).
NAVAIR WFl4AAD-1
5. To transmit time/date over air (broadcast)in A/J mode, momentarily push TOD switch to SEND. This will send TOD signal to all units that are in A/J andusing the same.net.
4. Frequency mode control - READ (display shows frequency indicating desired WOD segment). 5. Frequencyselect switch - Select Special FMT SegmentWith DesiredHop Rate(300.0xX XX = 00,25,50,75). 6. Frequencymode control - LOAD (desiredfrequencyloadedinto memory). 7. Frequencymode control -
19.3.4.13 Antijam Mode Selection If entering Have Quick II from a previous load mode, selecting MAN from that mode will automatically perform steps 1 through 5 below. In this case,proceedto step 6. Note TOD canbe receivedfiompowerup. It is not necessaryto enter any other load or operate mode first.
PRESET.
8. Frequency select switches - Select Segment7 (datetag) of the SameMWOD Used Above (1.7, 2.7,3.7, etc.).
1. Frequencymode control -
9. Frequency mode control - READ (display showstwo-digit datetag previously loadedor 00). 10. Frequency select switches Date Tag.
2. CHAN SEL switch -
Select Channel40.
3. Frequencymode control -
Select Desired
PRESET.
4. Frequencyselectswitches -
READ. Select220.00.
11. Frequencymode control tag loadedinto memory)
LOAD (desireddate
5. Frequencymode control - LOAD (the radio is now preparedto operatein Have Quick II).
12. Frequencymode control ceive TOD).
MAN (ready to re-
6. Frequencymode control 7. TOD -
19.3.4.12 TOD Load. TOD may be loadedin any of the following ways. 1. Emergency or forced start entry of time/date is performedby holding the TOD switch in receive (RCV) position until decimal point flashes,then momentarily settingTOD switch to SEND. Selecting the operationalday is performedusing stepsin paragraph19.3.4.7. 2. To receivetime/dateoverair (broadcast)in normal mode, momentarily push TOD switch to RCV when TOD is transmitted over manually selected UHF f%quency. This will allow acceptanceof TOD for 1 minute. 3. To transmit time/dateover air (broadcast)in normal mode, momentarily push TOD switch to SEND while on a manually selected UHF frequency. At this time, TOD signal is sentanda tone will be heard.
MAN.
Received.
8. Frequencyselectswitches Frequency.
SelectDesiredNet
9. NORM/A/J switch - Select A/J on Command to “GO ACTIVE” (fast digit ofnet frequencywill display as “A”). 19.3.4.14 Have Quick II Error Codes. The Have Quick II radiogeneratesdifferent errordisplaysfor three possible entry errors. If the radio has been initialized properly, an (A) will display in the left-most display segment.Ifa questionmark (?) displays,thenet number is invalid. If a backward questionmark (Y)displays,the MWOD or operationaldatais invalid. Ifthe displaydoes not changewhen AJ is selected,then TOD hasnot been receivedor entered.The error display for eacherror is shownin Figure 19-11. 19.3.4.15 Have Quick Basic Troubleshootlng Procedures
4. To receive new time in A/J mode or to update clock, momentarily push TOD switch to RCV. This will allow acceptanceof TOD for 1 minute.
19-17
1. Broken communications when A/J is selectedVerify all segmentsof the cunnnt WOD or all the FMT frequenciesare correct.
ORIGINAL
ERROR DISPLAY rxx.xxx
FRENQECY CONTROL
cFt~~:L
MAN
kn:M
xX.xXx
MAN
Invalid Net Number
rxx
MAN
No TOD
?XX
PRESET
Invalid MWOD and Date
xx
PRESET
No TOD
l
MWOD and l
Note The RIO volume control knob on the ARC-182 control panel is not functional. The volume control knob on the RIO RFCI is used to control volume. When JTIDS voice communication is selected, VAJHF plain voice communications are inhibited. If V/UHF encrypted voice communication is selected and JTIDS voice communication is selected, both V/UHF (encrypted)and JTIDS will transmit simultaneously.
19.4 V/UHF AUTOMATIC DIRECTION FINDER (OA-6697)
The Xs in the error display column respresents digits 0 to 9.
Figure 19-11. Have Quick II Error Codes 2. Lack of an “A” in the fmt digit of the net freqnwcy displayed on the radio - Receive another TOD transmission to resynchronize the
The’V/UHF automatic direction tinder is usedwith the ARC-182 radio in the AM mode (voice is sup pressed).ADF providesrelativebearingsto transmitting ground stations or other aircraft. It can receive signals on any 1 of 30 preset channelsor on any manually set frequenciesin the 108 to 399.975MHz range.
radio.
3. Broken communications after time, once good communications have been established - Receive anotherTOD transmission either in A/J or nomsl mode to resynchronizethe radio. 4. Invalid MWOD or datetag error code - Verify all MWOD segmentsfor the current day. 5. Invalid net error code net is being used.
Verify that the correct
6. No TOD errorcode - Anempt to receiveanother TOD &om themasW. If still unableto receiveTOD, use the self-startmethod and attempt to transmit TOD to othernet participantsif practical. 19.3.5 Radio Frequency Control/Indicators. TWORFCIs (Figure.19-7)are provided.EachhasLCDs that show the l?equencyor channelselectedfor V/UHF 1and 2 andJTIDS 1 and2, their transmit/receivestatus, and antijam and securevoice selection.The RFCIs are t&e-d by pressingthe TEST button on the panel. An indication is provided if the RFCI fails BIT. The RIO RFCI also containstransmit selectbuttons for V/UHF 1 and2 andJTIDS 1and 2 aswell asvolume ~~drols for adjusting their audio level.
ORIGINAL
The system has a line-of-sight range, varying with altitude. Operatingpower is 115Vat t%omthe essential No. 2 bus, 28 Vdc from the essentialNo. 2 bus, and 26 Vat throughthe RIO circuit breakerpanels.The system requiresa 5-minute warmup period.During the warmup time, failure indications shouldbedisregarded.The system uses a solid-state segmentrotation ADF antenna. Bearingto transmitting stationsis displayedon thepilot/ RIO BDHI (No. 1 needle),and on the HSD format of any MFD. The ADF signal is interruptedduring voice transmissions. 19.5 UHF VOICE SECURITY EQUIPMENT (TSECIKY-56) The security equipment is integrated,and operates, with theV/UHF 1 and 2 communicationssetsto permit UHF securevoice in a hostile environment,It shall be operatedasdirectedby appropriateauthority. Theory of operation and practical application are covered in the KY-58 operationmanual. The KY MODE switch and the KY-58 control panel (Figure 19-12)on the RIO left side consolearethe only cockpit controlsfor operatingthe KY-58 in eithercipher or plain language.Electrical power is from the dc essential bus No. 1 with circuit protection on the RIO dc essentialNo. 1 circuit breakerpanel, (7C3) KY-%/Z AHF.
19-16
NAVAIR
NOMENCLATURE 0
0 0
FUNCTION
ZEROIZE switch
ZEROIZE -
Guard lifted. The preset codes are erased and must be reset on the ground by qualified personnel before the cipher mode can be used.
DELAY switch
DELAY -
Provides a time delay between push-to-talk transmit.
Cipher switch
C/RAD-2 PLAIN C/RAD-1
c9
0
01.F14AAD-1
and actual
- Selects V/UHF 2 for secure voice. Enables plain audio to pass through without encryption. - Selects V/UHF 1 for secure voice.
FILL switch
Selects the position to be loaded with data. to load.
MODE switch must be in LD
MODE switch
OP-
Enables KY-58
LD -
Used for loading data into KY-58 control panel.
RV -
Receiver variable is not operational
operation after unit is loaded.
at this time.
Figure 19-12. KY-58 Controls (Sheet1 of 2)
19-19
ORIGINAL
FUNCTION
NOMENCLATURE @ 0
POWER switch
ON -
Used to transmit and receive secure voice communications over V/UHF radio. Applies operating power to KY-58 system.
KY MODE switch (operational only with KY-58 installed)
BB -
Normal mode for FM transmission
AUTO -
Provides automatic selection of BB/FM and DP/AM. as the frequency on the V/UHF is changed.
DP-
Normal mode for AM transmission.
Changes
Figure19-12.KY-58Controls(Sheet2 of 2) 7. Atlera2-minmewarmuppedirn$onthecipherae
The KY-58 hastwo statesof operation:plain and
lectedn3dio,liatenforasteady,unbrokentoneinthe headset followedbya double&chedbmkentone.
cipher(C).PlainisusedduringnormalUHF commtmications.Cipheris usedwhensecurevoicecommunications are desired.Thererue two cyphermodes:BB (baseband)for usewith FM transmissionsandDP @phase)for usewith AM. Theradiosetamustbe ON to attainsecureoperation.Thereceivingstationmu.4be properlyequipped to receivetransmissions in theproper ciphermode.
8. Key the appropriateradioselectedfor tmnsmis-
sion,hold for approximately2 seconds,andrelease.Double-pitched brokentonewill ceaseand no soundwill beheard.
0 Do not transmitplainvoiceon oneradio duringcipherreceptionsor while transmittingontheotherradio.
9. Key radioandhold. A siqle beep tone will be heardin approximately l-l/2 seconds, if delayis selected, otherwise,beepiaimmediate. Whenthis toneis heard,the equipmentis readyfor cipher transmission.
CommunicationsbetweenKY-28 and KY-58 voice securityequipmentis not possible.
10.Atler beeptoneis heard,establish two-waycipher radiocomnmnications with a cooperating ground station and check for readability and signal
Note
l
Strength.
19.5.1 KY-58 Operation
11. Setpowerandradioselectorswitchesin accordancewith thetacticalsituation.
19.52 Prelaunch
Note
1. Determinethat propercodehasbeensetby personnelqualifiedin voicesecurityequipment. 2. V/UHF radios3. Powerswitqh-
Ifagmundcheckoftheequipmentianotprao tical,thealxwepmwdmeamaybeusedto performauin-flightcheckof theeqmpment.
ON. ON.
19.53 Poatlaunch. The speechsecurityequipment
shallbeoperatedasdire&d by appropriate authority. 4. Cypherswitch -
0RAD 1 or C/RAD 2. 19.54 After Landing
5. KY MODEswitch - As Required.
1. ZEROIZEswitch - ZEROIZB(asbriefed). 6. If a groundtestof equipment is desired,establish two-wsyplaintext radiocommunications on the plainvoiceradiowithasuitablegroundstationand requestanequipment check.
Zeroize the code as directed by appropriate authority. 2. Powerswitch -
ORIGINAL
19-20
OFF.
NAVAIR 0%Fl4AAD-1
19.6 JOINT TACTICAL INFORMATION DISTRIBUTION SYSTEM The JTIDS is a high-capacitycommunications system providing jam-resistant, secure digital voice and data. This system also provides voice and data relay, dual navigationgrid operation,andtacan data.
When installed, the JTIDS receiver/transmittermplaces the AN/ARN-118 tacan system. Within the JTIDS terminal (DPG andWr), theequivalentfunctionality of the AN/ARN-118 tacansystem exists. 19.6.1 JTIDS Terminal. The JTIDS ANAJRC-107 Class2 terminal consistsof the following WRAs: 1. Data processorgroup (interface unit and digital dataprocessor)
The JTIDS digital voice function provides two secure,jam-resistant, separate(Jl and J2) 16 KBS voice channels. These are integratedinto both the pilot and RIO cockpits. The JTIDS datacommunicationsfonction providesa two-way data transfer between the F-14D and other JTIDS usersfor position and identification, air intercept control, and fighter-to-fighter functions. Identification is accomplishedamong participants,Navy (CVs, CGs, DDGs, E-2Cs, and F-14Ds) and other services (E-3s, F-l% etc.) by the PPLI message.The AIC function providesthe exchangeof command and control information and own-ship sensortracks/statusbetweenthe F-14D and a control platform (E-2C or ship). Fighterto-fighter functions provide the direct exchange of tighter tracks and statusamong fighters.
2. Securedataunit 3. JTIDS receivertransmitter 4. Battery assembly. 5. Circuit breakerprotection is provided throughthe 28-Vdc essentialand 1I5-Vat essentialbuses. 19.6.1.1 Digital Data Processor. The DDPispart of the JTIDS data processorgroup and the heart of the JTIDS Link-16 operation. It contains the net interface computer program. The DDP is common among all Navy and most non-Navy JTIDS platforms. The DDP performsthe following functions.
The relay fonctioa provides the capability for JTIDS to retransmitvoice or datamessagesfor extended-range communications.This function provides expandedbattle group operations by expanding communication ranges(voice, PPLI, etc.) beyond line of sight, greater than300 mn, air to air.
1. TDMA and messagemanagement 2. Network synchronizationand relative navigation processing 3. Receiver/transmittercontrol
JTIDS operatesin boththe geodeticandrelativenavigation modes simultaneously.JTIDS also provides the MCS correctionsto the own-ship navigation position, which is calculated using data received from the link, andown-ship INS or SAHRS data.SeeChapter20 for additionalexplanationof JTIDS navigationfunctions. The JTIDS communication systemutilizes threemajor tactical modes: one-way AIC (pass),two-way AK, and F/F. These modes are integratedinto the aircraft controls and displays utilizing the TID, DD, MFDs (TSD, VDI, and HSD formats) and DEU. Refer to NAVAIR Ol-F14AAD-IA for the detailedoperationof the TID, DD, and TSD. The JTIDS terminal interfaces with the various aircraft systemsvia 1553 mission bus No. 2 and MCS. The majority of JTIDS processingis performed by mission computer 1. In the event of a mission computer failure, the other computerwill support tacaaoperationand provide own-ship position for the PPLI message.JTIDS BIT function is providedvia the OBC pageon the MFD.
4. Signal decodingand decryption. 19.6.1.2 JTIDS Interface Unit. TheIUispartofthe JTIDS DPG and is unique for the Navy air platforms (F-14D andE-2C). The IU providesall theunique interfacesfor the aircraft. A 1553digital mux bus connects the IU to the MCS via mission bus 2. The IU contains the SICP that is also unique for the Navy air platforms. The IU performs the following functions. 1. TADIL-J(Link 16)messagegenerationandreception processing. 2. Systemcontrol (TDMA Tacan - OFF/ON).
OFF/STBY/NORM,
3. Navigation dataconversion. 4. JTIDS initialization. 5. Voice conversions (analog/digital and digital/ analog)andprocessing.
19-21
ORIGINAL
NAVAIR 0%FIWD-1
6.
Ta~an data (BDHI and 1553) and control panel interface.
7. A&& inter&es (1553 and hardwircd discrete signals). 19.6.1.3 Secure Data Unit. There are two types of KGV-8 SDUs currently in use:the KGV-8(E2) for lot 1 JTIDS systems and the KGV-8B for lot 2 and newer systems. The KGV-8B will eventuallyreplacethe older KGV-8(E2) SDU. The KGV-8 SDU is bolted to the ~ntoftheRTandprovi&sMSECandTSEC forJTIDS operations.Up to eight crypt0 variables can be loaded into the KGV-8 and are addressableon a time slot-totime slot basisby the DDP The eight locationsare split into two groups of four locations. Tbis allows loading andstorageof crypt0 variablesfor 2day operation.This provides uninterrupted JTIDS operation through mllover (oO:OO:OO Zulu). The JTIDS initialization loads are setup to use locations0,2,4, and6 for crypto period (day) 0 and locations 1,3,5, and 7 for crypt0 period 1. Refer to the Users’ Guide to Link-16/lTlDS Crypto, OPNAVINST C3120.43, Annex D, to determine the wnect crypt0 period for the day. 19.6.1.3.1 Load Control Unit. TbeLCUisusedto control the loading ofthe crypt0 variablesinto theKGV8(E2) SDU. The LCU andKYK-13 areconnectedto the remote fill assemblylocatedin the aircraftcrypt0 access panel. The remote till assemblyprovides accessto the JTIDS termiml Born the crypt0 accesspanel. This accessallows the loading of JTIDS crypto variableswithout openingthe avionics bay containingJTIDS. To load variables,the KYK-13 fill device (containingthe crypt0 variables) and LCU are connectedat the cry@ access panel. The LCU is thenusedto selectthe SDU location, load the variable, and verify the load. 19.6.1.3.2 Data Transfer Device. The AN/CZY-10 DTD is a handheldkeyboarddeviceusedto control the loading of the crypt0 variables into the KGVdB SDU or KGV-8(E2) SDU. The useof theDTD eliminates the need for KYK-13 and LCU when usedwith the KGV8B SDU. With the KGV-8(E2), theDTD eliminates the KYK-13 but requires the addition of the LCU. The DTD interfacesdirectly with the KGV-B(E2) or KGV8B via a cablethat co~fxts to the remotetill assembly. The remote fill assemblyis located behind the aircrafi crypt0 accesspanel.The DTD can thenbe usedto select the SDU location and load and verify the crypt0 variables. Refer to the AN/CZY-10 DTD Users Manual NSA ON477340, and the User’s Guide To Link16/JTlDS Crypto, OPNAVINST C3120.43,Annex D. 19.6.1.4 JTIDS Receiver-Transmitter. The JTIDS R/‘f provides RF detection and frequency translation ORIGINAL
betweenthe L-bandRF at the antennasandthe 75MHx IF at the DDP. The RT also containsan RF power amplifier that provides 100 watts to each of two antenna portsor 200 wattsto one antennaport. Frequencytuning control for the RT is provided from the DDP basedon a pseudorandom sequencegeneratedby the SDU. The JTIDS FUTalso performsmost of the JTIDS tacanprocessing.It provides tacan data (rangeand bearing) in a digital format to the DPG. 19.6.1.5 Battery Assembly. A battery assembly containing lithium and nickel-cadmium cells is usedto maintain the following: 1. NICAD a. Crypt0 variables (STBY - up to 48 hours, DATA SWNORM - duringpowertransients). h. Initialization (STBY - 5 minutes, DATA SILNORM - during power transients). 2. LITBIUM a. JTIDS chronometer(all modes). Note The battery assembly maintains terminal memory during switchover from ground power to enginepower but doesnot maintain terminal synchronixationor communication. 19.6.2 JTIDS Controls. The JTIDS control panel and DATA LINK MODE panel are shown in Figure 19-13.In addition to the basic panels(ANT SEL, VOLUME, and the RFCIs) the MFD (TSD formats), TID, DD, DSS, and DEU enable the crew to interfacewith the aircraft weaponsystemto supportJTIDS Rmctions. 19.6.3 Data Storage Set. The DSS is locatedin the RIO cockpit.It consistsof a receptaclethat is mountedin the a&raft, and a removablestorageunit. The DSU pm videsstorageoflTlDS initialiiondataandtherecoiding of engineand CSS data for postflight analysis.Refer to Chapter2 for the DSS enginedatarecordingandChapter 27 for the CSS datarecording.The DSU is loadedwith JTIDS initialization datausingtheTAMPS. On theselection of DOWNLOAD on theDEU, themissioncomputer quests the ITIDS initial&&ion datastoredon the DSU, pmccssesit, and transfersit to the JTIDS termimd. The exchangeof JTIDS initial&ion data is pertomied be twecntheDSS,missioncomputer,andJTIDSviathe 1553 busandtakesapproximately5 secondsto complete.Without initialiition data,ITIDS tacanandBIT lbnctionswill operatebut JTIDS synchronization, navigation, and communication functions will not be available.
19-22
NAVAIR 0%F14AAD.1
Figure 19-13. JTIDS Control Panels(Sheet1 of 3)
19-23
ORIGINAL
NAVAIR OM=l4AAD-~ FUNCTION
NOMENCLATURE 0
ZEROIZE switch
ZERO NORM -
0
0
THRM ORIDE switch
ON/OFF -
JTIDS MODE switch
OFF -
STBY DATA SIL -
NORM -
POLL -
@
0
Enables manual override of thermal shutdown. Indicated by a JTIDS HOT on the MFD caution advisory window. Removes all power from the JTIDS/Link-16 functions of the JTIDS terminal and zeroizes the crypto. To power down the JTIDS terminal, both JTIDS and Tacan have to be off. The JTIDS/Link-16 functions are off, the battery will hold crypt0 for up to 46 hours and initialization data for 5 minutes. The JTIDS/Link-16 is on but will not transmit except during BIT and voice. Net Entry will perform passive sync and once sync is achieved voice will transmit when keyed. Tacan transmissions are not affected by this selection. Digital tacan is available for display on the MFDs and HUD. The JTIDS/Link-16 is on. Net Entry will perform active synchronization and once sync is achieved all Link-16 transmit functions are available. Tacan transmissions are unaffected by this selection. Digital tacan is available for display on the MFDs and HUD. This mode is currently not used; however if selected JTIDS/Link-16 is on and digital tacan is available for display on the MFDs and HUD.
IPF RESET switch
Re-enables Link - 16 transmission detected failure.
REPLY switch
NORM CANC -
@
Zeroizes the crypt0 variables in the interface unit and the DSS JTIDS initialization load. Normal switch position (Spring loaded).
lX&LlNK
MODE
when they are shut down by an IPF
Enables Link-4 reply message transmission (no JTIDS function) Inhibits Link-4 reply message transmission (no JTIDS function)
TAC l
Selects Link-4 (AN/ASW-27C) as the primary link system. The following JTIDS functions operate in this mode. Synchronization
l
Ownship PPLI messages are transmitted messages are inhibited)
l
JTIDS voice (transmit and receive)
l
JTIDS navigation updates
(Ownship System Status
0 Tacan JTIDS -
Selects Link-16 (AN/URC-107) as the primary link system. All Link-4 functions are disabled.
Figure 19-13. JTIDS Control Panels(Sheet2 of 3)
ORIGINAL
19.24
NAVAIR NOMENCLATURE
Ol-F14AAD-1
FUNCTION CAINSI WPT -
Enables Link-4 carrier alignment and waypoint data to be received every 16 ms with no reply data. The same JTIDS
functions operate in this mode as when TAC is selected. Note The status of this event the DEU is mode will default ACLS function in ADDRESS thumbwheel
/
0
switch is not ready to Link-4 the event
sent to the MCS by the DEU. In the (No 1553 communications) the (D/L). This will prevent loss of the of a failure.
Selects fourth and fifth least significant octal digit for Link-4
address.
Figure 19-13. JTIDS Control Panels(Sheet3 of 3) 19.6.4 JTIDS System Operation. Procedures for the operationaluseof the JTIDS system areprovided in the following paragraphs.These paragraphsinclude power-up, initialization, and synchronization. These proceduresarenormally performed on the ground during aircraft startop; however, they can be performed anytime power is applied to the aircraft and the MCS is in full-up operation.
JTIDS manually initiated BIT shall not be performed without a fault indication by either background BIT or startup BIT. Manual BIT operation with no posted fault(s) can give false indications of JTIDS WRA/SRA failures.
l
3. Select JTIDS mode - DATA XL or NORM. This will power up the JTIDS part of the system.
Note 19.6.4.2
For other participants to display the F-14D PPLI, the INS or SAHRS has to complete alignment.During alignment, thePPLI messagewill be transmitted with position set to no statement.
1.. MFD3 - Select JTIDS own-aircraft data page and ACK all computer messages.
The following steps are required to power-up and initialize JTIDS. 19.6.4.1
Powerup
1. Verify STBY is selected on the JTIDS control panel and crypto hasbeen loaded. 2. Verify/install the DSU cartridge.
2. DEU - SelectDOWNLOAD then ENTR (initiates MCS download of DSU JTIDS load to the JTIDS system). 3. MFD3 - Verify DSS LOAD on own-aircraft data page changesto IN PROG (2 to 3 seconds) and finally to OK (6 to 8 seconds).Verify noneof the following JTlDS computer messagesare displayed. a. JTIDS NOT AVAIL - Verify JTIDS is poweredup and communicating on the bus.
Note l
Initialization
WithaircrafipowerON, theDSU28VDC C/B (9G3) should be disengagedbefore installing or removing the DSU from its receptacle.Failure to remove the power can eraseor damage the DSU cartridge.
b. NO LOAD -NEED DSS stalled and poweredup.
Verify DSU in-
c. NO LOAD - DSS FAIL clear failure.
DSS fail; try to
d. LOAD ERROR- JTIDS - Bad JTIDS load; net operationswill be effected. 19-25
ORIGINAL
NAVAIR 9%Ff4AAD-1
Note
4. MFD3 (own-aircraft data page) - Verify correct crypt0 period. To changecrypt0 period:
Course sync can be verified by verifying the display of PPLI messages on TSD, TID, JTIDS data readout pages, or IRST summary page. JTIDS must be selected on the DATA LINK control panel to process PPLI messages.
a. DEU - Select JTIDS COMM page, toggle CRYPT0 option switch to 0 or 1, then press ENTR. b. MFD3 (own-aircraft data page) crypt0 period selected.
Verify
c. JTIDS MODE switch - Cycle MODE switch from NORM or DATA SIL to STRY then back to NORM or DATA SIL. Note Cycling the JTIDS MODE switch is required to direct the DPG to accessthe desiredcrypt0 variables.If theMODE switch is not cycled, the DPG will continueto accesstheprevious crypt0 variableswhile displayingthe desired crypt0 period on the own-aircraft data page and net entry will not occur.
8. DATA LINK control panel - Verify/select JTIDS for JTIDS tactical functions. 19.6.4.4 JTIDS Shutdown. If network operations areanticipatedwithin 24 hours: 1. JTIDS MODE switch -
If network operations are not anticipated within 24 hours: 1. JTIDS MODE switch -
1. Verify/select desiredJTIDS antenna. 2. MFD3 (own-aircrattdatapage) - Verify JTIDS time is i6 secondsof net time (GOEStime, NTR, or any participant in the net). 3. DEU (time entry, JTIDS COMM page, TIME pushbutton) - Enter hours, minutes, seconds, and selectENT. Verify cor-
5. MFD3 (own-aircraft datapage) - Verify NET ENTR - NS (net entry not started), IN PROG (attempting sync or course achieved),OK (synchronization complete/fine synchronization achieved). 6. DEU (net entry, JTIDS MODE page) NET ENTR pushbuttonand ENT.
Press
7. MFD3 (own-aircraft data page) - Verify NET ENTR - IN PROG. Changesto OK synchronization complete (3 to 5 minutes normal mode, 7 to 10 minutes data-silentmode).
ORIGINAL
OFF.
Note Under no circumstancesshould the JTIDS MODE switch be left in DATA SILENT or NORM for greaterthan 90 secondswithout electrical power on the aircraft. Doing this will depletethe battery and require it to be chargedby maintenancepersonnel.Clypto variables cannot be acceptedor maintained if the battery is depleted.
19.6.4.3 Synchronization. Thefollowingstepsare requiredto synchronizeJTIDS with the network.
4. MFD3 (own-aimmft data page) rect time.
STBY.
19.7 IN-FLIGHT VISUAL COMMUNICATIONS Communications between aircraft are visual whenever practicable.Flight leadersshall ensurethat all pilots in the formation receive and acknowledgesignals when given. The visual communication chapters of NAVAIR OO-80T-113,the Aircraft Signals NATOPS Manual, should be reviewed andpracticed by all pilots and RIOs. Common visual signals applicable to flight operationare listed in Figure 19-14. 19.8 GROUND HANDLING SIGNALS Communications between aircraft and ground personnelare visual wheneverpracticable,operationspermitting. The visual communication chapters of NAVAIR 00-8OT-113shouldbe reviewedandpracticed by all flightcrew and groundcrew personnel. For ease of reference, visual signals applicable to F-14 deck/groundhandling arelisted on Figure 19-15.During night operations,flashlights or wands shall be substituted for handandfinger movements.Referto NAVAIR OO-80T-103for aircraft arming and sating handsignals.
19-26
NAVAIR MEANING XNERAL
SIGNAL
I
Ol-F14AAD-1
RESPONSE
I
CONVERSATION
\ffirmative (I understand.)
Thumb up, or nod of head.
degative (I do not know.)
Thumb down, or turn of head from side to side.
Juestion (repeat); used in :onjunction with another signal, his gesture indicates that the signal is interrogatory.
Hand cupped listening.
Vait
Hand held up in a fist with palm outward.
gnore last signal
Hand waved in an erasing motion in front of face, with palm forward.
‘erfect, well done
Hand held up, with thumb and forefinger forming an 0 and remaining three fingers extended.
Numerals, as indicated
With forearm in vertical position, employ fingers to indicate desired numerals 1 through 5. With forearm and fingers horizontal, indicate number which, added to 5, gives desired number from 6 through 9. A clenched fist indicates zero.
Nod of head (I understand). To verify numerals, addressee repeats. If originator nods, interpretation is correct. If originator repeats numerals, addressee should continue to verify them until they are understood.
rake over communications.
Tap earphones, change signal.
Execute.
:ONFIGURATION
behind ear as if
followed by lead
As appropriate.
CHANGES
.ower or raise landing gear.
Rotary movement of hand (flashlight at night) in cockpit, as if cranking wheels, pause, drop below canopy rail.
Execute when hand/flashlight drops.
Speed brakes
Open and close four fingers rapidly and repeatedly. Flashlight at night -a series of flashes followed by a steady light; light out for execution.
Execute on head nod/light out.
Lower or raise flaps.
Rotary movement of hand (flashlight at night) in cockpit, as if cranking wheels, pause, drop below canopy rail.
Execute when hand/flashlight drops.
Figure 19-14. In-Flight Communications (Sheet1 of 4)
19-27
ORIGINAL
NAVAIR
QI-PI4AAD-I
MEANING
SIGNAL
I
RESPONSE
I
UEL AND ARMAMENT weep wings aft.
Hand held up, palm aft, and swept aft along canopy rail; at night, Flhlight swept aft along canopy
Execute on head nod/light out.
weep wings forward.
Hand swept night, along
Execute on head nod/light
low much fuel have you?
Raise fist with thumb extended drinking position.
.rm or safety missiles and rdnance.
Pistol cocking motion with either hand.
Execute and return signal.
Section leader gives thumbs-up signal.
Stands by for reply from wingman, holding thumbs-up until answered.
Leader gives a two-finger turn-up signal.
Wingman returns two-finger signal and executes.
have completed my takeoff hecklist and am. in all respects, sady for (section) takeoff.
Section takeoff leader raises arm overhead and waits for response from wingman.
Wingman gives thumbs-up indicating checklist complete, and ready in all respects for takeoff then lowers arm and stands by for immediate section takeoff.
hkeoff path is clear ommencing takeoff.
Section takeoff leader lowers arm.
Wingman executes section takeoff.
ake combat cruise.
Leader holds up open hand palm out towards his wingman and pushes out and in.
Execute.
sader shining lead to wingman.
Leader pats self on head and points to wingman. At night, leader aircraft switches lights to bright, and turns anti-collision light on. If an external light failure, leader shines flashlight on helmet, then shines light on wingman.
Wingman pats head and assumes lead. At night, wingman puts external lights on dim, and turns anti-collision light off when he accepts the lead. If an external light failure, wingman shines flashlight at leader, then on his helmet.
held up, palm forward, and forward along canopy rail; at flashlight swept forward canopy rail. in a
out.
Indicate fuel in tens of gallons or hundreds of pounds by finger numbers.
‘ORMATION tK
:ommence Irn-up.
take off power
I am
Figure 19-14. JTIDS Control Panels(Sheet2 of 4)
19-28
NAVAIR MEANING
01.Fi4AAD-1
RESPONSE
SIGNAL
.eader shifting lead to division designated by numerals.
Leader pats self on head, points to wingman, and holds up two or more fingers.
Wingman relays signal: designated division leader assumes lead.
rake cruising formation.
Thumb waved backward over the shoulder.
Execute.
Any pilot blows kiss.
Nod (I understand.)
4ircrafl pointed out, leave ‘ormation.
Leader blows kiss and points to aircraft.
Execute.
Xrects plane to investigate object x vessel.
Leader beckons wing plane, then points to eye, then to vessel or object.
Wingman indicated blows kiss and executes.
defers to landing of aircraft, generally used in conjunction with mother signal: I. I am landing 2. Directs indicated aircraft to land.
Landing motion with open hand: 1. Pats head. 2. Points to another aircraft.
Execute. Alternate signal - Lower gear.
I. Join up or break up, as appropriate !. On GCA/CCA final: Leader has runway/ship in sight.
Flashing external lights.
1. Comply. 2. Wingman continues approach accordance with standard operating procedures.
Mngman
Leader raises forearm vertically.
Execute.
Section cross under.
Leader raises forearm vertically and moves arm in pumping motion.
Execute.
3efers to CV Case l/Case II Jattern: 1. Spin whole flight. !. Indicated aircraft spin.
1. Leader gives a two finger turnup
1. Execute 2. Counting from last aircraft in flight specified number of aircraft execute spin.
am leaving formation.
cross under.
signal.
2. Turnup signal followed by number of aircraft to spin.
in
MR REFUELING Extend Drogue
Form cone-shape move hand aft.
with hand, and
Tanker execute.
RetractDrogue
Form cone-shape with hand, and move hand forward.
Tanker execute.
Secure Turbine
One finger turn-up by cut signal.
Tanker execute.
signal followed
Figure19-14.In-FlightCommunications (Sheet3 of 4)
19-29
ORIGINAL
NAVAIR 0%FUAAD-1 ~OORMATION SIGNALS
MADE By AIRCRAFT
MANEUVER
(COMBAT
OR FREE CRUISE)
iingle aircraft cross under in ,irection of wing dip.
Single wing dip
Execute.
;ection cross under.
Double wing dip
Execute.
:lose up.
Series of small zooms
Execute.
oin up: join up on me.
Porpoise aircraft
Expediiejoin-up.
Figure 19-14. In-Flight
ORIGINAL
Communications
19-30
(Sheet 4 of 4)
NAVAIR Ol-Fl4AAD-1
WING SWEEP 20’ ARIAS IN HU66lN6 POSlllON ACROSSIHC CHCST.THENSWEPT OUT IO SIDES, ARMS WELD SlllAlSll~Jl. _
WING SWEEP SO’ ARMSF6OMSTRIIGHTOUTSWEPl NAli WAYDOWNTO SIOE.
BACKUP MODULE CHECK/ FLIGHT CONTROLS CYCLE CHECK PILOT ROTATESCLENCNEOFIST IN A HORKONTAL PtANE.Sl6NAt. MAN REPEATSSIPNAL If ALL CONIROLSURfACESARE CtLAR Of PERSONNEL/EO!4lPMENT.
OVERSWEEP ARMS. fROM SYRAIGNYOUT SWEM IN ACROSSRE CHEST HU66lNETHESNOULOERS 3 x
DLC CHECK/ RAISE SPOILERS AOMS CXKNOLD H06lZ0NlAt ANDOlllEClll ANEA6.NANOSPOP UP FROMWRISTTOSHOWPALMS. 3 a
LOWER SPOILER ARMS EXIENREO HORKONTAL IIIRECILV AHEADWAH PALMS SHOWING.DROP PALMS FROM WRIST. 3 &
Nl6HYSIGNALSARE THESAMEAS 011 Sl6NAtS UCEPYA6 NOTED.ftASHLl6HYSOR WANDS WILLSURSVlYlJYE FORNANDAN6 FlN6ERMOVEMENTS OURIN Nl6Hl OPERATIONS. CARRIER RIGHTDECK PERSONNELCOLOR CODING REDWIRTSORONANCE and CRASNCREW GREENSPRYS- AIRCRAFIMANITENANCE, CATAPULT CREW,ANO YELLOW SHIRTS- PRIFLY,PUNt OIRECYORS. CATAPULT ARlKSYHENlCREW OFfICERmdARRESYMENY OFFICER BROWN WIRTS- PUNE CAPTAINS BLUE SHIRVSPtANEHANDLERS mhsn. chockAJon,NC.) WHlYE SHIRTS- MEOICAL,SAFETY, VROU6tESHOOTERS. PURPLESWRYS- FUELHANWIN AN0 LSO
Figure 19-15. Deck/GroundHandling Signals
W-31 (Reverse Blank)
ORIGINAL
NAVAIR 01.F14AAP1
CHAPTER
Navigation
20
System the CIU. These units and the information they provide areas follows:
20.1 NAVIGATION SYSTEM Thenavigationsystem(Figure 20- 1)combinesinputs from various on-boardsensorswith inputs enteredby the crew and provides the following outputs of aircraft position: velocity, attitude,heading,accelerations,and angularrates.This information is displayed to the crew andalso usedby the weaponssystemand otheraircrag functions.The systemalsoprovidessteeringandcontrol commandsfor display to the crew as required.
1, Central air data computer and otherair relateddata. 2. AN/ARN-118 tacan tunedtacanstation.
Altitude, airspeed,
Rangeand bearingfrom
3, AN/ASW-2lC datalink - Ship inertial navigation system data for carrier alignment, waypoint coordinates, automatic carrier landing system commands,andvector steeringcommands.
‘Ihe ANIASN-139 inertial navigation set is the primary navigation sensor.It provides inertial information to the MCS via a standarddata bus. As a backupto the INS, the AN/USN-2(V) SAHRS can provide similar, but somewhatdegradedinertial information. Selection of SAHRS datais eitherautomaticon failure of theINS or by operator selection. The MCS processesinertial dataalong with information from other navigation aids to provide smoothedand optimized outputs for display or for use by other aircraft systemsand functions.
4. Instrumentlanding system- SPN-42 courseand glideslopedeviation inputs. 5. UHPiADF tion.
Relative bearing to the tuned sta-
6. ANIAPN-194 radar altimeter the surface.
The ANAJRC-107 ITIDS provides navigation correction data for use in updating the navigation system and velocity data for aligning the INS in flight. When installed, the JTIDS receiver/transmitterreplaces the AN/ARN-118 tacan. With JTIDS installed, the CIU is not usedto convertthe tacandatato a 1553format; the datagoesdirectly from JTIDS to the MCS on the 1553 bus. Navigation information that requires data entry is normally insertedby the RIO using the DEU, however, most parameterscan also be enteredon the RIO digital display keyboard.Navigation and steeringdisplays are provided to the pilot and RIO by meansof various formats on the three MFDs and to the pilot on the HUD. The TID can also provide most navigation displays to the RIO. A BDHI in each cockpit can display aircraft heading from the SAHRS, tacan range, bearing, and UHFiADF bearing. Navigation information from equipment not on the standarddatabus is convertedto the proper format by 20-I
Height above
The CIU also convertsMCS steeringcommand outputsandroll andpitch attitudeinformation from theINS into analogform for the APCS. 20.1.1 AN/ASN-139 Inertial Navigation Set. The INS is the primary navigation sensor.It is a selfcontainedsystemthat includes an inertial measurement unit, processingequipment,andthe supportingelectronics and power supply. It provides inertial navigation inputs to the MCS. The IMU is an all-attitude strapdownnavigation set that mounts three laser gyros for angular rate sensing and three single-axis accelerometersfor acceleration measurement. In the strapdownconfiguration, the sensorassembly is not isolated from the airhame by gimbals and senses aircraft angular rate and accelerationsdirectly. However, local level and wander angle (the difference between initial pointing angle and true north) must be ORIGINAL
NAVAIR Ol-Fl4AAD-1
1
-
SAHRS
I
DP 1
Figure 20-l. Navigation System ORIGINAL
20-2
AFCS
NAVAIR 01.Fl4AAD-1
establishedby alignment for the INS to provide useful information. After alignment, the INS processorkeeps track of the sensorassembly’s orientation with respect to local level and true north by integrating the sensed angularrates.The sensedaccelerationsareresolvedinto north,east,anddown components;correctedfor coriolis andotherfactors;andintegratedto provide velocity and position information. This information aswell as accelerations,body rates, altitude,andtimetaggingdata is provided in digital form to the MCS. Analog outputs of roll and pitch are provided to the AFCS via the CIU. The INS is controlled by the NAV MODE switch (Figure 20-2) on the RIO right console. This switch controls power to the INS and selection of modes of alignment and navigation. This switch is also used to control SAHRS alignment mode during concurrent alignment when both the INS and SAHRS are being alignedin the samemode to the samedatasource.Data entry and selection of INS submodesare by means of the MFD and DEU. The INS uses 115 Vat f?om ac essentialNo. 2 bus throughcircuit breakem3C7, 4C1, and 4C2. Refer to Chapter2 for thealphanumericlisting of circuit breakers.
The INS backuppower supply is a separateunit that provides 28-Vdc power to the INS for transientprotection for up to 20 secondsin flight and to 2 secondson the ground.Battery chargingpower is provided by the ac left main bus throughcircuit breaker 117. 20.1.2 ANIUSNIM Standard Attitude Heading Reference System. The SAHRS is the secondary navigation sensor.It is a self-containedstrapdown all-attitude INS that usesthree laser gyros for angular rate sensing and three single-axis accelerometersfor acceleration measurement. The SAHRS includes a power supply,processor/memory,and otherelectronics to provide outputsto the MCS. In the strapdownconfiguration,the sensorassembly is not isolated t?omthe airfixme by gimbals and senses aircraft angular rate and accelerationsdirectly. However, local level and wander angle must be established by alignmentfor SAHRS to provideusetil information. Afier alignment, the SAHRS processorkeepstrack of the sensorassembly’s orientation with respectto local level and true north by integrating the sensedangular rates.The sensedaccelerationsare resolvedinto north, east,and down components;correctedfor coriolis : d other factors; and integrated to provide velocity and position information.
Figure 20-2. NAV MODE Select/ComputerResetPanel (Sheet 1 of 2) ORIGINAL
NAVAIR
0%F14AAD-1
FUNCTION
NOMENCLATURE 3
NAV MODE Selector
NORM CV - Initiates alignment with or without ships Inertial navigation system (SINS) data. Without SINS data, manual entry of the ships latitude, longitude, true heading, and speed is required. AUGN GND - Initiates alignment for shore based operations. latitude and longitude required for inltlallzatlon.
Own alrcrafl
INS - Selects INS navlgation. IFA - Initiates inflight alignment (alrbome). Requires a valid source of true heading from SAHRS or manual entry of best estimated true heading. Al7 - Selects the IMU backup navigation mode. May require entry of alrcrafl true heading at least one tlme, vla the DEU Own Alrcrafl format. GB - Gyro Bias mode, not functlonal TEST - Provides Built-In-Test deck only).
for Installation and functional verlflcatlon
(On
OFF - Secures system function.
0
SYS RESET switch
Resets translent fallures In the data processors
and mlssion computers.
Figure 20-2. NAV MODE Select/ComputerR&et Pane(Sheet2 of 2) Outputs to the MCS include velocity, heading, attitude, linear accelerations,angular rates,and time tagging data. The SAHRS also generatessynchro outputs of roll and pitch for direct use by the AFCS, and magnetic heading for the BDHI.
breaker9I3 if acpower is not available.Referto Chapter 2 for the alphanumericcircuit breakerlisting.
The SAHRS is controlled by MFD formats. During concurrentalignment with the INS, the NAV MODE select switch also controls the SAHRS. In ita normal operatingmode, the SAHRS is an inertial system with velocity aiding selectable.It can also operateas a conventional attitude heading reference system having slaved, directional gyro, or emergencycompassmodes available.The ‘WI-IRS receivesmagnetic headingfrom the magnetic azimuth detector;provides compensation for aircraft magnetic errors; and provides magnetic headingto the BDHI using the best sourceavailableas determinedby the navigation system. The SAHRS uses115 Vat from the ac left main bus through circuit breakers113,115,and 116.It may also use2%Vdc power corn the interrupt-freebusvia circuit ORIGINAL
Mission Computer System. The navigation system includes the navigation computationsperformed by the MCS. The computations of inertial parametersare performed respectively in the INS and SAHRS processing modules that interface with the MCS. The MCS processesthis inertial data as well as initial entereddataand navigation aiding inputs. Processingincludesgeneratingothernavigationparameters, filtering, time tagging, storing, and distributing datato the displays andother system functions.
20.1.3
204
The MCS consistsof two AN/AYK-14(XN-6) tactical computers: MC1 and MC2. Normally MC2 performs navigation system processingand computations. Should MC2 fail, MC1 will perform virtually all navigation system functions with the exceptionof datalink, JTIDS and radar position updates,JTIDS continuous position update,JTIDS in-flight align, andsurfacewaypoint position determination.
NAVAIR Ol-F14AAD-1
The MCS is the data bus controller; it acceptsINS data and SAHRS data.It acceptsnavigation initialization datafrom the DEU or the DD and subrnodeselections from the MFDs, providing this information to the INS andSAHRS in therequiredformats.It alsoprovides JTIDS the INS or SAHRS dataand acceptsnavigation correction and tacandatafrom JTIDS. Inputs from the variousnavigationaidsareprovided to the MCS via the databus after formatting in the CIU.
paragraph20.3, Navigation System Operation.The displays are discussedin detail in Chapter2. 20.1.6 Tactical Information Display. The TID providestheRIO analternatemeansof display for many of the alphanumericand graphic outputsof the navigation system. Information is transmitted from the MCS to the APG-7 1 andthen to the TID. Selectionof display data is made via the DD.
Basedon crew mode selection,equipmentavailability and input data received, the MCS determinesthe mode of operationand the parametersto be computed. It processesandstoresthesevalues,using them for other functions within the MCS as well as distributing them to the displays and other aircraft functions. 20.1.4 Navigation Data Initialization. Initial manual entry of requirednavigation information is accomplished by the RIO. Either the DEU or the DD control panel canbe used. 20.1.4.1 Data Entry Unit. The DEU allows the RIO to manually entertheinitial navigationinformation requiredfor INS and SAHRS alignmentsand for waypoint location. Such required data inputs include latitude, longitude, altitude, carrier speed and heading, directionalgyro magneticheading,aircrafttrueheading, and surfacewaypoint range and bearing. The various DEU formatsusedareshownin Figure20-3.This Figure showsthe DEU MENU display and the five DEU formatsusedfor entry of initial dataand navigationrelated information. Use of theseformats is discussedin paragraph 20.3, Navigation System Operation. Refer to Chapter2 for detailedinformation on the DEU. 20.1.4.2 Digital Display. The APG-71 DD provides the RIO with an alternatemeansof enteringmost initial navigationdatainto the systemexceptfor SAHRS DG headingandbarometricaltimeter settingandcontrol of JTIDS navigation functions.Use of the DD for entry of navigationis provided in paragraph20.3,Navigation SystemOperation. 20.1.5 Displays Subsystem. Navigation information is provided to the pilot andRIO in both graphic andalphanumericformatsvia HUD for thepilot and the threeMFDs for both crewmembers.In addition, certain MFD formats provide pushbutton legendsthat permit submodeselectionandselectionof otherrelateddisplay formats. These include HUD, VDI, HSD, OWN A/C, NAV AID, SURFACEWPT, INS UPDATE, andseveral alignment formats. A description of the outputs available and the use of theseoutputs can be found in paragraph 20.2, Navigation System Data Distribution, and
20-5
20.1.7 Converter Interface Unit. The CIU acceptsall nondata,bus-compatiblenavigation aid inputs and convertsthem to the proper format. The CIU also convertsthe steeringerror commandsgeneratedby the MCS into the required analog signals for the AFCS. Thesenavigation aids, as they pertain to the navigation system,aredescribedin the following paragraphs. 20.1.8 Central Air Data Computer. The CADC is a single processor digital computer that gathers, stores,andprocessespitot pressure,staticpressure,total airstream temperature,and angle-of-attackdata from aircraft airstream sensors.In addition to performing wing sweep, flap and slat schedulecomputations,and limit controlsfor the flight control systems,the CADC provides air datarelatedparametersto the MCS via the CIU. This information includespressurealtitude, pressurealtituderateof change,true andcalibratedairspeed, angle of attack,and Mach number.True and calibrated airspeed,angle of attack, and Mach number are displayed directly to the crew on the HUD andVDI format of the MFDs. Pressurealtitude is correctedfor nonstandard day conditions and then displayed as system altitude.True airspeedmay also beusedin thecomputation of wind. Wind providesa referencevelocity sourcefor the INS or SAHRS for in-flight alignment and is a component of system velocity during backup navigation modes.A descriptionof the pitot-static systemand the CADC is provided in Chapter2. 20.1.9 ANIARN-118 Tactical Air Navigation System or ANIURC-107 Joint Tactical Information Distribtuion System. The tacan system is a UHF navigationreceiver-transmitterthat is usedto provide navigation information by determiningslant range and bearingto a selectedtacanstation.Operatingrange is line of sight to approximately 300nm. Accuraciesare 0.1 nm in rangeand 0.5’ in bearing.The tacanstation I can be surface (land basedor shipbome) or airborne. Surface stations can be either tacan or vortac. When operatingin the REC or T/R modes,the systemis capable of receiving signals from a ground station simultaneouslywith 99 other aircraft. When in the A/A mode, the system is capableof transpondingwith eachof five cooperatingaircraft, providing slant range information to each;however, the system will interrogateand lock ORIGINAL
NAVAIR Ol-F14AAD-1
Figure 20-3. DEU Navigation Formats
ORIGINAL
20-6
NAVAIR 0%F14AAD-1
I
on, a failure is indicated and tacan information should be disregarded.As in all tacansets,undetectedfailures can occur,so information provided by the tacanshould becross-checkedwithotheravailablenavigationinformation.
on to only one. In A/A mode, the secondaircratI must be 63 channelsapart.An airbornestationprovidesonly slant rangedistanceunlessthe aircraft is equippedwith a bearing transmitter and a rotating antenna. The ANIARN-llSorANiURC-107arenotabletotransmit bearinginformation but can receive it from a specially equippedaircraft.
Available tacanrangeand bearing information is always displayedon thepilot and RIO BDHIs andcan be selectedfor display on the BUD and MFDs. The tacan data supplied to the MCS can be used for a one-fix updateofthe INS andSAHRS, continuousupdateof the system navigation solution, or for steering. The AN/URC-107 (JTIDS) tacan requires the selection of DATA SE., NORM, or POLL on the JTIDS control panel (Figure 20-4) to supply digital tacan information to the MCS. This is required for tacan displays on the MFD, navigation updates,and tacan steering.Refer to paragraphs20.3.6.2,Updates,20.3.6.3,ContinuousPosition Updating, and 20.3.6.5,Display SteeringModes. The tacan has 126 X channelsand 126 Y channels available 1 MHZ apart.The tacanusestwo aircraft antennas,automatically switching betweenthe two at 5secondintervalsuntil a thresholdsignal is received.The AN/ARN-1 18 requires approximately 2 minutes for warmup; AN/URC-107 (JTIDS) is operationaloncetacan self-test is complete. If stable range and bearing indicationsarenot availableafter this time, tune another stationor check circuit breakers. Note JTIDS tacan has shown reduced receiver sensitivity on channel 83. Use of channel 83Y (G/Aand A/A) and83X (A/Aonly)may not receive accurateinformation outside 40 miles. The tacm hasa memory featurethat allows tracking to continueuninterruptedby momentarylossof received signals.A rangesignal that hasbeentrackedfor at least 10 secondswill be retained in memory for 13 to 17 secondsafter signal loss; a bearingsignal trackedfor at least 15secondsis retainedfor 2 to 4 secondsafter signal loss. This featureallows for automatic antennaswitching without loss of tacanoutputs. If the signal Born a tacan station becomes unreliable or is lost for more than memory time, then the tacan switches to self-test automatically. This may causethe BDHI relative bearing to be 270’ for 2 to 4 seconds.If the signal is not acquired during the selftest, the BDHI bearing pointer will continuously slew in a counterclockwise direction andthe TEST light on the tacan control panel will light. If the light remains 20-7
The AN/ARN-118 tacan uses 115 Vat from the ac essentialNo. 2 busthroughcircuit breaker3D5,28 Vdc 6om dc essentialbus No. 2 via circuit breaker8E7, and 26 Vat Born the 26-volt essentialbus through circuit, breaker3D4. In addition to the power andcircuit breakers usedby the AN/ARN- 118,the ANKIRC- 107 tacan also requires115Vat from essentialNo. 2 bus through circuit breaker4D3 and4D4. Referto Chapter2 for the alphanumericcircuit breakerlisting. 20.1.9.1 Tacan Controls and Indicators. Two identical TCN control panels(Figure 20-4), onein each cockpit, are provided to permit either crewmember to operate the tacan. To determine which crewmember controls the tacan, each cockpit has an alternateaction TACAN CMD pushbuttonthat illuminates either PLT or IWO to show which cockpit has command. Both buttonsallow each crewmemberto either give or take commandof the tacan.A BDHl in eachcockpit provides rangeand bearingto a tuned tacanstation. Other tacan displaysmay be selected. 20.1.9.2 Tacan Testing. Tacan testing includes continuousmonitoring and commandedself-test.Continuousmonitoring checkscertain internal timctious of the tacanon a continuousbasis.Failure of one of these checkscausesthe TEST light on the TCN panel to illuminate.Commandedself-testis eithermanually or automatically initiated. The TEST button is a momentary action pushbutton switch that is pressedto place the tacaninto thecommandedself-testmode manually.The testmay be accomplishedin all operatingmodes.Commanded self-testinterrupts normal operationfor a 22secondcycle andprovides a high-confidencetest of the tacan exceptfor the antennas.When TEST is selected in T/R, a power check is initiated for the transmitter, receiver,distance,andbeating circuita.The BDHI hearing pointer should swing to 270’ in 2 to 7 secondsand the rangeOFF flag should appear.After approximately 7-seconds,the BDHI bearingpointer should swing to 180’ and thenOFF flag should disappear.The distance indicatorshouldread000.0nm. The BDBIshould return to its original bearing and distance readings after 15 seconds.The TEST light will momentarily flash when the test is initiated. If the light goes on and stays on during test, a malfunction is indicated.In addition, the OBC CNT format on the h4FD displays a tacanNO-GO or NOT READY indication if thereis a test failure. If a self-testiu the TIR mode resultsin a failure indication, select REC and perform the test again. If the failure ORIGINAL
NAVAIR Oi-Fl4AAD-1
Figure 204. Tacan Controls and Indicators(Sheet1 of 3) ORIGINAL
20-E
NAVAIR
NOMENCLATURE 0 0 @
BDHI tacan needle
FUNCTION Displays relative bearing to the selected tacan station
BDHI UHF/ADF needle
Displays relative bearing to a tuned UHF transmitter.
i,“d;;m
Displays slant range to a selected tacan station.
r=w3
Q1-Fl4AAD-I
Alternate action lighted pushbutton that lights PLT or NFO to indicate which cockpit has command of the tacan. Pressing the button cycles command to the other cockpit and changes light indication. 0 @
Tacan VOL control
Varies level of the tacan audio signal to the headsets. Clockwise rotation increases volume.
Tacan mode switch
OFF -
Power not applied to tacan
REC -
Receive: Tacan determines bearing from aircraft to selected tacan station. Bearing displayed on BDHI; available for MFD, HUD. Station identifier is received, no range is calculated.
T/R -
Transmit-receive: In addition to the REC functions, tacan determines slant range to selected tacan station. Distance displayed on BDHI; available for MFD, HUD.
A/A REC - Air-to-air receive: Tacan receives bearing information from a suitably equipped cooperating aircraft and calculates the relative bearing to the cooperating aircraft. No distance information is available. A/A T/R -
Air-to-air transmit-receive mode: Tacan receives both distance and bearing information from a suitably equipped cooperating aircraft and calculates the slant range distance and relative bearing of the aircraft. If the aircraft is not equipped with bearing transmitting capabilities, only slant range is available. Note
0
Right hand channel knob
l
Air-to-air tacan operation requires a 63 channel separation between cooperating aircraft. Channel use should be prearranged. Air-to-air tacan between F-l+ is limited to slant range, no bearing is provided.
l
When the ANAJRC-107 (JTIDS) is installed, tacan data on the HUD and MFD requires the selection of DATA SIL, NORM, or POLL on the JTIDS control panel.
The inner knob sets the channel number units digit. The outer knob sets X and Y channels.
Figure 204. Tacan Controls and Indicators(Sheet2 of 3) 20-9
ORIGINAL
NAVAIR 0%F14AAD-1 FUNCTION
NOMENCLATURE c9
@
0fg
TEST button/light
The TEST button is used to initiate self-test. The light illuminates to indicate failure of continuous monitor test or either manually or automatically initiated self-test.
Left hand channel knob
Sets channel number hundreds
CHANNEL window
Displays selected channel number and X or Y
and tens digits.
Figure 20-4. Tacan Controlsand Indicators (Sheet 3 of 3) indication is removed,bearing information is still valid. The ANKIRC-107 performs all the sametacantestsas the AN/ARN-1 18. It also performs a commandedselftest when a JTIDS OBC is selectedon the MFD OBC page.JTIDS OBC provides tacanfail dataon the JTIDS fail datapage.Refer to JTIDS self-testChapter27. The following will causethe tacan lock to break for 4 seconds:the power up or down of JTIDS, going from OFF or STBY to DATA SIL, NORM, or POLL or back to STBY or OFF on the JTIDS control panel. The range off flag will appearandbearingwill swing to 270” for 2 secondsthen reacquirelock to the station. Whenevera signal becomesunreliable (loss exceeds memory time), self-testis initiated automatically. If the TEST light goeson at any time during flight, it indicates a failure of automatic self-testandall tacaninformation should be disregarded. 20.1.10 AN/ASW-27C Data Link. During carrier alignment, D/L provides SINS datato the INS via the CIU. This data is also provided to the SAHRS during concurrent carrier alignment, Before takeoff the D/L can be used to provide waypoint coordinates to the MCS via the CIU for later use in steering andposition updating. After takeoff, the D/L provides control and steering commands that are available for display or may be coupled to the autopilot during vector steering or ACL operation. Refer to NAVAIR Ol-Fl4AAD-1A discussionof datalink.
ORIGINAL
for a complete
20.1.11 UHF Automatic Direction Finder. The UHF/ADF provides the relativebearingto a UHP transmitting station t?om the aircraft. This information is displayeddirectly on the BDHI and on the MPD HSD format. 20.1.12 Bearing Distance Heading Indicator. A BDHI is on the left side of the pilot andRIO instrument panels (Figure 20-4). The BDHI is a remote heading indicator that displays aircraft magnetic heading,tacan and UHPIADF bearings,and tacan slant range.The rotating compasscard receivesits headingreferencefrom the SAHRS. Aircraft heading is read against a fixed index mark at the 12-o’clock position, The two servodrivenneedlesarepositionedby relativebearinginfomration providedby the UHP/ADF to the singlebar (No. 1) needleandby the tacanto the double bar (No. 2) needle. Magnetic bearingto the stationis readunderthe headof the needle.Relative bearingcanbe determinedby comparing the bearingreading with magnetic heading.The rangewindow on the right side of the indicator displays tacan slant range. When the tacan is off or range is unreliable,an OFF flag coversthe window. 20.1.13 ANIURC-107 Joint Tactical Information Distribution System. JTIDS is a jam-resistant communication system that provides the F-14D with two-way securedata and digital voice communication. In addition to the JTIDS communication functions, it also provides the F-14D with navigation and tacan data.
20-10
NAVAIR 01.F14AAD-1
The JTIDS systeminternally computesrelative navigation and position location information. All patticipants(JTIDS terminals) in the samenet determinetheir position relative to eachother.This is referredto as the JTIDS relative navigation function. The basis of this function is the TDMA architectureandprecisesynchronization of all participantsto a common time base(net time reference).This allows each JTIDS system to accuratelydeterminethe time a messagewas transmitted and its TOA, and then compute the range from the sourceof the message.JTIDS computesan estimateof its own relative position coupled with the position and navigationquality containedin each participantsPPLI message.With data from multiple participants with equalor betterposition plus the navigation datafrom the INS or SAHRS, JTIDS can compute an excellent estimate of own-ship position and velocities. JTIDS will automatically updatethe own-ship position in the PPLI messagewith its estimatedposition. It also provides an estimatedquality (accuracy)ofthe position it computed. This quality is provided to the MCS and included in the PPLI message.
hasthe ability to selecteither of theJTIDS grids via the NAV SYSTEM AID page. This selection determines which datathe MCS will use to perform the track conversion and continuousposition updates.Independent of this selection,JTIDS one-f= andINS in-flight alignmentswill alwaysbe performedusingthe geodeticdata.
JTIDS is a dual grid systemutilizing a geodeticand an independentrelative grid. JTIDS can operatein both grids simultaneously,but the MCS is limited to operating in one grid at a time. The relative mode requiresa coordinatedgrid origin (latitude and longitude) and the selectionof NAV controller (a high-quality navigation source).The geodetic grid is the F-14D default mode and,unlike the relative grid, requiresno special coordination.RefertoNAVAIROl-F14AAD-IA forthe MFD displaysof JTIDS navigation parameters.
20.2.1. Navigation Data Display. Navigationinformation is displayedto the aircrew in graphicform on the HUD and MFD and in tabularform on the MFD.
JTIDS receivesnavigation sensordatafrom the MCS and returnsnavigation corrections.The sensor data is used by JTIDS in its relative navigation calculations, own-ship position in the PPLI message,and for calculating navigation corrections. The JTIDS navigationcorrectiondatasentbackto the MCS is used to perform track conversionsand navigation updates.The JTIDS correction data will only be usedfor track conversionsandnavigationupdateswhen it is valid andhas a quality 53 (5 18,080feet in error). The track conversion function uses the JTIDS delta navigationcorrectionsto pad all received and transmitted tracks on the JTIDS link into the JTIDS navigation reference.This function is performed automatically by the MCS. The navigation update function has to be manually selected.Theseselectionsare JTIDS one-fix, continuous position, and INS in-flight alignment. The aircrew
Internal to the JTIDS system is the equivalent of an AN/ARN- 118 tacan system. Installation of JTIDS in the aircraft replacesthe AN/ARN-1 18with the JTIDS receiver/transmitter. Refer to 20.1.9 for JTIDS tacan operation. 20.2 NAVIGATION SYSTEM DATA DISTRIBUTION The navigationsystemprovidesdatato othersystems and functions as well as for display to the crew. In general,this is similar to displayed data,but such parameters as aircraft angular rates, accelerations,and time tag dataare alsoincluded. Figure 20-Ssummarizes navigationsystem outputs.
With the DISPLAYS panel TLN (takeoff, landing, navigation) MODE button is selected,both the HUD andthe MFD VDl format show navigationinformation graphically in the vertical plane. The MFD can also show a HSD format that provides graphic navigation information in the horizontal plane. Tabular information relating to alignment, waypoints, and own aircraft can be displayedon theMFDs. The navigation information provided by the various display selections is described in the paragraphsthat follow. 20.2.1.1 HUD TLN Basic. The HUD provides ptimary flight and navigation information in graphic and numeric form in a portion of the pilot’s field of view throughthe windscreenencompassingl lo0 in azimuth andelevation(Figure 20-6).A repeatofthis information can be displayed on the MFD by selecting the HUD pushbuttonon the MENU1 format. In addition to the information in Figure 20-6, other HUD formatsprovide indicationsofglideslope andcenterline errorsfor ACL and ILS steeringmodesas well as flight director steeringinformation and commanded heading.
20-l 1
ORIGINAL
NAVAIR
01.F14AAD-1
NAV
OUTPUTS
TO DISPLAYS
OTHER MC5 FUNCTIONS
LAT. LONO.ALTITUDE TRUE“EAOINO TRUEAIRSPEED
ANOLEOFATTACK I ....--.FITCHBODY .--. RATE
I
-
I -
MFD VDI FORMATS ORAPHlCS a ALPHANVMERCS
NAVIGATION SYSTEM
HSD FORMATS ORAPHICS a ALPHAN”MERlCS
Figure 20-5. Navigation SystemData Distribution ORIGINAL
20.12
SYSTEMlRIOAR ALTITUDE VERTICAL VELOCITY CAUBRATEOAIRSPEED MACH NO., am0 PRESSURE Aa. LAT a “WIT ERROR ILS A2 (L EL DEVIATION TCN,OESTlNATlON RANOE OIL CM0 ALTlMACH NO. OIL CM0 HEAOINO COYHAND HEADlNO
NAVAIR Ol-Fl4AAD-1
TLN GEAR UP, FORMAT SWITCH-ANALOG
LEGEND HEADING SCALE
FLIGHT PATH MARKER
WATER LINE
NAV RANGE
PITCH LADDER
ANGLE-OF-BANK
POTENTIAL FLIGHT PATH MARKER
PEAK G
GHOST FLIGHT PATH MARKER
AIRCRAFT G
RADAR ALTITUDE READOUT
MACHNUMBER
SCALE
ALTITUDE ANALOG DIAL
ANGLE-OF-AlTACK
VERTICAL VELOCITY
AIRSPEED ANALOG DIAL
*DISPLAYED
READOUT
AS REQUIRED
(WI-F50D-411-0
Figure 20-6. HUD Navigation Outputs(TLN Basic)
20-13
ORIGINAL
NAVAIR Ol-Fl4AAD-1
20.2.1.2 MF D VDI (Basic) Format, TLN Mode. The h@Ds provide a VDI format that is a representation in the.vertical planeof a field of view of *4Y in azimuth and elevation.In theTLN basic mode (Figure 20-7),the VDI format displays the sameinformation as the HUD exceptfor theairspeedandaltitude dials, angleofattack, and g readouts.
20.3 NAVIGATION SYSTEM OPERATION
This format also provides readoutsof the courseand headingselectedusing the CRS and HDG knobs on the pilot center instrument panel (FO-3). Pushbutton legendspermit selection of destination@EST), data lii (D/L), tacan (TCN), manual (MAN), or all-weather landing (AWL) steering.
Proceduresfor operationaluseof the navigationsystem are.providedin the paragraphsthat follow including display formats and control selections for alignment, datainitialization, m-flight navigation,sensorselection, degradedmode operation,and tactical navigation.Tactical navigation includes position updating, surface waypoint position determination,rangeand bearing to selectedwaypoints, display steering,autopilot steering, and AWL aircrafi control. These proceduresare normally performedin the TLN mode; howevernavigation outputsareavailableto otheraircraft functionsand displays in all modes.
In addition to the information in Figure 20-7, other MFD formats provide indications’of ACL glideslope and centerline errors, glideslope and centerline errors from ILS, flight director glideslopeandcenterlinesteering information, commanded heading, commanded speedand altitude information, and HUD flight director declutter.
20.3.1 INS and SAHRS Concurrent Allgnment. In all modes of concurrentalignment,both the INS andthe SAHRS are alignedin the mode selectedon the NAV MODE switch (Figure 20-2). The systemwill always align to WPT 1 unlessmanual entriesaremade. Normal operationof the MCS and MFD is requiredfor any alignment.
20.2.1.3 MFD Own-Aircraft (Basic) Data Format. The MFD own-aircrafi (basic) data format (Figure 20-8) tinnishes navigational data in tabular form. This format can be called up from severalof the MFD formats by selectingthe DATA pushbuttonlegend.
20.3.1.1 Normal Concurrent Ground Alignment 1. Selectown-aircmfth@D format, (Figure20-8) by depressing “DATA” pushtile on the MFD MENU1 page(Figure 20-l 1).
In addition to the parametersshown in Figure 20-8, other own-aircraft MFD formats are available. During alignment, theseprovide indications of alignment progressin both numeric and graphic form and INS north and eastvelocities. 20.2.1.4 MFD HSD (Basic) Format, TLN Mode. The MFDs provide a HSD format (Figure20-9)showing anaircral?centeredrepresentationof the situationin the horizontal plane. In the TLN basic mode, it furnishes information on the position of waypoints,tacanstations, and destinationpoints with respectto the aircraft that is at the display center.The distancescalefrom the aircraft symbol to the inner edgeof the compassrosecan be set at 200, 100, 50, 25, or 10 miles. Numeric displays of range,bearing, and time-to-go to a selectedwaypoint andto a selectedtacanstation areprovided. In addition to the information shown in Figure 20-9, otherHSD formats provide two tacansteeringdisplays as well as data-link, destination, and manual steering displays (see paragraph 20.3.6.5, Display Steering Modes). 20.2.1.5 Navigation Data DisplaySummary. Figure 20-10 summarizesthe navigation dataavailable on HUD and MFD formats. ORIGINAL
20-14
2. Verify displayed latitude and longitude. If incorrect, entercorrect coordinatesvia the DEU or DD. For DEU dataentry, the DEU OWN A/C pageis selectedandthe latitude andlongitudecoordinates may be enteredto 0.01 arc minute using the LAT and LONG pushtiles and the proper hemisphere numerals (Figure 20-12). On the DEU, longitude entriesless than 100’ require a 0 be enteredprior to the value. For DD data entry the DD control panel is usedwith the NAV categoryselectedusing the MFK pushtile (I%gure20-13). The OWN A/C acronym is thenboxed by depressingthe correspondingpushtile and the coordinatesare entered via the LAT, LONG, hemisphere, and numeric pushtiles shown on the computeraddress panel on the lower left portion of the DD control panel. Latitude and longitude coordinatesmay be enteredvia the DD to the nearest0.1 arc minute. Longitude entries on the DD below 100’ do not require a 0 prior to enteringthe numerals. 3. Verify parking brake is set. 4. Set NAV MODE switch to GND. The OWN A/C GRND format will be displayedon the MFD (Figure 20-14).
NAVAIR
Ol-Fl4AAD-l
TLN BASIC
LEGEND
Figure 20-7. h4FD VDI (TLN Basic) Navigation Outputs 20.15
ORIGINAL
NAVAIR 01-Fl4AAD-1
I
Figure20-8. Own-AircraftBasicDataFormat ORIGINAL
20-16
NAVAIR 01.F14AAD-1
g
SELECTED
WAYPOINT
12 DESTINATION
0 0 0 3
MAGNETIC
4
ADF BEARING POINTER
5
SELECTED
g
0
13 SELECTED
HEADlNG
WAYPOINT
DATA
COURSE @
WAYPOINTSYMB~L 7
BEARING
TIME-TO-GO
SELECTEDCOURSEREADOUT
0
COMMANDED HEADING (DESTINATION MANUAL AND DATA LINK), SELECTED HEADING (TACAN)
COMPASS
ROSE RANGE SCALE
DESTlNATlON
g
SELECTED
HEADING READOUT
9
10 INSISAHRS
g
GROUND SPEED 17
HEADING SOURCE INDlCATlON
WAYPOINT
TRUE AIRSPEED
(ATj2-FSOM14-0
Figure 20-9. MFD HSD Format-Navigation
20-17
Outputs
ORIGINAL
NAVAIR
0%F14AAD-1
DISPLN _.-. _
NAVIGATION
I
Own Aircraft lnflight
Latitude Longitude Altitude Barometric Setting Magnetic Variation Wind Direction/Speed True Airspeed Groundspeed True Heading Navigation Quality
Own Aircraft Ground Align
Latitude Longitude Altitude Barometric Setting Magnetic Variation Groundspeed True Heading Align Time/Quality
DATA DISPLAYED
North/EastVelocities Aircraft Carrier (CV) Alignment
Latitude Longitude Magnetic Variation CV Speed CV Heading Vertical Lever Arm Align TlmelQuality
SAHRS Alignment
Latitude Longitude CV Speed CV Heading
HUD Display
Roll (Symbols) Pitch (Symbols) Magnetic Heading (Symbol) Flight Path Marker (Symbol) Potential Flight Path Marker (Symbol) System Altitude Radar Altitude Vertical Velocity Calibrated Airspeed Barometric Setting
Figure 20-10. Navigation Data Display Summaq (Sheet 1 of 2) ORIGINAL
20-18
NAVAIR
DISPLAY
I
NAVIGATION
Ol-F14AAD-1
DATA DISPLAYED
Flight Director Position and Rotation Angle-of-Attack Mach Number Normal Acceleration (g) ACL Lateral &Vertical Errors (Symbol) ILS Azimuth & Elevation Deviation (Symbols) Command Heading (Symbol) MFD VDI Format
Roll (Symbols) Pitch (Symbols) Magnetic Heading (Symbol) Flight Path Marker (Symbol) System Altitude Radar Altitude Vertical Velocity Calibrated Airspeed Barometric Setting Mach Number ACL Lateral 8. Vertical Errors (Symbol) ILS Azimuth &Elevation Deviation (Symbols) Command Heading (Symbol) Range to Tacan/Destination D/L Command Alt/Mach No D/L Command Heading (Symbol)
MFD HSD Format
Magnetic Heading (Symbol) Magnetic Course (Symbol) Wind Direction/Speed True Airspeed Groundspeed Way Point No/Brg/RangeiTfG Tacan Sta NoIBrglRangeilTG Tacan Brg/Deviation (Symbols) Tacan Command Course (Symbol) Destination No Destination Brg/Cmd Course (Symbols) ADF Bearing (Symbol) Command Heading Course Select Heading Select
Figure 20-10. Navigation Data Display Summary (Sheet2 of 2) 20-19
ORIGINAL
NAVAIR Ol-F14AAD-1
Figure 20-I 1. MFD MENU1 and MENU2 Displays ORIGINAL
20-20
NAVAIR Ol-Fl4AAD1
TYPICAL DATA ENTRY DISPLAYS OWN AIC PARAMETER SELECTED/DATA KEYED IN.
OWNAC-ALT
-
OWN Ax:.
ALT 1050
OWN AC.
THDG 210
_
OWN NC
WSPO
-
OWN AIC~ WSPD 35
_
OWN A/c.
WDlR
OWN NC.
WOIR
--*ONLY THE RESPECTIVE CHARACTER LEGENDS (S, -, W. N. +, E, OR BLANK) APPLICABLE TO THE PARAMETER SELECTED WILL APPEAR ON THE OPTION DISPLAY LEGEND
Figure 20-12.
_
OWN AC - MVAR
030 OWN A/o.
MVAR 17.5E
OWN AIO~ BAR0 29.92
DEU Own-Aircraft
20-21
Data Enhy (Typical)
ORIGINAL
NAVAIR Ol-F14AAD-1
Figure 20-13.
ORIGINAL
DD/TID
Own-Aircrafi
Data Entry
NAVAIR 01.F14AAD-1
GROUND ALIGNMENT
STORED HEADING GROUND ALIGNMENT
OWN A/C
BUN0
SHOG GRND
000000
INSISWRS PUAL6.59 TIME, .31
Figure 20-14. MFD Ground Alignment Fomats 20-23
ORIGINAL
NAVAIR
Ol-F14AAD-1
10. Advancing the NAV MODE switch to INS will command the INS to its inertial navigation mode. If the parking brake is still applied at this time, the SAHRS will continue aligning.
5. Verify that SHDG is not boxed. If it is, pressthe SHDG pushbuttonto unbox SHDG. Note
Unboxing of SHDG must be performed within 17secondsof selectingGND ALIGN on the NAV MODE switch or the boxed SHDG will be selectedand unboxedby the systemanddeselectionwill not be available.
11, In order to improve INS performance,enhanced alignment may be obtainedby performing the following procedure. a. Initiate a standardalignment.
Verify latitudeandlongitude andentercorrectvaluesif necessary.If new entriesarerequiredat this time, the alignment time may be extended,dependingon the differencesbetweenthe newly entered valuesand thosedisplayed when alignment was initiated. Alignment progresscan be monitoredby observing the QUAL andTIME acronymsand the alignment scaleon the MFD OWN A/C format.The indicator on thealignmentprogressscalechangesRooma “V” to a diamondsymbol at the fmt tic mark. This representsan 8 nm per hour estimatednavigationquality. The secondtic mark representsan estimated2 nm per hour quality and the third an estimated0.8 nm perhourquality.At this pointa dotappearsin the diamond. An INS ALIGN COMPLETE message normally appearsat the top of the MFD display in 4 minutes.At this time the QUAL acronymis nearor slightly below 1 nm per hour andthe pointeron the align scaleshouldbe nearthe lasttic mark. During concurrent alignment, it is advisable to monitor the SAHRS alignment progressby pressing the SAHR pushbuttonon the MFD. The OWN A/C MFD format will show SAHR boxed;andthe QUAL and TIME acronyms and the align scale now refer to the SAHR. A SAHRS ALIGN COMPLETE message normally appears in approximately 2.5 to 3 minutes from the time when the parking brakewas set.The QUAL will be approximately 10(nm per hour) at this time. 9. Alignment may becontinuedaftertheappearance of the INS ALIGN COMPLETE messageif time permits. This will provide only slight improvementin alignmentquality butwill providesomegyrobiasing andeliminate unnecessarydrift in the INS mode,If the parking brakeis releasedduring alignment,the INS and SAHRS will go to a SUSPEND ALIGN stateas indicatedby the computermessageon the OWN A/C MFD format.Alignment will beresumed upon applicationof theparkingbrake. The numerical alignmentquality displayedwill neverbe lower than0.50.Actual INS/SAHRS drift rateis normally lessthan 0.50nm per hour, ORIGINAL
b. Allow alignment to continue until an INS ALIGN COMPLETE messageappearson the MFD. c. Without changingtheNAV MODE switch position, taxi the aircraft to a convenientlocation, changingtheheadingby at least70”, with 180” headingchangebeing optimal. d. Reapply the parking brake and allow the INS to continue alignment for a minimum of 1 minute (7 to 8 minutes desired). Note
The latitude and longitude waypoint 1 will be updatedto current aircraft position when the NAV MODE switch is placed to INS. 20.3.1.2 SAHRS
Stored Alignment.
Heading
Concurrent
INS/
Stored heading alignment is performedwhen rapid system reaction is operationally required. Under normal conditions, stored heading alignment can reduce ground align time by 1 minute. This procedurerequiresthat a previousreferencealignment be performed and that the aircraft remain stationary until the subsequentstored heading alignment is completed. Perfo’rma referencealignment by following the normal ground align procedure in paragraph 20.3.1.l. When the INS ALIGN COMPLETE messageappears on the HUD and/orVDI format, returntheNAV MODE switch to OFF. The aircraft heading should now be stored in the INS and should be available for the next alignment as long as the aircraft has not beenmoved.
20-24
Note
Selecting the SAHR pushbutton on the OWN A/C or NAV DATA MFD formats before the diamond reachesthe secondtic mark will inhibit a subsequentstoredheading alignment.
NAVAIR 01.F14AAD-1
1. Repeat steps 1 through 4 for normal ground alignment. 2. Verify that SHDG is boxedon theOWN A/C MFD format (Figure 20-14). Do not depressthe SHDG pushbutton. 3. Repeatsteps6 through9 asin normal groundalign procedure. 20.3.2 Concurrent Carrier Alignment. Carrier alignment of the INS and the SAHRS requiresknowledgeofthe carriermotion andposition. This information is best provided by the SINS. A storedheadingcarrier alignment is also available using SINS inputs, after a reference alignment has been performed. For SINS storedcarrieralignment,the storedparameteris actually the aircraft’s spotting angle on the carrier.
7. Select OWN A/C MFD format by depressing DATA pushbutton on MFD MENU1 display. The CV SINS DATA format will appear(Figure 20-15). 8. Verify that SHDG is not boxed. If it is, depress the SHDG pushbuttonto unbox it. 9. Monitor the progressof alignment by observing theQUAL andTIME acronymsandthe align scale on the MFD OWN A/C format. The SINS (ship’s) latitude,longitude, and INS north and eastvelocities can alsobe evaluatedon the MFD OWN AK format. An INS ALIGN COMPLETE message will normally occur in 7 minutes. At this time the align quality should be below 1 nm per hour. Note Do not select SAHR during CV ALIGN to check alignment progress. Wait until INS alignment is complete and INS hasbeenselectedon the NAV MODE switch beforeselecting SAHR.
In the event that SINS data is unavailable, carrier alignment can takeplace by manual entry of ship’s position,speed,andheading.This procedureis calledmanual carrier align. Because of the entry of fixed parameters,its real values may be changing and extendedalignment time with lesseralignment quality can be expectedfor manual carrier alignment.
10. SAHRS alignment progressmay be monitored at this time by selectingthe NAV page.
20.3.2.1 Concurrent SINS RF or Cable Carrier Alignment. Carrier alignment using SINS data from the ASW-27C D/L can be implementedby eithercable or RF transmission, depending on whether the SINS cable from the deck-edgebox to the nose wheelwell connectoris plugged in. For either mode of data transmission, the following alignment procedureis used,after verifying properoperationof the MCS andMFD.
Note The SAHRS alignment processwill initiate after the INS determinesa valid true heading (approximately at INS quality value of 5). SAHRS quality value should reinitiate to approximately 31.2 at that time.
1. EnsureSAHRSAC/DCcb’s(lA3,1A5,1A6,913) pulled prior to application of electrical power.
If power has been applied to the aircraft for anextendedperiod oftimeprior to INS CV align being initiated, the SAHRS may complete a ground align (NORM) and a SAHRS completemessageappearson the MFD. After the INS CV align is initiated, the SAHRS will initiate a concurrentCV align normally, but anotherSAHRS align completemessagemay not appear.
2. DATA LINK power switch 3. DATA LINK MODE switch -
ON. CAINSWPT.
4. Verify parking brake is set. Note Application of SAHRS powerprior to selecting CV ALIGN will not allow SAHRS to properly align, 5. NAV MODE switch -
11. It is advisableto continuealignment after appearanceof the INS ALIGN COMPLETE messageif time permits. When ready to take the alignment, the inertial navigation mode may be selectedby settingthe NAV MODE switch to MS.
CV ALIGN.
6. ResetSAHRS cb’s.
20.25
ORIGINAL
NAVAIR
01.Fl4AAD-1
CV ALIGNMENT
CV SINS
DATA
N 37’16.15 w134--34.31 MV-T 5.3E
STORED
CV SINS
HEADING
CV ALIGNMENT
DATA
N 37-15.15 w134*34.31 MY-T 5.3E C” SPD017
Figure 20-15. CV Alignment Formats- SINS ORIGINAL
20-26
NAVAIR Ol-Fl4AAD-1
Note Although SINS carrier alignment normally requiresno entry ofdata, ifa SINS alignment takesplace at any carrierlocation other than the flight deck, then it is advisable to enter the correct vertical lever arm via the DEU. This is the height in feet of the aircraft INS abovethe carrier’s SINS location,This entry canbe madeonly via the DEU by calling up the DEU CV ALIGN page and depressing the VLA pushtile shown in Figure 20-16.
Note If the SINS or data link is not operatingor if a manual carrier alignment is desired,skip steps2 and 3. 2. Enterbestknowledgeof ship’s latitude,longitude, speed,andheadingvia the DEU or DD. Whenthe DATA pushbuttonon the MFD is depressed,the CV MANUAL DATA format, shown on Figure 20-16 appears.
20.3.2.2 Concurrent SINS Stored Heading Carrier Alignment. Carrier alignment time can be reducedby 1 minute by performing a stored heading carrier alignment. This procedurerequiresthat a referencealignment be performedusing SINS dataandthat the aircraft’s position on the carrier remain stationary until thecompletion ofthe subsequentstoredalignment. Perform a referencealignmentby following the SINS carrier align procedurein paragraph20.3.4.2.1.When the INS ALIGN COMPLETE messageappearson the HUD/VDI formats, return the NAV MODE switch to OFF.
l
l
l
l
Note Do not box SAHR on the DATA or NAV formats during the referencealignment. This will preventthe referencealignment and SHDG will not be boxed when alignment is initiated. Do not cycle the parking brakeduring the reference alignment. This will prevent the referencealignment and SHDG will not be boxed when alignment is initiated. 1. Repeatsteps 1 through 7 of concurrentSINS carrier align.
Note If SINS is restored,MAN must be unboxed on the CV DATA format in order to returnto a CV RF alignment. Entry ofVLA is neverrequiredfor manual carrieralignment. When using the DEU, data entry is made via the DEU CV ALIGN format,usingthe LAT, LONG, CSPD and CHDG pushtiles, andtheappropriatequadrantandnumerals shown in Figure 20-16. Dataentryusing theDD requiresselection of the NAV category from the MFK pushtile and the boxing of the OWN A/C acronym prior to enteringthe carrierlatitude and longitude via the DD LAT, LONG, quadrantand numeral pushtiles, asshown in Figure 20-17.This is donein a similar manner as described in paragraph 20.3.1.1, and shown in Figure 2013.Entry of carrierspeedandheadingvia the DD requiresthe boxing of the WIND acronymprior to using theDD SPD, HDG andnumeric pushtilesas shown in Figure 20-17.
3. Repeat steps 9 through 11 for concurrentSINS carrieralign (paragraph20.3.2.1).
2. Verify that SHDG is boxed on CV SINS DATA MFD format (Figure 20-15). 3. Repeatsteps9 and 10of concurrentSINS carrier align. 20.3.2.3 Concurrent Manual Carrier Alignment. The INS and SAHRS will initiate ground alignmentsif thereis no SINS data. The CV MANUAL format will be displayedafter the ship’s data is entered. 1. Repeatsteps 1 through 8 of concurrentSINS carrier align.
20-27
In concurrentmanual carrier align, the INS ALIGN COMPLETE computer message may take 15minutesor longerto appear.The navigation quality at this time may not be better than 3 nm per hour. Becauseof the extensive alignment time, it may be necessary to launchprior to the receipt of the INS ALIGN COMPLETE computer message.
ORIGINAL
NAVAIR 01.Fl4AAD-1
MFD FORMAT
Figure 20-16. CV Aligmn~t Formats- Mamtal (Sheet1 of 2)
20.3.3. Standalone Alignment 20.3.3.1 INS Standalone Alignment. When the SAHRS is not available or has failed, the alignment procedurefor the INS is exactly the sameas for concurrent alignment describedabove in paragraph20.3.1.A SAHRS failure is indicated by the inability to box SAL-IRSon the MFD OWN A/C and align formats as well as its appearancein the failure history tile and in the MFD OBC-NAV format as describedin Chapter27. 20.3.3.2 SAHRS Standalone Alignment. When the INS has failed or is not available or if a SAHRS alignment mode other than that of the INS is desired, then a SAHRS standalonealignment can be selected Born the MFD SABRS ALIGN format (Figure 20-18). This format will appearby depressingthe NAV pushbutton on the OWN A/C MFD format. An INS failure is indicatedby the inability to box INS on the MFD align or OWN A/C formats as well as its appearancein the failure history file andin the MFD OBC-NAV format as describedin Chapter27.
ORIGENAL
As shown in Figure 20-18, the possible SABRS standalonealignment modes include normal ground align @IORM), storedheading ground align (SHDG), magnetic initiated ground align (MAG), and carrier align (CV). Theseare describedbelow. 20.3.3.2.1 SAHRS Standalone Normal Ground Alignment. SABRS normal ground alignment is the recommendedmode for SAHRS standalonealignment and it will be automaticallyselectedasthe defaultmode whenthe LNSis not available.This canbe ascertainedby selectingthe SABRS groundalign MFD format and ohservingthat the NORM legendis boxed.Verification of own-aircraft latitude and longitude shouldbe made by observingthe values displayedon the SAHRS ALIGN MFD format, and,if necessary,new valuesshouldbe entered via the DEU or DD control panel as describedin Normal ConcurtentGroundAlignment procedures,paragraph20.3.1.1.The SAHRS ALIGN COMPLETE messagewill usually appearin less than 3 minutes,with an align quality of lessthan 10mn perhour.
20-28
NAVAIR 01-FUAAD-1
*
I
TYPICAL DATA ENTRY DlSPLAYS. CV ALIGN PARAMETER SELECTEDIDATA KEYED IN SCRATCH
PAD.
*ONLY THE RESPECTME CHARACTER LEGENDS (S, -, W, N, +, E, OR BLANK) APPLICABLE TO THE PARAMETER SELECTED WILL APPEAR ON THE OPTION DISPLAY LEGEND
Figure 20-16. CV Alignment Formats-Manual
20-29
(Sheet2 of 2)
ORlGlNAL
NAVAIR 01-Fl4AAD-1
TWS TWS jrMAN irAUK Figure 20-17. DD Align Data Entry
Figure 20-18. SAHRS StandaloneAlign MFD Format ORIGINAL
20-30
NAVAIR 0%F14AAD1
20.3.3.2.2 SAHRS Standalone Stored Heading Ground Alignment. The SAHRS stored heading align mode is always availablesubsequentto a previous alignmentto a SAHRS ALIGN COMPLETE. However unlike an INS storedalignment, the SHDG pushbutton on the SAHRS ALIGN MFD format must be depressed to select this mode (Figure 20-18). As for all stored headingalignments,no dataentriesarerequiredandthe aircraft must not bemoved subsequentto SAHRS power down. Since this alignment mode usespredetermined heading, the alignment process will be shortened. SAHRS storedheadingalignment shouldnormally provide a S&IRS ALIGN COMPLETE messagein less than 1 minute. The navigationquality value at this time will exceed10 run per hour, and, if time permits, additional alignment is recommendedand will take place as long as the parking brake is set. 20.3.3.2.3 SAHRS Standalone Magnetic Initiated Ground Allgnment. The SAHRS magneticinitiatedgroundalignmentmodeis manually selectedfrom the SAHRS ALIGN MFD formatby depressingtheMAG pushbuttonshownin Figure 20-18. Verification of ownaircraft latitudeand longitudeon the aboveMFD format shouldbe made, and,if necessary,correctvaluesentered as described in SAHRS StandaloneNormal Ground Alignment, paragraph20.3.3.2.1.Since this alignment modeusessystemmagneticheadingto initialize heading, the alignment process will be shortened.A SAHRS ALIGN COMPLETE messageshould normally occur within 1 minute, althoughthe navigationquality valueat this time may exceed 10 nm per hour. If time permits, additionalalignmentis recommendedandwill takeplace as lone asthe ~arkinebrakeis set.In this mode of alianmerit,magnetich&g inputsfrom themagneticarim& detector(flux valve) areusedfor initializing the SAHRS heading.It shouldbeselectedonly in amaswhereno magnetic interferenceor anomaliesexist. 20.3.3.2.4 SAHRS Standalone Carrier Allgnment. The SAHRS standaloneCV alignment mode is manually selectedvia the SAHRS ALIGN MFD format by depressing the SAHR and then CV pushbutton shown in Figure 20-18. There are two SAHRS standalone align modes. Which mode obtained dependson when CV is selected.If CV is selectedprior to the INS determiningtrue heading(approximatelyMS quality of 5) and initiating the SAHRS CV concurrent align, a SAHRS standalone align is commanded when the SAHRS has no headinginformation. Note Currently there is no indication on the MFD displays that the SAHRS has gone into the standalonemode exceptthe SAHRS quality value will remain 10.0,the timer will be 00, 2091
SAHRS concurrentCV align will not initiate,andtherewill be no attitude information available from the SAHRS for up to 6 minutes or more. Reinitiating the INS alignment will allow a concurrentalignment to occur. The SAHRS hasno true standalonecarrieralignmode like theINS. Dming concurrentINSK4HRS carrieralign modes,the SAHRS dependson the INS to provide an initial input of true heading.Sincethis is not availablein SAHRS standalonecarrieralignment,when the SABRS CV pushbuttonis depressedin SAHRS standaloneoperation, it is commandedto a DG mode. Once the parking brakeisre]easedaWjheadingcanbeenteredviatheDEU. When the aimaft is airborne,the slavedmode csn be selectedor if a systemvelocity sourceis present,in-flight restartcan be selectedto bring the SAHRS to a normal operationalmode. This is describedin SAHRS Backup Modes,paragraph20.3.5.3.2. If CV is selected after the INS has initiated the SAHRS CV concurrentalignment, the SAHRS align ment proceedsbut is no longerreceiving updatedposition and velocity information from the INS. The alignment will be considerablyslower than concurrent alignment.The SAHRS is commandedto NORM mode. An in-flight restartmay or may not be requireddepending on the SAHRS alignment quality. WI-IRS cannotbe commandedto a CV mode unless the INS is in CV. If the INS is unavailable,the SAHRS will attempt a normal groundalign. 20.3.4 Initially Entered Navigation Parameters. Prior to takeoff, either during or after alignment, it may be desirableto enter certain initial navigationrelatedparameters,in addition to thosenotedabovethat are required for alignment. It may also be possible to entersomeof theseparametersat any time duringflight. They include the following and arediscussedbelow: 1. Day barometric setting 2. Way-pointdata 3. Wind speedand direction 4. Magnetic variation. 20.3.4.1 Barometric Setting. The barometric setting is normally madeby thepilot using his 2-inch barometric altimeter setting knob. Although this setting is normally madeprior to takeoff, it can be madeanytime including during flight. The settingrangeis from 28.10 to 30.99 inches of Hg and the value set should be that reportedby the control tower. This will provide system ORIGINAL
NAVAIR Ol-F14AAD-1
altitude correctionsto within a maximum error of 16 feet. Verify that the enteredvalue is displayed (Figure 20-6)on theHUD. A small differencebetweentheHUD and instrumentvalues may be expected.This will usually be lessthan 0.01 inch of Mercury but may on occasionbe 0.02 inch. If any differenceis present,adjustthe altimeter so that the correct control tower value is displayed on the lower right side of the HUD. Barometric settingsmay also be madeby the RIO via the DEW. To do this, the altimeter must be locked out by turning the setting knob to the minimum value (28.10 in Hg). The DEU OWN A/C page can now be used to enter the requiredvalue affer depressingthe BAR0 pushtile and theproper numeric values. Entry of barometric settings can be made on the groundor in the air. 1 20,.3.4.2 Waypoint Data Entry. Up to 100 waypomts canbe storedin the waypoint file at any time. The primary parametersthat may be enteredfor eachwaypoint are longitude,latitude, and altitude. Thesemay be enteredmanually via the DEU by selecting the DEU WPT page (Figure 20-19) and depressingfhe desired waypoint numberprior to enteringthecoordinates.Verification of correct entry can be made by examining the MFD WPT DATA format, selectable by depressing I WPTS (PB7) on the MFD OWN A/C format and shown in Figure 20-20. The DD control panel may also be usedfor entering 1 theseparametersfor waypoints 1 to 20. When the DD control panel is used,on the main menu, pressthe WP l-10 or WP 1l-20 pushtile and then box the desired waypoint. The coordinatesare enteredusing the quadrant and numeric pushtiles on the lower left portion of the DD control panel,as indicated on Figure 20-21. The primary waypoint parametersand their ranges areas follows: WPT Primary Parameter Longitude Latitude Altitude
feet
In addition to the above primary waypoint pammeters,four otherparametersrelating to thereconnaissance steeringfunction may alsobe enteredwhenthespecified waypoint is to be usedas a reconnaissancetargetpoint.
ORIGINAL
Reconnaissance Steering Parameter Command course Map lines Target length Map offset
Range 0 IO 360” 1 to 99 0 to 2048 nm f131,072 feet
J
During on-deck carrier operations, some waypoint datacanbe automatically provided from fhe DiL. if provisions on the carrier have been made. This is called waypoint insertion.The D/L must be operatingwith the reply panel MODE switch in CAINS/WPT. The NAV MODE switch shouldbe in any position otherthan CV. For theseconditions, the latitude and longitude of up to the first 16 waypoints may be received. 20.3.4.2.1 Waypoint Data File Use. In general the 100waypoints can be usedin any mannerdescribed 1 inparagraph20.3.6,TacticalNavigation, fordestination steeringor for the one-fix updating functions. Usually, however,certain of thesepoints arereservedfor special functions. Waypoint 1 is usually reservedfor homebasecoordinates.Its data is retainedafter use. Waypoint 17 is used as a dynamic steering point when a reconnaissancesteeringmode is selectedusing the MFD RECON DATA format. At this time any previously storeddata in waypoint 17 becomeinvalid and must be reentered. Waypoint 18 is usedfor the coordinatesof anagreed point for data-link one-fix position update.Its data are still valid after updateusage. Waypoint 19 is usedfor the coordinatesof the fighter link referencepoint, as describedin the Supplemental NATOPS Flight Manual, NAVAIR Ol-F14AAD-1A. Its data arestill valid after usagefor “FLRP.”
Range E/W 180” N/S 90” -5000 to 99,996
Theseparameters,however, can only be enteredvia fhe DEU using the DEU WPT page.They areas follows:
20-32
Waypoint 20 is usually reservedfor the approximate location and altitude of a hostile area.Its data are retained after use. Waypoints 2 to 16 and 21 to 100 are generalway- 1 points andareusedas requiredby the mission. The data of thesepoints are retainedafter use.
NAVAIR Ol-FMAAO-I
.
I
i
I I I i
Xx D REPRESENTS 1 OF 20 SELECTASLE WAYPOINT ENTRIES
-l---I I I
-- ----
+------!
i
i
i I I I 4 TYPICAL WPT DATA ENTRY DISPLAYS WAYFOINT PARAMETER SELECTED/DATA KEYED IN SCRATCH PAD, LAT. LONG, ALT, RNG, ERG, SET, MAPLINE, MAP OFST, TGT LNG. OR CMD CRS OPTION KEY PRESSED.
*ONLY THE RESPECTIVE CRARACTSR LEGENDS (S, z W, N. +, S, OR BLANK) APPLICABLE TO THE PARAMETER SELEClED WILL APPEAR ON THE OPTION DISPLAY LEGEND
i
..-.
----
Figure 20-19. Data Entry Unit Waypoint Pages(Typical)
20-33
ORIGINAL
NAVAIR
01.F14AAD-1
WAYPOINT DATA 0
Figure 20-20. MFD Waypoint Data Format Wind Speed and Direction. Wind parametersarenormally generatedby the navigation system using air dataandINS or SAHRS velocities. When the navigation systemcannotcomputewind becauseof unavailability of the requiredvelocity inputs, it will accept manual entries of wind from the DEU or the DD control panel.Entry ofwind canbemadepriorto takeoff with no sensorfailure since CADC true airspeedis not set valid until it reachesapproximately 60 knots.
20.3.4.3
Wind is enteredwith the DEU (Figure 20-12) by selecting the OWN A/C DEU format and depressing the WSPD and WDIR pushtiles and then the proper numerics. Wind is enteredwith the DD control panel (Figure 20-17) by selectingNAV and then boxing WIND and using the proper numeric pushtiles on the lower left portion of the DD control panel. Note
For both DEU and DD entries, wind direction is the direction from which the wind is blowing.
ORIGINAL
Magnetic Variation. MAG VAR is available from the navigation system from a prestoredtable using aircraft coordinates.This value, when displayed on the MFD OWN A/C format, is labeledMV-T. It may also be computedusing the difference betweensystem true headingand magnetic heading from magnetic azimuth detector(labeled Mv-C). In addition to this, fhe navigation system will accept and use a manually entered value of magnetic variation from either the DEU or the DD control panel (labeledMV-E).
20.3.4.4
Magnetic variation from the prestored table is fhe default value and will be automatically selectedand displayed to the nearest degree. This is the recommendedvalue and,unless aircraft position is unknown, will usually be the most accurate. Selectionof computedor enteredmagneticvariation is madeby depressingtheboxed MV pushbuttonon the lower right side of the MFD OWN A/C format (Figure 20-22).When this is donetheMV-T legendin thecenter ofthe format will cycle to MV-C, to MV-E, andback to MV-T, indicating the sourceandvalue ofmagnetic variation usedby the navigation system.
20-34
NAVAIR 0%F14AAD.1
Figure 20-21. DD Waypoint Data Entry Entered values of magnetic variation can be made using eitherthe DEU or the DD control panel.When the DEU is used(Figure 20-12),the MVAR pushtile on the OWN A/C or CV ALGN format is selectedandthevalue is enteredto the nearestdegree,precededby an E or W for east or west, respectively. When the DD control panel is used (Figure 20-22), the NAV category is selected and the MAG VAR pushtile is depressed.Entry is madevia the numericson the computeraddresspanel on the lower lefl portion of the DD by first depressing the HDG pushtile, followed by the appropriateE or W, and thenthe value also to the nearestdegree. 20.3.5 In-Flight Operation. During flight, the navigation system can operate in several modes and submodes.These consist of the following in order of expectedaccuracyand completenessof information. 1. Primary
4. SAHRS backup a. SAHRS/slaved b. SAHRSDG c. SAHRS EC d. SAHRS in-flight restart. Details on these modes, their capabilities, and the operational procedures are given in the following paragraphs. Unless a manual selection is made, the navigation systemwill automatically selectthe bestavailablemode in the decreasingorder given above. When a manual selectionis madean “M” will appearon the upperright portion of the OWN A/C MFD format. The disappearanceof the “M” indicatesautomaticmode selection.
a. In-flight align 2. Secondary 3. IMU backup
Manual selectionof the navigation systemmode can be madeby either the pilot or the RIO using the applicable MFD format as describedbelow. Navigation data entry andINS mode control is only a RIO function since the pilot doesnot havethe requiredcontrols.
20-35
ORIGINAL
NAVAIR
01.Fl4AAD-1
MFD MAGNETIC
VARIATION
DD MAGNETIC
SOIIRCF
VARIATION
CFI FCTI~N
ENTRY
NZ97
Figure 20-22. Magnetic Variation SourceSelectionand DD Entry ORIGINAL
20-36
NAVAIR
Primary Navigation. The primary navigation mode usesINS-senseddynamic inputs, with the INS in its inertial mode as inputs Born the CADC and otheraiding sources,when availableand selectedby the crew.This mode providesthemost accurateinformation to all systemsand is automatically selectedat the completion of alignment whenthe NAV MODE switch is set to INS. It will also be automatically selectedwhen the aircraft is airborne and the NAV MODE switch is still in thealign position, if a reasonablequality of alignment hasbeenobtained.The indication is that the INS legend ontheupperright portion ofthe OWN A/C MFD format is boxed. 20.351
INS In-Flight Align. It is possible to align the INS during flight using an available velocity sourceand certain navigation systemparameters,Presently thethreesourcesofvelocity dataavailablefor INS in-flight align are JTIDS, air data,and systemvelocity. Since an INS in-flight align using air data or system velocity may takeaslong as25 minutes, this shouldonly be attemptedif serious INS degradationis suspected, JTIDS is not available,anda reasonablesystemvelocity is available.The preferredsourceof INS in-flight alignment is JTIDS. A JTIDS in-flight align with good quality JTIDS velocity datashouldalign in 12to 15minutes (display of an ALIGN COMPLETE message). 20.3.5.1.1
The quality of the air datavelocity will dependupon the accuracyof enteredor available wind information. Systemvelocity is the computed optimum velocity using all available inputs. JTIDS velocity data is computed by the JTIDS system and is dependenton data receivedfrom the MCS and over the link. Since an INS in-flight align usescurrent systemposition information, it is desirableto perform a one-fix position update prior to performing an INS in-flight align. The procedurefor in-flight align is as follows:
Ol-F14AAD-1
4. Observethe alignment progresson the IFA MFD format. 5. To ensurea goodinitial platform alignment,flight should be straightand level from 1 to 5 minutes. I Note
Becauseof the extensive time required for INS IFA, it is possibleto selecttheINS mode via the NAV MODE switch prior to an INS align completemessage.At this time the INS may advanceto the inertial mode or may operatein the ATT mode, dependingupon the alignment progressat the time. The secondary navigation mode uses SAHRS-senseddynamic inputs, with the SAHRS in its normal operatingmode, as well as inputs from the CADC and other aid sources,when selectedandavailable.This mode will be automatically selectedwhen the INS primary mode is not available becauseof either an INS failure or INS operationin a degradedmode (i.e., ATT mode).Indication of this condition can be observedon the MFD OWN A/C format, that will show SAHR boxed in the upper right portion and only SAHRS appearingas the legend in the center of the display (Figure 20-24). Note If the navigation mode reverts to secondary on deck during CV operations,the SAHRS will default to a CV standalonealign mode (SAHRS continuesto align as long as there is weight on wheels); if a system reset is initiated or occursas a result of anotherfailure, the SAHRS will revert to a NORM groundalign mode.Attitude informationwill not be available for approximately 45 secondswhen this occurs. 20.3.5.2
Secondary
Navigation.
1, Verify a valid sourceof true headingis available, suchas SAHRS by selectingSAHRS on the upper right portion of the OWN A/C MFD format. If a reasonableSAHRS true heading is not available, then enter the best estimatedtrne heading via the DEU OWN A/C format (Figure 20-23).
The secondarynavigation mode can also be called anytime the SAHRS is operatingin its normal mode,by depressingthe SAHR pushbutton.For this condition, an “M” will appearon the upper right of the display indicating a manual selection has been made. Depressing the INS pushtile at this time will againreturnthesystem to the primary navigation mode with the “M” still ap. pearing,indicating a manual selectionhasbeenmade.
2. Advancethe NAV MODE switch to the IFA position. The IFA MFD format shown in Figure 20-23 will appear.
20.3.5.2.1
3. Select a velocity sourceby depressinga pushbutton on the right side of the IFA MFD format.
20-37
SAHRS
Velocity
Referencing.
When
SAHRS alignment is complete it will generateits own velocity outputs in a similar manner as the INS. Normally this parametershould be satisfactory for backup operation.In the eventofan inadequateSAHRS alignment or degradationof SAHRS performance, it may be desirable to select a velocity source for SAHRS ORIGINAL
NAVAIR
Of-F14AAD-1
N2lS7
Figure 20-23. INS In-Flight Align Formats ORIGINAL
20-38
NAVAIR OWl4AAD-1
I
..-.
_-__ ._.
,Al,l-m.u”-43+-o
WI97
Figure 20-24. SecondaryNavigation Mode Manually Selected refenzing. The sourcesavailable are shown on the lower right-hand portion of the NAV SYSTEM AID MFD format (Figure 20-25) and consist of the following: 1. SYS - Systemvelocity is the computedoptimum velocity using all valid velocity sources. 2. AIR - Air datacomputertrue airspeedwith wind compensation. 3. INS - INS-sensedvelocity. 4. JTIDS - JTIDS-computedvelocity. When none of the abovevelocity sourcesis boxed, the SAHRS will useits own velocity. This is the default velocity mode. 20.353 Backup Navigation Modes The backup navigationmodeswill provide most of the outputsavailablein theprbnsq andsecondarymodesbut with considerably degraded accuracy. Unlike the primary and secondarymodes,theavailablenavigationparametersare generatedwithin the MCS, with the exceptionof attitude
information, which is t7om the sensor selected.Best available system velocity is used to generateposition information, and CADC inputsare used for vertical velocity. In backup navigationmodes,certaindata entries may be made and will be acceptedas describedbelow. 20.3.5.3.1 IMU Backup Mode. The IMU backup navigation mode will be automatically selectedwhen both the primary (INS inertial) and the secondary (SAHRS normal) modes are not available, but the INS canstill provide attitude andplatform headinginformation and some form of system velocity is available.It may also be manually selectedby positioning the NAV MODE switch to A’IT with someform of systemvelocity available.The OWN AK MFD format for this mode (Figure 20-26) will show a boxed INS legend in the upperright portion andan IMU or IMU/SAHRS legend will appearin the center,dependingon SAHRS availability. If this mode was manually selected,an M will appearnext to the boxedINS legendasshown in Figure 20-26. For this mode, the systemwill computea bestavailable initial true heading.This parameter,however may not be accurateandit may be necessaryto enter,at leastonetime, someestimateofthe aircraft trueheading via the DEU OWN A/C format.
20-39
ORIGINAL
NAVAIR
01.F14AAD.1
SAHRS
NORMAL,
SYSTEM
NAV SYSTEM
AID-
VELOCITY
Figure 20-25. SAHRS Velocity ReferenceSelection
Note
Once ATT has been selected manually, the INS will degradefrom an inertial mode to an attitudereferencemode,and reversion to viable INS mode may be difficult or impossible. SAHRS Backup Modes. A SAHRS backupmodewill beautomaticallyselectedwhentheINS hasfailed or is not available,the SAHRS normalmode is not available,and someform of systemvelocity is available.The SAHRS backupmodesincludethreesubmodes basedon SAHRS operatingas an attitudereferencesystem.Theseincludethefollowing in theorderofpreference:
20.3.5.3.2
1. Slaved- Magnetic heading. 2. DG - Directional gyro. 3. EC - Emergencycompass. In the slavedandDG modes,the systemwill provide typical navigation outputsto the displays andother sys-
ORIGINAL
20-40
terns,as long as some form of system velocity is available. In addition to automatic selection, SAHRS submode operationmay be manually selectedvia the NAV SYSTEM AID MFD format shown in Figure 20-27. This is doneby first selectingSAHRS by depressingthe SAHRS pushbutton on the upper right portion of the NAV SYSTEM AID MFD format and verifying that SAHRS is boxed.A SAHRS submodemay be selected by depressingthe SAHR MODE pushtile on the lower let?of the sameMFD format until the desiredsubmode is boxed. piiDo not attempt this on deck. A weight-onwheels interlock for the in-flight restartwill freeze the SAHRS in the restart mode until weight off wheels. There will be no attitude information available from the SAHRS when this situation occurs.
NAVAIR Ol-Fl4AAD-1
Figure 20-26. IMU Backup Navigation Mode Selection DG headingentry is made.In the system,it is treatedas a magnetic-referencedparameter.Attitude information is derived Ram the SAHRS using fmt-order leveling and, like the SLV mode, is subjectto dynamic errors.
Note Although it is possible to cycle through the SLV, DG, EC submodes, reversion to NORM requires an in-flight restart. Inflight restartwill automatically be initiated when the selection pushbutton is depressed to roll from EC to NORM or canbe accomplished by depressing the in-flight RST pushbutton.
The SAHRS EC submode provides only magnetic headingoutputsusing the magneticazimuth detectoras the input source.It is not a navigation mode, and only magneticheadingandcertainair dataparameterswill be availablewhen it is selected.
Considerabledegradationin accuracyfrom the primary and secondaryand even the IMU backup modes can be expectedwhen the SLV and DG modes are selected.The SAHRS EC submodewill not provide navigationparametersto the system althoughsome air data parameterswill be available. Selection of the slaved submodewill result in magnetic heading information derived from the magnetic aximuth detector (flux valve) and true heading computedfWm this sourceplus magneticvariation. Attitude information is derived from SAT-IRSusing first-order leveling and, therefore, may be subject to certain dynamic errors. Selection of the DG submode will allow enuy of a desiredgrid headingvia the DEU, using the DEU NAV AID-M; HDG format (Figure 20-26). This enteredparameterwill be the initial headingreferenceuntil a new
20.3.5.3.3 SAHRS In-Flight Restart If the SAX-IRS is operatingin a degradedsubmode,it may be possible to revertto the normal mode of operationvia anin-Sight restart.Prior to attemptingan m-flight restart,the selection of SYS asthe SAT-IRSvelocity referenceisrecommended. In addition, aircraft position data should be evaluatedand a position updateshouldbe performedif large position errorsexist. An in-flight restartmay now be initiated by selectingNORM asthe SAHRS modeby depressingthe indicated pushbuttonon the lower left portion of the NAV SYS AID MFD format; or by do pressingthe RST pushbuttonon the right centerof the sameMFD format (Figure 20-26).The subsequentboxing of the NORM legendin the SAHR MODE selector box on this format indicates a reinitialimtion of the SAHRS to its normal mode. The data to which the SAHRS is reinitialized is the cutrent value of the navigation systemposition and velocity.
20-41
ORIGINAL
NAVAIR
01.F14AAD-1
SAHRS
BACKUP
SLAVED
MODE
SELECTED
NAV SYSTEM AID-
SAHRS
BACKUP
DG MODE
SELECTED
NAV SYSTEM AID-
Figure 20-27. SAHRS Backup SLV and DG Modes (Sheet 1 of 2)
ORIGINAL
20-42
NAVAIR 01-F14AAD-1
DEU DG HEADING
ENTRY FORMAT
(AT)1-FSOD437-2L
Figure 20-27. SAHRS Backup SLV and DG Modes (Sheet2 of 2) It is also possibleto perform an in-flight restart6om the SAHRS normal mode. This shouldbe done only if seriousSAHRS degradationis suspected. 20.3.6 Tactical Navigation. The following paragraphsdescribethe proceduresto be used for tactical navigation.This includesrange,bearing,andtime to go to waypointsandtacanstations;position updating;continuousposition updating;surfacewaypoint determinationposition; display steeringmodes;autopilot steering; andall-weatherlanding. 20.3.6.1 Range, Bearing, and Time To Go to Waypoints and Tacan Stations. The range,magnetic bearing,and time to go to any valid selectedwaypoint aswell asthewaypoint numberitselfare provided in alphanumericson the upperleft portion of the MFD HSD format (Figure 20-28). The desired waypoint 1 number (1 to 100) is selectedvia the increaseand decreasepushbuttonsshown on the left side of the HSD format. Pressing the upper left WPT pushbutton will result in the boxing of the above data and entry into 1 destinationsteeringmode.
merics, areprovided on the sameMFD HSD format but on the upperright-hand side. Included with this data is the tacan channel number. Depressingthe upper right pushbuttonon the MPD HSD format will causethis data to be boxedandwill result in the selectedcoursesymbol being displayedthrough the tacansymbol, as shown in Figure 20-28.This will alsounbox the waypoint dataon the upperleft of the HSD format. Steeringto a selectedwaypoint (destinationsteering), or to a tacan station (tacan steering),using the MFD HSD format is describedin paragraph20.3.6.5. 20.3.6.2 Update. All updates,except JTIDS, determine aircraft position onetime by computingits location with respectto a known waypoint. JTIDS updatesuse the navigation correctiondata computedby the JTIDS. The differencein the computedposition andthe navigation system’spresentposition arc displayedon theMFD or the DD as differences(deltas)in latitude and longitude. If thesedifferences are reasonable,the operator may electto updatethe navigationsystem,including the INS and the SAHRS, by depressingthe MFD FIX ENABLE pushbutton.
Range,magneticbearing,andtime-to-go information to a receiving/transmittingtacanstation,alsoin alphanu-
20-43
NAVAIR 014=14AAD-I
WAYPOINT
DATA BOXED
TACANDATABOXED
Figure 20-28. Display of Waypoint and TacanData
ORIGINAL
20-44
NAVAIR
A navigation update is performed by calling up the INS UPDATE MFD format shown in Figure 20-29 that will appearwhen the UPDT pushbuttonis depressedon the HSD basicMFD format, shown in Figure 20-30.The availabletypesofupdatesconsistof visual, tacan,radar, HUD/designate, data link, and JTIDS. If a particular updatetype is not available,an “X” will appearover the acronym as shown in Figure 20-29. Since all updates exceptJTIDS usethe coordinatesof a selectedprestored waypoint, the coordinates of the selected waypoint shouldbeverified prior to performing all updatesexcept JTIDS. This is doneby calling up the WPT DATA 1 or 2 MFD format containing the point as shown in Figure 20-20that is available from the OWN A/C basic format. The proceduresfor each of the types of updatesare providedbelow. Visual One-Fix Update. Visual onefix update computes the aircraft’s position using the coordinatesof a point selectedand stored in waypoint file and substitutedfor the aircraft’s position at the instantof direct flyover. This requiresthatentry,selection, andverification of the waypoint be madeprior to flying over the point and that the VIS pushbuttonon the INS UPDATE MFD format be depressedat the time of flyover. When this is done,the INS UPDATE FORMAT shalldisplay thecomputedlatitude andlongitudedifferencesfor evaluation.The procedurecan be performed by either pilot or RIO as follows:
WI-Ff4AAD-1
5. Ifthe deltaLATlLONG correctionsappearreasonable and a correction is required, press the FIX ENABLE pushbuttonon the INS UPDATE MFD format. The correctionswill be incorporatedinto the systemandsensorsandthecorrectlatitudeand longitudewill bedisplayedon theOWN A/C MFD format. Tacan One-Fix Update. Tacanone-fix updatecomputesaircraft position using tacanmeasurements of rangeand bearingfrom a tacanstationwhose coordinatesare known and storedin the waypoint tile. The procedurerequiresthat the tacan be operatingand the stationselectedcorrespondto the waypoint that will be called up and whose coordinateswill be usedin the updating process.The procedurecan be performed by either the pilot or RIO as follows: 20.3.6.2.2
20.3.6.2.1
1. With the tacan operating, select a tacan channel whose latitude and longitude coordinatescorrespondto the referencedtacanlocation storedin the waypoint tile. 2. Verify that the coordinates of the tacan station are the same as those of the waypoint to be selected for updating by calling up the appropriate WPT DATA MFD format, Figure 20-20. If incorrect, enter the correct values via the DEU or DD.
1. Verifythecoordinatesofthewaypointtobeoverflown by calling up theappropriateWPT DATA MFD format (Figure 20-20).If incorrect,enter the correct coordinatesfor thepoint via theDEU or theDD.
3. Call up the INS UPDATE format, Figure 20-29. Select the correct waypoint correspondingto the coordinatesof the tacanstationusing the increase/ decreasepushbuttonson the right sideof the INS UPDATE MFD format.
2. Call up the INS UPDATE MFD format, Figure 20-29:Select the correct waypoint corresponding to coordinatesof the visual update point via the increase/decrease pushbuttonson the right side of the INS UPDATE MFD format.
4. Depressthe TCN pushbutton.The legendwill be boxed and the computed delta LAT and delta LONG will appear,as shown in Figure 20-29.
3 At the instant of direct flyover of the visual point
depressthe VIS pushbutton.The VIS legend will be boxed at this time, and delta LAT and delta LONG will appearasshown in Figure 20-29. Optimum resultswill be obtainedwith low and slow flight conditions. 4. Verify that the delta LAT/LONG corrections are reasonable.
20-45
5. Verify that the delta LAT/LONG correctionsare reasonable. 6. IfthedeltaLAT/LONG correctionsappearreasonable and a correction is required,depressthe FIX ENABLE pushtile on theINS UPDATE MFD format. The correctionswill be incorporatedinto the system and sensors,and the correct latitude and longitudewill be displayedon theOWN A/C MFD format.
ORIGINAL
NAVAIR Cd-FlUAD-
INS UPDATE-VIS PLAT -N 2-15.31 ALONG - w I* a.42
Figure20-29.INS UPDATEh@DFormats(Sheet1 of 4) ORIGINAL
2046
INS UPDATE -TCN ALAT - N 2015.31 ALONG-W 1’ 8.42
INS UPDATE- RDR ALAT -N 2~15.31 ALONG- W ,* 8.42
Figure 20-29. INS UPDATE MFD Formats (Sheet2 of 4) ORIGINAL
NAVAIR OSF14AAD-1
INS UPDATE-HUD ALAT - N 2’15.31 ALONG -w I* 8.42
INS UPDATE-D/L ALAT - N 2015.31 ALONG -w ID8.42
Figure 20-29. INS UPDATE MFD Formats (Sheet3 of 4) ORIGINAL
20-48
INS UPDATE - JTID A UT - N 02: 16.31
(AT)O-F50D-4343O-;r
Figure 20-29. INS UPDATE h@D Formats (Sheet4 of 4)
/ I I
$1 3 0
a -I1
--
L
Figure 20-30. HSD Basic h@D Format 20-49
ORIGINAL
NAVAIR 0%F14AAD-1
20.3.6.2.3 Radar One-Fix Update. Radarone-fix updatecomputesaircraft position using radarmeasurements of range, azimuth, and elevation angles from a radar-identifiabletarget whose coordinatesare known and are stored in the waypoint file. This procedurerequires that the radar is operating in the ground-map mode andthat the DD cursorbe positionedover the DD displayedtargetprior to designatingvia the sensorhand control as describedbelow. Like other one-fix update modes it also requiresthat the waypoint corresponding to the radartargetcoordinatesis selectedfor the update asdescribedbelow. Sincethis procedurerequirestheuse of the DD control panel, it can beperformed only by the RIO. The procedureis as follows: 1. Select the radar ground-mapmode via the GND MAP pushtile on the DD, shown in Figure 20-31.
coordinatesare storedin a specific location in the waypoint file. The measuredinformation consistsof components of slant range to the waypoint that are transmittedto the aircraft via a specific data-link message.The procedurerequiresthat the coordinatesof the agreeddata-link target point are storedas waypoint 18 in the waypoint file and that the datalink is operatingin the tactical mode. Verification and selectionof the waypoint areperformedsimilar to other one& updateproceduresbut the tactical situationdisplay on the MFD is usedfor location and designationof the data-linktarget point (Figure 20-32). Both the pilot and the RIO can perform this updateprocedure.The pilot usesthe cursor control switch on the throttle, and the RIO uses the sensorhand control for designatingand positioning the cursor.The procedureis as follows:
2. Verify that the coordinatesof the radaridentifiable point are the same as those of the waypoint to be selectedfor updatingby calling up the appropriate WPT DATA MFD format, Figure 20-20.If incorrect, enterthe correct values via the DEU or DD. 3. Call up the INS UPDATE format, Figure 20-29. Select the correct waypoint correspondingto the coordinatesof the radar-identifiablepoint via the increase/decrease pushbuttonson the right side of the INS UPDATE MFD format. 4. Selecthalf-action mode by depressingthe trigger on the RIO sensorhand control to the first detent position. 5. PlacetheDDcursoroverthedisplayedradartarget on the DD (Figure 20-31) using the sensorhand control anddepressthe trigger to the seconddetent (full action). 6. Depress the RDR pushbutton on the INS UPDATE MFD format. The RDR legendwill become boxed and the computed delta LAT/delta LONG will appearas shown in Figure 20-29. 7. If the delta LAT/LONG corrections appearreasonableand a correction is required, depressthe FIX ENABLE pushtile. The corrections will be incorporatedinto the system and the sensorsand the correct latitude and longitude will be displayed on the OWN A/C MFD format, which will now appear. 20.3.6.2.4 Data-Link One-Fix Update. Data-link one-fix update computesaircraft position using inputs from an externalplatform that measuresthe aimratl position with respectto an agreeddata-linktargetpoint whose ORIGINAL
20-50
1. Verify data-link operation in the tactical mode (i.e., DATA LINK MODE switch is in TAC). 2. Verify the coordinatesof waypoint 18arethe previously agreed values by calling up the WPT DATA 2 MFD format. 3. Call up the INS UPDATE MFD format (Figure 20-29) and select waypoint 18 via the increase/ decreasepushbuttons. 4. Call up the TSD MFD format (Figure20-32)available from the MENU1 MFD format. Using the pilot cursorcontrol or theRIO sensorhandcontrol, place the cursor overthe data-link targetpoint position and depressthe switch. Note Both waypoint 18 from the waypoint file and thedata-linkreportedlocationof this point appearon the TSD format. Sinceboth symbols representthesamepoint, thedifferencein their locationon the TSD MFD formatis an indication of the aircraft position error. A check shouldbe made to ascertainthat this error is reasonableprior to pertormingtheupdate. 5. Call up again the INS UPDATE MFD format. Depress the D/L pushbutton.A delay of several secondsmay occur prior to the boxing of the D/L legend and the appearanceof the delta LAT and LONG displays (Figure 20-29). 6. If the errorsappearreasonableand anupdateis desired, depressthe FM ENABLE pushbutton.The correctionswill be incorporatedinto thesystemand sensorsandthecorrectlatitudeandlongitudewill be displayedon theINS UPDATE formatandwill also appearon theOWN A/C MFD format.
NAVAIR 01.Fl4AAD-1
TARGET
CURSOR
I
Figure 20-31. DD Control PanelWith GND MAP Selected
Figure 20-32. MFD TSD Format 20-51
ORIGINAL
NAVAIR 01-F14AAD-1
2. Call up INS UPDATE MFD format (Figure20-29) available from the MENU1 MFD format.
20.3.6.2.5 HUD/Designate One-Fix Update. HUD designateone-fix update computesaircraft position, using measurementsof azimuth andelevationfrom theHUD centerto a designatedtargetpoint thatis visible throughthe HUD andwhosecoordinatesareknown and stored in the waypoint tile and system altitude. This procedureis performedonly by thepilot using thecursor control switch on thethrottle to position the HUD cursor over the visually sighted target and to designate.Like other one-fuc update modes, it also requires that the waypoint correspondingto the visual targetcoordinates is selectedfor the updateas describedbelow.
3. Depress the JTID pushbutton on the INS UPDATE MFD format. If the data from JTIDS is not valid or the quality is >3, the JTID pushbuttonwill be crossedout.The JTID pushbuttonboxes and the JTlDS computed deltaLAT anddeltaLONG will appearasshownin Figure20-29. 4. Ifthe deltaLAT/LONG correctionsappearreasonable and a correction is required,depressthe FIX ENABLE pushbuttonon the INS UPDATE MFD format. The corrections will be incorporatedinto the system and sensorsand the correctedlatitude and longitude will be displayedon the OWN A/C MFD format.
1. Verify that the coordinatesof the HUD visual target are the same as those of the waypoint to be selectedfor updatingby calling up the appropriate WPT DATA MFD format (Figure 20-20). 2. Call up the INS UPDATE MFD format (Figure 20-29). Select the waypoint correspondingto the HUD visual targetvia the increase/decrease pushbuttons on the right side of the format. 3. Position the cursor over the visual target seen through the HUD using the cursor control switch and then depressthe switch (Figure 20-33). 4. Depress the HUD pushbutton on the INS IJPDATE MFD format. The HUD legend will become boxed and the computed delta LAT/delta LONG will appearas shown in Figure 20-29. 5. Ifthe deltaLAT/LONG correctionsappearreasonable and a correction is required,depressthe FIX ENABLE pushbuttonon the INS UPDATE MFD format. The correctionswill be incorporatedinto the systemandsensorsandthe correctlatitude and lot &de will be displayedon theOWN A/C MFD format. 20.3.6.2.6 JTIDS One-Fix Update. JTIDS one& updateusesthe delta latitude and longitude information calculatedby JTlDS to perform a one-timeupdateof the system and sensors.This fbnction will always use the JTIDS geodeticlatitudeandlongitudecorrectiondataregardlessof JTIDS NAV MODE. This procedurerequires JTIDS operatingin thenetasanactiveparticipant(NORM selectedon JTIDS control panel) with NET ENTR-OK. See Chapter 19 for JTIDS operatingprocedures.The JTIDS geodeticpositionquality mustbe 53 to displaythe data and allow the update.This procedurecan be performedby eitherthepilot or RIO asfollows: 1. Verify JTIDS operatingand in sync.
ORIGINAL
20.3.6.3 Continuous Position Updating. In addition to one-fix position updates,thenavigation system hasthe capability to accept continuousnavigation corrections from external sourceswhen they exist and are valid. For the current configuration of the aircraft, the only two sourcesavailable for continuousposition updating are tacan and JTIDS data. The tacan mode of continuousupdatinguses tacanmeasurementsof range andbearingto a prestoredselectedwaypoint that also is an active tacan station. Thus, as in one-fix updating, it is necessaryto ensurethat the selectedwaypoint correspondsto the tacan station that is being received.The JTIDS mode of continuousupdatingusesdeltalatitude, longitude, and altitude calculatedby JTIDS to continuouslyupdatethenavigationsystem.The JTIDS continuousupdatewill updatethe navigationsystemwith either geodeticlatitude, longitude, and altitude correctionsin the GE0 mode or relative latitude, longitude, and geodetic altitude corrections in the REL mode. When the JTIDS altitude correctiondataquality is 5 10,this function will display anduse only the latitude and longitude corrections. Selection of JTIDS continuousposition updating is madevia the MFD NAV SYSTEM AID format (Figure 20-34) that will appearwhen the NAV pushbuttonis depressedon the MFD HSD or OWN A/C format. The remaining proceduresfor JTIDS continuousupdateare the same as JTIDS one-fix update.Depress the JTID pushbuttonon theNAV SYSTEM AID-JTID format. If the datafrom JTIDS is not valid or the quality is >3, the JTID pushbuttonwill be crossedout.The J’TIDpushbutton boxesand the JTIDS computeddelta LAT, LONG, andALT will appearas shownin Figure 20-34.Dcpression ofthe ENABLE pushbuttonon the top centerof the
20-52
NAVAIR Ol-F14AAD-1
* 360 * ‘./* :
-
-
5L-
--A5 94
TWSA I
IOL - _
COOL _
-
110
Figure 20-33. HUD/Designate Position Update
NAV SYSTEM AID format now allows the corrections, which arecontinuouslycomputed,to updatethe system. Selectionofcontinuous position updatingis madevia the MFD NAV SYSTEM AID format (Figure 20-34) that will appearwhen the NAV pushbuttonis depressed on the MFD HSD or OWN A/C format. If tacan datais being received from a transmitting station, the TCN legendwill not be crossedout. The procedurefor tacan operationis thesameasfor one-fix tacanpositionupdate described in paragraph20.3.6.2.2. Select the correct waypoint using the up or down arrows on the HSD format, then depressthe NAV pushbutton.Oncethis is done,depressingthe TCN pushbuttonon the resulting NAV SYSTEM AID format boxesthe TCN legendand computedcorrectionsfor latitude andlongitude arethen displayed.Depressionof the ENABLE pushbuttonon the top centerof the NAV SYSTEM AID format now allows the corrections,which are being continuously computed,to be provided to the system. Note For continuousposition updatingneitherthe INS nor the SAHRS are updated.Once this aiding mode is deselected or becomes invalid, the computedcorrectionswill not be providedanda changein position may occur. 20-53
20.3.6.4 Surface Waypoint Position Determination. The position of a surface waypoint is determined by measuringits location with respectto the aircraft or with respectto some other known point. The following sensorsand procedurescan be used: visual, Wan, radar,HUD/designate,DEU, and TID. Selection is made from the SURFACE WPT POS format on the MFD. The computed latitude and longitude are displayed on the MFD or DD. The SURFACE WPT POS format is calledby selectingthe SWP pushbuttonon the INS UPDATE format. Note The INS UPDATE format is calledby selecting the UPDT legend on any of the HSD MFD formats. On the SURFACE WPT POS MFD format (Figure 20-35), an “X” over the legend for a position determination mode indicates that the mode is not available. Until one of the available modesis selected,the format shown in Figure 20-35 displays only the mode legends, the boxed SWP legend,and the SURFACE WPT POS header.
ORIGINAL
NAVAIR 0%Fl4AAD-1
NAV SYSTEM AID - TACAN
NAV SYSTEM AID - TCN b.LoNG-W
1.42
NAV SYSTEM AID - JTIDS
NAV SYSTEM AID - JTIDS d. LAT - N oo”ol.3c ALONG - w dol.42
fAT)l-F5OD431-0
Figure 20-34. Navigation SystemContinuousUpdate MFD Format
ORIGINAL
20-H
NAVAIR
SURFACE WPT POSLAT - N 40*45.00 LONG- w 7C3I .53
SURFACE
WPT
POS-
Figure 20-35. SurfaceWaypoint Position MFD Formats (Sheet 1 of 2) 20-55
Ol-Fl4AAD-1
NAVAIR
Ol-F14AAD-1
SURFACE
WPT POS-
SURFACE WPT POSUT - N 40~45.00 LONG- W74~31.00 RN0 ia. BRG - 330*
Figure 20-35. SurfaceWaypoint Position MFD Formats (Sheet2 of 2) ORIGINAL
20-56
NAVAIR 01.Fl4AAD-1
Whenusing the visual, radar,or HUD/designateprocedure,afterthe surfacewaypoint latitude andlongitude havebeencomputedanddisplayed on the MFD, pressing the ENTER pushbuttonon the MFD format enters the coordinates into the waypoint tile in an assigned waypoint number.For theDEU method, thecoordinates arealsodisplayedon the MFD, but areenteredby pressing the DEU ENTER pushtile. When using the TID method,pressingthe sensorhand control tiigger enters the coordinatesthat aredisplayed on the MFD.
3. Depressthe SWP pushbuttonto display the MFD SURFACE WPT POS format. 4. Depressthe up or down arrowpushbuttonuntil the desiredwaypoint number is displayed. 5. Depressthe TCN pushbuttonon the MFD SURFACE WPT POS format. This boxes the TCN legend and displays the tacan station latitude and longitude.
The paragraphs that follow describe the various methodsand provide procedures. 20.3.6.4.1 Visual Mode. For a visual waypoint position determination,the aircraft present-positioncoordinates are assignedto the waypoint position at the instantof flyover. This requiresthat the VIS pushbutton be pressedat that time. The assignedcoordinatesare displayed when the VIS pushbutton is pressed.This procedurecan be performed by either crewmember. Note For best results,the aircraft should be flown low and slow for this procedure.
6. If the coordinatesappearreasonable,presstheENTER pushbuttonto place the surfacewaypoint COordinatesinto the proper waypoint file. They can be verified by selecting the WPT DATA format (Figure 20-20). 20.3.6.4.3 Radar Mode. For a radar surface waypoint position determination,theposition of a radarsurface target is computed using radar measurementsof range,bearing,andelevationangleto the targetfrom the known aircraftpresentposition. The radarmustbe in the GND MAP mode. This procedure can only be performed by the RIO. 1. On the DD control panel, selectGND MAP.
1. CalluptheMFD INS UPDATE format(Figure20-29).
2. Call up the INS UPDATE format (Figure 20-29).
2. Depressthe SWP pushbuttonto display the MFD SURFACE WPT POS updateformat.
3. Depressthe SWP pushbutton,which resultsin the display of the SURFACE WPT POS format with SWP boxed.
3. Depresstheup or down arrowpushbuttonuntil the desiredwaypoint number is displayed. 4. At the instant of overflight, depressthe VIS pushbutton, boxing the VIS legendand displaying the latitude and longitude of the surfacewaypoint.
4. Depressthe up or down arrowpushbuttonuntil the desiredwaypoint number is displayed. 5. Set the sensorhand control cursorswitch to theup position (Figure 20-36).
5. If the latitude and longitude appearreasonable, pressthe ENTER pushbuttonon the SURFACE WPT POS format. This entersthecoordinatesinto the waypoint file; they can be verified by selecting the WPT DATA format (Figure 20-20).
6. Selectthe half-action mode by depressingthetrigger on the RIO sensorhand control to the first detentposition.
20.3.6.4.2 Tacan Surface Waypoint Position Determination. For tacansurfacewaypoint position determination,the position of the tacan station is computed using tacan measurementsof range and bearing from aircraft present position. This procedure can be performedby either crewmemberand requiresthat the tacanbe operating.
8. Depressthe RDR pushbutton on the SURFACE WPT POS format to display the waypoint latitude and longitude and box the RDR legend.
1. With the tacanoperating,selectthe channelfor the stationlocation to be determined.
7. Using the RIO sensorhand control, place the DD cursorover the radartargetand depressthe trigger to the seconddetentposition (full action).
9. Ifthe coordinatesappearreasonable,presstheENTER pushbuttonto placethe surfacewaypoint coordinatesinto the proper waypoint file; they can be verified by selectingthe WPT DATA format,
2. Call up the INS UPDATE format (Figure 20-29). 20-57
ORIGINAL
I
SENSOR
HAND
CONTROL
Figure 20-36. Cursor Controls
ORIGINAL
NAVAIR
HUD/Designate Mode. Using the HUD/ designatemode,the pilot usesthe HUD cursorto designatea visual targetand the targetposition is computed using aircraft present position and azimuth/elevation measuredfrom the HUD centerto the designatedtarget.
20.3.6.4.4
1. Call up the INS UPDATE format (Figure 20-29). 2. Depressthe SWP pushbuttonto display the SURFACE WPT POS format andbox the SWP legend. 3. Depressthe up or down arrowpushbuttonuntil the desiredwaypoint number is displayed. 4. Using thepilot cursorcontrolswitch (Figure20-36), place the HUD cursor over the visual target and depressthe switch to designatethe waypoint. 5. Depressthe HUD pushbuttonon the SURFACE WPT POS format to display waypoint latitude and longitude andbox the HUD legend. 6. If the coordinatesappearreasonable,depressENTER pushbuttonto placethe surfacewaypoint coordinates into the waypoint tile; they can be verified by selectingthe WPT DATA format. 20.3.6.4.5 DEU Mode. In the DEU mode, the position of a new waypoint is computedbasedon its range and bearing from an existing waypoint already in the waypoint file. The rangeandbearingvaluesareentered by the RIO via the DEU (Figure 20-19). 1. On the DEU, selectthe numberofthe known waypoint to be used asa reference. 2. On theDEU, enterthe rangeandbearing from the referencewaypoint to the new waypoint. 3. On the DEU, pressthe SET pushtile and select a waypoint number for the new waypoint. 4. Press the ENTER pushtile on the DEU. This causesthe coordinatesof the new waypoint to be computedand enteredinto the waypoint tile. 5. The latitude and longitude of the new waypoint may be verified by calling the WPT DATA format on the MFD. TID Spot Hook Mode. In the spot hook mode,coordinatesarecomputedfor a point designatedby the RIO by spot hooking on the TID basedon aircraft presentposition.
20.3.6.4.6
20-59
0%W&AD-f
1. Setthe sensorhandcontrol cursorselectswitch to the down (TID cursor) position. 2. On the TID control panel(FO-4), depresstheNON ATTK and SYM ELEM pushbuttons. 3. Set the azimuth scanto i20” on the sensorcontrol panel(FO-4) and adjustthe antennascancenterto zero. 4. Call the WPT DATA MFD format and depress the desired waypoint number to box the waypoint legend. 5. On the TID control panel, set the RANGE switch as requiredand the MODE switch to A/C STAB. 6. Place the sensorhand control trigger to the halfaction position. 7. Placethe TID cursoron the desiredscreenlocation and hook by selectingfull action. This causesthe latitude and longitude of the hookedposition to be computedand enteredin the waypoint tile. 8. The coordinatesof the hooked position can be verified by calling the WPT DATA format. Display Steering Modes. Selecting a display steeringmode presentsthe pilot with command steeringindicationson the MFD and HUD. The display steeringmodes include manual, data link, destination, and tacan.The following paragraphsdescribethe proceduresfor selecting these modes and the indications provided.For all steeringmodes,the HUD shouldbe in the TLN mode.
20.3.6.5
Manual Display Steering. In the manual display steering mode, the pilot maintains a command magnetic course by steering the aircraft to the command heading marker on the HUD or MFD VDI format.
20.3.6.5.1
Initially the pilot selectsa commandcoursefor manual displaysteeringwith the courseselectcontrol(FO-3);this results in the display of command courseand a course line pointer on the horizontal situation display MFD format. The manual display steering mode is initiated when the MAN pushbuttonon the MFD VDI display format is depressed.When this is done, the mission computer calculates command heading by offsetting commandcoursefor any wind drift that may bepresent,
ORIGINAL
NAVAIR Ol-F14AAD-1
Figure20-37showsthedisplayformatsusedfor manual steering.Manual steeringmodecanbeselectedasfollows:
5. Steerthe aircraft to the commandheadingmarker on the HUD or centerMFD MI format.
1. Call the VDI MFD format.
6. A comparison between the command coume mceivedtinm the data link and the d&-compensated command heading can be observedon the tighthandMFD HSD D/L format.Commandcourseis in the form of a courseline pointer,andthecommand headingto be flown is indicatedby captain’sbars.
2. Using the pilot’s CRS select knob on the course/headingpanel (FO-3), selecta course. 3. Verify the selectedcoursevalue under CSEL on the WI MFD format. 4. Depressthe MAN pushbuttonon the VDI format. 5. Steeraircraft to the command heading marker on the HUD or VDI. 20.3.6.5.2 Data-Link Display Steering. In the data-link display steeringmode (Figure 20-38),thepilot maintains a command course,commandedby external inputs from the ASW-27C data link or ANAJRC-107 JTIDS datalink, by steeringthe aircraft to the command headingmarker on the HUD, VDI, or HSD format. The pilot also adjustsaircraft altitude and speedin accordancewith commandedvaluesappearingon the VDI D/L MFD format. The ASW-27C must be in its tactical mode (TAC selectedontheDATALINKpane1) orJTIDS must be in AIC and its tactical mode (JTIDS on the DATA LINK panel). The data-link steeringmode is selectedby depressing the D/L pushbuttonon the MFD VDI display format. When this is done,themission computerthen calculates command heading to be flown to make good the D/L supplied command course by correcting for any wind drift. The resulting command heading marker appears on the MFD VDI D/L, MFD HSD D/L, and HUD D/L formats. The D/L also suppliescommand altitude and commandspeedthataredisplayedon the MFD VDI D/L format. Command courseis displayedon theMFD HSD D/L format as a courseline pointer. Figure 20-37 shows the display formats used for data-link display steering.
20.3.6.5.3 Destination Display Steering. In the destination steering mode, the pilot maintains a great circle routefrom the aircraft presentposition to a designated waypoint by steering to the command heading marker on the HUD and VDI. The pilot selectsthe destinationwaypoint for steering by depressingthe up or down arrow pushbuttonson the HSD basic format and then pressingthe ENTER pushbutton. This results in the HSD format in Figure 20-39. The mission computer calculatesrange, bearing, and time to go from the aircraft position. This datais shown in the upper left data block on the HSD format. The destinationdisplay steeringmode may thenbe initiated by depressingthe DEST pushbuttonon the MFD VDI display format or by boxing WPT on HSD. The mission computer then calculates the command great circle courseto the selectedwaypoint andthe commandheading to fly to make it good by consideringdrift angle. The destination command course,destinationcommand andheadiig, rangeto destination,time to go, and waypointnumberaredisplayedasshownin Figure20-39.
Data-link steeringusing the ASW-27C or IJRC-107 JTIDS can be performed as follows: 1. Call the VDI and HSD display formats on the pilot centerand right MFDs, respectively. 2. Depressthe D/L pushbutton on the center MFD VDI format.
For thedestinationsteeringmodeproceedasfollows: 1. Call the VDI and HSD formats on the pilot center and right MFDs, respectively. 2. On the HSD basic format, depressthe up or down arrow pushbuttonsuntil desireddestinationwaypoint number appearsbetweenthe arrows. 3. On the HSD basic format, depressthe ENT pushbutton. The selected waypoint will then appear underthe DEST waypoint symbol on all HSD displays and under the selectedWPT symbol of the HSD display used to enterthe waypoint.
3. Maintain the command altitude indicated on the right side of the centerMFD VDI format.
4. On the VDI basic format, depressthe DEST pushbutton or box WPT on the HSD format. Destination steeringwill now beprovided andDEST will be boxed.
4. Maintain the command speedindicatedon the left side of the centerMFD VDI format.
5. Steer aircraft to command heading marker on HUD or VDI.
ORIGINAL
20-60
NAVAIR 01-F14AAD-I
HUD
.
MARKER
-500 a M ,=
13.5 0.52 1.2 4.5
MANUAL SELECTED
MAN .
---,lO
lOL---
\ \
//
IT\’ I
VDI COMMAND HEADING MARKER
35 -+3
36
01 -
__
__
-
-
MANUAL STEERING SELECTED ----a---
(AT)2-F50D-445-1
Figure20-37.ManualSteeringModeFormats(Sheet1 of 2)
20-61
ORIGINAL
NAVAIR 0%F14AAD-1
Figure 20-37. Manual SteeringMode Formats (Sheet2 of 2) 20.3.6.5.4 Tacan Steering. In the tacan steering mode (Figure 2040), the pilot may steerto a selected tacanradial using the various coursedeviation displays on the HUD andMFD. The tacandeviation is the angular difference betweenthe bearing to the tacan station (tacan radial) and the command course (tacancourse) selectedbythepilotonthecourse~eadingcontrolpanel. To enterthe tacansteeringmode, the pilot depresses the TCN pushbuttonon the MFD VDI display format or boxes TACAN on the HSD format. After selection of a tacan course,the tacan deviation symbols are displayed on the HUD, MFD VDI tacan,andtwo possible HSD tacan formats. On the HSD tacanformat, the CD1 display mode may be selectedby depressingthe CD1 pushbutton.With CD1 selected,the tacan deviation is displayed in the form of a deviation bar whoseoffset is scaledalong a row of deviation tics. The arrow headon the bar is changedon the displays to indicate whether the tacancourse is toward or away from the tacanstation. If the tacandeviation is lessthan90”, a to indication is shownand, if greaterthan 90°, a from indication. The tacandeviation barson the HUD, MFD VDI tacandisplay format and MFD HSD tacan display format are solid bars when going to and dashedbars when coming from. The separationbetweendeviation tics is 4O.
ORIGINAL
If the CD1 display is not selected,then the second HSD format in Figure 2040 is displayed. On this format, the tacan radial is still displayed passingthrough the a&at? symbol but insteadof the deviation indication, the command course pointer is shown passing throughthe station symbol. The tacan ID, command course,tacan range,&an bearing,time to go to the tacanstation,andtacandeviation areall shown on the MFD HSD tacandisplay format. The tacanrangeand tacandeviation are shown on the HUD and MFD VDI tacan display format. Figure 2040 showsthe display formats usedfor tacandisplay steering.
20-62
The tacansteeringmode is performed asfollows: 1. Select the desiredtacanchannel. 2. Call the VDI or HSD formats on any MFD. 3. DepressTCN pushbutton on VDI format or box tacan information on HSD format to enabletacan steering. 4. DepressCD1pushbuttonon HSD format to bring up coursedeviation indication format.
NAVAIR 01.F14AAD-1
..-HI Ill
:+:
%
5L__
12OOR
---J5
:I+:
. -500 a M G /
13.5 0.52 1.2 4.5
x lOL-
--
---,10
/
y
\
\
T’2’5\DATALlNK
I
SELECTED
VDI
OMMAND
COMMAND MACH NO.
HEADING
fAT)2-F50D-446-1
Figure 20-38. Data-Link SteeringMode Formats(Sheet 1 of 2)
20-63
ORIGINAL
NAVAIR 0%FUAAD-1
HSD
--‘1MAND ,,lJRSE
Figure 20-38. Data-Link SteeringMode Formats (Sheet2 of 2) 5. On pilot course/headingdisplay control panel, commandcourseis selected.This is verifiedunder CSEL on pilot centerand right MFD. 6. Pilot steersto move tacandeviation pointerto center of MFD HSD tacandisplay format until it becomes coincident to command course (tacan course)line. 20.3.6.6 Autopilot Steering. The mission cornputer providesthe AFCS autopilot with a setof steering validity discretesand a computed steeringerror for its engagedsteeringmode.The availableautopilot steering modesare: headinghold, groundtrack hold/destination hold, and data-link vector hold. Refer to Chapter2 for a descriptionof theseAFCS functions.
20.3.6.7 All-Weather Landing. The mission computer provides the appropriatesteering information to the aircraft displays for a requestedAWL mode.This is derivedfrom datasupplied by theILS andACLS. AWL information is available from either the data link (AN/ASW-27C (ACL)) or the ILS receiver(AN/ARA63) or both. The AWL steeringmodesoperatecontinuously in the A/C landing phaseto monitor and respond to pilot AWL requests.The pilot steers to glidepath situationdisplays (both ACL and ILS) and flight director displays during the approachand descentphasesof the landing phase.Chapter2 describesthe AFCS ACL function, and Chapter 17 provides ACLS description andprocedures.
Note The autopilot data-link vector hold steering mode is not supportedusing JTIDS vector steeringdata.
ORIGINAL
20-64
Note The AWL function is not supportedby the JTIDS.
NAVAIR 01-F14AAD.I
&
*-. :
. * .
<
250 : 7- . *
5L---
2205 : ’ til - . * -500
a 13.5 M 0.52 G
1.2 4.5
/
WAYPOINT ELECTED FOR DESTINATION
l
---,5
--
lOI.---
4
/ WPT1225.4
-JlO
’
IV\’
\
I
RANGETO DESTINATION
VDI
MAND HEADING MARKER ’ -3
I ’ 35
I ’ 36 __
__ __
N
,
RANGE TO DESTINATION
__ __
--
-----q---
---
\ DESTINATION SELECTED
,._.^
Figure 20-39.
Destination
_.^_
._
Steering Mode Formats (Sheet 1 of 2)
20-65
ORIGINAL
NAVAIR
01-F14AAD-1
HSD COMMAND HEADING
\
SEARING TO DESTINATION WAYPOINT
Figure 20-39. Destination SteeringMode Formats (Sheet2 of 2)
ORIGINAL
20-66
NAVAIR Of-Fl4AAD-1
HUD
TACAN
TACAN
u M G /
13.5 0.52 1.2 4.5
COURSE
SELECTED
-500 TACAN IOL-
--
‘/
---,I0
/
y
\
TCN
\
’
12.5’
RANGE
\T,~GIN SELECTED
I
VDI COMMAND
__
+a
HEADING
__
TACAN RANGE CAN COURSE DEVIATION MARKER
TACAN SELECTED
TACAN SELECTED COURSE POINTER
(AT)%F50D448-1
Figure 20-40. Tacan SteeringMode Formats (Sheet 1 of 2)
20-67
ORIGINAL
NAVAIR
01-F14AAD-1
HSD CDI SELECTED
ADF POINTER /
\
CDI
POINTER
TACAN DEVIATION MARKER
SELECTED HEADING
-SELECTED
’
HSD CDI NOT
SELECTEI SELECTED
SELECTED HEADING
Figure 20-40. Tacan SteeringMode Formats (Sheet2 of 2)
ORIGINAL
20-66
NAVAIR
01.F14AAD-1
CHAPTER 21
Identification 21.1
IDENTIFICATION (AN/APX-100)
TRANSPONDER
21.1.1 IFF Transponder. The APX-100 IFF transpondersystem is capableof automatically reporting codedidentification and altitude signalsin response to interrogationsfrom surface(or airborne) stationsso thatthestationscanestablishaircratl identification, control air traffic, and maintain vertical separation.The systemhas five operatingmodes (1, 2,3/A, C, and 4). Modes 1 and 2 are IFF modes,mode 3 (civil mode A) andmode C (automatic altitude reporting)areprimarily air traffic control modes, and mode 4 is the secure(encrypted)IFF mode. The IFF control panel is in the rear cockpit (Figure 21-I). Master Switch. The MASTER switch applies power to all the transpondersystem components except the altimeter components.It is a four-position rotary switch placarded OFF, STBY, NORM, and EMER. The switch must be lifted over a detentto switch to EMER or to OFF. STBY should be selectedfor 2 minutesprior to switching to LOW or NORM to allow the transponderto warm up. In NORM, the transponder system is operationalat normal receiver sensitivity. In EMER, the transpondertransmits emergencyreplies to mode 1, 2, or 3/A interrogations.The mode 3/A emergency reply includes code 7700. When EMER is selected,all modesare enabledregardlessof the position of the selectorswitches. When the front seat ejects,a switch is tripped that automatically selects the emergency mode if the MASTER switch is in any position otherthan OFF. 21 .l .I .l
Antenna Select Switch. The position of fhe antennaselectswitch determinesAPX-100 antenna reply logic. Although the system is designedto receive an interrogationon either antennaat all times regardless of switch position, with TOP or BOT selected,it will only reply on theselectedantenna,andonly ifthe strongest interrogation signal was received on that antenna. For example,if BOT were selectedandthe interrogation signalwasstrongerfrom thetop antenna,no reply would be transmitted. In the DIV (diversity) position, an an21.1.1.2
21-1
tennadiversity comparatoridentities which antennareceived the strongestinterrogation signal and automatically selects that antennato transmit the reply. It is thereforerecommendedthat the antennaselect switch be left in DIV at all times.
IfeitherTOPorBOTisselectedon theAPX100 antennaselectswitch, a Mode IV reply will be transmittedonly if the Mode IV interrogationsignal is strongeston theantenna selected.If the strongerof the two antennas was not selectedat the time of interrogation, the aircrew will not have any indication that theiraircrafi was interrogatedor that no reply was made. IDENT-OUT-MIC Switch. The IDENTOUT-MIC switch is a three-positiontoggle switch. The spring-loadedIDENT addsan identification of position pulse to mode 1,2, and 3/A replies for a period of 15to 30 seconds.In MIC, the identification of position function is activatedfor 15to 30 secondseachtime the UHF microphoneswitch is pressed. 21.1.1.3
Mode 1,2, and 3/A Code Selectors The two mode-l thumbwheel selectorswitchesallow selection of 32 mode-l codes and the four mode-3/A thumbwheel selectorsallow selection of 4096 mode3/A codes. The mode-2 code that is set on the four MODE 2 selectorswitchesmay be readby moving the sliding cover. The code may be reset by inserting a pointed object like a pen tip or a paperclip to rotatethe thumbwheel. Mode 2 codesare not normally changed in flight. 21.1.1.4
Mode Switches. The four mode switches (M-l, M-2, M-3/A, and M-C) eachhaveOUT, ON, and spring-loadedTEST positions. The centerposition ON of eachswitch enablesthat mode. To test the transponder,pressthe mode switch of eachmode to TEST. 21.1.1.5
ORIGINAL
NAVAIR
Ol-F14AAD-1
II;:
/-i/-
‘u’ -
II
I,
II
h 18
IFF
!,-
!--.-.....-....-.---J
NOMENCLATURE
FUNCTION
1. TEST light (GO)
Illuminates when respective MODE switch TEST position is actuated; indicates proper (GO) operation of modes 1, 2, 3/A. and C. Master switch must be set to NORM.
2. TEST/MON
The light has two functions, Illuminates when respective MODE switch TEST position is actuated: indicates failure (NO GO) of modes 1,2,3/A and C. Master switch must be set to NORM.
light (NO GO)
3. ANT switch
Selects upper (TOP), lower (BOT), or both (DIV) antennas. DIV (diversity) permits the IFF to switch automatically for transmission to the antenna that received the strongest interrogation signal.
4. MASTER switch
OFF -
Deenergizes
se!.
STBY - Energizes receiver-transmitter switching to an operating position. NORM -Allows
receiver-transmitter
for immediate
operation
upon
response to interrogations.
EMER - Energizes receiver-transmitter and generates emergency replies to mode I,2 (thumbwheel settings), and 3/A (code 7700) and a normal reply to mode C, when interrogated, whether mode switches are at ON or OUT.
Figure 21-1. IFF Control Panels(Sheet 1 of3)
ORIGINAL
21-2
NAVAIR
NOMENCLATURE
Ol-Fl4AAD-~
FUNCTION
i. STATUS lights (red)
I. RAD switch
‘. IDENT-OUT-MIC switch
ALT
-
Illumination indicates MODE C test.
altitude
encoder
circuit failure
during
KIT
-
Illumination indicates KIT/KIR TSEC failure during MODE 4 test.
ANT
-
Illumination indicates excessive voltage standard wave ratio (VSWR) to antenna during MODE C or MODE 4 tests.
TEST
-
When selected, transponder replies to mode 3/A or 4 TEST mode interrogations from a ramp test set during ground maintenance testing.
OUT
-
Deenergized
position.
IDENT -
Momentary position provides IDENT reply for 15 to 30 seconds after releasing switch; replies to interrogation in modes 1,2,3/A.
OUT
-
Deenergizes
MIC
-
Transfers IDENT reply activation microphone switch
circuit, switch from
IDENT to radio
I. MODE 4 REPLY light
Illuminates when system has successfully replied to a mode 4 interrogation provided the AUDIO/LIGHT/OUT switch is not in the OUT position.
I. MODE4 AUDIO/LIGHT/OUT
AUDIO -
Enables (1) An ICS tone indicating either incomplete signal reception or that the received interrogation code does not match the installed code, (2) no go and IFF caution lights indicating no reply to a valid mode 4 interrogation, and (3) MODE 4 REPLY light indicating a valid mode 4 interrogation reply.
LIGHT -
Enables (1) no go and IFF caution lights indicating no reply to a valid mode 4 interrogation, and (2) MODE 4 REPLY light indicating a valid mode 4 interrogation reply. Disables ICS audio tone monitoring.
OUT
Disables all ICS tone and light monitoring interrogations, replies, and nonreplies.
switch
-
of mode
4
IO. CODE selectors (MODE 1 and 3/A
Code selectors are rotatable drums with imprinted numbers that appear in code selector windows, permitting selection of codes for mode 1 and 3/A.
Il. MODE 4 switches
ON
-
Enables mode 4.
OUT
-
Disables mode 4. See Figure 21-2 for mode 4 caution/reply
TEST -
light logic.
Activates KIT mode 4 computer self-test. TEST illuminates if system if functional, NO GO if it is not.
GO light
If KIT computer is at fault, STATUS KIT light illuminates red. If KlTlKlR is not installed, NO GO and STATUS KIT lights illuminate. Figure 21-I.
IFF Control Panels (Sheet 2 of 3)
21-3
ORIGINAL
NAVAIR 01-F14AAD-1
FUNCTION
NOMENCLATURE 12. MODE2
Code selectors are rotatable drums with imprinted numbers that can be seen when sliding cover is moved out of view. Changing requires pointed object. Not normally changed in flight.
13. MODE 4 CODE switch
ZERO -
Erases code 4 from KIR-IA and KIT-1A computers. IFF ZERO advisory legend appears on upper left of RIO’s MFD.
B-
Selects KIT-IA computer
A
Selects KIT-1A computer A code.
HOLD -
Retains code in KIR-1A computers or when system is turned off.
TEST -
GO TEST light illuminates if system is functioning GO TEST light illuminates if system failure.
ON
-
Permits selection of interrogating transponder will reply.
OUT
-
Deenergized
14. MODE switches (1.2, 3/A, and C)
B code.
when landing gear is down property; NO
modes to which the
position.
15. M4 ALARM OVERRIDE switch
Disables the mode 4 tone alarm to the RIO’s ICS.
16. FAULT light
Indicates a malfunction of APX-76 receiver-transmitter, video, or transmitter signals.
17. CHAL light
Remains illuminated for the duration of a challenge operation.
18. CODE selectors
First thumbwheel selects mode, 1, 2, 3A, 4A, or 4B. Last four thumbwheel rotatable drums with imprinted numbers appearing in code selector windows, permit selection of desired interrogation code.
19. TEST-CHAL
Momentary
CC switch
TEST -
CHAL cc -
two-position
center-return
correct
Onboard transponder is triggered by onboard interrogator. Both sets must have same code setting. IFF solid lines are displayed on DD at 3 and 4 miles. A selective identification
feature (SIF) interrogation
cycle starts
the 5-to lo-second challenge period. Only correct modes and (two brackets only on DD).
Indicates mode 4 interrogation was received, but system has not generated reply; mode 4 KlTlKlR computers have been zeroized; KIT/KIR has failed self-test.
Figure 21-1. IFF Control Panels(Sheet3 of 3)
ORIGINAL
period indicating
switch.
code replies are displayed 20. IFF warning legend
caused by receiver,
21-4
NAVAIR
TRANSPONDER (APX-100)
4 OUT (A) STBY 4 ON (A) STBY 4 ON (A) NORM 4 ON (A) NORM 4 ON (B) NORM 4 ON (B) NORM 4 ON (B) STBY 4 ON (B) STBY 4 ON (A) NORM RAD
INTERROGATOR (APX-76)
CAUTION
A A A
01.F14AAD-I
REPLY (APX-100)
A B B B VERIFY BIT 1 (A)
ON ON OFF OFF OFF OFF ON ON OFF
OFF OFF ON OFF OFF ON OFF OFF ON
VERIFY BIT 1 (A) VERIFY BIT 1 (A) AORB
ON ON ON
OFF OFF OFF
0
TEST
4 ON (A) NORM 4 ON (A) STBY KIT ZERO
Figure 21-2. Mode 4 Caution and Reply Light Logic Illumination of the GO TEST light indicatesproper operation of that mode. Illumination of the NO GO TEST light indicatesfailure of the selectedmode. The MASTER switch must be set to NORM for the test function to operate.The modesnot being testedshould be OUT when testing on the ground to prevent unnecessary interferencewith nearby ground stations. If a malfunction exists during theseself-tests,an IFX acronym will appear on the tactical information display (TID). The IFF transponder is also continuously checkedby aircraft self-test. Failure causesthe IFX acronym to be shown on the TID. Calling up the failure historytileortheCNIOBCdisplayonanyMFDwillshow whetherthe failure is in the transpondercomputer(IFA), thetransponder(IFXPN), or the entiresystem(IFX). 21.1.1.6 RAD TEST-OUT Switch. The springloadedRAD TEST is usedfor testing.It enablesamode3/A code reply to a TEST mode interrogation from a ramptestset.It alsoenablesa mode4 reply to a VERIFY 1 interrogationfrom a surfacestationor a ramp test set. A VERIFY 1 interrogationis a modified mode 4 interrogationusedfor testing. 21 .I .l .7 Mode 4 Operation. Mode 4 operation is selectedby settingthe MODE 4 toggle switch ON, provided that the MASTER switch is NORM. Setting the MODE 4 switch to OUT disablesmode 4. The MODE 4 CODE switch is placardedZERO, B, A, and HOLD. The switch must be lifted over a detent to switch to ZERO. It is spring-loadedto return from HOLD to position A. PositionA selectsthe mode4 code for the presentcode period and position B selects the mode4 codefor the succeedingcodeperiod.Both codes aremechanicallyinsertedinto the transponderby main21-5
tenancepersonnel.The codes are mechanically held in the IFF, regardlessof the position of the MASTER switch or the statusof aircraft power, until the first time the landing gearis raised.ThereaRer,the mode 4 codes will automaticallyzeroizeanytime theMASTERswitch or the aircraft electrical power is turned off. The code settingscan be mechanically retainedafter the aircraft has landed(landing gear must be down and locked) by turning the CODE switch to HOLD and releasingit at least 15secondsbefore the MASTER switch or aircraft electricalpoweris turnedoff. The codesagainwill beheld, regardlessof the statusof aircraflpoweror the MASTER switch,until thenext time the landinggearis raised. The mode 4 codescan be zeroized anytime the aircraft power is on andthe MASTER switch not OFF by turning the CODE switch to ZERO. An audio signal, the REPLY light, and the IFF caution light are used to monitor mode 4 operation.The AUDIO/LIGHT/OUT switch controls thesemode 4 indicators. When the IFF MASTER switch is in NORM andtheMODE 4 TEST/ON/OUT switch is on,selecting AUDIO on the MODE 4 AUDIOiLIGHT/OUT switch providestwo types of mode 4 cautionindications: (1) an ICS audio tone indicating either incomplete signal reception or the received interrogation code does not match the installed code, and (2) a no go light and IFF caution light indicating the system is not respondingto a valid mode4 interrogation.Selectingthe lightposition disablesthe ICS audio tone and provides only the IFF cautionlight andno go light. Selectingthe OUT position disablesthe ICS tone,no go light, and IFF caution light indications and disablesthe REPLY light indication of a valid reply. (Caution and REPLY light logic is shown in Figure 21-2.) I ORIGINAL
NAVAIR 0%Fl4AAD-l
Note When flying in a tactical environment, the MODE 4 AUDIO/LIGHT/OUT switch should remain in the AUDIO position at all times. Use of a switch position other than audio will deny the aircrew mode 4 caution indications.
A/A dc circuit breaker(9F6). It is capableof interrogation anddisplay of modes I, 2,3A and4, andof displaying EMERG AND IDENT on the DD. Refer to NAVAIR 01-F14AAD-IA. The APX-76 interrogatorconsistsofan antennaarray that is part of theradarantenna,a control panel,receivertransmitter,switch amplifier, and for mode 4 operation, an interrogatorcomputer.
21.1.1.6 IFF Caution Light. The IFF caution light on the RIO’s ladder lights comes on to indicate that mode 4 is not operative.The light is operativewhenever aircraftpowerison andtheMASTERswitchisnotOFF. However, the light will not operateif the mode 4 computer is not physically installed in the aircraft. Illumination of the IFF caution light indicatesthat: (1) the mode 4 codeshave zeroized, (2) the self-test function of the KIT-lA/TSEC computer has detected a faulty computer, or (3) the transponderis not replying to proper mode 4 interrogations.
The IFF antenna consists of six dipole antennas mountedon the surfaceofthe radarplanaranayantenna. The antennaazimuth and vertical coverageis the same as that of the radarantennaexcept that the beam width of theAPX-76 is 13”. The transmitter operatesat a fixed frequencyof 1,030MHz and the receiver operatesat a fixed frequencyof 1,090MHz.
Ifthe IFF caution light illuminates, switch the MASTER switch to NORM (if in STBY) and ensurethat the MODE 4 toggle switch is ON. If illumination continues, employ operationally-directedflight proceduresfor an inoperativemode 4 condition. 21.1.1.9 IFF ZERO CAW. An IFF ZERO CAW is displayed in the MFD CAW window when a KIT computer is installed and the mode 4 codes have been xeroized.The IFF ZERO CAW is only valid ifthe APX100 MASTER switch is not OFF. If the MASTER switch is OFF, the IFF ZERO CAW is displayedregardlessof whetherthe IFF codesarezeroizedor not.
Except for the display of IFF video, the APX-76 is the same in all modes of radar operation. The radar analog signal converter provides an IFF pretrigger for the purpose of synchronizing the IFF and radar. On receiving thepretrigger from theradar,the IFF synchronizer generatestriggersthat establishthetimingoftransmission of challenges and decoded reply video for display on theDD. With the radarin low PRF, IFF video is mixed with radar video and displayed in the radar format. In high PRF, the IFF video isdisplayed in a B-scan format without radarvideo.
21.I .2 Altitude Computations. Altitude computations areperformed by the CADC. The computer outputs are altitude information corrected for static position error. The synchro output is supplied to the altimeter providing the crew with a corrected altitude indication. The digital output from the computer is applied to the transponderfor transmission on mode C, codedin incrementsof 100 feet, and referencedto 29.92 inches of mercury. 21.2 IFF INTERROGATOR (ANIAPX-76) The AN/APX-76 provides radaridentification of airborne and surfaceMark 10 IFF systems.It operatesin conjunction with the radarand is automatically turned on whenever the RDR power switch is placed to any position except OFF. A minimum warmup time of 3 minutes is requiredbefore successfuloperationor BIT can be performed. The system requires l l5-Vat from the main ac bus through the IFF A/A ac circuit breaker (157)and 28-Vdc from the main dc bus throughthe IFF ORIGINAL
21-6
‘Ihe synchronizeralso sendsa mode 4 pretriggerto the interrogatorcomputer. The interrogatorcomputer generatesmode 4 intermgationsandinterpolatesmode4 replies.Display ofmode 4 is the sameas all other modes. The mode 4 codesare preventedfrom zeroing when the RDR power switch is cycled. 21.2.1 IFF Self-Test. Prior to APX-76 operation, self-test of the unit should be performed.The APX-76 containsa self-test function that provides closed loop testing in conjunction with the on-boardAPX-100 (IFF Transponder).To perform theself-test,the RIO must set the mode and code switches on the control panel to correspondwith the mode and code switches of the APX- 100.The APX- 100 must be in NORM or EMER before performing the test. ‘Ihe RIO may now initiate self-test by holding the TEST/CHAL CC switch in TEST for 5 to 10seconds.Providedboth the IFF andthe APX-76 are functioning properly, two horizontal bars will be displayedacrossthe DD at approximately4 and 5 miles illumination of the green CHAL light on the control panel while the switch is being held in the test position, also indicates that the APX-76 made a valid interrogation.The bottom line on the DD indicatesthat
NAVAIR 0%FI4AAD-1
the APX-100 respondedin mode and the top line indicatesit respondedin code.Both lines togetherindicate that the APX-76 is decoding properly. Biasing of the mode and code lines enablesthem to be spreadout on theDD during test.Ifthe first attemptto testthe APX-76 fails becauseof lack of video on the DD, or the amber fault light on the control panel illuminates, the RIO shouldinitiate a validchallenge by momentarily holding the CHAL CC/TEST switch in CHAL CC in order to reset the BIT flags associatedwith the APX-76. The APX-76 normally powers up with the BIT flags in the fault position. The systemwill continuously fault until the flags are reset. The APX-76 antenna is checked during the test by receiving actualvideo from the APX100 antenna.Failure of any part of the APX-76 closed loop test will causeIFI to be displayed in continuous monitor. A further breakdownas to what portion of the
systemhasfailed canbeverified by calling up the maintenancetile. Testing of all modesof the APX-76 should be performed independently.Failure of one mode does not necessarilymeanthat all modesaremalfunctioning. The APX-76 receiver-transmitter,switch amplifier, interrogator (KIR) computer, and synchronizer are checkedduring CNI OBC. Results can be called up on any MFD. These units are also subject to continuous monitoring. Statuscan be readby calling up the failure history file. In addition, the TID displays the IF1 acronym if the receiver-transmitter or switch transponder fails continuous monitoring. During OBC, CHALLENGE IFF is displayed on MFD 3 in order to remind the RIO to reset the BIT flags by making a valid challenge.
ORIGINAL
NAVAIR
01.F14AAD-1
RIO HAS MODE 3, CODE 1200 SET SEARCH PROPER MODE AND CODERETURNS WT” TARGETVIDEO
MODERETURN ONLYWITH TARGETVIDEO
SINGLE-TARGET TRACK TARGET UNHOOKED
MODES PROPER MOOE AND CODERETURNS NOTAROETWDEO
TARGETNOTSO”AWKlNG OR SO”AWKINGANOTHERMODE
STTTARGET*o”AWKINO PROPER MODEANDCODE ,PDSTTB-OUNPRESENTATION,
SINGLE-TARGET TRACK TARGET HOOKED
TEST
Figure.21-3. IFF Display Formats ORIGINAL
21-a
NAVAIR O1-F14AAD-I
PART VIII
Weapon Chapter22 -TARPS
Systems Subsystem
Chapter23 -Navigation
Commandand Control Grid
Chapter24 -Resewed for LANTIRN Targeting System The followingchaptersare tobc foundinNAVAIROl-F14&4D-IA: Chapter25 - F-14D WeaponSystem Chapter26 - Weapon SystemControls and Displays Chapter27 - AN/AFG-71 RadarSystem Chapter28 - ANlAAS-42 l&wed Searchand Track System Chapter29 - AN/AXX-1 Television CameraSet Chapter30 - IntegratedSensorOperation Chapter3 1 - StoresManagementSystem Chapter32 -Air-to-Air
Weapons
Chapter33 - Air-to-Ground Weapons Chapter 34 -Electronic
WarfareSystems
Chapter 35 -Data-Link
Systems
Chapter36 -Weapon System DegradedOperation
89 (ReverseBlank)
ORIGINAL
NAVAIR 01-F14AAD-l
CHAPTER 22
TARPS Subsystem 22.1 RECONNAISSANCE
SYSTEM
The reconnaissancesystem establishesthe aircrafi as a multisensorreconnaissanceaircraftwith the flexibility for a wide range of reconnaissancemissions. Specific missions include order-of-battlegeneration,prcstrike/ poststrikephotography,and maritime surveillance. The sensorsand associatedequipmentare contained in the pod? four compartments(Figure 22-l). The sensorsam serialfhme camera!J&87D), low- to mediumaltitude panoramic camera (KA-99), or long-range standoff frame camera (KS-153A with 24-&h lens), andAN/AAD-5A in&red reconnaissanceset .
This capability is compatible with the F-14 tactical air reconnaissancepod system and includes target designation and steering command functions and reconnaissance sensor control as well as specific reconnaissance displaysto crew andin-flight BnnOtation of reconnaissancedata. The TARPS consistsofthe following components(as shown in Figure 22-l): 1. TARPS pod 2. Serial frame camera 3. Panoramiccamera
2-wm-263-O
Figure 22-l. Tactical Air ReconnaissancePod System
22-1
ORIGINAL
NAVAIR Ol-Fl4AAD-1
4. I&S,&
22.1.6 TARPS Environmental Control System. The ECS supplies conditioned air for pod cooling and heatingand for defogging the camerawindows.
limescannerset
5. Data display system 6. TARPS environmentalcontrol system
22.1.7 Control indicator Power Distribution Unit. The CIPDU provides power and signal distribution aswell as fail indicators for eachof the variousood sensorsandmajor pod equipmentto guide mainten&e personnel in the identification of faulty WRAs. The CIPDU also provides the verification of proper operation following corrective maintenance for preflight checkoutpurposes.
7. Control indicator power distribution unit 8. Controller processorsignal unit The TARPS location on the aircraft is shown in Figure 22-2. 22.1.1 TARPS Pod. The TARPS pod (Figure 22-2) is 207.5 inches long and weighs approximately 1,625 poundsincluding sensorequipment.The pod is nonjettisonabie and is mountedto the aircraft on weapon station 5 with an integral pylon adapter. The adapter providesthepod with sensorcontrol signals,dataannotation signals, electrical power, and ECS supportfrom the aircraft. Circuit breaker protection is provided throughthe ac left and right main circuit breakerpanel. The pod is designedfor carriagethroughoutthe flight envelope.
22.1.8 Controller Processor Signal Unit. The CPS (Figure 22-3) andcockpit displaysprovide thecontrols and information required by the RIO and pilot for operationandcheckoutof TARPS. The CPS is in the aft cockpit left console and contains the primary TARPS controls and indicators. Using the CPS with the multifunction displays,the RIO hasfull control of TARPS. A descriptionof the CPS controls and their functions are provided in Figure 22-3.
22.1.2 Serial Frame Camera. The serial frame camera can be directed in flight either to the forward oblique position to obtain photogmphsof the area as seenby the pilot, or to a vertical position for use as a backup sensorin the event the panoramic camerafails or for mapping missions.
As describedin Chapter 2, the display system provides the following:
The serial cameramount assemblyholds the camera andprovides the capability to move the camerain flight from the vertical position to the forward position. Controls for the camerapositioning are on the CPS.
2. Display of reconnaissancesteeringcuesand camera statusto the HUD when valid steeringis selectedand the aircrafl is not in A/A with a weapon selected.
22.1.3 Panoramic Camera. The panoramic camera offers full horizon-to-horizonpanoramic imagety over a broadvelocity/above groundlevel mission envelope.
3. Display of reconnaissancesteering cues on the VDI when the VDI is selected.
22.2 DISPLAY SYSTEM
22.1.4 infrared Line Scanner Set. The IRLS provides a film record of termin being traversedby the aircraft. ScanningopticsreceiveIFt energyfrom the area under surveillance. Electrical signals, representingthe scannedarea,are recordedon black andwhite film. The IRIS is roll stabilized to %?O’ in NFOV and ~4~ in WFOV. If normal INS and SAHRS modesarenot avaiiable, lR imagery may be degradedbecauseof poor roll stabilization. 22.1.5 Data Display System. The DDS performs two basic TARPS functions. It provides codedannotation on the sensorfilm for future interpretationof the recordedintelligence data and suppliesnecessarycontrol signals to the individual sensors. ORIGINAL
2212
1. Selection of waypoint to be reconnoitered and steering mode (point-to-point, command course, or mapping) to be employed.
4. Command steeringdisplays using the reconnaissance steering symbol and reconnaissancecommand headingmarker. 5. Displays of reconnaissanceTARPS sensorstatus and camera solution cues to crew on the MFD RECON DATA statusformat. 6. Display of target waypoint (referencepoint) data on the IvlFD RECON DATA statusformat. 7. Display of waypoint reconnaissanceparameters (command crossing angle, target length, map lines, map separationdistance(map offset))on two formats.
NAVAIR 014=14AAD-1
TARPS POD ON STATION 5 /
SrATlC
ORO”N0
LINE
Figure 22-2. TARPS ComponentLocation
ORIGINAL
NAVAIR 01.Fl4AAD-1
_...
@---a----
Figure22-3. ControllerProcessor SignalUnit (Sheet1of 6)
ORIGINAL
22-4
NAVAIR 01.F14AAD-1
NOMENCLATURE
FUNCTION
0
FRAME lights l Amber l Green
Green FRAME IigM flashes once per camera cycle when serial frame camera is activated and no failure exists. Amber FRAME light illuminates if failure exists in serial frame camera and green FRAME light goes off.
0
MOUNT light l Amber
Illuminates indicating mount fallure. This occurs when serial frame camera fails to achieve directed position within 23 seconds. (It may be finly locked In positlon opposite to directed one.) CIPDU internal failure can also give mount failure indication.
0
SC (Sensor Control) iigm 0 Amber
Illuminates when SC/DDS has failed to furnish Film Motion Compensation (FMC) or cycle commands to sensors. Failure to deliver formatted data on command to sensors will not show SC failure. Consequently, SC GO indication can result In good sensor imagery operation but without data annotation.
@
PAN lights l Amber l Green
Green PAN light flashes once per camera cycle when the panoramic camera has been activated and no failure exists. Amber PAN light lllumlnates and green light goes out if failure occurs.
0
ECS (Environmental Control System) light l Amber
Illuminates only under failure condition (compartment temperature or above 51 OC). ECS is automatically activated on takeoff by welght-on-wheels switch.
@
tR NR (lR not ready) llgm l Amber
Illuminates when sensoris not sufficiently cooled. Cool down period Is a maxlmum of 17 minutes. After cool down is completed the IR NR light goes out for 120 seconds, then on for 80 seconds during BIT testing, then extinguishes indicating sensor is ready.
IR LS (IR Line Scanner) light l Green . Amber
Green IR LS light flashes once per foot of film exposed. Green IR LS indicator goes out and amber IR LS light illuminates If failure occurs in infrared sensor.
Frames and feet (Indicators)
Display number of frames remaining In frame and pan cameras, and number of feet of film remaining in infrared sensor. Indicators are set inltlally as part of sensor servlclng via reset knobs directly under indicators. Each frame or pan camera cycle decreases indication by 1. Each foot of film cycles through IR sensor decreases feet indication by 1.
FRAME camera switch
OFF -
Frame camera Is shut off.
VERT -
SYSTEM switch is RDY. Power applied to frame camera. Mount placed In vertical posltlon. When FILM switch In RUN, camera Is cycling.
FWD-
SYSTEM switch In RDY; power Is applled to frame camera.Mount placed In forward positlon (depressed 16O from horizon). When FILM switch in RUN, camera Is cycling.
0
69
@
below 0°C
Figure22-3. ControllerProcessor SignalUnit (Sheet2 of 6) 22.5
ORIGINAL
NAVAIR Ql-F14AAD-l
FUNCTION
NOMENCLATURE
Note Requires approximately 15 seconds to transition between FWD and VERT (The amber mount light illuminates if transition not completed in 23 seconds.) 63
PAN camera switch
BIT -
(momentary position) SYSTEM switch must be in RDY to get BIT. Applies power to pan camera. Initiates 12 second BIT With FILM switch to RUN, BIT will not function.
Do not run PAN BIT check. iam)
(May cause the film to
OFF -
Pan camera is shut off.
CTR -
SYSTEM switch in RDY Pan camera enabled. Awaiting operate command. FILM switch to RUN; pan camera cycling. Exposure, average of left and right light sensors. Camera set for 55% overlap at NADIR. KS-153A/24 NADIR.
LEFT -
inch: selects 21.4 degree scan centered on
SYSTEM switch in RDY Pan camera enabled. Awaiting operate command. FILM switch to RUN: pan camera cycling. Exposure controlled by left light sensor. Camera set for 55% overlap at 30” below left horizon. KS-153A/24 inch: selects 21.4 degree scan centered on one of the preset depression angles. To prevent interference in coverage by the external fuel tanks the following preset value is recommended: 27” depression angle.
RIGHT -
SYSTEM switch in RDY Pan camera enabled. Awaiting operate command. FILM switch in RUN: pan camera cycling. Exposure controlled by right light sensor. Camera set for 55% overlap at 30” below right horizon. KS-153A/24 inch: selects 21.4 degree scan centered on one of the preset depression angles. To prevent interference in coverage by the external fuel tanks the following preset value is recommended: 31’ depression angle.
Figure 22-3. Controller ProcessorSignal Unit (Sheet3 of 6)
ORIGINAL
22-6
NAVAIR Of-F14AADf
NOMENCLATURE
FUNCTION Note LEFT or RIGHT positions should only be selected for high altitude standoff, or low angle photography. With LEFT or RIGHT selected, blurring of Imagery at nadir will occur at lower altitudes because focus Is set 30 degrees below horizon slant range.
0
IRLS switch
OFF -
Sensor is shut off.
STBY -
SYSTEM switch in RDY Continuous monitor mode (CMM) mode is acttvated. Sensor begins cooldown. (tf cooldown Is not achieved wlthln 17.6 minutes, the IRLS fail light (amber) will Illuminate.) The IR door will remain closed during cooldown. After cooldown Is achieved mlrror spin motor is energlzed and IR door will open unless landing gear handle is down.
NFOVI WFOV
SYSTEM switch In RDY Sensor in ready mode. Sensor selects narrow (or wide) field of view In response to switch posltlon. Sensor Is ready to cycle if cool down has occurred. IR door will open if gear handle is UP Note FILM switch In RUN. IR LS flashes green (one flash/foot of film travei). If cooldown is Incomplete, the IR NR will be Illuminated amber and the sensor will not respond.
012
MAN V/H light l Amber
OFF -
Vg/H from aircraft computer within acceptable
ON-
lllumlnated amber:
Ilmits.
V/H switch In TEST With VEL set at 90 (900 MS) and ALT set at 995 (599 ft), or any equivalent of 1.9 ratio, the thumbwheel circuitry has failed If the light stays on. V/H switch In AUTO. Computer failed or computer fall discrete Is received with or without TARPS pod on aircraft. Manual VgjH being used. Set correct values to Vs/H In thumbwheels. Set V/H switch to MAN. If negative AGL or computed Vg/H = 0, MAN VgfH is being used. Set corrected values of VgfH In thumbwheels.
Figure 22-3. Controller Pmc&sor Signal Unit (Sheet 4 of 6)
22.7
ORIGINAL
NAVAIR
0%F+lAAD-I
NOMENCLATURE
FUNCTION V/H switch in MAN. Manual V/H intentionally selected. Values set in thumbwheels being used. Set correct values in thumbwheels. Note l A TARPS advisory will appear on the Reconnaissance MFD CAWS window when MAN V/H Is selected (figure 24-6). In addition, a TARP1 is generated on the OBC Basic Display and Maintenance Failure Format (figure 24-7). l If negative AGL or Vg/H = 0, and the TARPS pod is not on the aircraft, there is no MAN Vg/H advtsory.
0
DATA IlgM
OFF -
Data received from computer. ON -Data from alrcrafl computer failed (via CPS DATA FAIL discrete). Note A TARPS advisory will appear on the Reconnaissance MFD CAWS window (figure 24-S) when MAN V/H Is selected. In addition, a TARP1 and TARP2 are generated on the OBC Basic Display and Maintenance Format. (Figure 24-7).
014
ALTFTX
015
VELKTXlO thumbwheels
Use to set manual ground speed inputs to pod. Counter range is from 00 to 99, read In multiples of 10 knots.
FILM swttch
MARK -
(momentary position) Allows RIO to mark special interest frame with * in data block.
RUN -
Activates selected sensor when SYSTEM switch is set to RDY.
OFF -
Terminates TARPS sensor operation
@
190
Used to set manual altitude Inputs to pod. Counter range Is from 000 to 999, read In multiples of 100 feet.
Figure 22-3. Controller
ORIGINAL
Processor Signal Unit (Sheet 5 of 6)
22-8
NAVAIR
NOMENCLATURE
017
FUNCTION
V/H selector switch
SYSTEM switch
@
MAN -
Selects manual thumbwheel inputs. (TARPS advisory appears on MFD CAWS figure 24-6. TARP1 appears on OBC Basic Display and Maintenance Failure Format figure 24-7).
AUTO -
Selects aircraft computer value of Motion Compensation WV.
TEST -
(Momentary position) Tests proper functioning of thumbwheels Vs/H circuitry. With a 1.6 ratio set in the thumbwheels, a good test is Indicated by the MAN V/H light extinguishing.
Factor
UNDER - -1 f-stop exposure for doubled S/C film setting.
EXPOSURE selector swkh
69
Of-F’blAAD-1
NORM -
Normal exposure for doubled S/C film setting.
OVER -
+ 1 f-stop for doubled S/C film setting.
OFF -
AIrcraft power denied to TARPS. No sensors can be operated.
ROY -
Aircraft power available at sensor connectors. If respective sensor moved from OFF position, sensor is placed in standby or ready mode.
RESET -
Clears TARPS failure signal. If failure Is other than transient, TARPS advisory remains.
Figure 22-3. Controller ProcessorSignal Unit (Sheet6 of 6) 8. Provide selectionof TARPS air-to-ground
ranging for altitude aboveground level determination.
22.3
TARPS EQUIPMENT BREAKERS
NOMENCLATURE
CIRCUIT
RECON RECON RECON RECON RECON
The main power circuit breakersthat control TARF’S equipmentare in the aft cockpit. FO-8 and FO-9 show their location. The circuit breakersare numbered and labeledas follows:
c%ZT POD POD CONT POD DC PWR NO. 1 POD DC PWR NO. 2
PWR PHA PWR PHS PWR PHC CONT AC CONT DC
281 2D1 2Fl 2G4 6El
Refer to Chapter 2 for an alphanumeric listing of circuit breakers.
NOMENCLATURE
RECON RECON RECON RECON
HTR HTR HTR ECS ECS
CIRCUIT CARD
22.4
lE2 6E2 6E4 6E3
RECONNAISSANCE FORMATS
DISPLAYS
AND
The reconnaissancedisplay symbologyprovidessensor status/ reconnaissancesteering selection (via the MFD RECON DATA statuspage)andthe steeringcues (via HuDivDI displays) to the flightcrew. In addition, 22-9
ORIGINAL
NAVAIR OI-FMAAD-I
the position of the dynamic steeringpoint can be displayed on the horizontal situation display or tactical information display/repeaton the MFD.
c. SUDDS failure.
The MPD RECON DATA statusformat is selected from the MPD MENU2 format (Figure 22-4) by depressingthe RECON pushbutton.
e. CPS data fail (a TARP2 will be shnultaneously stored in OBClfailure history file).
22.4.1 MFD RECON DATA Status Format. This h&D format (Figure 22-S) provides the following functions:
f. Manual Vg/H test fail.
I. Selection of waypoint to be reconnoitered (via increment/decrementpushtile on the upper letI cornerof the MPD RECON DATA statusformat) and steering mode (point-to-point, command course,or mapping) to be employed.
d. Manual VgiH in use.
22.4.2.2 OBClFailure History File. The following faulta will be simuhaneously stored in the OBC and failure history tile (Figure 22-7) when the TARPS advisory is displayedon the h4FD: 1. TARP1 - Reports a general failure (crew alert) from the CPS.
2. Displays TARPS sensor status, advisories (TARPS andNPOV), and camerasolution cuesto crew.
2. TARP2 -Reports a data communication failure betweenthe mission computer andthe CPS. This meansthat the annotationdataand control signals are no longerbeing transmittedto TARPS.
3. Displays target waypoint (referencepoint) data. 4. Provides selectionof TARPS air-to-groundranging for AGL determinationandAGL datadisplay. 22.4.2 Reconnaissance Fault/ Problem Reportha. The reconnaissancesvstem will reoort the TARE% fa&.s/problems via the MPD warning, &ution, and advisory window and storethe faults in the OBC tile and faihue.history file. 22.4.2.1 MFD Wamlng/Cautlon/Advlsory Window. The mission computer will rcpott the following advisorieson the MFD (Figure 22-6): 1. TARPS - Reportsa generalfailure (crew alert) from the CPS.Monitor CPS to determinewhether or not this is a catastrophicfailure (sensor(s)fail). A TARPS advisory neednot scrub the reconnaisssncemission.
22.4.3 Reconnaissance Steering Selection. There are three reconnaissancesteering modes available: PTP, CCRS, and mapping. They are selectedvia the MPD RECON DATA statusformat in either TLN, A/G, or A/A. The steeringtimction is initiated when a TARPS steering mode is selected.Steering cues will always be computed when a steeringmode is selected andwill be displayedon the BUD exceptin A/A with a weaponselected.The VDI will always display steering cues. Before a steeringmode canbe selected,thewaypoint must be selected.In order to do so, the up-down arrow on the h4PD RBCON DATA status format is used to select the desired waypoint number. Next, by hitting ENT, the desired waypoint parameters will be displayed. Waypoint 17 is inhibited for reconnaissance steeringsince this waypoint containsthe position of the DSPT.
A CPZW alert is generatedfrom the CPS when any of the following conditions occur:
22.4.3.1 Point-to-Polnt Steering. PTP is selected when the navigation system is properly operating.Selecting PTP onthe reconnaissanceMFD RBCON DATA statusformat immediately computesthewings-level position for the initial placement of the DSPT and computes a heading to command the pilot to fly to that position.
a. Sensorfailure (includesserial frame cameramount position).
Note
2. NPOV - Reports to the RIO that the BUS is requiredto be placed in the WPOV position.
The wings-level distanceis approximately4 to 8 ran from target(dependson velocity and altitude).
b. ECS failure,
ORIGINAL
22-10
Figure 22-4. MFD MENU2 Format
Figure 22-5. MFD RECON DATA StatusFormat
22-11
ORIGINAL
NAVAIR 01.F14AAD-1
Figure 22-6. TARPS Advisories In addition,the algorithm will put the reconnaissance target designatorover the targeton the HUD. The PTP steering will transition into CCRS for fmal approach over the target. Note PTP remains boxed on the MFD RECON DATA status format. The reconnaissance steeringsymbol and command ground-track line assist the pilot in a wings-level flight over the target.
Note PTP would be selected(insteadof CCRS) if the targetlength is zero.
PTP steeringis deselectedwhenthe aircrafthasflown 0.5 nm past the target or the crew manually deselects PTP on the reconnaissanceMFD RECON DATA status format. At this time, all steeringcuesareremovedfrom the HUD andVJX. In addition, theDSPT (waypoint 17) is removed from the HUD. 22.4.3.2 Command Course Steering. CCRS is selectableif the navigation systemis properly operating and the selectedwaypoint to be reconnoiteredhas a nonzerovalue for targetlength. When the aboveconditions are satisfied, the selectionof CCRS on the h4FD RECON DATA statusformat will box CCRS. Immediately following that, TARPS will compute the DSPT, which is displayedon the HSD format, andthe complete setof steeringcues(thereconnaissancesteeringsymbol, ORIGINAL
CGTL, reconnaissancetargetdesignator,andrecotmaissame commandheadingmarker) to guidethe aircraft to fly over the target at a command crossingangle (stored in the waypoint file). When the aircraft approachesthe wings-levelposition (indicatedwhen the DSPT initiates movement to the target),the CGTL will appearto provide additiona visual cuesfor proper targetcrossing.
CCRS steering is deselectedwhen the aircmfi has flown the target length (storedin the waypoint file) past the target or when the crew manually deselectsCCRS on the MFD RECON DATA statusformat. As in PTP, all steeringcuesare removed from the HUD and VDI. In addition, the DSPT (waypoint 17) is removed from the HSD. 22.4.3.3 Mapping Steering. MAP is selectableunder the following conditions:
22.12
1. Navigation system is properly operating. 2. The selectedwaypoint to be reconnoiteredhas a nonzerovalue for targetlength.
MAINT
CURRENT
FAILURES
Figure 22-7. hfFD OBCiMaintenanceFailure Formats
ORIGINAL
NAVAIR Ql-Pl4AAD.1
3. The two ma* parameters,map offset (separation distance between adjacent map legs) and map lines, arenonzerovalues. Whenthe aboveconditionsaresatisfied,theselection of MAP on the MFD RECON DATA statusformat will box MAP. TARPS will then compute the DSPT (displayedon theHSD) andthecompletesetofsteeringcues (thereconnaissancesteeringsymbol, CGTL, reconnaissancetarget designator,and reconnaissancecommand headingmarker). MAP steeringincludesguidancethroughtherequired 90° to 270” tum maneuvers,using command heading and steeringsymbology, for the necessaryreturnlegs of the reconnaissancemissions.
l
l
Note PTP would be selectedif only condition 1 was valid. Insufficient parameters are available for mapping. CCRS would be selectedif only conditions 1 and 2 were valid.
22.5 RECONNAISSANCE OPERATION
The RIO is primarily responsiblefor the entry of re connaissanceparametersfor waypoints and selection/ operationof TARPS sensors.In addition, the RIO may assist in updating the INS just prior to flying over the target and plotting the target leg (im CCRS and MAP modes)on the HSD. 22.5.1 Reconnaissance Parameter Entry. Recon(Figores 2%11and 22-12)by the RIO via the‘rjEU. T’he maximum numberofwaypoints availablefor recommissame is 19. (Waypoint 17 is reservedfor the dynamic steeringpoint. Waypoints 18 to 20 have dual fimctior~ asreccefdes or ashostile area,FLRP, and datalii) In addition to the standardway-pointentry (targetlatitude, longitude, and altitude), the following reco&ssance parametersare entered:commandcrossingangle,target length, map lines, and map offset (separationdistance betweenadjacentmap legs). The altitude enteredis the targetMSL altitude. The targetlength is enteredvia the DEU. Figure 22-13 shows TARPS DEU entry matrix.
MAP is deselectedat the completion of the last map leg or when manually deselectedby the crew on the MFD RECON DATA statusformat. When MAP is deselected,the following will occur: removal of thereconnaissance overlay symbols (CGTL, reconnaissance command headingmarker,racotissance targetdesignator, and reconnaissancesteering symbol) from the HUDandVDI;removaloftheDSPT~mtheHSD,and MAP LINES REM (on the MFD RECON DATA status format) will be zero.
l
l
22.4.4 HUDNDI Symbology. TheHuDMXsymbology is available when there is a valid selection of reconnaissancesteering.This symbology consistsof the following timctions: 1. Displays recommissancesteeringcuesand sensor statusto the HUD when valid steeringis selected and the a&&l is not in A/A with a weapon selected (Figures22-8 and 22-9). 2.
Displays reconnaissancesteeringcueson the VDI when the VDI is selected(Figure 22-8).
The H’UD/VDI symbols are listed and displayedin Figures 22-8,22-g, and 22-10.
SYSTEM
Note A target altitude of 0 is considered invalid. In the event that the radar altimeter and radaraltitude from APG-71 is not available,thentheAGL altitudewill be the difference between the system altitude and hostile areaaltitude (and not the waypoint altitude). Entries of odd tenths will be rounded to the next lowest even digit.
22.5.1.1 Reconnaissance Parameter Display. Reconnaissanceparametersare displayed on the MFl) RECON WPT DATA 1 (Figure 22-l 1) and MFD RECON WPT DATA 2 formats (Figure 22-12).MFD RI5 CON WPT DATA 1 format containi the reconnaissance parametersfor the fast ten waypoints. This pageis selected by depressingthe R-l pushbuttonon the MFD RECON DATA statosformat. The RECON WPT DATA 2 format containstheremaining tenwaypoint reconnaissance parameters.These parametersare accessedby depressingthe R-2 pushbutton on the MFD RECON DATA statnsformat. The reconnaissanceparametersconsist of command crossingangle,target length, map lines, and map separation distance(map offset).
ORIGINAL
22-14
NAVAIR 0%FWAAD-1
HUD RECON SYAllBOLS HEADING
TRACK
RECON TGT BOX
LINE
STEERING SYMBOL
CAMERA SELECTION (SHOWN WHEN ON AND RUNNING)
k____c
VCN
VDI RECON SYMBOLS
Figure 22-8. HUD/VDI ReconnaissanceSymbology (Sheet1 of 2)
22.15
ORIGINAL
NAVAIR 0%F14AAb1
NOMENCLATURE
I
FUNCTION Indicates the magnetic heading for Recon steering. - Primary steering cue for initial phase of PTP steering. - Indicates intended magnetic Recon Steering Symbol).
heading to DSPT (as commanded
by the
0
Recon Steering Symbol
Provides command velocity vector.
0
Target Designator, Hexagon
Displays target position referenced to the aircraft navigation
@
Command Ground Track Line (CGTL)
Displays the path of the command displacement error.
Camera Selection Legend
Displays the camera operational mode. First letter indicates frame position: V=vertical, F=forward, blank=not selected. Second letter indicates pan position: C=center, Rxight, L=left, or blank=not selected. Third letter indicates IRLS position: N=narrow field of view; W=wide field of view; S=Standby; or blank=not selected. (Note - This is only available on the HUD)
bank information
via azimuth displacement
When weapon is selected in A/A, the Recon Steering Symbol set (which includes the Recon Steering Symbol; GCTL; Recon Target Designator, and Recon Command Heading Marker) will be displayed on the VDI
Figure 22-8. HUDMX ReconnaissanceSymbology (Sheet2 of 2)
22.16
system.
ground track. Indicates cross track
Note
ORIGINAL
from
NAWAlR OW14AAD1
RECON COMMAND HEADING MARKER
PILOT MUST FLY LEFT TO REACH CGTL. PILOT FLlES FLIGHT PATH MARKER TO OVERLAP STEERING SYMBOL. AS CORRECT GROUND TRACK IS REACHED, CGTL WILL CENTER AND AIRCRAFT WILL CROSS TARGET ON COMMAND HEADING.
. - . : 360 : ./. .
----J5.
5L---
< a M G
7.0 0.82 1.8 4.5
lOL-
_
. AIRCRAFT IS APPROACHING TARGET AT COMMAND CROSSING ANGLE
---A,0
-
VCN
(AT)3-F50D-313-1
Figure 22-9. HUD ReconnaissanceDisplay (Command CourseSteering)(Sheet1 of 2)
22-l 7
ORIGINAL
NAVAlR 0%FUAAD-1
.15oQR -. . *. 4---J5 : 2doo: : .I* yo. : 5L--7,0 Q < **ii 0.82 lOL-
G
-
-
--
INITIAL
APPROACH
FOR
-,I0
1.8 4.5 VCN
I
.*.
.
*
I 1 SOOR .-.
I
1 SOOR
.
: 360 : ./. .
5L---
---J5
: 2doo:
<
cl M G
7.0 0.82 1.8 4.5
IOL-
-
-
--
FINAL
APPROACH
-,I0
VCN
(AT)3-F50D-313-2
Figure22-9. HUD Reconnaissance Display(Command CourseSteering)(Sheet2 of 2)
ORIGINAL
22-18
NAVAIR 01.F14AAP1
. .--
DYNAMIC STEERING WAYPOINT
-.-.
_-.
TARGET
POINT 17
TSD REPEAT
Figure 22-10. Dynamic SteeringPoint Display
22-19
N2B7
ORIGINAL
NAVAIR 0%Fl4AAD-1
RECON
SMS
RECON WPT
MEN”2
R-2 DATA
ECU
I
WPTI
Figure 22-11. h4FD RECON WPT DATA 1 Format
Figure 22-12. MFD RECON WPT DATA 2 Format
ORIGINAL
22-20
NAVAIR 0%F14AAD-1
\
I
i
Xx q REPRESENTS 1 OF20 SELECTABLE WAYPOINT ENTRIES
I I I
I
I
I
I
i
--J
I
/
TYPICAL WPT DATA ENTRY DISPLAYS WAYPOINT PARAMETER SELECTED/DATA KNED IN SCRATCH PAD, LAT, LONG, ALT, RNG, BRG, SET, MAPLINE, MAP OFST. TOT LNG. OR CMD CRS OPTION KEY PRESSED.
*ONLY THE RESPECTIVE CHARACTER LEGENDS (S. -, W, N. +, E, OR BLANK) APPLICABLE TO THE PARAMETER SELECTED WILL APPEAR ON THE OPTION DISPLAY LEGEND
------+-------i -
Figure 22-13. DEU ReconnaissanceSelection
22-21
ORIGINAL
NAVAIR Ol-F14AAD-1
22.5.2 In-Flight Entry of Reconnaissance Waypoint Parameters. The RIO may update the waypoint tile at any time when a reconnaissancesteering mode is engaged,without affecting the Currentsteering. In order for the pilot to use the updatedreconnaissance parameters,he must reselectthe steeringmode. 22.5.3 One-Fix Update. Unlessthe aircraft is flying in a ITIDS net, it is recommendedthat one-fix position update be performed just prior to flying over the intendedtargetto minimize miss distance.Refer to Chapter 20 for the proceduresfor one-fix position updates. 22.5.4 Plotting Command Course/Map Target Leg. This optional procedureprovides the flightcmw with additional steeringcue/informationon the HSD. If a tile waypoint is available,the RIO may use this waypoint to mark the end of a target leg by performing the following steps: 1. On the DEU, selectWPT andenterthe designated waypoint for reconnaissance. 2. SelectRNG and enter the target length of the reconnoiteredtarget.
will cycle at its proper rate for velocity/height ratio (V/H) and the IRLS will ruu continuouslyat the proper speeduntil the pilot releasesthe BOMB button. Note The BOMB button will not initiate camera operation with the expandedchaff adapter installed. 22.6.1 Navigation Visual Surface Waypolnt Update. Unless the aircraft is flying in a JTIDS net, it is recommendedthatthe one-fix positionupdatebeperformed just prior to flying over the intended target to minimizemiss distance.Referto one-fixpositionupdate in Chapter20 for INS updateoperations. 22.6.2 Pilot TARPS Steering. TARPS aircraft steeringis displayedon theMI andon the HUD in A/G and A/A (weaponnot selected).The VDI is selectedvia the MPD RECON DATA statusformat. HUD TARPS steering using TARPS symbology (Figure 22-9) is obtainedby selectinga reconnaissance steeringmode (FTP, CCRS, or MAP) on the recomtaissanceMFD RECON DATA statusformat. Note In addition to the steering cues, the reconnaissance target designator will be positioned on the HUDNDI to indicate actual targetposition. (It is recommendedto perform a surface waypoint update to the navigation.system to ensure that the reconnaissance target designator will overlay the expectedtarget site.) Steeringis accomplishedby noting the direction thatthe recommissancesteeringsymbol is displaced from the velocity vector.Banking the aircraft in the samedirection to achieveandmaintain alignment of the two symbols will produce the desired flightpath. If in PTP steering, match aircraft heading with reconnaissance commandheadingmarker.
3. SelectBRG and enterthe command courseof the reconnoiteredtarget. 4. PressSET and enter the number of the available (or free) waypoint. 5. SelectMENU. 6. SelectPLOT. 7. Select DRAW. The DEU will respond “Plot from . . .” Enter waypoint number to which aircraft is flying. When DEU responds“‘Plot to. . .,” enterthe waypoint number usedin step4. 22.5.5 Cycling Sensors. The RIO will put the FILM switch on the CPS in the RUN position when the RANGE-TO-GO goesto zero or transitionsto RANGE REMAINING. The RIO will turn off the selectedsensorswhen RANGE REMAININ G goesto zero. 22.6 PILOT RECONNAISSANCE
OPERATION
A sensoroperating button is provided on the pilot control stick. With the SYSTEM switch on the controller processorsignal unit setto RDY andany or all sensor selector switches in the ready position, the activated sensorcan be cycled by the pilot pressing the BOMB button on the control stick. This is the only TARPS control capability provided to the pilot. Each camera ORIGINAL
At the completionof a PTP, CCRS, or MAP mission, the TARPS symbology will be removed from the HUD/VDI. In addition, the steeringmode will become unboxedontheMFDREcoNDATAstatus format Them is no sequencingof waypoints.To steerto the next waypoin&the d&i waypint numbermust be selected.
22.22
NAVAIR 01.Fl4AAD-1
cation will result if the transition is not complete within 23 seconds.FrequentFWD-VERT switching can cause the mechanical drive to overheatand seize,resulting in a mount fail. The mount will automatically move to vertical when the SYSTEM switch is at RDY and the FUME switch is turned OFF, or if the landing gear handle is moved to DN. The KS-87D canbe reloadedor replacedin approximately 10 minutes and with the aircraft’s enginestuming, if necessary. Figure 22-14 summarizes some specific characteristics and information on the KS-87D serial frame camera. 22.7.3 Panoramic Camera. The KA-99A is a 9inch focal length, U4.0lens panoramiccamerathat provides highquality, medium- to low-altitude imagery. Located in bay 2, the KA-59A offers tit11horizon-tohorizon imagery with 55-percentoverlap up to a maximum of 1.06Vg/H (8 cps).When externalfuel tanks are
installed, the field of view is reducedabout 25” on the right and 17Oon the left. The film cassettewill hold a maximum of 2,000 feet of film. A single exposure measures4.5 X 28 inches,anda datacodeblock appears between each frame. The camera will indicate FALL when the film load is down to approximately 40 exposures,preventingthe film bitter end from going through the high-speeddrive gearsand causingcameradamage. The KA-99A will automatically focus down to approximately 500 feetbutwill revertto a focusaltitudeof 6,000 feet if the TARPS program fails to input andthere is no manual input of V/H t?om the CPS. The RIO may select CTR, LEFT, or RIGHT for the KA-99A on theCPS.When LEFT or RIGHT is selected, the camerausesonly the light sensoronthe sideselected instead of averaging the two as it does when CTR is selected,in addition, the cycle rate and FMC arebased on the slant rangedistancefrom aircrafl to the groundat a 30° depressionangle. To avoid degradedimagery, do not useLEFT or RIGHT settingsbelow 1,500-footaltitude. The KA-99A can be set for air to air (focus on
Focal length Diaphragm
6 inches range
f 2.8 to 6.7
Field of view
41”
Negative Format
4.5 x 4.5 inches
VglH Range+
0.01 to 1.18
Maximum Cycle Rate
6 cycles per second
Effective Shutter Speeds
l/60 to l/3,000
Filters
Yellow, red, or none
Angle of View
Vertical or Forward (16” below horizon)
Hyperfocal Distance**
1339 feet (fixed focus)
tVg/H is listed as a knots per foot of altitude ratio (computed DDS is capable of generating a maximum of 1.42 Vg/H.
x41”
for vertical camera position only). The
**The hyperfocal distance is the distance from the optical center of the lens to the nearest point of acceptable sharp focus, when focused at infinity. The sensor may be effectively used well below the hyperfocal distance, but will render increasingly soft imagery at lower altitudes. The automatic exposure control (AEC) system uses an external light meter. The AEC can be overridden (plus-or-minus one F-stop) on the CPS. The mount requires approximately 16 seconds to move the camera from vertical to forward, or back to vertical. The Cps will display a mount fail light if the transition is not completed within 23 seconds. Optional 3 inch focal length lens available.
Figure 22-14. KS-87D Serial Frame CameraCharacteristics ORIGINAL
22.24
NAVAIR WI-Ff4AAD1
infinity, no FMC, and 1cycle persecond)oo theCIPDU. There is no cockpit indication that air-to-air settings havebeenselected.The KA-99 is favoredby fightcrews on combat missions becauseits horizon-to-horizonlateral coverageallows it to be used with a considerable offset. This capability increasesthe flightcrew’s probability of successfully completing the mission in defendedareaswhere evasive combat maneuveringwill benecessary.Although it is not necessaryfor theaircrafi to be flown wings level when photographinga target withtheKA-99 camera,thelackofmll-rate stabilization dictatesthat an establishedangleof bank be maintained while the targetis within the camera’sFOV.
22.7.4 Long-Range Oblique Photography Camera (KW53AWkh 610-Mm Lens). The KS-153A still picture camera set is a modular, pulse-operated, sequentiaM?amecameradesignedfor oblique or vertical reconnaissancephotographyat medium to high altitude. TIvo configurationsareavailable: 1. Low-altitude, high-speedphotography(80mm focal length tri-lens contiguration) 2. Medium-altitude standoff (610 mm/Zcinch focal
length standoffconfiguration) The 24-&h standoff configurationwill be utilized to replace the KA-93C LOROP sensor and will be mounted in bay 2 of the TARPS pod in lieu of the
Figure 22-15 summarizes some specific characteristics and information on the KA-99A panoramic camera.
U-99.
Focal Length
9 inches
Maximum Aperture
f/4.0
Field Of View
28”
Negative Format
4.5 x 28 inches
Vg/H Range
0.5 to 1.06
Maximum Cycle Rate
8 cycles per second
Effective Shutter Speeds
l/43
Filters
Yellow, red, or clear
Forward Overlap
CTR 55% at NADIR; L/R 55% at 30” horizon
Film Load
2,000 feet (2.5 mil); 800 exposures
xl80
to l/22,600
below side (750 usable)
Note l
The Automatic Exposure Control (AK) system uses internally mounted light meters which average the scanned field. AEC can be overridden (* 1 Fstop) in-flight with the CPS.
l
Sensor does not have roll stabilization, of view and may blur imagery.
thus aircraft rolling will alter angle
l
Maximum listed Vg/H can be exceeded, by incorrect FMC and reduced overlap.
but the imagery will be degraded
Figure 22-15. KA-99A PanoramicCameraCharacteristics 22-25
ORIGINAL
NAVAIR 61.FlUAD-
The KS-153A features true angle corrected FMC acrossthe entirefilm format for any obliqueangle;automatic range focus from 1,000feet to infinity, and selfcontained automatic temperature/pressure focus compensation;shutterpriority automaticexposurecontrol using preflight setting of aerial film speedand aircraft V/H signal; 12- or 56percent preflight-selectable overlap; roll compensation; and data annotation.The 4.5-inch K 9-inch film format provides sequential thnes 10.7Oalong-trackand 21.4” across-backcoverage on 9.5-i& wide film. This image format reduces processingtime and allows direct stereoviewing without cutting the film. The KS-153A can be programmed for any desired depressionangle from horizon to horizon, limited in coverageonly by the aircraft titel tanks (17’ left, 25’ right). Typically, the KS-153A will be.preprogrammed for the following three depression angles: 27’ left oblique, vertical, and 31” right oblique. These are selectedusing the LEFT, CTR, and RIGHT positions on the CPS PAN cameracontrol switch. When selected,a 21.4’ scan will be used, centered about the preset oblique angle.Depressionanglescannotbe changedin flight. Figure 22-16 summarizes some specific characteristics and information on the KS-153A standoff camera. 22.7.5 Photographic Film. Film can be separated by generaltype asfollows: 1. Black and white film: a. Aerial film speed b. Resolution c. Spectral sensitivity 2. Color film: a. Aerial film speed b. Negative/reversal c. Camouflagedetection infrared. Film speedis a value assignedto a specific film to enableyou to determinethe correctexposurein various light conditions. High-speedfilms are requiredfor lowavailable-light missions and for high-speed,low-level missions where very fast shutter speedsare required. High-resolution films provide greaterdetail but require more light. A film’s spectral sensitivity means some ORIGINAL
colorswill reproduceon the film betterthanothercolors. Most of thecommon black andwhite tilms arepanchromatic: sensitiveto all three primary colors (red, green, and blue) that are found in normal daylight. Since the red light doesnot scatterin hazeas much asblue, contrast filters are usedto reducethe blue light. A yellow filter will passthe greenand red light, eliminating the scatteredblue light. A red filter will passonly the red light, eliminating the scatteredblue and also the green (which scatterslessthan theblue). However, the yellow filter will normally require one additional Vstop of exposureandthe dark red filter will normally requiretwo additional t%tops of exposure.Some black and white. films have extrasensitivity to intiared light. This film is most helpful in producing contrastdetail betweensome objectsthat would tend to blend with normal films. Most notable would be the difference between water and vegetation.Color films produce greatershadow detail thanblack andwhite films and showcolor separationin someobjects that would reproduceat the samedensity on black and white film. However, color film has less fme resolution to show very intricate detail in a target. Some color films arereversedin the processing,so that they reproducethe colors in the original scenewithout printing. Thesefilms aretermedreversalor transparency Elm. CDlR color film is usedto show contrastsbetween live vegetation and camouflage material. This greatly increasesthe chancesoflocating difticult targets.Aerial color films requireexpensive,complex processingthat is not generallyavailable at sea. 22.7.6 Infrared Reconnaissance Set. The AADinfmred line scanning detectoris a passive detectorof energyin the far infraredregion.The most striking characteristic of the AADJ is its ability to detect thermal activity, such as the hot-water dischargeof a power plant, the heat from the boiler of a ship, or the thermal shadowleft on a runway or ramp by a departedaircraft. This characteristiccan beused for many purposes,such asdeterminingthe stateofreadinessof shipsin a harbor, judging the tratlic load of an airfield, determining the quantity of P-O-L in storagetanks,determiningwhether buildings areoccupied,and separatingrecentbomb craters fiorn old ones.Sincethe AAD- IR detectorcannot determine the difference betweenthe radiated energy generatedby activity and infmred (IR) energyreflected from the sun, some types of activity cannotbe reliably detectedduring the day. The naturalphenomenonof crossoverwill causeland and water bodies to have identical IR signaturesabout 1 hour after sunriseand 1 hour after sunset.Missions flown to detect land and water contrast (such asbomb damage assessmenton bridges) should avoid these times by at least2 to 3 hours.
NAWAlR Of-FMAAD-I
Focal Length
24 inches/MOmm
Angular Field Of View
21.4 across track, 10.7 along track
Film Format
4.5 x 9.5 inches
Image Frame Format
9.06 inches across track, 4.53 inches along track
Frame overlap (preflight selected)
12% or 56%
Film Capacity
200 feet of 2.5 mil/2.47 feet optional)
Aperture
f/4 to f/16 continuously
Range
Maximum Cycle Rate
4 frames per second
Average
75 Lp/mm, EK 3412
Resolution
frames per foot (500
Shutter Speed Range
l/l50
Film Speed (preflight setting)
AFS 0 to AFS 999
Linear Coverage (200 feet fflm @ 30K. 12 nmi standoff @ 56% overlap)
467 nm
Weight (500 foot cassettes without film)
233 pounds
V/R Rate
0 - 0.196 knots/foot @ 56% 0 - 0.39 knots/foot @ 12% 1.25 knots/foot maximum
Camera Oblique Rotation (24 inch)
+I-
Angle of View (preflight adjustable)
Vertical and left/right (at selected depression angles)
to l/2,000
86”
set
of vertical
Note l
Optional yellow, red, orange, or clear filters.
l
Shutter priority automatic exposure control by preflight film speed setting and aircraft V/H signal, accuracy l/2 f/stop.
l
Sensor will automatically compensate for altitude pressure (sea level to 5,000 feet) and temperature (25 “C to 45 “C stable withln +I- 2°C).
l
Sensor produces time.
a LED matrix array data block wkh a 3 millisecond
Figure 2246. KS-153A Still Picture CameraCharactitics
write
(610-Mm Standoff Configuration)
ORIGINAL
The AAD-~ IR detectoris not an all-weathersensor. It cannot collect imagery through clouds or extremely heavy haze.It is relatively unaffectedby smoke. At low altitudes,the AAD- IR detectoris arelatively goodidentification sensor.At higher altitudes,it may be adequateonly for detection or general identification, dependingon the type of target.A specialgroundtesolution chart is included in Tactical Manual NWP-322.5-F14A/B (NAVAIROl-F14AAA-1T). The AADJ IR detectoris folly roll and roll-rate stabilized thorna O0to 20’ angle of bank in NFOV andO0 to 4Oangle of bank in WPOV. Beyond angle-of-bank hits, a steadybank anglewill not seriouslydegradeIR imagery. This featuremakesit a highly practical sensor for combat maneuveringsituations.Becauseof varying scale at the outer edges, the target should be placed within the center 90” of the format. The AAD- IR detectorcan be.reloadedin apptuximately 10 minutes and with the aircmft enginesturning. Thesystemismadeupofseveralmodularsectionsthat can be replacedrapidly (ii about 15 minutes).Replacement ofthe entim systemmquiresin excessof45 minutes. 22.7.7 Digital Data System. The reconnaissance pod carriesa digital datasystemthat interfaceswith the aircraft inertial navigational system,altimeters,computers,and standardheadingreferencesystemto automatically control and integratethe reconnaissancesystem.
ORIGINAL
Reconnaissancesystem control is accomplishedby the data coryerter, Sensorstabilization signals and operating rate voltages are generatedand routed to the sensors.Stabilization signals are provided from the inertial navigation system or, if it fails, from the SAHRS. Operatingratesignalsare.determinedt?ominertial navigation and radar altimeter inputs. A semiautomatic backup method of generatingVg/H signals is available if the inertial navigation system fails. A titlly manual option is availablethrough the CPS if othercomponents (including the dataconverter)fail. Maximum automatic Vg/H is 1.42knots per foot. IftheaircmftiscarryingaTARPSpod,negativeAGL causesthe MAN Vg/H light on the CPS panel to be lit. This light goesout when AGL becomespositive. Without a TARPS pod on the aircraft, negativeAGL doesnot light the MAN Vg/H light. CADC or computerfailure, however,causesthe light to be lit with or without a pod aboard. Reconnaissancesystem integration is accomplished through digital information &om the data converter, which is translatedinto bii or alphanumericform and addedto presetinformation and real time, which is adjusted prior to flight. Code matrix boxes am printed on all imagery in eitherbinaty or alphanumericform. Integration information includes data,squadmnanddetachment, sortie, sensor identification, system altitude, heading, roll, pitch, latitude, long&ode.,radar altitude, time, inertial navigation system status,relative drift to groundtrack, and Vg/H.
22.28
NAVAIR 0%FMAAD-1
CHAPTER 23
Navigation Command and Control Grid 1. FromtheDEU menupage,selectNAV GRID.
23.1 NAVIGATION CObWAND AND CONTROL GRID
NAV GRID enhances fleetair defense by providing navigationcommandand controlinformationduring combatair patroloperationsandfor fleetdefenseof a specificfixed position.NAV GRID pmvidesaircraft positionrelativeto a geographic referencepoint (grid origin)that is commonto all fleet defenseunits.This eliminates dependence onnavigationaidssuchastacan for positionreferenceduringAAW operations. Combat air patrolsusingNAV GRID canreporttargetcontacts usinggrid coordinates or rangeandbearingrelativeto grid origin(TID only) in additionto normalreports referenced to own-aircraftposition.
2. Usingthe NAV GRID page,enterthe following parameters: a. Latitudeandlongitude&AT, LONG) of grid origin,ormngeandbearing(RNG,BRG)from ownto gridorigin. b. Threataxisheading(HDG) (00to 359’). c. Gridcoverage angle(COWL)(0’ to 180”). d. Numberof gridsecton(SECT)(1 to 6). 23.1 .1.2 DD Data Entry Procedures
23.1.1 NAV GRID Data Entry. Inordertodisplaya
NAV GRID, the RIO must first defmethe following parameters: 1. Grid origin,eitherin latitudeandlongitudecoordinatesor as a rangeandbearingfrom own-air-
l.OntheDD,presstheMFKpushtiletobringupthe MFK menuonthedisplay. 2. OntheMFK menu,selecttheSPLlegendto bring uptheSPLmenuonthedisplay.
Cliltl.
3. SelectNAV GRID legendontheSPLmenu(Figure 23-2).
2. Grid heading(threataxis),in degrees,from 0 to 359O(magnetic).
4. OntheDD keyboard,enter:
3. Grid coverageangle(throatsector,in degrees, from 00to 18OO). Gridheadingwill alwaysdefme thecenterof thetotalgridcoverage. 4. Numberof grid sectors,from 1 to 6. Totalgrid coverageangledividedby thenumberof sectors yieldstheangularcoverageof eachsector. Gridpammeters canbe enteredvia the DEU or the DD computeraddress panel.TheDEUNAV GRJDparametersareusedfor NAV GRID entriesandarethe primaryentry&vice with theDD asthebackup. 23.1.1.1 DEU Data Entry Procedures.
(See
Figure23-l.) 28-I
a. Latitudeandlongitude(LAT, LONG) of grid origin,orrangeandbearing(RNG,BRG)Born owmairc&to gridorigin. b. Azimuthscancoverage(grid coverage angle) (ALT) (0” to 180’). c. Azimuth scancenter (threat axis heading) (HDO) (00to 3590). d. Numberof grid sectors(NBR) (1 to 6).
NAVAIR OI-FWAAD-1
TYPICAL DATA ENTRY NAV QRID SSLE-ATA KEYSDIN.
DISPLAYS
GRID. NA” NA”
GRID.
LAT N81’?5.36
GRID-LONG
IXWR
112.5 NAV QRlD . BRQ
NAV GRID-SECT *ONLY IliE RESPECTIVE CHARACTER LEGENDS (S. -, w, N, +, + OR BLANK) APPUCASLE TO THE PARAWYSR SELECYSD WILL APPEAR ON THE OPTION DISPLAY LEGSND
GRlD - HW
Figure 23-l. DEU NAV GRID Data Enlry -
ORIGINAL
23-2
Typical
NAVAIR 01.F14AAD.1
I Figure. 23-2. DD NAV GRID Data Entry 23.1.2 NAV GRID Displays. NAV GRID can be displayed independentlyon both the TSD and TlD in eithera ground-stabilizedor aircraft-stabilizedformat. 23.1.2.1 Tactical Information Display. The l’lD NAV GRID display is enabled by selecting the A/C STAB position of the TlD mode switch. Selecting this position directly from ATTK resultsin an aircraft-stabilized NAV GRID. Own aimrat?is fixed at the bottom centerof the TID with the top of the display orientedto own-aircraftmagneticheading(Figure 23.3, detail A). A ground-stabilizedNAV GRID display on the TID is achievedby moving the TID MODE switch to GND STAB then to A/C STAB. Gwn aircraft is initially displayed at the center of the TTD. The top of the TID is oriented to magnetic north. Chvn-aircraft and sensor tracks transit the display in the direction of magnetic headingat own-aircraft groundspeedwhile the grid and any waypoint positions remain fixed (Figure 23.3, detail B). The grid itself is representedby grid strobesemanating from grid origin. Grid center is oriented to grid heading(threataxis) with eachsector boundedby two
‘23-3
strobes.Shorttic marks on the strobesrepresent50-mile incrementst?om grid origin, longer tic marks represent lOOmile increments. A maximum of sevenrangetics (350 miles) is displayed. When the grid contains six sectors,no rangetics are displayedon the centerstrobe. Selectablerangescalesare25,50,100,200, and 400 in either stabilized mode. A TID offset can be utilized to repositionown-aircratl anywhereon the display. The grid is repositionedaccordingly and may only be partially displayed(Figure 23-3, details B and C). Offset positioning is canceledby momentarily cycling out of the selectedSTAB mode. Tactical use of the NAV GRID often makesit desk able to referencetracks,waypoints, or own-aircraft position asa rangeandbearingfrom grid origin ratherthan Tom own-aircraft. This is accomplishedby RIO seleetion ofNAV GFUD on the DD (SPL category)as shown inFigure 23.2. 23.1.2.2 Tactical Situation Display. The TSD format can be selectedon any MFD. NAV GRID can be selectedfor display via the GRID pushtile on the TSD DCL format (Figure 23.4). Lie the TID, the TSD can
ORIGINAL
NAVAIR 01.F14AALb1
AIRCRAFT STABlUZEO NAVGRlO NOT BOXED ON DO.
(AT)2-F50D-274-O
Figure 23-3. TlD NAV GRID Displays
ORIGINAL
23-4
NAVAIR 01.Fl4AAD1
Figure 234. TSD NAV GRID Display
display the NAV GRID in either ground- or aircraftstabilii formats as selectedby theGSTAB or ASTAB pushtiles.The ASTAB display hasown-aircraft position fixed on the lower third of the display with the top of the display rapresenting own-aircraft magnetic heading. The GSTAB display initializes with own-aircraft at the centerof the display. The top of the display represents magnetic north. Own-aimaft and sensortracks transit thedisplaybasedon magneticheadingandgroundspeed while the grid andany waypoint positionsremain fixed.
The grid itself is displayedas on the TlD, with up to six sectorsdefinedby strobesemanating&om grid origin andcenteredon grid beading(threataxis). Shortand long tic marks representSO-and 100~mileincrements, respectively.Any TSD rangescale(25,50,100,200, or 400) is selectable.Future softwarewill include an OFFSET andEXF’AND capability for all TSD formats.Unlike the TKD, bearing and range data hooked tracks or waypoints cannotbe referencedto grid origin.
23-5 (Reverse Blank)
ORIGINAL
NAVAIR Ol-Fl4IuP1
CHAPTER 24
LANTIRN Targeting System Reserved.
241 (Reverse Blank).
ORIGINAL
PART IX
Flightcrew
Coordination
Chapter37 - Flightmw Coordination Chapter 38 - .%imaft Self-Test
91 (ReverseBlanhj
ORIGINAL
NAVAIR
CHAPTER
Flightcrew 37.1
tem. The RIO will normally be responsiblefor all communicationsexcept in tactical situations.
INTRODUCTION
PILOT
37
Coordination
The dutiesof the pilot/RIO team arenecessarilyintegratedand contribute to the performanceof the other. Successfulcrew interactioncanprovidecockpit synergy that significantly improves mission success.However, a pilot/RIO team that doesnot interact successfullycan be a major detrimentto mission success,In this chapter, specificresponsibilitiesaredelineatedfor eachphaseof flight. Specific mission flightcrew responsibilities are also delineated. 37.2
0%F14AAD-1
AND RIO RESPONSIBILITIES
Aircrew Coordination. Aircrew coordination is the flightcrew’s use and integration of all available skills andresourcesin orderto collectively achieveand maintain crew efficiency, situation awareness,and missioneffectiveness.Integrationof the flightcrew’s activities will provide error protection through human redundancy.Crew coordination is one of the most significant factorstoward mission success. 37.2.1
Pilot Responsibilities. The pilot is the aircraft commanderand responsiblefor the safe and orderly flight of theaircraft andthewell-being of thecrew. In the absenceof direct orders from higher authority cognizant of the mission, responsibility for starting or continuing a mission with respectto the weather,mission environment,or any other condition affecting the safetyof the aircraft restswith the pilot.
Mission Commander. The mission commander may be either a pilot or a RIO. He shall be qualified in all phasesof the assignedmission and be designatedby the unit commanding officer. When the assignedmission commander is a RIO, he shall be responsiblefor all phasesof the assignedmission except thoseaspectsof safety of flight that are directly related to thephysical control of the aircraft. The mission commandershall direct acoordinatedplan ofaction andshall be responsiblefor the effective executionof that plan. 37.2.4
37.2.5 37.2.5.1
Specific Flight
Responsibilities Planning
Pilot. The pilot is responsible for the preparationof required charts,flight logs, and navigation computations including fuel planning, checking weather and NOTAMS, and for filing required flight plans.
37.2.5.1.1
37.2.2
37.2.3
Radar
Intercept
Officer
37.2.5.1.2 RIO. The RIO is responsible for the preparationof charts, flight logs, navigation computations including fuel planning, checking NOTAMs, obtaining weather for tiling purposes, and completing requiredflight plans. Briefing. Accomplish those tasks delins atedin the precedingparagraph.
37.2.5.2
Responsibilities.
The RIO constitutesan extensionofthe pilot’s observation facilities. By intercommunication,the RIO should anticipateratherthan await developmentsin flight. The RIO will be a safetybackupfor the pilot. In this capacity, the RIO shall offer constructivecomments and recommendations,as necessary,throughoutthe mission in order to maintain the safest and most effective flight environment.The RIO will be responsiblefor the reading of the checklistsutilizing a challengeand reply sys-
37-l
Mission Commander. The mission commander,pilot or RIO, is responsibleforbrietingall crewmemberson all aspectsofthe mission to be flown. Refer to Chapter6 of this manual for specific items.
37.2.5.2.1
37.2.5.3
Preflight
Pllot. The pilot is responsiblefor accepting andpretlighting the assignedaircraft and coordinating preflight operationalchecksin accordancewith this
37.2.5.3.1
ORIGINAL
NAVAIR Ol-Fl4AAD-1 manual and appropriatepreflight checks contained in NAVAIROl-F14AAD-lB.
rolling or catapulting. The pilot will report “Rolling” or “Saluting,” as appropriate,to the RIO.
37.2.5.3.2 RIO. The RIO will be capableof, andproficient in, performing a complete aircraft preflight, including armament,in accordancewith this manual and appropriatepreflight checklists containedin NAVAIR Ol-Fl4A4D-1B.
37.2.5.7.2 RIO. The RIO will execute Pretakeoff ChecklistsprescribedinNAVAIROl-Fl4AAD-1B; will initiate, using the challenge-reply method, the posted Takeoff Checklist in the aircra& and, at completion of the Takeoff Checklist, RIO informs thepilot “Ready for takeoff.”
37.2.5.4 Prestart 37.2.5.6 Takeoff and Departure 37.2.5.4.1 Pilot. The pilot will execute prestart checks prescribed in NAVAIR 01-F14AAD-1B and, when external power is applied and checks requiring external power are completed, will inform the RIO “Prestart checks completed.Ready to start.” 37.2.5.4.2 RIO. The RIO will execute prestart checks prescribed in NAVAIR 01-F14AAD-IB and, when external power is applied, will inform the pilot “Prestart checks completed.” 37.2.5.5 Starting 37.2.5.5.1 Pilot. The pilot will start enginesas prescribed in paragraph7.4.3 and will keep the RIO informed of any unusualoccurrences. 37.2.5.5.2 RIO. The RIO will remain alert for any emergencysignal from the groundcrewandwill inform the pilot if such signalsare observed.
37.2.5.8.2 RIO. Where departuresaremade in actual instrumentconditions,the RIO will monitorthe published clearancedepartureproceduresand inform the pilot ofany deviation from theprescribedflightpath. The RIO will copy all clearancesreceived and at all times be preparedto provide the pilot with clearanceinformation of navigational information derived from these instruments.Built-in-test checkswill not beconductedduring instrumentclimbouts. 37.2.5.9 In Flight (General)
37.2.5.6 Poststart 37.2.5.6.1 Pilot. At completion of the emergency generatorcheck, the pilot will inform the RIO “Emergency generatorcheck complete.” The pilot will complete all poststart checks prescribed in NAVAIR 01-F14AAD-1B and coordinate with the RIO the initiation of OBC. 37.2.5.6.2 RIO. At completion of the emergency generator check, the RIO will perform the poststart checksprescribedin NAVAIR Ol-F14AAD-1B. When OBC is completed and the inertial navigation system aligned, the RIO informs the pilot, “Ready to taxi.” 37.2.5.7 Pretakeoff 37.2.5.7.1 Pilot. The pilot will execute Pretakeoff, Instrument, and Takeoff Checklists prescribed in NAVAIR 01-F14AAD-1B and as postedin the aircraft. The pilot will reportto the RIO Takeoff Checklist items, using the challenge-replymethod.The pilot will receive the “Ready for take&” reportfrom the RIO andadvise him of type and configuration takeoff planned,prior to ORIGINAL
37.2.5.8.1 Pilot. The pilot shall ensurethat the intercom remainsin HOT MIKE for normal flight operations and will report “Gear up” and “Flaps up” to the RIO insofar as safetypermits. The RIO should be advisedof any unusualoccurrencesduring takeoff that may affect safetyof flight. ‘Ihe pilot or RIO will request,copy, and acknowledgeall clearances.
37.2
37.2.5.9.1 Pilot. Thepilotwillinform theRIOofany unusualoccurrencesand will ensurethat the aircraft is operatedwithin prescribedoperating limitations at all times. The pilot or RIO will normally request,copy,and acknowledgeall clearances. 37.2.5.9.2 RIO. The RIO will assistthe pilot in normal or emergencysituations,including navigation,communication,andvisual lookout. The RIO will inform the pilot of the weaponsystem status.During ascentor descent,the RIO will inform the pilot 1,000 feet prior to the intendedlevel-off altitude. 37.2.5.10 Intercept 37.2.5.10.1 Pilot. The pilot will maneuveror coordinate aircraft maneuverswith, or as directed by, the RIO, observingnormal operatinglimitations. The pilot will inform the RIO of weapons status, weapons selectedandarmed,andwhen thetargetis sightedvisually. The pilot will monitor aircraft position from initial vector throughbreakawayby pigeons information or navigational display
NAVAIR RIO. The RIO will handleall communications from initial vector through breakaway,excluding missile-away transmissions;provide the pilot with descriptive commentary, including weapon status and targetaspect,if available; anddirect andcoordinateaircraft maneuverswith the pilot, asnecessary,to complete the intercept.
Ol-Fl4AAD-1
37.2.5.10.2
37.2.5.13
37.2.5.11
Pilot. The pilot will inform the RIO of any unusual occurrenceson the landing roll or arrestment. The pilot will report flap and wing position to the RIO when clear of the runway or landing areaand will report when the wing is actuated.The pilot will inform the RIO when shutting down engines.The pilot will conduct a postflight inspectionof the aircraft.
Instrument
Approaches
Pilot. The pilot is responsible for the safe control of the aircraft, the decision to commence theapproachwith the existingweather,andtheselection of the type of approachto be made. The pilot, before commencingany penetration,will report to the RIO the completion of eachitem of the Instrument Checklist. In addition, the pilot will challenge the RIO Instrument PenetrationChecklist, as to approachplate availability and correctedaltimeter setting. 37.2.5.11.1
Postflight
37.2.5.13.1
RIO. The RIO will challengethepilot on flap position ifthe reportis not received.Wheninformed by the pilot thatthe wing hasbeenactuated,theRIO will visually verify wing and spoiler positioning. The RIO will completethe built-in-test checksremainingandsecurethat rearcockpit for shutdown,thennotify the pilot “Ready for shutdown.” The RIO will assistthe pilot in conductinga postflight inspectionof the aircraft. 37.2.5.13.2
Note
The RIO will monitor aircraft instrumentsand appropriateapproachplate during holding, penetration,and approachand shall be ready to providethepilot with any requiredinformation. He shall beparticularly alertto advisethepilot ofdeviations from the courseof minimum altitudes prescribedon the approachplate.Built-in-test checkswill not be conducted in actualinstrumentconditions.The RIO will inform the pilot of the status of the radar and will do nothing to causethe display to be lost. During penetrationsand/or descents(VFR or IFR), the RIO will report to the pilot the aircraft descentthrough each 5,000 feet of altitude above 5,000 feet and each 1,000 feet of altitude loss below 5,000feet,until, on reachingthe desiredaltitude, the RIO will report when altitude error exceeds 10 percentof actual altitude or +300 feet. 37.2.5.11.2
37.2.5.12
RIO.
Landing
37.2.5.12.1 Pilot. The pilot will utilize the Landing checklist and will report each item to the RIO prior to reporting“Gear down, hook down” to the final controller, tower, or Pri-Fly. The pilot will receivea “Ready to land” report from the RIO.
The RIO will vacatetheaircraft first andafter the aircraf?is on the ground, flight deck, or hangar deck, the pilot will exit. This is particularly important during shipboard operations. Debriefing. The pilot and RIO will complete the yellow sheetandall requireddebriefingforms.
37.2.5.14
Maintenance. The pilot and RIO will complete the yellow sheet,BER card, and all other requiredmaintenancedebrief forms. The crew will ensure a complete debrief is provided for all maintenance discrepancies. 37.2.5.14.1
37.2.5.14.2 Mission. The mission commanderwill be responsiblefor conducting a thorough mission debrief to include the accomplishment of mission goals, adherence to SOPIROEMATOPS, intercockpit and flight communication, and conflict resolution. 37.3
RIO. In the landing pattern, the pilot shallreadand theRIO acknowledgethe postedLanding Checklist.The RIO shall visually checktheflap position and landing gearposition by looking through the opening on the 1eAsideof the instrumentpanel.The RIO will report “Ready to land” to the pilot. Built-in-test checks shall not be conductedwhile in the landing pattern. 37.2.5.12.2
SPECIAL
CONSIDERATIONS
37.3.1 Functional Checkflights. The pilot and RIO shall brief with maintenanceto determinethe discrepanciesthat were correctedandthe intentionsof the functional checkflight. Pilot. The pilot is responsiblefor adherence to all FCF procedures as described in NAVAIR OlF14AAD-IF.
37.3.1 .l
37.3.1.2 RIO. The RIO is responsiblefor monitoring the FCF proceduresandthe completion of specific tasking outlined in NAVAIR 01-F14AAD-IF.
37-3
ORIGINAL
NAVAIR 0%Fl4AAD-1 37.3.2 Formation Flights 37.3.2.1 Formation Leader. A pilot will be designatedthe formation leader.The statusof eachmember of the formation shall be briefed andclearly understood priorto takeoff.As a minimum, formationbrief itemsshall include loss of sight, lost communication, inadvertent IMC, and formation integrity. The formation leader is responsiblefor the safe and orderly conductof the formation. This includesvisual lookout, the separationbetweenaircraft within theformation andduring transition periods,breakups,and rendezvous. 37.3.2.2 Pilot. The pilot is responsiblefor the safe separation of his aircraft and the other aircraft in the formation. Lead changeswill include a positive acknowledgment by both pilots. 37.3.2.3 RIO. The RIO will monitor formation separation and closure during joinup and advise the pilot when an unsafesituation exists. 37.3.3 Training 37.3.3.1 Instructors. All instructorswill be designatedin formal directivesby unit commandingofficers. In FRS the instructorwill be chargedwith authority and responsibility to provide proper diction to pilot and RIO replacementsto ensuresafeandsuccessfulcompletion of each training mission. On training missions where a pilot under instructionis the pilot in command, the instructor’s guidanceshall be advisory in natureand under no circumstanceshall the pilot in command be relieved of his authority and responsibility as aircraft commander.Termination of the training or evaluation portionsofthe flight forreasonsofsafety, unsatisfactory performance,or material discrepancyshall be the instructor’sprerogative. 37.3.4 SAR. The mission commander or senior member of the flight, shouldthe mission commanderbe unavailable, shall assumeresponsibility for the rescue operationuntil relievedon sceneor me1dictatesa return to base.The primary responsibilityof the on-scenecom-
ORIGINAL
374
manderwill be communication of the downed crew’s position and condition to potential rescue aircraft or vessels.Additionally, the on-scenecommanderwill ensure searchcoordination, trafftc control on the scene, and provide communication with the downed crews if feasible. 37.4 PROCEDURES, TECHNIQUES, AND CHECKLISTS 37.4.1 General. Even though some of the procedures, techniques,and checklists are specifically designed for the pilot and RIO, the entire contentsof the flight manualandpocket checklist shouldbe thoroughly read, understood,discussed,and agreedupon collectively by the pilot-RIO team. Discrepanciesin procedures or the need for additional proceduresshould be broughtto theattentionof theNATOPS evaluatorand/or instructor.Most of the procedures(individual andcoordinated) are covered in this manual and are grouped under flight phasesand/or categories.Aircraft systems descriptions,with their individual operatingcriteria,are covered in Chapter 2. Classified systems descriptions and procedures,and some limitations information, are covered in the classified supplement (NAVAIR OlF14AAD-IA). The pocket checklist (NAVAIR OlF14AAD-1B) containsthepilot andRIO checklist items for preflight, prestart, start, poststart, takeoff, built-in test, instrumentand descent,and postflight procedures. Improper crew coordination is usually an attributable factor to improper emergencyprocedures. 37.4.2 Pilot. The pilot should relate to the RIO all indicationsrelevantto the ongoingemergency.The pilot should assessthe situation, set emergencypriority, and direct the RIO to effectively assisthim. 37.4.3 RIO. The RIO shouldmonitor all critical flight parametersand read all applicablechecklists in a challengeand reply system. He should assistin navigation, communication, and coordinate with outside agencies andaircraft, but not to the detriment of the resolutionof the emergency.
NAVAIR Ql-Fl4AAD-I
CHAPTER 38
Aircraft Self-Test 30.1 AIRCRAFT SELF-TEST OVERVIEW
Thesefeaturesarc availablein all systemmodesandarc usedfor troubleshootingandmaintenancepurposes.
Aircraft self-test allows testing of the operational statusof all major avionics and radar subsystemsand display of the results.This capability is also referredto as OBC throughoutthis section.Figure 38-1 identities the major components associatedwith this function. Most of the statusinformation is derived from BIT implementedwithin theavionics andradarsubsystems.All operationalaspectsof aircraft self-test are fully supportedby the MCS if one of the mission computershas failed. There are two categoriesof test: (1) tests that are performed by the system automatically, (2) those that require initiation by the flightctew. Testing should be initiated by the flightcrew aspart of thenormal preflight checkout to obtain the overall status of each system. Figure 38-2is a summarydescriptionfor thevarioustest types, including origin and purpose.Avionics testingis controlled by the pilot and the RIO primarily through the MFDs and cockpit control panels.Radar testing is controlledby theRIO via theDD andTID. The majority of the displayedinformation is the result of eachsubsystem performing a particular mode of BIT or the MCS performing databus or softwarecontiguration tests.On an automatic(i.e., periodically by the MCS) basis,suhsystemsare polled by the MCS in order to determine their operationalstatus.Operationalstatusis displayed at a subsystemandWR4 level througha seriesof OBC formatson the MFDs. Both currentandhistorical equipment status is displayable. Warning/caution/advisory cuesare displayed on the MFDs for critical equipment failures and overtemperatoreconditions. Details of radar subsystemfailures areavailableonly on the DD and TID. Avionics andradarfailure acronymsaredisplayed on the TID during normal tactical operation. Aircraft self-testalso allows examinationof memory contentsfor WRAs that supporta CSS capability. CSS is controlledwith the DEU and tberesultsaredisplayed on the MFDs. The radar subsystemprovides a similar but limited capability that is controlled via the DD. 38-l
38.2 MASTER TEST PANEL CHECKS Master test checks am initiated by the pilot through the MASTER TEST panel (Figure 38-3) on the right outboard console. These tests check the operational statusof specificaircrafi systemsbasic to safetyof flight andmission success.The OBC, WG SWP, FLT GRIP, andFLT GR DN positions areusedon the deckonly and are prevented from inadvertent use in flight by the weight-on-wheelssafetyswitches.The remaining tests, except for emergency generator,which also requires combined hydraulic pressure,can be done whenever electricalpowerandcoolingairare available.Fordetails of specific aircraft systemstests,refer to the applicable systemdescription.
During groundoperations,oncethe OBC position is selected,do not deselectOBC until the program has completedthe entire cycle. When the disable signal, which inhibits throttle movement,is removed,the APC will run throughits BIT and advancethe throttles to greaterthan 80 percent.
l
l
Note Before startingthe test,depressthe MASTER RESET button on the left vertical consoleto turn off any cautionor advisory lights associated with the air data computer. In LTS, the MASTER CAUTION light will flash unless there is a circuit failure within the caution advisory indicator, in which casethe light will be steady.
ORIGINAL
NAVAIR Of-Fl4AAD-I
A”lONlcs CONTROLS AND STATUS DWLAYS
WILOTS CENTER & RIGHT. RIO, MASTER CAVTION PANEL
-I AVlONlCS
I I
/
/’
, /
/
/
/
,
/
/
,
/
/
/
/
/
r------
RADAR CONTROLS AND STATUS DISPLAYS
Figure 38-1. On-Board Checkout ORIGINAL
38-2
NAVAIR Ol-Fl4AAD-1 NAME
ORIGINATOR
Master Test Checks Onboard Checkout Sequences Continuous
(OBC)
Monitor
Unit/Subsystem
Data Bus Tests
Self-test
PURPOSE
PILOT
Selectable tests of instruments, fuel system, warning system (lights), wingsweep, AOA
PILOT and RIO
Tests various avionics, flight controls, actuators, AICS, and computers
AUTOMATIC
Monitors majority of avionics and radar functions for in-flight or on-deck failures. Typically performed every 2 seconds
PILOT and RIO
Independent testing of individual, functionally related subsystems
AUTOMATIC
Tests each data bus channel for each bussed subsystem
AUTOMATIC
Tests the compatibility program loads
or groups of
of subsystem
software
Figure 38-2. Test Types 38.2.1 MASTER TEST Switch Operation. The mastertest check is madeby pulling the knob up, rotating to tbe desiredposition, and depressingit. After the test is completed,the MASTER TEST switch must be pulled up and deselectedto deenergizethe system.
Electrical power for the mastertestpanelcomesBorn the left main dc bus throughthe MASTER TEST circuit breaker(9H4) on the DC MAIN circuit breakerpanel. When operatingon aircraft poweror whenexternalelectrical poweris connectedto the aircra-dft, cooling air must be supplied to all avionic equipment before a test is initiated. 38.3 ON-BOARD CHECKOUT
Cycling the CID circuit breakers(3E7,4El, and4E2) with the MASTER TEST switch in or above the OBC position will cause the AFCS BIT sequenceto initiate. AFCS BIT sequencetests and deflects various aircmfi control surfaces,which could be a hazardto unsuspectinggroundpersonnel: System status and test results are indicated on the cockpit instruments: GO-NO GO lights on the master test panel;warning, caution, and advisory lights in both cockpits; and displays including MFDs and TlD The GO-NO GG indicator lights on the MASTER TEST panel will illuminate only in LTS, FIRE DET/EXT, EMERG GEN, andFLT GR Up. In theLTS testposition,only the bulbs in the GO-NO GO indicators are.checked.In EMERG GEN, FIRE DET/EXT, and FLT GR UP, a GO light indicatesa valid test anda NO GG light indicates an unsatisfactorytest. The STICK SW utilizes only the GO light; therefore,a valid test in STICK SW is indicatedby a GO light but the lack of a light indicatesan unsatisfactorytest.
38-3
OBC checksthe opemtional statusof the equipment listedinFigme.384.ItprovidesfaultisolationtotheWRA level without the use of groundsupportequipment.The systemautomaticallymonitorsall equipmentpmviding an initisl, periodic,or operator-initiatedmodeofBlT in order to detectfailures or command subsystemsinto test as a resultof selectionsmadewith theMFD OBC displayformats.When a test is completed the testedequipmentrespondswith eithera GO (when all testshavepassed)or NO GO (whenat leastonetesthasfailed) for eachWRA testedDetectedfailuresareprocessedbytheMCSinorder to maintain currentstatusanda historicalrecordof failure information.Test statusis alsousedto controlthe operation of the systemandis displayableon the MFDs. OBC formats presentfailure acronymsfor failed equipments only (i.e., the absenceof a failure acronym implies that the equipment is operational). A historical record of failures is maintained during the courseof a flight and is displayableat any time on the FHF format including during postfiight operationsby maintenancepersonnel. The historical record of failures should be cleared (erasedBorn the FHF) prior to a mission by the flightcrew so that only failures relevant to the current mission are retained by the system. ORIGINAL
NAVAIR
Of-Fl4AAD-1
FUNCTION
NOMENCLATURE 0
MASTER TEST switch
)FF -
Dlsabies test functions.
TS -
Turns on caution, warning, and advisory lights; emergency stores jettison button; GO and NO GO lights; landing gear and hook transition lights; approach indexer; FIRE warning lights.
:LRE DEf/EXl
-
Land R FIRE warning lights Illuminate. If a circuit problem exists, the corresponding FIRE light will not iliumlnate. Simultaneously, the fire extinguishing system initiates a self-test. if tests pass, the GO light illuminates. If the NO-GO light illuminates or if both or neither GO or NO-GO lights illuminate, a failure exists in the system.
Figure 38-3. Master Test Panel (Sheet 1 of 2)
ORIGINAL
38-4
NAVAIR WF14AAD1
Note
INSi -
0 The ID second audio alarm goes on. l
If EIG fails self test, the BIT se ment to the left of the E&legend remains illuminated.
0
GO-NO
GO lights
Note
Decreases the RIO’s fuel counter to 2000 pounds, illuminates the FUEL LOW, MASTER CAUTION, and BINGO (if the pilot bingo counter set >2000 pounds) lights. Displays the following pilot cockpit indications. RPM EGT
.
FF FUEL CITY WING SWEEP AOA BINGO FEED/WING/EXT FUEL QTY ,
.
_. 96% 960°C (initiates engine over temperature alarm) 10,500 pounds per hour 2,000~ 200 pounds (both oockpits) 45” * 2.5” 18i.5” units ON (l Bingo set > 2,000) 2,000 pounds
OBC -
Enables preflight testing when selected prior to selecting a subsystem for test via the MFDs. Failure acronyms are displayed on the MFDs.
EMERG GEN -
Activates automatic transfer feature of generator and checks tie contaotors. GO lights indicate satisfactory check. If the NO GO light remains illuminated, a maffunction is indicated.
WG SWP -
Air data computer simulates that circuit to the wing sweep system (wings do not move). Requires wings in oversweep, and wing sweep button in AUTO.
FLT GR DN -
Initiates ground check of auto throttle interlocks. Requires throttles in AUTO throttle region and enables ground selection of AUTO throttles. Engines will respond to stick movement and nozzles remain closed.
FLT GR UP -
Permits checking external fuel tank pressurization. GO light indicates required pressure. WING/EXT TRANS switch must be in AUTO and DUMP switch set to OFF.
D/L RAD -
Tests the data link convener. Test results are available on the MFDs. Inhibits tactical control messages during test sequence. Symbology displayed is determined by the display mode selected.
STICK SW -
Checks left and right spoiler symmetry switches and 1 -inch stick switches (left and right).
GO-
Indicates valid test.
NOGO-
Indicates unsatisfactory
test.
Functional only in LTS, FIRE DET/EXT, IN~T, EMERG BEN, FLT GR UP and STICK SW.
Figure 38-3. Master Test Panel (Sheet2 of 2)
38-s
ORIGINAL
NAVAIR
0%F14AAD-I
SUBSYSTEM/DESIGNATION ADAC CP - 1770
INITIAL 30.
COMMANDED 20.
CONTINUOUS MONITOR 2.
COCKPIT N/A
AFCS AN/ASW-43
N/A
53.
2.
N/A
AICR C-8684
N/A
63.
2.
N/A
AILR C-8684
N/A
63.
2.
N/A
N/A
03.
2.
03.
ASPJ AN/AL&165
N/A
110.
30.
110.
SAG ANlAPN - 154
N/A
3.
N/A
N/A
SSF
N/A
3.
2.
N/A
CADC CP-1035
N/A
4.
2.
N/A
CIU
2.
2.
10.
N/A
DEU
N/A
20.
2.
N/A
DPI
N/A
40.
5.
N/A
DP2
N/A
40.
5.
N/A
DLS ANlASW-27C
N/A
15.
(Note 2)
DSS
N/A
(Note 3)
N/A 1.
EMSPl
N/A
N/A
2.
N/A
EMSP2
N/A
N/A
2.
N/A
IFS
N/A
3.
2.
N/A
IFI ANIAPX-76
N/A
2.
N/A
N/A
IFX ANlAPX- 100
N/A
2.
2.
N/A
INSANIASN-130
N/A
55. Mins
1.
N/A
IRSTS
N/A
30.
2.
N/A
JTIDS ANIURC-107
10.
15.
12.
N/A
MCI ANIAYK-14
.2
12.
10.
N/A
MC2 ANIAYK-14
.2
12.
10.
N/A
MFA LEFT
N/A
2.
N/A
N/A
MFA RIGHT
N/A
2.
N/A
N/A
RADAR ANIAPG-71 RALT ANIAPN -194
210.
150.
2.
N/A
3.
N/A
N/A (Note 4)
RFPANIARC-182
N/A
N/A
2.
N/A
RFR AN/ARC- 182 RWR ANIALR-67
N/A
N/A
N/A
N/A
2. 1.
N/A (Note 5)
SAHRS AN/USN-2
16.
5.
5.
N/A
SDIS
2.
6.
2.
N/A
SMS ANIAYQ-15 TACAN ANIARN-118 TARPS
2.
10.
1.
N/A
(Note 6)
(Note 6)
(Note 6)
(Note 6)
N/A
N/A
2.
N/A
APC AN/ASW-
105
or ANIURC-107
Figure 38-4. SubsystemBIT Mode Test Times (Sheet I of 2) ORIGINAL
38-6
N/A
NAVAIR
SUBSYSTEM/DESIGNATION
INITIAL
Notes: 1. All test times are in seconds unless other&e
COMMANDED
CONTINUOUS MONITOR
01.F14AAD-1
COCKPIT
noted.
2. This test is the Data Link BAD (D/L BAD) test initiated by the RIO or Pilot. This test remains in effect for as long as the MASTER TEST panel switch is in D/L BAD. Refer to Operator Initiated BIT section for more information. 3. DSS Commanded BIT times of 5.0 and 65.0 seconds correspond to the Data Storage Set (DSS) test, and the DSS test including the Bulk Memory Checksum test, respectively. 4. This test remains in effect for as long as the PUSH TO TEST knob on the RADAR ALTITUDE indicator is held depressed. 5. This test remains in effect for as long as the TEST switch on the RADAR WARNING RCVFI panel is held to BIT. Once released, the test completes in approximately 13 seconds. 3. JTIDS initial BIT will cause a 4-second loss of tacan lock. Atacan self-test OBC. See Chapter 20 for additional details.
is performed
during JTIDS
Figure 384. SubsystemBIT. Mode Test Ties (Sheet2 of 2) Currentfailure information is also displayed on the TlD in the OBCCM window (refer to paragraph38.5), and on the MFDs in the warning/caution/advisory window for certain equipment failures. Built-In-Test Description. Several types ofBITaresupportedbyeachsubsystemandareperformed internally.Thesemodesinclude:power-up(or initial), pe riodic (continwus or automatic), and commanded(includesbothMFD andcockpit controlpanelinitiated)BIT. Referto Figure38-4 for approximateBIT times for each subsystem.Regardlessof the BIT type, detectedfailures areretainedfor theaffectedsubsystemby the MCS. Each modeofBITcontainsaseriesofteststhatdifferticmmode to mode.Becauseof thesedifferences,a priority for each subsystemdetermineswhena subsystemfailureno longer exists.Othertestsperformedby theMCS includedata-bus channeltests,anda test to determinethe compatibility of eachsubsystem’s&ware loadwith the MCS OFR 38.3.1
BIT Modes. The following is a brief description of each BIT mode. Refer to Figure 384 for subsystemapplicability.
38.3.1.1
Initial BIT is performedby eachsubsystemupon the applicationof electricalpower.This modeof BIT is only performedafterpowerhasbeenoff for a specificlengthof time (i.e.,cold start)and thenm&red. For shorterpower intenuptions(i.e.,warm start),this modeof BlT is not performed TheMCS monitomeachsubsystemfor a response (GOor NO GO) at the completionof this mode.
38-7
Continwus-monitorBIT is performedby eachsubsystem ons continwus andnoninterfetingbasis(i.e.,subsystem continuesto perform normal operationalmode as well). The BIT time is usually2 seconds.The MCS monitors eachsubsystemat a l-secondratein orderto establish currentstatus(GO or NO GO). CommandedBIT is performed by each subsystem when commandedthrough the MFDs or by a cockpit control panel (when available). This mode is typically the most comprehensiveandprovidesthehighestdegree of fault isolation. When used,this mode interruptsnormal operation of the selected subsystem. The MCS monitors the subsystemwhile it is in test and the response(GO or NO GO) at the completion of test. Data bus test is performed by the MCS in order to detectdatabus (mission bus No. 1 andNo. 2, and intercomputerbus) channelfailures. Computerbus channel failures are detectedand reported by the RDP to the MCS. Each channel is tested on MCS cold start, and when a subsystemfmt respondson the data bus. The test consistsof transmitting severaltest patternsof data acrosseachchannel to a subsystem,and then reading back the data.A disagreementin the dataestablishesa NO GO for the data bus channel at fault. Since most bussedsubsystemsare dual redundanton the databus, a single-channelfailure will not affect the operationof the applicablesubsystem.In the eventthatboth channels have failed, the subsystemwill be maintained as NOT READY, making the subsystemunavailableto the rest of the system. ORIGINAL
NAVAIR 0%F14AAD-1 STATUS NOT READY
1 DEFINlTlON Subsystem Is not responding on a data bus as determined by the MCS, due to one of the followlng conditions: power-down, not Installed, remote terminal failure, bus message enor, excessively busy, or failure of all data bus channels to a particular subsystem. In addltlon, any bus subsystem that does not complete commanded BIT within a speclfled perlod of time will be set to thls status type.
NO GO
Subsystem has at least one WRA fault detected as a result of performing one of its Bm modes. These failures are reported to the MCS only after an approprlate failure threshold has been reached. Depending on the etient of the failure, the subsystem may not be operationally usable by thesystem, causing a degraded mode to be entered where available. Subsystems that are not on a data bus and are not responding due to being powered down or not Installed are reported as NO GO.
CONFIG ERROR
Subsystem has an Inconsistent sofhvare program, or firmware load as determlned by the MCS. This type of failure does not preclude the system from operatlonally using the affected subsystem. The subsystem can be powered down at the flightcrew’s Ulscretlon to prevent the subsystem from being used by the system. I
Figure 38-S. Defmition of StatusTypes Softwarecompatibility test is performedby the MCS in order to detectincompatible software programloads ascomparedto the configuration for the rest of the system. In addition, a subsystemwill test and report the internal compatibility between its main program load and fmware. Each subsystemis testedby the MCS on MCS scoldstart and when a subsystemfmt respondson the databus. When an incompatibility is detectedwith a subsystem,the subsystemstatuswill be maintainedas CONFIG ERROR, and a computermessagewill be displayed indicating the WRA at fault.
READY will not be displayed as such for 1 minute. After this time has elapsed,only equipmentthat is currently NOT READY will be consideredfailed. This allows subsystemsthat needtime to warm up or perform initial BIT to do so without being prematurelyreported asNOO0. Each mode of subsystemBIT is weighted according to the amount of fault isolation that it provides.Subsystem failures can be removed from the system(i.e., will clear any equipment failure maintained by the MCS) only by one of the following:
38.3.12 BIT Status/Priorities. OBC displayformats provide the flightcrew with continuousstatusof avionics and radar subsystems.Note that weaponand stores statusaredisplayedon the SMS format, which is selectable from the menu format. Failure acronyms am displayed on the OBC formats for every failed item. These acronymsidentify failures at the subsystemand WRA level on various OBC formats. Equipment BIT statusis displayedaseitherNO GO, NOT READY, or CONFIG ERROR. Refer to Figure 38-5 for status-typedefmitions. Note that absenceof a failure acronym indicates that the equipmentis GO. Refer to Figure 38-6 for a list of subsystemsversustypesof status.Note.that when the MCS cold-starts as a result of a power-transient or a system reset, BIT status for equipment that is NOT
ORIGINAL
38.8
1. Selectingsystem reset. 2. Cycling power to the MCS. 3. Cycling power tc subsystem (only pertains to equipmenton databus).During power-off, equip ment BIT statusrevertsto NOT READY. 4. CONFIG ERROR is overridden by NO GO or NOT READY. 5. Equipment status of NO GO will remain unless same or higher weight of BIT reports GO condition.
NAVAIR
SUBSYSTEMS ADAC AFCS
X X(l) X(1)
AICL AICR APC ASPJ BAG
WV X(l) X X(l) X(1 ) X(l) X X X X
BSF CADC CIU DEU DPl DP2 DLS DSS EMSPl EMSP2 IFB IFI IFX eINS
X(l) X X X
IRSTS JTIDS MC1 MC2 MFA LEFT MFA RIGHT RADAR RALT RFP RFR RWR SAHRS SDIS SMS TACAN TARPS wow ,OTE: (1)
NOT READY
NOGO X X X X X X X X X X X X X X X
38.3.1.3 MFD Commanded BIT. In addition to displaying equipment BIT status,the MFD OBC formats are the primary meansfor generatingcommandinitiated BIT. Testing can be controlled from any MFD on which an OBC format is displayed. The only other availablemethodof testing(for equipmentlisted in Figure 38-4) is to use a dedicatedcockpit panel to control test on an individual equipmentbasis. Test controls allow testsof the selectedsubsystem(s)to be initiated or terminated.The OBC display formats allow testing at several different levels, including sequencetesting, functionalgrouptesting,andindividual (or unit) testing. Sequencetestingallows severalitems to be testedat the sametime, with the MCS automatically testing (i.e., in parallel or in sequence)the appropriate equipment. Functional group testing allows functionally related equipment to be tested at the same time in a similar mannerto the sequencetests.Each OBC format generally containsa seriesofpushbuttonlegends representing systems that have command-initiated BIT capability. CommandedBIT canbe initiated oneat a time, or in any combination,as long asthe prerequisitesfor testing are satisfied.Referto paragraph38.32 for commandedBIT test prerequisites.
CONFIG ERROR X
X
X X X X
X X
WV X
X
X(l) X X X X X
X X X X X X
OBC display formats also serveto provide feedback or the progressof testing(i.e., in test,test complete,and awaiting test) throughMFD acronym status.Computer messagesare generatedand displayedon the MFDs in responseto invalid test selections.
X X X X
38.3.1.4 Control Panel-lnltiated BIT. ControlpanelinitiatedBIT is an alternatemodeof BIT initiatedtiom a cockpit control panel.Refer to Figure 38-4 for applicability, Control panel initiated BIT is describedwith the applicablesubsystem.
X X X X(l)
X X X X
X X X X X X X X X X
01.FQIAAD-1
38.3.2 Test Prerequisites/Restrictions. CommandedBIT testing requiresthat certain conditions be satisfiedprior to the test command from the MCS, for safety-of-flight purposes.These conditions govern the control of all commanded BIT initiated through the MFDs anddependon the type of test. In addition, there aresomerestrictionsthat disabletestsbecauseof equipment or operationalmode conflicts. (Initial andcontinuous BIT arenot subject to theseconditions.)
X X X X
38.3.2.1 BIT Interlocks/Test Restrictions. Preflight tests are enabledby the pilot selecting OBC on the MASTER TEST panel with weight on wheels, TAS < 76 knots, and handbrake set. These tests are designated preflight and it is recommendedthat they be performed at this time since a failure may cons& tute a flight safety hazard. All interlocks are constantly checked for change in status to ensure the safetyof the aircraft. In-flight testsareperformed only
X Subordinate to the converter interface unit (CIU), and equipment status is displayable as NO GO as a result of a subsystem not completing commanded BIT within a set time.
Figure 38-6. StatusTypes 38-9
ORIGINAL
NAVAIR 0%Fl4AAD-1
whenthe aircraft is airbornewith weight off wheelsand TAS > 76 knots. Refer to Figure 38-7. 38.3.3 Avionic BIT Operation. Avionic BIT operationis controlledthroughMFD OBC display formats. For some systems,dedicatedcontrol panelsserve as a redundantand alternatemeansfor controlling BIT. All OBC formats display equipmentstatus,equipmentfailure acronyms for detectedWRA failures, andthe progressof testing.Theseformats provide the capability to manually initiate/terminate command BIT and to mask/unmask current failures on the displays. These formats are accessibleon any MFD including the pilot center (MFDl), pilot right (MFD2), and RIO (MFD3) displays. When the system is powered up from a cold-start condition (i.e., power to MCS off for greaterthan 300 milliseconds) or when systemresetis ordered,the mission computersperform initial BIT. All other equipment takesvaryingamountsoftimetowarmuportocomplete initial BIT. At the completion of mission computer initial BIT, MFD2 will display the OBC BASIC format. At all other times, the OBC BASIC format can be accessedon any MFD by selectingthe MENU1 pushbutton followed by the OBC pushbutton.The OBC BASIC formaJ allows initiation of various test sequences,and also serves as the menu for accessto all other OBC formats. Tests can also be commandedthrough OBC functional groupformats.OBC computermessagesprovide feedbackto the flightcrew and aredisplayedwhen testing is completedor in responseto testselectionsthat arenot acceptablebecauseof invalid interlocks and operationalconflicts.
correspondingfunctional group format. Each acronym that appearson the OBC basic format indicatesthat the subsystemis not currentlyoperational.Eachacronymap pearsin a dedicatedlocation asshownin Figme 38-10. 38.3.3.1.2 Functional Group Formats/Fail Data Format. The OBC functional group format display failures are at the WFW level. Additional information for a WRA failure can be found on the corresponding fail data format for that functional group. Subsystem failure status is indicated as either NO GO, NOT READY, or CONFIG for each subsystemin the functional group. -Refer to Figure 38-5 for failure status types.When the statusis NOT READY for a subsystem on the bus, the WRA correspondingto the remote terminal (i.e., the WRA that directly communicates on the bus with the MCS) is displayed subordinateto the subsystem. A prompt (* NEXT PAGE *) on the bottom of an OBC fonctional group format (or a fail data format) appearsif thereare additional failure acronymsfor the group or additional fail datapages.Pressingthe PAGE pushbuttonin responseto theprompt will causethenext pageof information to be displayed.Pagingpastthe last pagewill causethe fmt pageto be displayedagain. Fail datainformation is only displayedon a fail data format after at least one commandedBIT hasbeenperformed for the applicable subsystem. Note Fail data is available for display continuously for CADC, EMSP 1, and EMSPZ.
When the system is in a backup mode of operation (only onemission computeroperational),it will support all the OBC functions that are normally provided in a full-up mode (i.e., both mission computersoperational).
Otherwise,if commandedbit hasnot beenperformed, a prompt will be displayed on the fmt line of the fail dataformat asFAIL DATA NOT AVAILABLE for the applicableWR4 or system.
38.3.3.1 MFD OBC Formats. There are several different typesof OBC formats: basic,functional group, fail data, maintenance,and failure history tile. Figure 38-8 identifies the equipmentthat canbe commandedto test, or masked,Tom eachof the format types.
38.3.3.1.3 Failure Acronym Masking. Masking removesor inhibits display of OBC equipmentfailure acronymsfor known WRA faults.Failure acronymswill beremovedfrom the OBC formats (basicandfunctional group) and from the TID OBCCM window regardless of the mode of BIT that detectedthe failure. Failure acronyms are maskable at the OBC basic level, where all currently failed equipmentis affected,andalsoat the timctional grouptit level, whereonly equipmentin the functional groupis affected,Failure acronymsmay also be unmaskedin orderto causetheir redisplayafter having been previously masked. Unmasking is initiated with OBC formats or by the system as a result of performing commandedBIT. Whicheverlevel of masking/ unmaskingis selected,all the correspondingequipment appearingon the OBC basic,OBC functionalgroup,and
Figure 38-9 identities all possibleOBC failure acronyms andfailure history tile acronymsthataredisplayed on OBC formats. It also provides an explanation and possible action that the aircrew can take in responseto the fault. 38.3.3.1.1 OBC Basic. The OBC basic format displays failures at the subsystemlevel and provides the capability to initiate the OBC sequencetests.Additional information for a subsystemfailure canbe found on the ORIGINAL
3840
NAVAIR
FLIGHT STATUS ‘REFLIGHT weight-on-wheels, TASc76 KTS, 4TP set to OBC. Parking brake set)
TEST SELECTS Preflight test
EQUIPMENT TESTED (1) CIU, CADC, APC, AFCS, AICS, RALT, IFB, ADAC, DSS, SM S, (1) DLB, BSF, (2) SDIS, IRST, JTIDS
Retest test
(1) CIU, ADAC. DSS, DEU, SMS, (3) ASPJ, (NON-RADIATE), SDIS, IRST
Indiiidual/group
test
(1) CIU, CADC, APC, AFCS, AICS
Weight-on-wheels, et)
parking brake
Individual/group
test
(3) INS, SAHRS, JTIDS
in/eight-on-wheels,
TAB.<76 KTS)
Individual/group
test
RALT
\IFLIGHT weight-off-wheels,
TAS>=76
Retest test
ADAC, DSS, DEU, SMS, (2) ASPJ (NON-RADIATE), SDIS, IRST
lnflight test
IFB, DEU, IFX, BAG, SMS, (1) DLS, (2) ASPJ (RADIATE), MFA LEFT/RIGHT, SDIS, IRST
KTS) Individual/group
test
BAG, IFX, (3) ASPJ (RADIATE)
Retest test ,reflight/lnflight
0%F14AAD-1
ADAC, DSS, DEU, SMS, (2) ABPJ (RADIATE), SDIS, IRST
Individual/group
(4) DPl, (4) DP2, DEU, IFB, (5) MCI, (5) MC2, ADAC, (6) DSS, SMS, (1) DLS, SDIS, IRST
test
Retesl test
ADAC, DSS, DEU, SMS, SDIB, IRST I
IOTES: I) CIU/DLS: When the CIU or DLS is selected for test through the MFD’s, the system will reject the selection(s) ti a CV SINS mode of alignment is in progress. This allows the SINS alignment to continue to completion without interruption. ?) ASPJ: In addltion to the interlock conditions indicated above, the following switch settings must be made on the ASPJ control panel in order to initiate test: -When the ASPJ is selected for test with the MFD’s, the ASPJ will perform BIT and radiate (i.e., transmit RF) only lf XMIT switch is selected. If RCV is selected, the ASPJ will perform BIT without radiating. -When the ASPJ Is seteoted for test with the MFDs, the ASPJ will not perform BIT if SlBy or OFF is selected.
Figure 38-7. Interlock Test Restrictions(Sheet1 of 2)
38.11
ORIGINAL
NAVAIR Ol-F~4AAD-~
3) INS: Prior to selecting selected.
INS for test with the OBC NAV format, TEST on the NAV MODE panel must be
4) DPlIDP2: When DPl or DP2 is selected for test through the OBC CD formats, the following restrictions ALLOWABLE TEST SELECTION DPI or DP2
apply:
FLIGHT STATUS In-flight
(Weight off wheels), both DP’s must be operationally
GO
OR Preflight (Weight on wheels) NONE
In-flight
(Weight off Wheels), one DP not operationally
GO
5) MCl/MC2: When MCI or MC2 is selected for test with the OBC AUXformats, ALLOWABLE TEST SELECTION MCI or MC2
the following restrictions apply:
FLIGHT STATUS In-flight
(Weight off wheels), both MC’s must be operationally
GO
OR Preflight (Weight on wheels) NONE
In-flight
(Weight off wheels), one MC not operationally
GO
‘6) DSS: Prior to selecting the DSS for test through the MFD’s, the data storage unit must be inserted into the Data Storage Unit Receptacle (DSUR). DSS BIT will be limited (i.e., less bulk memory checksum test) when the DSS is tested as part of a preflight or retest sequence. Otherwise, if the test selection is an individual or functional group type made through the OBC AUX format, DSS BIT will include the performance of the bulk memory checksum test. The bulk memory checksum test adds approximately 1 minute to the overall test time.
Figure 38-7. Interlock Test Restrictions(Sheet2 of 2)
ORIGINAL
38.12
NAVAIR
osc DISPLAY FORMAT ASIC
TID OBCCM window will be affected.Format examples are shown in Figure 38-11. Note that tbe OBC maintenanceformats are unaffected by any masking operation. Masking and umna&ing is controlled via OBC basic, any OBC functional group, or any fail data format as follows:
TEST SELECTIOM TYPE SEQUENCES: Prelight lnflight Retest
unctional group
1. OBC basic masking is performedby selectingtbe MSK function on the OBC basic format, at which time the MSK pushbuttonlegend will be boxed This allows all the equipment failure acronyms currentlyappearingon theOBC basic format to be removed.Unmasking is performedby pressingthe MSK pushbuttonwhile it is boxed, As a result, failure acronymsaredisplayedfor equipmentcurrently failed and the MSK pushbuttonlegend is unboxed to indicate that no failures are masked. The MSK pushbuttonappearsboxed on the OBC BASIC format if thereis at leastone WRA failure maskedin the system.
Group or individual:
FLT (flight)
AFCS, AICS, APC
CNI (communication, navigation, identification)
RFP, RFR, BAG, IFX, IFI, RALT, TCN
NAV (navigation)
CADC, CIU, DINS, SAHR
CD (controls and displays)
DEU. DPl , DP2
AUX (auxiliary)
MCI, MC2, EMSPl, EMSP2, ADAC, DSS, DBUS
SMST (stores management system)
SMS
TAC (tactical)
DLC, JTIDS
EW (electronic warfare)
ASPJ, BSF, IFB, RWR, MFA
SNSR (sensors)
IRST, RDR, SDIS, TARPS
0%FIWD-I
2. Functionalgroup masking is performedby selecting the ALL and MSK pushbuttonson the respeotive OBC functional group format. The ALL pushbuttonlegendis boxedto indicateits selection andunboxedif deselected.Group maskingis only performedif the ALL pushbuttonis boxedprior to making the selection of the MSK pushbutton. Groupmaskingwill only removefailure acronyms associatedwith equipment on the corresponding functional group format Group unmaskingis performed by deselectingthe ALLJMSK pushbutton when the MSK pushbuttonlegend is boxed. The MSK pushbuttonlegendappearsboxed if thereis at least one equipmentthat is maskedon the correspondingiimctional group format.
:AIL DATA CNI NAV CD AUX
3. Unit masking is performedby selectingequipment and MSK pushbuttons.Any number of WRAS may be selectedprior to selecting the MSK pushbutton in order to mask more than one failure at thesametime. Each equipmentpushbuttonlegend is boxedto indicate its selectionand is unboxedif reselected.Only those items that remain selected (i.e., boxed)beforeselectingthe MSK pushbutton will be masked.Unit unmasking is performedby selecting the equipment and MSK pushbuttons when the MSK pushbuttonlegendis boxed.
JTIDS SMST SMST SWITCHES Ew SNSR MNTENANCE ;URRENT FAILURES :AlLURE HISTORY FILE
Figure 38-8. OBC Display Format Types 3843
ORIGINAL
NAVAIR
01.Fl4AAD-1
OBC ACRONYM 4DAC
FHF ACRONYM 4DAC
4FCS
SFCS
KCELEROMETER
4FCAM
Yaw accelerometer
‘ITCH ACTUATOR
SFCPA
Pitch actuator position does not agree with command
?ITCH COMPUTER
4FCPC
Pitch computer failure (Valid only with corresponding CAUTION-ADVISORY lights on. Autopilot caution light and indicated failure is not valid)
PITCH SENSOR
4FCPS
Pitch sensor failure
ROLL ACTUATOR
4FCRA
Roll actuator position does not agree with command
ROLL COMPUTER
4FCRC
Roll computer failure
ROLL SENSOR
AFCRS
Roll sensor data failure
YAW ACTUATOR
4FCYA
Yaw series servo actuator failure
YAW COMPUTER
RFCYC
Yaw computer failure (Check that ALPHA COMP/PEDAL shaker clrcult breaker (RBl) is engaged)
YAW SENSOR
RFCYS
Yaw sensor failure
AICS
AICS
AICS-L or AICS-R
PROGRAMMER
DEFINITION ,Irbome Data Acquisition :omputer
REMARKS ADAC failure, Fatigue and Engine Monltorlng data records will no longer be recorded on the DSS
utomatic Flight Control iystem
Failure of a system WRA as shown below
ur Inlet Control System
Failure of AICL or AICR (See below)
4lr Inlet Control (Left or 3lght)
Indicates which AICS has falled. Used in conjunctlon with INLET/ RAMPS caution lights.
AILP AIRP
Programmer failure, without INLET light, computer uses normal values
Figure 38-9. OBC Failure Acronyms (Sheet 1 of 11)
ORIGINAL
failure
m-14
NAVAIR Ql-Fl4AAD-l
OBC ACRONYM $0.1 RAMP \CTUATOR
FHF ACRONYM AIlAl AIRAl
JO. 2 RAMP VZIJATOR
AllA AIRA
NO. 2 actuatorposition does not agree with command
r10.3 RAMP ACTUATOR
AiLA AiRA
NO. 3 actuatorposition does not agree with command
;TATlC PRESSURE
AILS1 AIRS1
Static pressuresensor.With INLETlight, SENSORfall safe mode. Without INLET IigM, failure operational.No filght restrictlon
rOTALPRESSURE
AlLS2 AIRS2
Total pressuresensor.With INLETlight, SENSORfall safe mode
4NGLEOF ATTACK
AILS4 AIRS4
Angie-of-Attack (AOA)or enginefan speed. (AFTCmay be in secondary mode.) Without INLET light, fail operational.No flight restriction
,D/MCS
AIUD AIRID
identifierconflict
WC
APC
RCCELEROMETER
APCAM
APC accelerometerfail No associated light Auto throttleinoperative APC not authorizedfor landing
COMPUTER
APCPU
APC computerfail Auto throttleinoperative
ASPJ
ASPJ
PROCESSOR
SPJPR
Possible processorfailure. Run commanded SIT to provide fault isolation to WRA level
RECEiVERLOW
SPJRL
Low-band receiverfailure
DEFINITION
ApproachPower Compensator
AirborneSelf-Protection JammSr
REMARKS NO. 1 actuatorposition does not agree with command
Auto throttle Inspection.System will defaui to BOOST automatically.A REV4 AIC programmeris installed in lieu of correct REV5 programmer.
ASPJ failure. ECM may not be available. Runcommanded BIT
Figure 38-9. OBC Failure Acronyms (Sheet2 of 11)
38-15
ORIGINAL
NAVAIR 01-FI4AAD-1
OBC ACRONYM TECENERHIGH
FHF ACRONYM SPJRH
tECEtVERAUG
SPJRA
Augmentationreceiverfailure
RANSMtllER LOW
SPJTL
Low-band transmitterfailure
nXAN.SMtlTERHIGH
SPJTH
High-band transmitlerfailure
rRANSMtllER AUG
SPJTA
High-band augmentationtransmitterfailurs
3WRINTERFACE
SPJRI
Interfacefailure between ASPJ and RWR
3AG
BAG
DEFINITION
Beacon Augmentor
REMARKS High-band receiverfailure
BAG not powered on Run commanded SlT Degradedposition approachon automatic carrier landing (ACL)and/or ground vectoring
Band SuppressionFllters
BSF failure
BSF
BSF
FILTERI-RWR 315
BSFl
BSF filter FWD 315 deg
FILTER2-RWR 45
BSF2
BSF filter FWD 45 deg
FILTER3-ASPJ
BSF3
BSF filter -ASPJ
CADC
CADC
CentralAir Data Computer Check caution/advisoryIlghts. Examine CADC Fail Data Format
au
au
ConvenerInterfaceUnit
CIU fall
Data Bus
MIL-STD-1553 data bus channelfallUre (See below)
DBUS ADAC MBUS 2 CHAN A
AAC2A
Mission Bus NO. 2 channelA fail
ADAC MBUS 2 CHAN B
AAC2B
Mlsslon Bus NO. 2 channel S fail
ARDP MBUS 1 CHAN A
RDPlA
Mission Bus NO. 1 channelA fail
Figure38-9. OBCFailure. Acronyms(Sheet3 of 11)
ORIGINAL
36-16
NAVAIR
OBC ACRONYM I\RDP MBUS 1 CHAN B
FHF ACRONYM RDPIB
DEFlNlllON
0%Fl4AAD-1
REMARKS Mlssion Bus NO. 1 channel B fail
ARDP MBUS 2 CHAN A
RDP2A
Mission Bus NO. 2 channel A fail
ARDP MBUS 2 CHAN B
RDP2B
Mission Bus NO. 2 channel B fail
RMlC
Computer Bus (Radar/MCI)
channel fail
RMX
Computer Bus (RadadMC2)
channel fail
RCIUC
Computer Bus (Radar/(X)
RSPJ MBUS 1 CHAN A
SPJlA
Mission Bus NO. 1 channel A fall
ASPJ MBUS 1 CHAN’ B
SPJIB
Mission Bus NO. 1 channel B fail
CIU MBUS 2 CHAN A
CIU2A
Mission Bus NO. 2 channel A fail
CIU MBUS 2 CHAN B
CIU2B
Mlssion Bus NO. 2 channel B fail
DSS MBUS 2 CHAN A
DBWA
Mission Bus NO. 2 channel A fail
DSS MBUS 2 CHAN B
DSMB
Mission Bus NO. 2 channel B fail
DPI MBUB 1 CHAN A
DPI IA
Mission Bus NO. 1 channel A fall
DPI MBUS 1 CHAN B
DPl 1 B
Mission Bus NO. 1 channel B fail
DP2 MBUS 2 CHAN A
DP22A
Mission Bus NO. 2 channel A fall
DP2 MBUS 2 GHAN B
DP22B
Mlsslcri Bus NO. 2 channel B fail
DEKI MBUS 2 CHAN A DEWA
Mission Bus NO. 2 channel A fall
DEKI MBUS 2 CHAN B
DEU2B
Misslon Bus NO. 2 channel B fall
INS MBUS 2 CHAN A
INS2A
Mission Bus NO. 2 channel A fail
channel fall
Figure 38-9. OBC Failure Acronyms (Sheet4 of 11)
38-17
ORIGINAL
NAVAIR
0%Fl4AAD-1
OBC ACRONYM INS MBUS 2 Cl-IAN B
FHF ACRONYM INS28
IRST MBUS 1 CHAN A
IRlA
Mission Bus NO. 1 channel A fail
IRST MBUS 1 CHAN B
IRlB
Mission Bus NO. 1 channel B fail
JTIDS MBUS 2 CHAN A
JT2A
JTIDS MBUS 2 CHAN B
JT2B
MC1 MBUS 2 CHAN A
MC12A
Mission Bus NO. 2 channel A fail
MC1 MBUS 2 CHAN B
MC128
Mission Bus NO. 2 channel B fail
MC2 MBUS 2 CHAN A
MC22A
Mission Bus NO. 2 channel A fail
MC2 MBUS 2 CHAN B
MC228
Mission Bus NO. 2 channel B fail
MC1 MBUS 1 CHAN A
MCllA
Mission Bus NO. 1 channel A fail
MCI MBUS 1 CHAN B
MCtlB
Mission Bus NO. 1 channel B fail
MC2 MBUS 1 CHAN A
MC2lA
Mission Bus NO. 1 channel A fail
MC2 MBUS 1 CHAN B
MC2lB
Mission Bus NO. 1 channel B fail
MC2 IBUS CHAN A
MC21A
Intercomputer
Bus NO. 1 channel A fail
MC2 IBUS CHAN B
MC21 B
Intercomputer
Bus NO. 1 channel B fail
SAHRS MBUS 1 CHAN A
SHRIA
Mission Bus NO. 1 channel A fail
SAHRS MBUS 1 CHAN B
SHRIB
Mission Bus NO. 1 channel B fail
SDIS MBUS 1 CHAN A
SDllA
Mission Bus NO. 1 channel A fail
SDIS MBUS 1 CHAN B
SDllB
Mission Bus NO. 1 channel B fail
SMP MBUS 2 CHAN A
SMP2A
Mission Bus NO. 2 channel A fail
SMP MBUS 2 CHAN B
SMP2B
Mission Bus NO. 2 channel B fail
DEU
DEU
DEFINITION
Date Entry Unit
REMARKS Mission Bus NO. 2 channel B fail
DEU failure
Figure38-9. OBCFailureAcronyms(Sheet5 of 11)
ORIGINAL
38-18
NAVAIR Ol-F14AAD-1
OBC ACRONYM DINS
FHF ACRONYM DINS
DEFINITION Digital Inertial Navigation System
REMARKS INS or battery failure
INERTIAL NAV SYSTEM
INS
INS failure
INS BATTERY BACK-UP
DNSPS
INS battery failure
DLS
DLS
Data Link System
Data Link powered BIT
JTIDS
JTIDS
Joint Tactical Information Distribution System
JTIDS failure
SDU
JTSDU
Secure Data Unit
BDU (KGV-6) failure/JTIDS are not loaded.
BAlTERY
JTBAT
JTIDS Battery
JTIDS Battery Failure. Keys will not load/hold in BTBY with a failed battery.
RCVWXMTR
JTRT
JTIDB Receiver/Transmitter
JTIDS lUT failure. Tacan operation.
DATA PROCESSOR
JTDDP
JTIDS Digital Data Processor
JTIDS DDP failure. This unit is part of the JTIDS Data Processor Group.
INTERFACE UNIT
JTIU
JTIDS Interface Unit
JTIDS IU failure. This unit is part of the JTIDS Data Processor Group.
DSS
DSS
Data Storage Set
DSB failure. Possible loss of data on data storage unit
EMSPl
EMSPI
Engine Monitoring Processor no. 1
Signal
EMSPl failure
EMSP2
EMSP2
Engine Monitoring Processor no. 2
Signal
EMSP2 failure
IFB
IFB
Interference
IRST
IRST
Infrared Search and Track
SENSOR UNIT
IRSU
Sensor unit failure
ELECTRONIC UNIT
IREU
Electronic unit failure
IFI
IFI
RECEIVER/ TRANSMITTER
IFIRT
Receiver/transmitter
SWITCH/AMP
IFISW
Switch amplifier failure
KIR COMPUTER
IFN
APX-76
SYNCHRONIZER
IFISYS
Synchronizer
Blanker
IFF Interrogator
off. Run commanded
crypt0 keys
This can also effect
Possible interference between Tacan, Radar Altimeter, IFF, APG-71, RWR, and ASPJ IRST failure
APX-76
failure
computer
failure
failure/not
installed
failure
Figure 38-9. OBC Failure Acronyms (Sheet6 of 11) 38-19
ORIGINAL
OBC ACRONYM Fx
FHF ACRONYM IFX
rRANSPONDER
IFXPN
IFF failure. Set MASTER switch on IFF control panel to NORM. Select test for each mode and observe Ilght.
:OMPUTER
IFA
APX-100 computer failure
vfc1
MCI
Mission Computer NO. 1
MCI failure. System will revert to backup mode If MC2 Is functional.
WC2
MC2
Mission Computer NO. 2
M2 failure. System will revert to backup mode If MC1 Is functional.
Multifunction Dlsplay System NO. 1
MDSl failure
WDSl
DEFINITION IFF Transponder
REMARKS APX-1 00 failure
DISPLAY PROCESSOR
DCPl
DP NO. 1 failure
PILCT CENTER MFD 1
MFDl
Pilot center MFD failure
HUD
HUD
Head-up
PILOT RIGHT - MFD 2
MFD2
Pilot right MFD failure
RIO - MFD 3
Mrn3
RIO MFD failure
HUD INTERFACE
HUDI
Interface failure between DP NO. 1 and HUD, or HUD not powered up
MFD 1 INTERFACE
MFDll
Interface failure between DP No. 1 and MFD NO. 1, or MFD NO. 1 not powered up
MFD 2 INTERFACE
MFD2l
Interface fallure between DP NO. 1 and MFD NO. 2, or MFD NO. 2 not powered up
MFD 3 INTERFACE
MFDBI
Interface failure between DP NO. 1 and MFD NO. 3. or MFD NO. 3 not powered up
MDS2
DISPLAY PROCESSOR
MultifunctIon Display System NO. 2
display failure
MDS2 failure
DP No. 2 failure. System will revert to Dl? backup mode lf DP No. 1 is functlonal.
DCP2
Figure 38-9. OBC Failure Acronyms (Sheet7 of 11)
ORIGINAL
38.20
NAVAIR
OBC ACRONYM PILOT CENTER MFD 1
FHF ACRONYM MFDl
DEFlNiliON
WFI4AAD-1
REMARKS Pilot center MFD failure
HUD
HUD
Head-up
PILOT RIGHT - MFD 2
MFM
Pilot right MFD failure
RIO - MFD 3
MFD3
RIO MFD failure
HUD INTERFACE
HUDI
Interface failure between DP NO. 2 and HUD, or HUD not powered up
MFD 1 INTERFACE
MFDli
Interface failure between DP NO. 2 and MFD NO. 1, or MFD NO. 1 not powered up
MFD 2 INTERFACE
MFD21
Intedace failure between DP NO. 2 and MFD NO. 2, or MFD NO. 2 not powered up
MFD 3 INTERFACE
MFD3i
interface failure between DP NO. 2 and MFD NO. 3, or MFD NO. 3 not powered up
DPl/DP2 INTERFACE
DP12l
Interface failure between DP NO. 1 and DP NO. 2
MFAL
Multiple Filter Assembly
Len
display failure
MFA left failure
FILTER A
MFAtA
Filter A failure
FILTER B
MFALB
Filter B failure
FILTER C
MFALC
Filter C fallure
MFAR
Multiple Filter Assembly Right
MFA rlght fallure
FILTER A
MFARA
Fliter A failure
FILTER B
MFARB
Filter B failure
FILTER C
MFARC
Filter C failure
RDR
Radar
APG-71 failure
RADAR
Radar not powered/not
irstaiied
Figure 38-9. OBC Failure Acronyms (Sheet8 of 11)
38-21
ORIGINAL
NAVAIR
0%Fl4AAD-1
OBC ACRONYM
FHF ACRONYM ARDP
DEFINITION Advanced Radar Data Processor
REMARKS ARDP failure
ARSP
Advanced Radar Signal Processor
ARSP failure
BPS
Beam Power Supply
BPS failure
RCVR
Receiver
RCVR failure
DD
Digital Display
DD failure
RDHCU
Sensor Hand Control
SHC failure
XMTR
Transmitter
XMTR failure
CPS
Collector Power Supply
CPS failure
SPS
Solenoid Power Supply
SPS failure
ANT
Antenna Array
ANT failure
RIC
Radome Interlock
RIC failure
ASC
Advanced Slgnal Converter
ASC failure
RDSCU
Radar Sensor Control Unit
RDSCU failure
TlD
Tactical Information Display
TlD failure
TCS
Television Camera System
TCS failure
SALT
RALT
Radar Altimeter
RALT failure (OBC BASIC)
3ADAR ALT
RALT
Radar Altimeter
RALT failure (OBC CNl)
IFP
RFP
Radio Frequency Pilot
Pilot RFI failure
1FR
RFR
Radio Frequency RIO
RIO RFCI failure
;AHRS
SAHRS
Standard Attitude Headlng Reference Set
SAHRS failure. Loss of back-up navlgatlo mode
Figure 38-9. OBC Failure Acronyms (Sheet9 of 11)
ORIGINAL
38-22
NAVAIR
FHF ACRONYM
OBC ACRONYM
REMARKS
DEFINITION
SDIS
SINS
SENSOR CONTROL UNIT
SDSCU
Sensor control unit failure
SENSOR SLAVING PANEL
SDSSP
Sensor slaving panel failure
SMS
Sensor Display Indicator Set
Stores Management set
Of-F14AAD-I
SDIS failure
SMS failure
SMP
SMP
Stores management
processor failure
MPRU
MPRU
Missile power relay unit failure
GUN CONT UNIT
GCU
Gun control unit failure
FTJU STA 2
FTJ2
Fuel tank jettison unit station No. 2 failure
FTJU STA 7
FTJ7
Fuel tank jettison unit station No. 7 failure
TYPE 1 DECODER INB
DlSl
Type 1 decoder station IA/B failure
TYPE 1 DECODER
3/6
DlS.36
Type 1 decoder station 3/6 failure
TYPE 1 DECODER
415
DlS45
Type 1 decoder station 4/5 failure
DlS6
Type 1 decoder station 6AlE failure
TYPE 1 DECODER 6AfB TYPE 2 DECODER
IB
D2SiB
Type 2 decoder station IB failure
TYPE 2 DECODER
3
D2S3
Type 2 decoder station 3 failure
TYPE 2 DECODER 4
D2S4
Type 2 decoder station 4 failure
TYPE 2 DECODER
5
D2S5
Type 2 decoder station 5 failure
TYPE 2 DECODER
6
D2S6
Type 2 decoder station 6 failure
TYPE 2 DECODER
6B
D2SBB
Type 2 decoder station 6B failure
AW-4
AWW-4
AWW-4 electrical fuzing switch failure
MISSILE PS
MPS
AIM-54 missile power supply failure
Figure 38-9. OBC Failure Acronyms (Sheet 10 of 11) 3833
ORIGINAL
I
NAVAIR
0%Fl4AAB1
OBC ACRONYM
FHF ACRONYM
DEFiNiTlON
REMARKS
TCN
TACAN
Tactical Air Navigation
TACAN failure (OBC BASIC)
TACAN
TACAN
Tactical Air Navigation
TACAN failure (OBC CNI)
TARP1
TARP1
Tactical Airborne Reconnaissance Pod
TARP system failure (crew aleri)
TARP2
TARP2
Tactical Airborne Reconnaissance Pod
TARP/CiU communlcatlon
RWR
RWR
Radar Warning Receiver
RWR failure
COMPUTER
RWRCP
Analyzer (CP-1293) failure
CONTROL STATUS UNiT
RWRCU
Control status unit failure
QUAD RECENER 45
RWRQl
Quadrant receiver (45 degrees) failure
QUAD RECEiVER 135
FiWRQ2
Quadrant receiver (135 degrees) failure
QUAD RECEiVER 225
RWRQB
Quadrant receiver (225 degrees) failure
QUAD RECEIVER 3 15
RWRQ4
Quadrant receiver (315 degrees) failure
SPECIAL RtXR
FtWRSR
Superhet receiver failure
IhmGRATED ~~N-~ENNA
RWRAN
Integrated antenna failure
@.PJ INTERFACE
RWRAI
interface failure between RWR and ASPJ
IFB INTERFACE
RWRBI
interface failure between RWR and IFB
NOW
wow
Weight on/oft wheel discrete failure
Figure 38-9. OBC Failure Acronym (Sheet11 of 11)
ORIGINAL
38-24
faliure
NAVAIR 01.FI4AAD-1
Figure 38-10. OBC Basic Format 38.3.3.2 Avlonlc Test Operation. Tests may be done in a sequence(preflight/in-flight, and retest sequence),or in groups(functionalgroup),or on anindlvidual basis.For any equipmentselectedand validated for test, the progress of testing is indicated on all OBC formattypesthat containequipmentpushbuttonlegends. Referto Figure 38-l 1 for format examples.Test progress is indicatedon the OBC formatsas follows:
ment is currently not ready,equipmentpushbuttonlegendswill remain steady. All testing is terminated by the system when any of the following occurs: 1. The ACM guardis lifted. 2. A weaponis selected.
1. Equipment pushbuttonlegendsappearbright and steadywhen a test cannot begin immediately because of a dependencywith at least one other equipment. When the dependencyno longer exists, the equipment is commandedto test and the pushbuttonlegendwill then appearflashing.
3. A radarACM mode is selected. 4. Interlock statuschangesfrom thoseconditionssatisfied at the initiation of test. Note that not all testscan be terminated.
2. Equipment pushbuttonlegendsflash at bright intensity when an equipmentis in test. 3. Equipment pushbuttonlegendsappearsteadyat a normal level of intensity when an equipmentis not in test. CommandedBIT testing interfereswith normal operationalmodes of equipment.Testing canbe initiated only when equipmentis poweredup andready.If equip-
38.3.3.2.1 Automatic Test Sequences. There are threetypes of automatictest sequences,all of which sm. initiatedtbmughthe OBC basicformat:in tlight, pretlight, and retest. Each sequenceallows the testing of many WRAs with a singlepushbutton.The systemcommands eachWRA tc testin a predeterminedordersothatequipment conflicts are eliminated. Refer to BIT interlocks/ restrictionsfor the testsin eachsequence.
38-25
ORIGINAL
NAVAIR 0%Fl4AAD-I
CONTROLS THE MASKING OF FLT EO”IPMENTS ONLY
FWCS "06 - TL, cl L T Arcs APC ._^_ ==P /G AFCS ^-A
r,
.,
q/
I
EO"w"%NT P"SHS"TTON LEGENDS REFLECT THE PROGRESS OFTESTlNO
d D SELECTS THE ENTIRE F”NCTlON OROUP FOR TEST OR MASK
SELECTS FAlL DATA FORMAT
Figure 38-11. Format Examples ORIGINAL
36-26
NAVAIR 01.F14AAD-1
1. In-flight/preflight test sequences are initiated through the OBC basic format by pressing the TEST pushbutton while the aircraft is on the groundor airborne.Dependingon the Sight status, either the in-Sight or preflight test sequencewill be initiated (refer to BIT interlocks/restrictions).
10. Nominal test time varies based on the mix of equipment. Maximum test time is 35 seconds. (Note: Test times may vary asa function of equip ment status.) 11. ReselectingtheRETEST pushbuttonwhile the sequenceis in progresswill terminatetest for equip ment still in test. Equipment that cannot be terminatedwill continuein testto normal comple tion. When all tests are completed,the RETEST pushbutton is unboxed to indicate that the sequenceis no longer in progress.
2. If interlock conditions/restrictions are not satisfied, testing will not be initiated and a computer messagewill be displayed to indicate the reason for rejection. Refer to paragraph38.3.3.2.3 for computermessagedescriptions. 3. If interlock conditions are satisfied, the TEST pushbuttonlegendis boxed to indicate a valid test selection and BIT is initiated in parallel or in sequential order for all WRAs in the sequencethat arepoweredon and ready. 4. Nominal testsequencetime for preflight is 69 seconds,andin flight is 35 seconds.(Note: Test times may vary as a function of equipmentstatus.) 5. Reselecting the TEST pushbutton while the sequenceis in progresswill terminatetest for WRAs that are still in test. WRAs that cannot be terminatedwill continuein testuntil normal completion. When all WRAs have completed test, the TEST pushbuttonlegendis unboxedto indicate that the sequenceis no longer in progress.
38.3.3.2.2 Function Group/Unit Test OBC functional groupformatsallow groupsof tbnctionallyrelated or individual (i.e., unit) WRAs to be selectedfor test. Referto Figure38-8.The OBC functionalgroupformats are accessible8om the OBC basic format: FLT, CNI, NAV, CD, AUX, SNSR, SMS, EW, and TAC. Croup tests am initiated with the respective OBC functional group format by pressing the ALL and TEST pushbuttons. The ALL pushbutton legend is boxed to indicate its selection and is unboxed when deselected.Croup testing is only initiated if the ALL pushbutton is boxed prior to making the selection of the TEST pushbutton.Depending on flight status,all WRAs that satisfy individual interlock conditions will be initiated into test. Refer to Figure 38-7 for group test selects.
6. The retest sequenceis initiated through the OBC basic format by pressingthe RETEST pushbutton while the aircrafi is on the ground or airborne. WRAs are selectedby the system for retestif the last entry in the FHF indicates a NOT READY statusand if individual equipment interlocks are satisfied Refer to BIT interlocks/restrictionsfor the equipmentapplicable to this sequence. 7. If interlock conditions/restrictionsare not satisfied, testing will not be initiated. Refer to paragraph 38.3.3.2.3 for computer message descriptions. 8. If the interlock conditions are satisfied, the RETEST pushbuttonis boxed to indicate a valid test selectionand BIT is initiated in parallel or in sequential order for all WRAs in the sequencethat arepoweredon and ready. 9. At thecompletionof theRETEST sequence,the last FHF entry (mdicating NOT READY) will be removedfrom theFHF for all equipmentthatcurrently indicatesa statusothertbanNOT READY.
38-27
1. If interlock conditions/restrictionsarenot satisfied for at least oneWRA, testing will not be initiated. 2. If interlock conditionsare satisfiedfor at least one WRA, the TEST pushbuttonlegend is boxed on the applicable OBC functional group format to indicate a valid test selection and BIT is initiated in parallel or in sequentialorderfor all powered-on andready WRAs in the sequence. 3. Nominal test times may vary as a function of the selectedfunctional group and are based on the equipmentinitiated to test (referto Figure 38-4). 4. ReselectingtheALL andTEST pushbuttonswhile the timctional group test is in progresswill terminate test for equipment in test. Equipment that cannot be terminated will continue in test until normal completion. When all equipmenthascompleted test, the TEST pushbutton legend is unboxedto indicatethat testing is complete.
ORIGINAL
NAVAIR Ol-Fl4AAD-I
Unit tests are initiated from any OBC functional group format by pressing equipment and TEST pushbuttons. Any number of equipment pushbuttons may be pressedprior to pressing the TEST pushbutton in order to test more than one item at the sametime. For each selection, the pushbutton legend is boxed to indicate selection and unboxed when deselected.Only equipment with a boxed legend will be tested. Depending on flight status, all equipment that satisfies individual interlock conditions will be initiated into test. Refer to Figure 38-7 for individual test selects. 1. If interlock conditions/restrictions are not satistied for at least one equipment, testing will not be initiated. 2. If interlock conditions are satisfied for at least one equipment, the TEST pushbutton legend is boxed on the applicable OBC functional group format to indicate a valid test selection and BIT is initiated for ail equipment that is powered on and ready. 3. Nominal test times may vary as a Iunction of the selectedequipmentinitiated to test (referto Figure 384). 4. Reselecting equipment and TEST pushbuttons while test is in progress will terminate test for equipment still in test, Equipment that cannotbe terminatedwill continuein testuntil normal completion. When all tests are complete, the TEST pushbuttonlegendis unboxedto indicatethat testing is no longer in progress. 38.3.3.2.3 OBC Display Messages. OBC display messagesare shown on the MFDs in responseto invalid test selections resulting from interlocks not being satisfied, interlocks changing, and for tests completed. Normally, OBC computer messagesare displayed on the pilot centerMFD andthe RIO MFD. If thepilot center MFD is powered off or failed, computer messageswill be displayed on the pilot right MFD. These messagesareremoved ftom the display headby pressing the ACK pushbutton, which is boxed to indicate that at least one display message requires acknowledgment (refer to Figure 38-12).
ORIGINAL
OBC/CSS messages are displayed on the MFD from which the test selection is made and also displayed on the sameMFD if a CSS format is presented. There are two types of messageswithin this class: 3-secondtype, displayed for 3 secondsand then removed by the system; conditionally removed type, displayed until either the applicable interlock condition is satisfied, or until the format is changed(refer to Figure 38-13). 38.3.3.2.4 OBC-Related Warning/Caution/ Advisory Messages. Figure 38-14showsacronyms that are displayedon MFD3 in responseto equipment failures or overheating. 38.3.3.2.5 Failure History File Format. The FHF format displays a history of WRA thihuea.There is a maximum of 10 entries per WRA for which the WRA failure statusand the time of failure are.displayed. The time of failure is relative to the last time the systemwas cold startedor SYSTEM RESET waspressedThe FBF is cleared when the CLR pushbutton is pressedwith preflight conditions satisfied. The preflight conditions are: weight on wheels, TAS < 76 knots, pilot’s OBC discretevia the MASTER TEST panel, and handbrake set. 38.3.4 Joint Tactical information Distribution System On-Board Check. JTIDS OBC can be selected whenever electrical power and cooling air are available. The JTIDS secure.data unit needsto be installedand loaded for JTlDS to passOBC. Without the unit installed and loaded, JTIDS OBC will display a DDP fail. A JTIDS download is not requiredfor JTIDS OBC; however, if the DSS is loaded, a download is recommended.The selectionof JTlDS OBC when not in sync (receiving messages)will passbut the fail data will havebit 4 in word 11and bit 8 in word 12because no messagesare received The selection of JTIDS OBC will interrupt tacan data (momentary display of tacan fail detectedcomputer message)and initiate a tacan self-test. This will disable tacansteering and tacannavigation updates,if selected, range will go invalid, bearing will display 270”; then range will display 000 miles and bearing 180’.
38-28
NAVAIR
01.Fl4AAD-1
COMPUTER MESSAGE PRE-FLT OBC COMPLETE
DESCRIPTION Displayed when the preflight OBC test sequence is completed. Message is displayed if sequence completes normally or is terminated, or if interlock conditions change.
IN-FLT OBC COMPLETE
Displayed when the in-flight OBC test sequence is completed. Message is displayed if sequence completes normally or is terminated, or if interlock conditions change.
3ETEST COMPLETE
Displayed when the retest OBC sequence is completed. Message is displayed if sequence completes normally or is terminated, or if interlock conditions change.
TEST COMPLETE -
Displayed when a functional group test is completed. Message is displayed if group test completes normally or is terminated, or if interlock conditions change. appears as AUX, CD, CNI, FLT, NAV, EW, TAC, or IRST for the functional group that completed test.
3BC SEQ ABORTED
Displayed when an OBC sequence (preflight or in-flight) the OBC BASIC format while it is in progress.
%ETEST ABORTED
Displayed when a retest sequence while it is in progress.
‘ILOT OBC DISABLE
Displayed when the Pilot’s MASTER TEST panel switch remains in OBC 10 seconds after commended BIT completes for an equipment that required this interlock to initiate test.
NTERLOCK ABORT
Displayed when an interlock condition changes state (i.e., no longer satisfied) for an equipment that is already in test. Commanded BIT will be terminated for the affected equipment.
ZHALLENGE IFF
Displayed when the IFF Interrogator has not been challenged prior to the selection of a test sequence. This message is displayed only once at the time of the test sequence selection. If the system cold starts, or SYSTEM RESET is pressed, this message will be displayed again when a test sequence selection is made.
NVALID .OAD
Displayed compatible applies to DEU, INS,
is terminated
is terminated
through
through the OBC BASIC format
when an equipment has an inconsistent firmware load, or is not with the mission computer software load. The field the following equipments: MCI, MC2, CIU, SAHR, MD%, MDS2, ADAC, SMS, RWR, ASPJ, RDR, SDIS, IRS-T
Figure 38-12. OBC ComputerMessages
38-29
ORIGINAL
NAVAIR 01.Fl4AAD-1 OBC/CSS MESSAGE
DESCRIPTION
JOW NOT SATISFIED
Displayed when equipment is selected for test via a unit, inffight, or preflight test selection, and the WOW (Weight-on/off-Wheel) interlock condition is not satisfied. Testing will not be initiated for the selected equipment. Note that this message will not be displayed for functional group or retest test selections.
AS NOT SATISFIED
Displayed when equipment is selected for test via a unit, inflight, or preflight test selection, and the TAS (True Air Speed interlock condition less than or greater than 76 knots) is not satisfied. Testing will not be initiated for the selected equipment. Note that this message will not be displayed for functional group or retest selections.
1ULTI INTLK NOT MET
Displayed when equipment is selected for test via a unit, inflight or preflight test selection, and more than one (i.e., multiple) interlock conditions are not satisfied (WOW, TAS, PARKING BRAKE, or MTP). Testing will not be initiated for the selected equipment. Note that this message will not be displayed for functional group or retest selections.
,QlJlPMENT CONFLICT
Displayed when equipment is selected for teti whidr conflicts with other equipment already in test. These conflicts are primarily between equipments subordinate to the CIU, between CIU subordinate equipment and the CIU itsetf, between DPI and DP2, and between MC1 and MC2. Testing will not be initiated for equipment that conflict operationally.
IO COMMANDED
Displayed when equipment for test.
BIT
that does not support command
BIT is selected
IBC SEQ IN PROGRESS
Displayed when equipment is selected for test that is the same as equipment already in test as part of an OBC inflight or preflight test sequence. Testing for the selected equipment will not be initiated.
ETEST IN PROGRESS
Displayed when equipment is selected for test that is the same as equipment already in test as part of an OBC RETEST sequence. Testing for the selected equipment will not be initiated.
IASTER TEST NOT SET
Displayed selection message removed
IANDBRAKE NOT SET
Displayed when equipment is selected for test via a unit or preflight test sequence selection and the handbrake is not set. This message is continuously displayed as long as an OBC or CSS format is presented and is removed when the handbrake is set.
iAD JTID DATA LOAD
Displayed when JTIDS test is selected during initialization JTIDS.
ACAN FAIL DETECTED
Displayed for a TACAN failure or JTIDS NOT READY.
TIDS FAIL DETECTED
Displayed for a JTIDS failure or JTIDS NOT READY.
when equipment is selected for test through a unit or preflight test and the pilot’s MASTER TEST panel switch is not set to OBC. This is displayed as long as an OBC or CSS format is presented, and when the switch is set to OBC.
Figure 38-13. OBC/CSS Messages
ORIGINAL
38-30
(Down Load) of
NAVAIR ACRONYM
DISPLAYED
CONDITION
0%FMAAD-1
CAUSE
MCI
Mission computer READY
No. 1 is NO GO or NOT
Mission computer powered off
No. 1 is failed, or
MC2
Mission computer READY
No. 2 is NO GO or NOT
Mission computer powered off
No. 2 is failed, or
CIU
CIU is NO GO or NOT READY
CIU is failed, or powered
INS
INS is NO GO or NOT READY
INS is failed,or powered off
IMU
IMU is not valid
IMU is failed. Loss of inertial and attitude data from INS
RWR
RWR is NO GO or NOT READY
RWR is failed, or powered off
FWD ASPJ
ASPJ receiver (low or high), ASPJ transmitter (low or high) or processor is NO GO
ASPJ RECEIVER, TRANSMITTER, PROCESSOR is failed
AFT ASPJ
ASPJ processor, receiver augmentation transmitter augmentation is NO GO
MCI HOT
Mission computer
No. 1 overheated
Possible loss of cooling air
MC2 HOT
Mission computer
No. 2 overheated
Possible loss of cooling air
ASPJ HOT
ASPJ is overheated
Possible loss of cooling air
CIU HOT
CIU is overheated
Possible loss of cooling air
DPI HOT
DPl is overheated
Possible loss of cooling air
DP2 HOT
DP2 is overheated
Possible loss of cooling air
SMS HOT
SMS is overheated
Possible loss of cooling air
RDR HOT
RDR is overheated
Possible loss of cooling air
HUD HOT
HUD is overheated
Possible loss of cooling air
RWR HOT
RWR is overheated
Possible loss of cooling air
DSS HOT
DSS is overheated
Possible loss of cooling air
DEU HOT
DEU is overheated
Possible loss of cooling air
MPS HOT
MPS is overheated
Possible loss of cooling air
IRST HOT
IRST is overheated
Possible loss of cooling air
SAHRS HOT
SAHRS is overheated
Possible loss of cooling air
JTID HOT
JTIDS R/T is overheated
Possible loss of cooling air or a high JTIDS transmit duty cycle.
IPF
JTIDS Interference detected failure
JTIDS is failed, a momentary glitch or 20% duty cycle has been exceeded in “Limit”. Select IPF Reset on JTIDS Control Panel.
SDU ALRM
JTIDS Secure Data Unit failure or no crypt0 load
or
Protection Feature
off
or
ASPJ PROCESSOR, RECEIVER AUG, or TRANSMITTER AUG is failed
SDU fail or the crypt0 key is erased.
Figure38-14.OBC-Related Waming/CautiodAdvisory Messages 30-31
ORIGINAL
NAVAIR Ol-Fl4AAD-1
30.4 COOPERATNE
SUPPORT SOFTWARE
3. Pressing the TM pushbutton allows CSS datato be telemetered or down-linked to a groundbasedstation.
CSSauowScaptureanddisplayofsystemdatainreal time and the optional recording of data from avionics procemors that are CSS compatible. CSS is typically used to aid in troubleshooting system problems. The CSS compatiile processorsinclude mission computer No. 1, mission computer No. 2, multifunction display systemNo. 1, multit%nction display systemNo. 2, airbornedataacquisition sysm storesmanagementpmcessor,converterinterfaceunit, dataenuy unit, intImed searchand track system joint tactical infomtation distribution system, and sensordisplay indicator set.Note thatradarflycatcherdisplaysareprovidedonthetactical information display.
4. Pressing MC1 or MC2 allows CSS data to be storedin mission computerNo. 1 or mission computer No. 2 memory, mspectively, and is only accessiblefor future referenceby the CSS function. A maximtmr of 300 blocks of CSS data can be storedin either mission wmputer. A block of data is saved when a trap or block addressfunction completes,and one block per secondis savedfor anactive flyeateher.This datawill only beretained by the mission computers until the system cold startsor is reset.
Note
5. Pressingthe DSS pushbuttonallows CSS datato be recordedby the data storageset.
The JTIDS processoronly supportsthe flycatcher functions (start address,increment, decrement,and disable). CSS supports the following modes, all of which are selectable on the DEU: flycatcher, block address, and trap. CSS data is displayed on the MFD CSS format. The CSS format is selected by pressing the FAULT pushbutton on the OBC basic format and then pressing CSS on the MAINT CURRENT FAILURES format. 38.4.1 CSS Operation. The CSS page (seeFigme 38-15), displayed on the DEU. allows the entry of DATA TYPE and OPER CODE used for data recording purposes, and allows the selection of ail CSS modes including flycatcher, block address,and trap. Ail CSS data is displayed on an h4FD CSS format, using pushbutton controls. Note that if the DEU is slaved to the RIO MFD, selection of the CSS format on that MFD will causethe CSS page of the DEU to be displayed.
The CSS OPER CODE page format (seeFigure 3816) allows the optional selection of an operator code. This code is usedto identify the operator/a&rat?when CSS data is analyzed offline. The code is enteredby pressingthe correspondingnumerics and thenpressing ENT. 38.4.1.2 Flycatcher Operation. Flycatcher mode allows memory contentsfor a selectedprocessorto be continuouslyexamined anddisplayedon the MFD CSS format. The contents of 16 contiguousmemoty locations are displayed relative to a specified flycatcher memory start address,updatedat a l-second rate. A previously specified start addressmay be incremented or decrementedby a fixed bias.Each processorsupports only one flycatcher at a time. Flycatcheris initiated or terminatedas follows, using the DEU (seeFigure 38-17):
38.4.1.1 Data Recording Operations. The CSS DATA TYPE page (see Figure 38-16) allows the optional selection of a recording/storage device for the retention of data that is capturedvia a CSS mode. CSS data can be telemetered or recorded for offline analysis based on one or more of the following selections: 1. Pressingthe AUX pushbuttonallows CSS datato be displayed on an auxiliary display head (this function is not available). 2. Pressingthe REC pushbuttonallows CSS datato be recordedon a flight recorder,if one is installed in the aircraft.
ORIGINAL
38-32
1. Selectflycatcher by pressingFLY CATC on CSS pageof DEU. 2. Selectprocessorto be examined by pressingone of the WRA pushbuttonson F-CATC page. 3. Initiate flycatcher. Press STRT ADRS to allow entryof startingmemory addressfor selectedprccessor;enter start addressin hexadecimalwith numeric pushbuttons.PressENT to completeaddress entry and activate flycatcher. 4. For flycatchertermination, pressDSBL to deactivate current flycatcher. 5. Repeatsteps2 and 3 to initiate or terminateadditional flycatchers for otherprocessors,
Figure 38-15. DEU CSS Page
(AT)l-FSOO-3&M
Figure 38-16. DEU Pagesfor OperatorCodeand Data Type ORIGINAL
NAVAIR Q14=14AAD-1
DEPRESS FLY CATC OPTlO,N KEY
I L; I I I 4 I I I I I L-
I I
-
(AT)%FsnD-385-o
Figure 38-17. DEU Flycatcher Pages
ORIGINAL
38-34
NAVAIR 01.FI4AAD-1
, S”SSYSTEM DATA ADDRESS
Figure 38-18. MFD CSS Display Format An active flycatcher canbe biasedby a fixed number of memory locations, relative to the current memory addressas follows, using the DEU (seeFigure 38-17):
that hasactive flycatcher.Note that flycatcherdata word field will display flycatcher last selected,if any, when format is tirst displayed.
1. Selectflycatcher by pressingFLY CATC on CSS pageof DEU.
The messagesshown in Figure 38-19 are displayed on the RIO MFD computermessageareain responseto an invalid flycatcher operation.
2. Select INCR (to increment) or DECR (to decrement) pushbutton.Enterbiasvalue in hexadecimal with numeric pushbuttonsandpressENT to complete entry. 3. Repeatstep2 for subsequententry of bias values for selectedprocessor. Flycatcherdatais displayedon thelefthrdf of theCSS format anytime them is at least one active flycatcher as follows, using the MFD (seeFigure 38-18). 1. Select CSS format on any MFD by pressing FAULT pushbuttonon OBC basic format andthen pressingCSS pushbuttonon h4AlNT CURRENT FAILURES format.
38.4.1.3 Block Address/Trap Operation. Block addressallows the memory contentsof a selectedprocessorto be capturedonceupon its selection;trap allows data to be capturedonce upon the satisfactionof a selected algorithm. Data captured as a result of either mode is displayed on the MFD CSS format. The contents of 16 contiguousmemory locationsare displayed relative to a specified memory start address. Block addressis initiated as follows, using the DEU (seeFigure 38-20) (note that block addressterminates automatically after its activation):
2. SelectSTEP pushbuttonto display 16-wordblock of flycatcher dataassociatedwith next processor
38-35
1. Select block address mode by pressing BLK ADRS on CSS pageof DEU. 2. Select system to be examinedby pressingone of equipmentpushbuttonson B-ADRS page.
ORIGINAL
NAVAIR
01.Fl4AAD-1
MESSAGE (Note 1) E FLYCH ADD {SSSS}
REASON FOR DISPLAY Error in DEU entered flycatcher start address for the subsystem identified in the {SSSS) field.
FLYCH EXISTS {SSSS}
Only one flycatcher can be active per subsystem. The subsystem is identified in the {SSSS} field. In order to setup the next flycatcher, the previous flycatcher must be disabled.
E FLYCH INC {SSSS)
Error in DEU entered flycatcher increment identified in the {SSSS} field.
N FLYCH IN {SSSS}
Error in DEU entry to increment, decrement or disable a flycatcher for a subsystem that has no active flycatcher. The subsystem is identified in the {SSSS} field.
E FLYCH DEC (SSSS}
Error in DEU entered flycatcher decrement identified in the {SSSS} field.
E NOT AVAIL
Flycatcher not available. (TOMs 21-27) enabled.
address for the subsystem
address for the subsystem
System is not ready. JTIDS tape recording
Note: (1) {SSSS} identifies the affected CSS compatible
subsystem.
Figure 38-19. FlycatcherError Messages 3. Eater start addressin hexadecimalwith numeric pushbuttons.PressENT to complete the entry of dataaad to activateblock addressmode. 4. Repeatsteps2 and 3 for additional block address operationsfor other systems. Trap is initiated or terminated as follows using tbe DEU (seeFigure 38-21). There is a maximum of four trapsper processor: 1. Selecttrap mode by pressingTRAP on CSS page of DEU. 2. Select system to be examinedby pressingone of equipmentpushbuttonson TRAP page.
a. PressALGO to selectalgorithm that is usedto trigger the capture of data. Eater algorithm numberwith numeric keypads,sad pressENT to completethis entry. b. For eachvariable (i.e.,Vl, V2, V3) ia selected algorithm, press either an appropriateaddress pushbutton (Vl ADRS, V2 ADRS, V3 ADRS), orcoastaatpushbuttoa(Vl CNST, V2 CNST, V3 CNST). Both selectionsrequireaumerit entry defining addressof variable or actual constant to be used in evaluation of algorithm. Eater value with numeric pushbuttons sad then pressENT to complete entry. c. PressDATA ADRS to allow entry of start addressfor data.Eater addressvia numeric pushbuttons, andpressENT to completeentry.
3. Eater tmp number (00 to 98) where number caa representexisting trap or new one (dependingon the desiredfunction).
d. PressCOMP to completethe activationoftrap.
4. Set up trap algorithm as indicatedbelow, or press DSBL to disable existing trap:
5. Repeatsteps2 through 4 to initiate or terminate additional trap operationsfor other systems.
ORIGINAL
38-36
NAVAIR Q1-FUAAD-I
DEPRESS SLK ADRS OPTION KEY
-1 I I I I I I I
I
DEPRESS SUBSYSTEM ““‘9”
KEY
S-ADRS
S-ADRS
Figure.38-20. DEU Block AddressPages
38-37
ORIGINAL
NAVAIR 01.F14AAb1
DEPRESS TRAP OPTION KEY
; t I I I I I A
DEPRESSSUBSYSTEM OPTlO,N KEY
I I I
7
I
I I I
-
I
I I L I
-
I I I T I J 7 I I t
I I
L
_I
Figure 38-21. DEU Trap Pages
ORIGINAL
38.38
NAVAIR
0%FI4AAD-I
MESSAGE (Note 1) E BLOCK ADD {SSSS)
REASON FOR DISPLAY Error in DEU entered block start address for the identified subsystem.
E TFIAP ADD {SSSS) {NN}
Error in DEU entered trap start address for the identlfled subsystem and trap number.
E 4 TRAPS {SSSS} {NN}
Current trap entry exceeds the maximum of 4 allowable traps per subsystem.
E TRAP VAR {SSSS} {NN}
Error in DEU entered trap variable address for the identified subsystem and trap number.
E TRAP ALGO {SSSS} {NN}
Error in DEU entered algorithm code for the identified subsystem and trap number.
NO TRAP NO. {SSSS} {NN}
Error in DEU entered trap number that 1sselected to be disabled.
TRAP TRU IN (SSSS}
Trap in identified subsystem has been triggered. Contents of the captured data block can be displayed on the CSS format.
Note: (1)
{SSSS} identiies the affected CSS compatible between 1 and 4.
subsystem.
{NN} identiies
a trap number ranging
Figure38-22. BlockAddresSrrrap ErmrMessages Blockaddress andtrapdataaredisplayed ontheright halfof theh4FDCSSformatwhenthereis at leastone blockof datato be reported.As a maximum,only the last 15block-address andtrapreportswill beretained by thisfunction.Displaysareselected asfollows:
Themessages shownin Figure38-22aredisplayed in the computermessage areaof theRIO MFD in m spouseto invalidblockaddress or trapoperations.
1. SelectCSS format on any MFD by pressing FAULT pushbuttonon OBC basicformat, and thenpressingCSSpushbuttonon MAINT CURRENTFAILURESformat.
RadarsystemBIT detectsAN/APG-71radarsystem hardwarefaultsandprovidesassessment of tacticalradarmodeavailability.BIT hasfour majorcapabilities:
30.5
RADAR
SYSTEM
BUILT-IN
TEST
1. Fault detectionusescomputer-controlledand RIO-initiatedteststo detectfailuresin flightor on thedeck.
2. PressNEXT pushbuttonto displaynext datareport.Thenumberofblock-addres&apreportsindicatesif any additional reports of data are availablefor displayand is decremented upon eachdepression of NEXT pushbutton.Notethat block-address/trap data-wordsfield will display lastselected blockof data,if any,whenformatis tirst displayed.Repeatthis stepas necessary to displayeachreport.
2. Faultisolationallowsisolationof a detectedsystemfailureby indicatingDPandthesuspect WIU or groupof WlWs.
3. PressCLR pushbuttonto clearanydatareports. This actioninhibits displayof any remaining reportsandresetsthe numberof block-address! trapreportsto zero.
4. CM automatically providestheRIO with a warning when systemfailuresoccur duringtactical modes.
38.39
3. DMA providesa pass,fail, or degraded evaluation of theoperational modes.
ORIGINAL
NAVAIR Ol-FIWAD-1
Figure 38-23. DD RadarWarning Maltese Cross BlT providesindicationof AN/ARC-7 1radarthnctional statusfor gmund-levelmaintenanceandairborneopemtion. Priort0 aircraftempl~yrnen~or following anairbornemission.tbeeroundcrewcauexecuteBlTtodekrmineradarset stat& CtTkctivemaintenauceactionmmmen~onsare providedon the maintenancedisplay. This display indicates the detectedhardware failure(s) along with replacementrecommendationsfor associated WRA(s). During tactical operation,the RIO will be alertedto any anomaliesthat will impact radar or aircraft operation. A Maltese crossis displayedin the lower left-hand quadrantof the DD if the radar has failed and/or the transmitter is not radiating (except in sniff mode). The Maltese cross is also displayed when the radar is in standbyor during initiated display test (Figure 38-23). The cross is not tied to the WOW switch, and will not be displayed solely for a WOW condition. Radar anomalieswill appearin the lower left quadrantof the TID as two-characteracronyms.Aircraft anomalieswill appearon tbeTID asthree&amcter acronyms,displayed below the radar acronyms.Acronyms will be displayed continuouslywhile theihihue conditionexists.Ifmultiple failuresoccur,the appropriateacronymswill be automatically cycled at a 2-secondrate. More detailed failure information is available on the continuous monitor maintenancedisplay. The RIO can initiate BIT at any time to confirm that hardwarestatusis unchanged, ORIGINAL
3840
38.5.1 BIT Modes. BIT allows the flightcrew to quickly assessradarset status,identify hardwarefaults, andtakethe corrective action.This assessmentincludes a radarconhdencetest, verification of controls and displays functionality, and, asnecessary,confirmation that the television cameraset is operational. The following BIT modes areavailable: 1. Operationalreadinesstest 2. Computerand displays mode test 3. Initiated radar test
4. Initiated displays test 5. Television cameraset test 6. Digital display built-in self-test 7. Initiated specialtest 8. Test-targetBIT 9. Continuousmonitoring.
NAVAIR WF14AAD-1
38.5.1.1 Operational Readiness lest. ORT is automatically initiated when aircraft power is appliedto the radar,with the sensorhand control in either STBY or KMIT or if a radar power interruption occurs for longer than 2.65 seconds.This radar confidence teat includestests of radarcomputers,RF subsystems,system interfaces,and targetdetectioncapability. ORT requiresnominally 3.5 minutes to complete (including 3 minutesfor transmitterwarmup), but could take as long as 7 to 8 minutes if radar functionsare degraded.When ORT hascompleted,the DMA display is automatically displayedon the TID and the BIT menu will appearon the DD (see Figure 38-24). The DMA algorithm provides an evaluation of the working status of tactical modes.If additional information is required,the maintenancedisplay can be selectedfrom the BIT menu
38.5.1.2 Computer and Displays Mode Test. CDM is automatically initiated when aircraft power is applied to the radarwith the SHC in CMPTR. CDM is interruptibleby pressingthe PGM RST pushtile on the DD. This radarconfidencetest includes a subsetof the testsperformedduring ORT. It differs t?omORT in that theantennahydraulicsandtransmittersubsystemarenot tested.CDM requires,nominally, 2.5 minutes to complete (the 3-minute transmitter warmup delay is not required).At the completion of CDM, the degradedmode assessmentdisplay is automatically displayed on the TID, and the BIT menu will appearon the DD. The DMA algorithm will give an evaluationof the working statusof tactical modes.If additional information is required,the maintenancedisplay canbe selectedfrom the BIT menu.
At thecompletion of ORT, the following testscanbe selectedfrom the BIT menu on the DD: radartest, displays test,television camerasettest, specialtest, or test target.If no further testing is required, a tactical mode canbe entereddirectly by selectingthe DD pushtile for the desiredmode.
At the completion of CDM, the following tests can be selectedfrom the DD BIT menu: radartest, displays test,television camerasettest,specialtest,or test target. if no further testing is required,a tactical mode canbe entereddirectly by selecting the DD pushtile for the desiredmode.
IfORT is running when a tactical situation arises,the RIO canabort ORT by pushingthePGM RST button in the lower right comer of the DD. ORT abort is not recognizeduntil afterthe initialization phaseis complete (5 secondsor less).To reportthat ORT hasbeenaborted, the CM acronym OA is displayedin the lower left position of the TID and the event is recordedin the failure history tile. The system will transition to 5-mn pulse search.The 3-minute transmitter warmup period will, however,still be in effect. This meansthat the system capabilitieswill be limited to a nonradiationmodeuntil warmup is complete. The system may have someperformance degradationbecauseof insufficient calibrations. These calibrations are normally executedduring the ORT sequence.Possible radarperformancedegradationsareas follows:
38.5.1.3 Initiated BIT. TheIBITmodecontainsfive submodes:radar BIT, displays BIT, television camera setBIT, digital displaybuilt-in self-test,andspecialtests BIT.
1. LPRP a. Short p&e - Up to SOO-footrangebias.
38.5.1.3.1 Radar BIT. Initiated radartest (RDR) allows retestof the radar system. If the SHC is in either STBY or KMIT, radar BIT will be the same as ORT (with the exception that the 3-minute transmitter warmup delay is not required). Consequently, radar BIT executiontimeisshorter. IftheSHCisinCMPTR, radarBIT will be the sameas CDM. Radar BIT is initiated by depressing the MFK pushtile on the DD to obtain the radar modes menu, selectingthe pushtile adjacentto BIT to obtain the BIT submenu,and then depressingthe pushtile adjacentto RDR on theBIT menu. Test executionrequiresapproximately 2.0 minutes, and is interruptible by a program restart(depressingPGM RST pushtile on the DD), @ otherBIT selection,or a radarmode selection.
b. Pulse compression-Up to 2-nm rangebias. 2. HPRF - RWS andPDS perform as requited. 3. RAM -RAM accuracymay be degraded. 4. PDSTTlRGSTT -Noise jammer problem will occur fust time until periodic calibrations are performed. These calibrations shall be performed within 5 minutes of the exist or ORT.
38.5.1.3.2 Displays BIT. DISP is a controls and displays subsystemconfidencecheck.The TID andDD display a predefmedset of static and dynamic symbology for evaluation of symbol intensity, completeness, contrast,and motion. Displays BIT symbology is dependentonthe TID mode switch settingandDD keypad entry. The RIO must confm visually that this subsystem is functioning properly.
38-41
ORIGINAL
NAVAIR Ol-FWIAD-1
ORT ABORT ACRONYM
‘ME OF ,lRRENCF Oc’-~~~~-~~--
FHF WRA ASCII STRING
\
ORT ABORT INDICATION
(AT)O-F?Xl-49%-0
Figure 38-24. MFDITID ORT Abort Displays ORIGINAL
3842
NAVAIR 0%Flu-1
Displays BIT is initiated by depressingthe h4FK pushtile on the DD to obtain the radar modes menu, selectingthe pushtile adjacentto BIT to obtain the BIT submenu,and then depressingthe pushtile adjacentto DISP on the BIT menu. Displays BIT is intarruptiile by a programrestart(depressingPGM RST pushtile on the DD), anotherBIT selection,or a radarmode selection. 38.5.1.3.3 Televlslon Camera Set BIT. The TCS test verifies the statusof the television cameraset. The capability of the TCS slave modes is verified, the mechanical tracking functions (i.e., slewing and track) are checked, and the radar-relatedTCS support functions aremonitored.Detectedfaults aredisplayedon the TID at test completion. TCS TEST is initiated by depressing the MFK pushtile on the DD to obtain the radar modes menu, selectingthe pushtile adjacentto BIT to obtain the BIT submenu,and then depressingthe pushtile adjacentto TCS on the BIT menu. TCS testing is interruptibleby a program restart (depressingPGM RST pushtile on the DD), anotherBIT selection,or a radarmode selection. 38.5.1.3.4 Digital Display Built-h Self-Test. The DD hasa standaloneBIST capability that must be initiatedand evaluatedby the RIO. It testsDD fonctions as well as its discrete interfaces with the sensorcontrol unit, sensorhand control, andTID. DD BIST is initiated by depressingthe CiD TEST pushtile on the radarcontrol panelportion of the digital display, When in flight, continuous depressionof the C/D TEST pushtile clears DD display and initiates BIST. Releasecausesthe DD to revertto tactical operation. When not airborne,the fmt depressionclears the DD display and initiates BIST; the seconddepression causesDD to revert to tactical operation. 38.5.1.3.5 Special Tests BIT. Initiated SPL TEST is designedto validate the operationof a specific radar submodeor subfunction,andis u&primarily for maintenancepurposes.Thesetestsareinitiated with selection of the SPL TEST pushtile on theBIT menu, selectionof the NBR pushbutton on the DD keypad, entering the appropriatetest number, and then pushing the ENTER button. 38.5.9.4 Test Target BIT. Thetesttargettimctionis a RIO activated and evaluated end-toend test of the radarsystem. It can be used to quickly verify that the radar system is capable of detecting, processing,and displayingreasonablysizedtargets.It is availablein, and can be usedto check the operationof low, medium, or high PRF tactical modes.Test target entry is indicated by a TT display on the lower let?position of the TID. I
ToinitiatetesttargetBITJ4FKpushtileonthedigital display is depressed,selecting the BIT menu The test target is selectedby depressingthe button adjacentto TEST TGT. To enablethe location for test targetinjection, the pushtile adjacentto RDM TGT or RCVR TGT is depressed.To terminate the test target BIT, the pushtile adjacentto the enabledtargetinjection location is reselected. 385.1 .J Continuous Monitoring. CM pericdically samplesmission essentialradarset signals during tacticaloperation,andinforrmrtheRIOofdetectedproblems. CM performs passive monitoring of key radar signals,at a onequarter-secondrate.These,signalsinclude power faults, overtemperatureindicators, BIST status (i.e., equipment ready) signals, processorload status, transmitterpeakpower,calibration failures,antennahydraulic interlocks, and transmitter interlocks. Radaranomaliesappearon the TlD, in the lower left quadrant,astwo characteracronyms.Acronyms will be displayedcontinuously while a failure condition exists. If multiple failures occur,the appropriateacronymswill be automatically updated at a 2-second rate. W’ :n an acronym is displayed, the RIO can select the CM maintenancedisplay to obtain more detailed information on the specific unit that hasa maltimction or anomaly. The RIO can also initiate BIT at any time to co&m that hardwarestatusis unchanged. Aircraft systemanomalieswill appearon the TID, in the lower leti quadrant directly below the radar CM acronyms,whenevera fault is detect& Corresponding failure acronymswill be displayedfor 2 seconds. 38.5.2 Radar BIT Operation. The radarBIT function is containedin theRDP. This specializedradarcomputer provides necessarytiming and control signals to F-14D radar subsystem to conduct various tests. BIT testingis generallyindependentof RIO interaction,with the exceptionof some mamud switch settings,such as thoseon the SHC, which arenot software controllable. BIT execution can be either automatic or operator initiated.Upon applicationof aircmtl radarpower, ORT is automatically initiated. The RIO either switchesthe SHC from OFF to CMPTR (to startCDM execution),or STBY or XMIT (to startORT execution).Afler powerup, CDMorORTmaybeabortedbypressingthePGMRST button on the lower right comer of the DD. If CDM/ORT is not aborted,ORT requireanominally 3.5 minutes to complete and CDM requims nominally 2.5 minutes to complete.
38-43
ORIGINAL
NAVAIR 0%Fl4AAD-1
Figure 38-25. Test-m-ProgressDisplay The test-m-progressdisplay is presentedon the TID (seeFigure 38-25).The WRA unit designatorsblink for those units that are undergoing test. Approximately 3 minutes afterradarturn-on,an XMT acronymat the top of the TID prompts the RIO to switch to XMT, if the SHC switch is in STBY. The RIO has 25 secondsto respond Failure to do so within the allotted time results in bypassingthe system transmitter test. If the RIO respondsin time, the transmitter test is executedandthe transmittersubsystemunit groupblii, indicating that testing is in progress.At the completion of ORT (and CDM) DhL4 is presentedon the TID. This display pmvides an evaluationof the working statusof the tactical modes.If the RIO desiresmore detailedinformation, the maintenancedisplay can be selectedby depressingthe DD pushtile adjacent to MAINT DEP. This display provides test fail or passstatus, the detectedmalfunctioning WRAs, and the associatedDPs. DPs provide specific detailed information on the faults detected within a particularunit. In orderto getback to the DMA display, the pushtile adjacent to MAINT DISP is reselected. 38.5.2.1 BIT Display Formats. BIT displays provide feedbackon test progress,required RIO actions, pass/fail status,detectedfaults, andmaintenanceaction recommendations.These displays include the test in pmgress,BIT menu, degradedmode assessment,mainORIGINAL
tenancedisplay, test target, CM, TCS test, DD BIST, displays test (static and dynamic), and specialtest. 38.5.2.1.1 Test-in-Progress Display. The testin-progressTID display is presentedupon initiation of ORT, CDM, or IRT (see Figure 38-25). This display provides statuson WRA testing progress,OBC, continuous monitor failures, missile channelselection,and the DPs from previousORT, CDM, IRT, or CM tests(if power wasnot interruptedto the radar).The appropriate WRA referencedesignatorsblii for units undergoing test.WRA designatorsandtheir correspondingcommon namesarelisted in Figure 38-26. At the completion of ORT, CDM or IRT, the degradedmode assessmentformat (describedin paragraph 38.5.2.1.3)is displayedon the TID. 38.5.2.1.2 BIT Menu Display Format. The DD BIT menu is presentedat the completion of ORT or CDM, and provides allowable RIO BIT test selections (seeFigure 38-27).The RIO can initiate the following tests t?omthis menu: displays test, radartest, TCS test, special test, or test target. These tests are initiated by depressingthe pusbtile adjacentto the desiredtestname on the DD. A highlighted box appearsaroundthe test nameon the DD to indicatethat a testhasbeenselected. Testscannotbe initiated concurrently.
38-44
NAVAIR 0%F14AAD-1
3. TWS -Track WRA ID# co4
4. PDSl-r -Pulse Doppler shlgle-targetuack
044
-
084
-
851 580
-
011 013 014
015 024 083 034
818 819 831
882 835 844 845
while mm.
Radar master oscillator (RMO) Radar transmitter (TX) Collector power supply (CPS) Beam power supply (BPS) Solenoid power supply (SPS) Radar receiver (RCVR) Radar antenna (ANT) Analog signal converter(ASC) Advanced Radar signal processor (ARSP) Advanced Radar data processor ww Digital display (DO) Tactlcal Information display (TID) Televlslon camera set (KS) Radome Interlock circuitry (RIC) Mission computer 2 (ME!) Mission computer 1 (MCI) Converter Interface unit (CIU) Sensor control unit (SW) Sensor hand control (SHC)
5. MRL -
Manual rapid lock-on.
6. PAL - Pilot automatic lock-on. 7. PSI-r-Pulse
singl&tget track.
8. RGSTT - Range-gated sin@etar@t
track.
9. VSL - Vertical scan lock-on. 10. PLM -
Pilot lock-on mode.
11. PS - Pulse search. ‘2. GM-Ground
map.
13. AGR - Air-to-ground ranging. 14. BIT-Built-m
test.
For a more detaileddescriptionof the pass/fail status of ORT, CDM, or IRT, the maintenancedisplay format (describedin paragraph38.5.2.1.4)is called up on the TID by depressingthe pushtile adjacent to MAINT DISP (on theDD BIT menu).The DMA display format is restored by reselecting the pushtile adjacent to MAINT DISP. Note After a tactical mode is entered,the DMA display format cannotbe restored.
Figure 38-26. WRA Common Names and Designators The BIT menu can also be accessedwhile the radar is in a tactical mode by depressingthe lvlFK pushtile to obtain the radarmode menu and then selectingBIT. 38.5.2.1.3 Degraded Mode Assessment Format. The display shown in Figure 38-28is provided on the TID at the completion of DMA. The purpose of DMA is to give the RIO an evaluation of the working statusof tactical modes.An acronym for eachmode is displayedon the TID anda pass(J), fail (X), degraded (O), or unevaluatedindication is presentedwith each acronym. The symbols that appearon the displays andthe correspondingmodesor fonctionnamedfor thebasic DMA arc as follows: 1. PDS - Pulse Doppler search.
38.5.2.1.4 Maintenance Display Format. The maintenancedisplay is obtainedby depressingthe DD BIT menu pushtile adjacentto MAINT DUP. It can be selectedduring displays test, a tactical radar mode, or specialtest.It can alsobeobtainedbytransitioning from the DMA display (describedin paragraph38.5.2.1.3). The maintenancedisplay provides test pass or fail status to the RIO. If no faults are detected,an RDR PASSED indication is displayednearthe top of theTID, no WR.4 designatorsare displayed, and a checkmark appearsadjacent to the appropriate test (see Figure 38-29). If a failure is detected,an RDR FAILED indication is displayed near the top of the TID, and the WRAs recommendedfor replacement,along with the associatedDPs, are displayed on the TID (see Figure 38-30). The WRA designatorsand their corresponding common namesarelisted in Figure 38-26.
2. RWS -Range while search. 3845
ORIGINAL
NAVAIR Ol-Fl4AAD-1
I
Figum 38-27. BIT Menu Display Format
J-
PASSED
0
-DEGRADED
X
-FAILED
BLANK
- UNEVALUATED
OBCCM ACRONYM FIELD DL ACRONYM FIELD NOTE:
THE MEDIUM PRF MODES RWS. TWS. RGSIT. MRL. PAL, PLM, VSL, AND THE PVU MODE REMAIN UNEVALUATED FOR OFP D61.
Figure 38-28. DegradedMode AssessmentFormat ORIGINAL
3046
NAVAIR 0%F14AAP1
Figure38-29.Maintenance DisplayFormat(TestComplete)
._.0
DEClSlON POINT ,DP,
NUMBERS \
i
3.7 0.34 044 004 034 0RT~008~157~326~349 \gT :;m:.“”
Yc
2 011
551
/
.i
Figure38-30. Maintenance Display(TestComplete) ORIGINAL
NAVAIR 0%F14AAD-1
I
Figure 38-31. Test Target Menu Detected failures are isolated to a maximum of six WRAs. A maximum of 10 DPs are displayedadjacent to the test that was performed: ORT, IBIT (radar test, displays test), or CM. Values for DS and PP for HPRF and LPRF modes are.displayed on the TID along with the AIM-54 or AIM-7 channelbeing tested. 38.8.2.1.8 Test-Target BIT. The test-target tiction is an end-to-endtest of the radar system, initiated and evaluatedby the RIO. It can be used to quickly verify thatthe radarsystemis capableofdetecting,pmcessing, and displaying reasonably sized targets. It is available in and can be usedto check the operation of I low, medium, or high PRF tactical modes. To initiate the test target, the DD MFK pushtile is usedto selectthe BIT menu. The test target is selected by depressingthe button adjacentto TEST TGT. The test-targetmenu is displayed on the DD (see Figure. 38-31). The test target can be injected in two places dependingon RIO switch activation.By depressingthe pushtile adjacent to RDM TGT, the target is injected throughthe radomeradartest horn and is receivedand processedthroughthe antennaarmy. By depressingthe pushtile adjacentto RCVR TGT, the target is injected
ORIGINAL
directly through the receiver, thus bypassing the antenna.To terminatetest targetBIT, thepushtile adjacent to the enabledtesttargetinjection location is reselected. The RIO can now select any tactical mode by de pressingthe DD pushtile for the desiredmode.The radar test target will be processedand displayed on the DD and TID just as any newly detectedtarget in the mode being testedwould be. In addition to testing the operation of the various modes,the test target can also be used to check many radarcontrols(suchas displaycontrols) andverify computer functions such as hooking. For example,the RIO can hook the test target (which fmt appearsas an unknown target) on the TID, designateit hostile (noting symbol change);initiate single-targettrack (noting operation of ANT and RDR indicator lamps); enter data pertaining to the target; a&even test the track hold function after deselectingthe test target. All targetshave nominal initial values inserted for range, range-rate, and target power level. I-IPRF targets
have initial rangeset to 20 miles and range-rateset to 800knots (closing). LPRF targetshave initial rangeset to 18miles, with the DD rangescalesetto 20 or greater, or 4.5 miles, with the DD rangescaleset to 5 or 10.
38-48
NAVAIR Of-Fl4AAD-I
Figure 38-32. ContinuousMonitor Display Targetpower level selectioncanbe enteredmanually a&r enablingtest-targetBIT. A power level is selected by depressingthe pushtile adjacentto TGT LVL and enteringthe following keyboardcommandsz Low values of X are correlatedwith weak target rcturns and allow for testing the radar%sensitivity. High valuesof X are correlatedwith strongtargetreturns. 38.5.2.1.8 CM Display Format. CM fault detection is an integral part of the tactical radar display. A two-characteracronym is displayed in the lower left quadrantof the TID whenever a fault is detected(see Figure 38-32). This acronym is continually displayed while the failure condition exists. If multiple failures occur, khre. ecmnyms will cycle at a 2-secondrate. The RIO can obtain more detailed failure information byaccessingtheBITmenuontheDD(depressinghfFK pushtile) and depressing the pushtile adjacent to MAINT DISP. The RIO canalsoinitiate BIT at any time to confii that the hardwarestatusis unchanged. Alistcon&ingthehvo-leneracmnymsthatmayappear asa resultof radarCM 5ilutes is shownin Figure38-33. Aircraft anomalieswill appearon the TID (lower left quadrantdirectly below the radarCM acronyms)whenevera fault is detected(seeFigure 36-33).All acmnyms
(exceptfor MM) appearfor 2 secondswhencorresponding equipmentis failed. The acronymMM overridesany previously displayedacronymfor 4 seconds.The conespondii acronym is masked when an equipment is maskedthroughthe MFDs. A list containing the OBCCM acronyms that may appearas a result of aircraft CM fbilums is shown in Figure 38-34. 38.5211 TCS Test Format ‘l-beTCS test is an RIOinitiated test of the TCS and associatedswitches. It is initiated by depressingthe DD MFK pushtile to obtain the radarmodesmenu,selectingthepushtile adjacentto BIT to obtainthe BIT submenu,andthen depressingthe pushtile adjacentto TCS. TCS testing is interruptible by a program restart (DD PGM RST pushtile), another BIT selection, or a radar mode selection. The TCS test tunction consistsof 15 major subtests, that occur in the following order:TCS on-boardcheckout, TCS cursor,manual acquisition, TCS slavedto radar, TCS returnto search,TCS slavedto radarpointing accuracytest, TCS slavedto computer pointing accuracy test, automaticsearch,TCS scanpatterntest,independentmode,radarslavedto TCS, radarslavedto TCS pointing accuracytest, handcontrol forward right, hand control half-action,and TCS slewing test. ORIGINAL
NAVAIR QI-Fl4AAD-I EQUIPMENT
CRONYM
\CRONYM
BB
Computer 409)
BF
TID buffer overload (DP 283)
CA
Calibration failure (DPs 418-421 426)
CB
Computer bus status word error (DPs 32, 34, 38, 38)
cc
No sparrow CW channels available (DP 373)
MX
bus backup enabled (DP
CS
RDP CPU checksum
CW
CW power failed to turn off or below acceptable levels (DPs 354, 380)
cx
Data check WMX CPUl, capacitor voltage error, or data check WMX CPU2 (DPs 4,10,13)
DD
DD CM function fault (DPs 273,274, 276-280.282,284) Display power fault (DD, TID, SCU) (DPs 394,395,396)
DR
DD RAM checksum
ER
Equipment 410-415)
FA
No frequency agility channels available (DP 374)
HI
Antenna hydraulics on interlock open (DP 288)
error (DP 275)
ready failure (DPs
HS
RSP.clock error (DP 51)
MM
Missed missile (AIM-54)
message
EQUIPMENT
1RMX status word error (DPs 40.42. 44)
OA
ORT has been aborted
OH
Overheat (RMO, RX, DD, RDR RSP ASC) (DPs 184,198,272,397,398, 399)
PH
No PHX channels available (DP 371)
PL
RSP load error (DP 96)
PM
APG-71 liquid cooling pump failure (DPs 327,331)
RO
RMO status word error (DP 176-183)
RP
Radar power fault (Rx, ARSR RMO, ANT, ASC, TX) (DPs 197,385,386, 387. 388, 390)
SA
Semi-active
SI
TID SSI parity error (DP 47)
SP
No sparrow PD channels available (DP 372)
TT
Test target switch enabled (DP 377)
XL
XMTR dummy load switch failure (DPs 338-338,340)
XM
XMTR peak power output below minimum acceptable or XMTR is not selected (DPs 352,353)
x0
Selected XMTR channel is not phase locked (DPs 185,189,190)
x-r
Transmitter subsystem failure (DPs 320-328,328-330.332-334)
error (DPs O-3)
DP
1
Figure 38-33. RadarContinuousMonitor Acronyms ORIGINAL
38-50
decoder error (DP 187)
NAVAIR WF14AADI OBCCM ACRONYM AFC
OBCCM ACRONYM IR
EQUIPMENT Automatic flight control system
EQUIPMENT Infrared search and track system
AIC
Air inlet control system
MC1
Mission computer
no. 1
APC
Approach
MC2
Mission computer
no. 2
BAG
Beacon augmentor
MFA
Multiple filter assemblies Right)
BSF
Band suppression
MFD
MFD no. 1, MFD no. 2, or MFD no. 3
BUS
Data bus NPS
Navigation power supply
CAD
Central air data computer PDP
CIU
Converter interface unit
Display processor processor no. 2
DEU
Data entry unit
POD
patcal
DLS
Data link system RAD
Radar altimeter
RFP
Radio frequency indicator
DSS
power compensator
(Left or
filters
no. 1 or display
airborne reconnaissance
Data storage set -Pilot
ECM
Airborne self-protection
RFR FEM
Airborne data acquisition computer, engine monitoring signal processors 112
Radio frequency -RIO
RWR
Radar warning receiver
GCU
Gun control unit
SDI
Sensor display and indicator set
HUD
Head-up
SMS
Stores management
IFB
Interference
SRS
Standard attitude and heading reference set
IFI
IFF interrogator TCN
Tactical air navigation
wow
Weight-on/off-wheelssensor
IFX INS
jammer
display blanker
control indicator
system
IFF transponder Inertial navigation system (BLANKS)
No system failures
Figure 38-34. OBC ContinuousMonitor Acronyms
38-u
ORIGINAL
NAVAIR 01.F14AAD-1
When theTCS testbegins,thedisplayinFigure38-35 shall appearon theTID. The TCS test-in-progressmenu consistsof acronyms denotingthe conditions of the associated TCS test function subtest. The RIO has 15 secondsto supply the indicated action for eachprompt. Figure 38-36 containsa list of the prompts and associatedRIO responses. 38.5.2.1.8 Digital Display Controls and Dlsplays Test (C/D Test). The DD has a standalone built-in self-test capability that must be initiated and evaluatedby the RIO. It tests DD functions as well as its discrete interfaceswith the sensorhand control and TlD. C/D test is initiated with the DD radarcontrol panel C/D TEST pushtile. When the F-14D is airborne,continuous depressionof the C/D TEST pushtileclearsDD display andinitiates test.Releasecausesthe DD to revert to tactical operation. When the F-14D aircraft is not airborne,the fmt depressionclearsthe DD display and initiates test;the seconddepressioncausesDD to revert to tactical operation. While the C/D TEST pushtile is depressed,a diagonal line should be displayed on the TlD. After the C/D TEST is selected,the DD display will appearas shown in Figure 38-37.Adjust DD BRT and CONT controls for optimal viewing of the eight displayed shadesof gray. Adjust the SYM control for best display of stroke symbology. From this display, three separatetestsmay be selectedby pressingthepushtiles (along the left edgeof the DD display) next to the legends(1,2, and 3) displayedon the CRT. a. CID TEST 1 Display. WhenUDTEST 1display is selected,the backgroundwill be shadesofgray. Right to letI sweepsstart as soon as the display appears,with each sweep diminishing the intensity of the shadesof gray (aging). Afler 13 sweeps,the shadesof gray will have disappeared(the backgroundwill be uniform). C/D 1 test is used to test all front panel momentary pushtiles. As each of the DD front panel momentary pushtilesare depressed,an X appearsat the appropriate location on the CD TEST 1 display (seeFigure 38-38). Note Depressingthe C/D TEST pushtile will exit C/D TEST. Depressingthepushtile adjacent to legend 2 or legend 3 will exit C/D 1 and initiate C/D 2 or C/D 3.
ORIGINAL
b. CID TEST 2 Display. When C/D TEST 2 is selected,the display shown in Figure 38-39will appearon the DD. The numeric values next to BRT, CON, and SYMmaydifferslightlyfromthoseshownintheFigure, dependingon knob position. CID TEST 2 tests all t?ont panel toggle and rotary switches and potentiometers.As each of the SNIFF, TGT, TRACK, andMLC switchesaretoggledinto their allowablepositions,an Xwill be displayedin theappropriate location. Rotating the CHAN, FA/MAN, and JAM/JET switches into their allowable positions will causecorrespondingsymbology changeson the panel for the selectedswitch position. Rotating eachpotentiometerthrough its 111 movement rangewill display a correspondingdecimal numberthat will vary from 00 to lOto9Oto99. c. C/D TEST 3 Display. When C/D TEST 3 is selected,the DD display shown in Figure 3840 will appearThisdiqlayteststhecapabiityoftheDDtoreqmd tosignals~minterfacing~~andtoothersignals.when theSHC RDR switch is setto CMPTR, andthecommands showninFigure3841amissuedbytbeSCU,SSP,orDD, theindicatedresponsesaredisplayednexttotheassociated C 3 displaylegends.The SHC RDRCMPTR selectionalso enablestestsinitiatedby otherSHC controlsandTlD conMs. Selectionsandmponses areshownin Figures3842 and38-43,mspectively. 39.5.2.1.9 Display Test Formats. The displays test gives the RIO standardtest patternson the TID and DD for evaluation.The displaystestis divided into static and dynamic testing. It is initiated by depressingthe MFK pushtile on the DD to obtain the radar modes menu, selecting the pushtile adjacent to BIT to obtain the BIT submenu,and then depressingthe pushtile adjacent to DISP. a. Static Testlng. When A’lTK is selectedwith the TID MODE switch, the DD ANT, RDR, JAT, andTCS indicator lamps will illuminate. The TID LAUNCH ZONE, VEL VECTOR, and CLSN indicator lamps will illuminate. ‘lhe TID centerdrum and steeringdrum will beblank. The testpatternshown in Figure 38-44will be displayedon the DD, and the pattern shown in Figure 38-45will be displayedon the TID. When A/C STAB or GND STAB is selectedwith the TID MODE switch, all DD indicator lamps will go off. In addition, all TID indicator lamps will go off, the TID centerdrum will read SENSOR, and the steeringdrum will read MAN. The DD test pattern shown in Figure 38-46 will be displayed, and the TID will display the patternshown in Figure 3847.
38-52
TCS IN PROGRESS TCS CURSOR MAN AC0
4
TCS SLV RDR
J 4
TCS
HALF-ACT
J
RDR
SLV TCS
d
=
PASS
x
=
FAU
Figure 38-35. TID Menu for TCS JBIT, In Progress RIO RE PONSE
1
PROMPT DISPLAY ON TlD TCS CURSOR
UNIT Sensorhand control
ACTION SelectTCS cursor
1MAN ACQ
Digital display
DepressTCS MAN pushtile
1TCS SLVRDR
Sensorslaving panel
Select TCS slave
TCS HALF-ACT
Sensor hand control
Select half action and release
AUTO SRCH
Dlgltal display
DepressTCS ASCH pushtlle
1INDEP
Sensorslaving panel
SelectTCS IND
1RDR SLVTCS
Sensor
slaving panel
Select RDRslave
HCFWDRT
Sensor hand control
Positionhand controlto upper right comer
,HC HALF-ACT
Sensorhand control
Select half a&on, malntalnlngHCN In upper rlght comer
Figure 38-36. TCS BIT Prompts and RIO Responses
38-53
ORIGINAL
I
. .
I
Figure38-38.C/D TEST1Display(After AgingIs Completed) ORIGINAL
NAVAIR Of-WIAAD-T
I
Figure 38-39. C/D TEST 2 Display
ETH 7
I Figure 38-40. CID TEST 3 Display 38-55
N2lE
ORIGINAL
NAVAIR
0%FUAAD-I
SW CONTROL/SELECTION STAB/IN STAB/OUT FOV/WlDE FOWNAR TCS TRIM/A2 TCS TRIM/EL AZ SCAN/flO” AZ SCANkt20° AZ scANlf4o~ AZ SCANkkS5” EL EL EL EL
BARS/l BARS12 BARS14 BARS10
SSP CONlROL/SELECTlON SLAVEIRDR SLAM/INDEP slAvErrcs
SHC CONTROUSELECTlON
DD RESPONSE
DD RESPONSE
HC MODE/IR/lV
IRrrV
HC MODEIRDR
RDR
IN OUT WlDE NARROW -22to +22 -44to
+44 10 20 40 85 1 2 4 8
DDRESPONSE
HC MODE/TlD CURSOR
TlD CURSOR
HC MODEIDD CURSOR
DD CURSOR
HANDGRIP ACTlON SWlTCH/ (NO DETENT)
NO
HANDGRIP ACTION SWlTCH/ (FIRST DETENT)
HALF
HANDGRIP ACTION SWTTCH/ (FULL DETENT)
FULL
HCX (HANDGRIP) LEFT/RIGHT
-99 to +99
HCY (HANDGRIP) FORE/AFT
-99 to +99
RDR INDEP TCS
DDRESPONSE
MRL
X
ACCIIMAN
AUTO SEARCH MANUAL
OFFSET
X
ACQ/AUTO VSUHI VSUOFF
AUTO HI OFF
DD CONTROL/SELECTION
ACCVAUTOSRCH
vsl.no
Figure 38-42. DD Responsesfor SHC SelectTests
Lo
TID CONTROL/SELECTION
Figure 38-41. DD Responsesfor SCU/SSP/DD SelectTests
DD RESPONSE
TRACK HOLD
X
TlD MODErm
C
Figure 3843. DD Responsesfor TID SelectTests
ORIGINAL
38.58
NAVAIR 01.F14AAD-1
2
TCS
INSTR
o2 -
MAIN1 DISP
SPL TEST (NBR)
4
6
L, I
AL
BIT SPF ‘3
6
\
22999
TGT
TCS
-
Figure 384.
BIT Static DD Display (ATTK Selected) 38-57
ORIGINAL
NAVAIR 01.FUAAD-1 T*PE CONFIO”R*T,ON N”hf.sER ,INFORMATION FOR LOCATlON ONLY, TARGET CURSOR SYMBOL VELOCITY VECTOR CENTROIO DOT
ARTlFlCAL HORUON
STEERIN SYMBOL
SYMBOL
Figure 38-45. BIT Static TID Display (ATTK Selected) These test patternsshould be examined by the RIO for the absenceof any requiredsymbols, symbol intensity, and symbol position. During the running of the static test, the RIO should also selecthalf action or fall action on the hand control. The RIO shouldensurethat the TID cursor can be moved throughoutthe range of the TID by moving the handcontrol.Upon releaseofthe action switch, the cursorsymbols shouldreturnto their original positions.
sizeor position. A fixed initial point symbol is displayed for reference.To enterthe dynamic test,the RIO selects CLEAR, NBR, 1, 1, and ENT on the DD keypad. When the RIO selects ATTIC with the TID MODE switch, the displayson the TlD and DD (Figures38-38 and 38-39) will go through the following movements every 2 seconds: On the DD, the following occur simultaneously:
The static portion of the displays test gives the RIO an indication that the computer doesor doesnot have the display capability for each of the indicated symbols. It is more than a displays test becauseit also tests computer ability to generate symbols needed for a tactical situation. The computer assiststhe RIO in the static portion of the displays test by monitoring power failures that haveoccurred in the controls anddisplays units. A DISP FAILED indicator will appearon the maintenance display if a power failure is detected. The maintenance display indicates DISP PASSED until a failure occurs. b. Dynamic Testing. The dynamic test consists of a visual evaluation of the movement of the artificial horizon, ASE circle, steeringsymbol, closing rangerate indicator, launch zone symbols, and a velocity vector with MUIR andTUOR markersthat sequentiallyvary in ORIGINAL
2. The artificial horizon stepsin roll 6om O” to +15’ (right wing down), +30°, +45“, backto O”,-lSO(leI? wing down), -30°, -45’, and back to 0’. 3. The ASE circle stepsfrom 0.8 inch in diameterto 0.1,0.3,0.56,thenbackto0.8. 4. The steeringsymbol stepsaroundthe ASE circle in a clockwise direction in stepsfrom its position in the upper right quadrant to the lower right, lower left, upper left, thenback to the upperright quadrant.
NAVAIR 0%Fl4AAD-1
HALF
OR FULL ACTION
NOT SELECTED
TWS A
RDR
4
1,
2
INSTR 12
6
MAINTDISP
SPL TEST (NBR)
4
BIT PHC I
. \ AZIMVT”
TIC MARK
SCANS
6
Figure 3846. BIT Static DD Display (GND STAB or TV Selected)(Sheet 1 of 2) 30-59
ORIGINAL
HALF OR FULL ACTION NOT SELECTED
200 GM NCTR MAN
TEST TGT
SNIFF
INS-W
SPL TEST (NBR)
BIT 1234
HALF OR FULL ACTION SELECTED
20GM NCTR MAN
SNIFF +/h\
+
+
INSTR
SPi TEST WJBA)
BIT G
Figure38-46.BIT StaticDD Display(GND STABor TV Selected) (Sheet2 of 2) ORIGINAL
38-80
NAVAIR
0%F14AAD-1
.iLl III64 w’
RRIGHT RI INKS N
W+
E
S
Figore 38-47. BIT Static TID Display (Non-ATTK Selection) 7. The velocity vector will vary in length from 1.5
On the TID, the following occur simultaneously: 1. The artificial horizon stepsin pitch t?om zero to +150 (up), +300,+45q 00, -150(down), -300,-450 thenback to 0”. 2. The artificial horizon stepsin roll hrn 0” to +15’
(right wing down), +30”, +45O,back to 0’. -15’ (left wing down), -30°, -45’, and back to 0”. 3. The bar marker steps fmm 1.5 inches above the
ratiticial horizon to 1.0, 0.5, 0, and back to 1.5 inches. 4. The dot marker steps from above the artificial to 0.5, 1.0, 1.5 inches and back to the artificial horizon.
inchesto 0 inches,0.5 inches,1.Oinches,thenback to 1.5inches. 8. TheF-14baroxiginwillvaryits distanceabovethe artificial horizon along the velocity vector 6om 1.5inchesto 1.0 inches,0.5 inches,0 inches,then back to 1.5 inches. 9. The additional dot marker will vary its distance abovethe artificial horizon along thevelocityveotor from 0 to 0.5 inch, 1.0 inch, 1.5 inches,then back to 0 inches. The eventsoccuning during the dynamic portion of the test are repeateduntil the RIO selectsanotherBIT sequencetest, selectsanothercategory,interruptsvia a programrestat$or selectsanotherradarmode.
5. The artificial horizon, ASE, and steering symbol move on the TID at the samerate as the DD. 6. The ASE circle stepsfrom 2.0 inches in diameter
to 0.2,0.8,1.4, thenbackto 2.0 inchesin diameter.
38-61
When the RIO selectsA/C STAB or GND STAB with the TJD MODE switch, thedisplayson theTID and DD will go through the following movements every 2 seconds.
ORIGINAL
NAVAIR 0%FMAAD-1
Figure3848. BIT DD DynamicDisplay Dynamictest in A/C STABandGND STABwill havedisplayssimilarto thoseshownin Figures38-48 and38-49,exceptthatATTK will blink abovetheBIT horizontalboundary,andthe artificial horizon,ASE circle,and steeringsymbolwill be deleted.A DISP FAILED message will appearon the TID duringthe staticor dynamictestswhena faultis detected.A fault isolationdisplaycanberequestedby depressing the pushtileadjacentto MAINT DISP on the DD BIT menu.If a power fault or computersubsystemfault wasdetected,theunit designator ofthe malfunctioned WRA is displayedalongwith the associated DPson theTID. 38.5.2.1.10 Special Test Format. Specialtest is
initiatedviathe selectionof theSPLTESTpushtileon theBIT menu,selection of theNBR pushtileontheDD keypad,enteringtheappropriate testnumber,andthen pushingtheENT pushtile.Testexecutionis continual whilespecialtestis selected. Testingis interruptiileby aprogramrestart(by depressing PGMRSTontheDD), anotherBIT selection, or radarmodeselection.
theRDPandRSP,respectively, andtheinterfaceto the datarecorder.Whencommanded by this function,inStrrnnentationmodutesintheRDPandRSParew~~ to outputrepeatable testpatternsto the ins!rumentation recordem. Faihaeindications aredetermined by analysis of theserecordingsofllme. The displayis shownin Figure38-50. Flycatcheris acomputerroutine thatallowstheopemtorto examinethecontentsof spe cific RDPmemorylocations.Thisinformationis generallyusedin troubleshooting. Flycatcher readouts will be displayed on theupperleft portionof theDD. Thedisplaywill consistof the computerdesignation readous address readout,anddatareadout(in hexadecimal).
38.5.3 Flycatcher.
To initiatethesereadouts,thefollowingsequence of entriesontbeCAPportionof theDD mustbeused:
Thespecialtest 804nstrumentation testverifiesthe properoperation of theAPG-71instminemation system. ThissystemincludestheIST andICIJ moduleswithin ORIGINAL
38-82
1. CLR 2. 7 3. 1 4. Em.
NAVAIR QI-Fl4AAD-1
Figure 38-49. BIT Dynamic TID Display (ATTX. Selected)
SPL TEST IN
Figure 38-50. Special Test SO-hstnmentdion Test ORIGINAL
A computer number of 1 selectsthe RDP memory, currently the only valid selection. Next, a hexadecimal memory addressmust be enteredin the following sequence:
1. CLR 2. I 3. s-w
1. 9 4. ENT. 2. 0 If an increment is performed, and no further CAP selectionshave been made, subsequentincrementsor decrementscan be made by simply pressingthe ENT pushtile repeatedly.
3. l-to S-digit hex address 4. ENT. The flycatcherhasthe capability to incrementor decrement the displayed address.To increment the displayedaddress,the following sequencemust be entered:
The flycatcher is turned off with the following CAP sequence: 1. CLR
1. CLR 2. 7 2. 7 3. 0 3. N+E 4. m. 4. Elm. To decrementthe displayed address,the following sequencemust be entered:
ORIGINAL
38.84
NAVAIR Ol-FUAAD-1
PART X
NATOPS Evaluation Chapter39 - NATOPS EvaluationandQuestionBank
93 (ReverseBlankj
ORIGINAL
CHAPTER
39
NATOPS Evaluation 39.1 NATOPS EVALUATION PROGRAM 39.1 .l Concept. The standardoperatingprocedures prescribedin this manualrepresentthe optimum method of operating the aircraft The NATOPS evaluation is inter&d to evaluatecompliance with NATOPS proceduresby observingand grading individuals and units. This evaluationis tailored for compatibility with various operationalcommitments and missions of both Navy and Marine Corps units. The prime objective of the NATOPS evaluationprogram is to assistthe unit commanding otXcer in improving unit readinessand safety throughconstructivecomment. Maximum benefit from the NATOPS program is achievedonly through thevigorous supportof the program by commanding officers aswell asby flightcrcwmembers. 39.1.2 Implementation. The NATOPS evaluation program shall be carried out in every unit operating naval aircraft. The various categories of flightcrewmembersdesiringto attainandretainqualification in the F-14D shallbe evaluatedinitially in accordancewith the currentOPNAV Instruction 3710,andat least onceduring the 12 months following initial and subsequent evaluations,Individual and unit NATOPS evaluations will be conductedannually; however,instruction in and observationof adherenceto NATOPS proceduresmust be on a daily basiswithin eachunit to obtain maximum benefitsfrom the program. The NATOPS coordinators, evaluators,and inr4tuctorsshall administerthe program asoutlined in the currentOPNAVINST 3710.Evaluees who receivea gradeof Unqualified on a groundor flight evaluation shall be allowed 30 days in which to complete a reevaluation.A maximum of 60 days may elapse betweenthe date of the initial ground and flight evaluationandthedatethatqualification is satisfactorily completed. F-14A/A(PLUS) NATOPS evaluationscsn be accomplishedduring the same evaluation flight, provided the currency requirementsfor eachmodel establishedinChaptcr5aremet.Thercsultswillberccorded ontheNKfOPSeval~onreport(OPNAVForm3710/T).
39.1.3 Deflnltlons. The following terms, used throughoutthis chapter,are detined below as to thcii specific meaningwithin the NATOPS program. 39.1.3.1 NATOPS Evaluation. Aperiodic evaluation of individual flightcmwmembers standardizationconsisting of an open-bookexamination, closed-bookexamination,oral examination, and flight evaluation. 39.1.3.2 NATOPS Reevaluation. A partial NATOPS evaluationadministeredto a flightcrewmember who has been placed in an Unqualified status by receiving an Unqualified grade for any ground examination or for the flight evaluations.Only thoseareasin which an unsatisfactory level was identified need be observedduring a reevaluation. 39.1.3.3 Quallfled. The evaluationtermappliedto a flightcmwmember who is well standardizedand who demonstrateshighly professional knowledge of and compliance with NATOPS standardsand procedures. Momentary deviations from or minor omission in noncritical areasare permitted if prompt and timely remedial action was initiated by the evaluee. 39.1.3.4 Conditionally Quallfled. The evaluation term appliedto a tLightcrewmcmberwho is satisfactorily standardized,who may have made one or mom signiticant deviations Tom NATOPS standardsand proceduresbut madeno errorsin critical areasand no errors jeopardizing mission accomplishmentor flight safety. 39.1.3.5 Unqualified. The evaluation term applied to a tlightcmwmember who is not acceptably standardized,who failed to meet minimum standardsregarding knowledge of and/or ability to apply NATOPS procedute.s,or who madeoneor more significant deviations from NATOPS standards and procedures that could jeopardize mission accomplishment or flight safety. 39.1.3.0 Area. An area is a routine of preflight, Sight, or postflight
39-1
ORIGINAL
NAVAiR 0%Fl4AAD-1 39.1.3.7 Subarea. A performance subdivision within an areathat is coveredand evaluatedduring an evaluationflight
fiightcmwmember in an aircraft and admiistering appropriatequestions. 39.2.7 Grading instructions. Examinationgrades shall use a 4.0 scale and be convertedto an adjective gradeof Qualified or Unqualified.
39.1.3.8 Critical Area and Subarea. Any areaor subareathat covers items of significant importanceto the overall mission requirements,the marginalperformanceof which wouldjeopardizesafeconductof the flight.
39.2.7.1 Open-Book Examination. To obtain a gradeof Qualified, an evaluecmust obtain a minimum scoreof 3.5.
39.2 GROUND EVALUATION Prior to commencingthe flight evaluation,an evaluee must achieve a minimum grade of Qualified on the open-bookand closed-bookexaminations.The oral examination is also part of the groundevaluationbut may be conductedas part of the flight evaluation.To assure a degreeof standardiition betweenunits, theNATOPS instructorsmay usetheaank of questionscontainedin this chapterin preparingportionsof tire writtenexaminations. 39.2.1 Open-Book Examination. The open-book examination shall consist of, but not be limited to, the questionbank. The purposeof the open-bookexamination portion ofthe written examinationis to evaluatethe flightcrewmember’s knowledge of appropriatepublications and the aircraft. 39.2.2 Closed-Book Examination. The closedbook examination may be taken from, but shall not be limited to, the questionbank andshall include questions concerningnormal and emergencyproceduresand aircraft liiitations. Questionsdesignatedcritical will be so marked. 39.2.3 Oral Examination. The questions may be taken t?om this manual and may be drawn from the experienceof the instructor-evaluator.Such questions should be dimct and positive and should in no way be based-solelyon opinion.
39.2.7.2 Closed-Book Examination. To obtain a gradeof Qualified, an evalueemust obtain a minimum scoreof 3.3. 392.7.3 Oral Examination and MFTand WSTPro cedum Check (if Conducted). A gradeofQualifiedor Unqualified shall be assigned by the instructorevaluator. 39.3 FLIGHT EVALUATION The flight evaluationmay be conductedon any routine syllabusflight with theexceptionofflights launched for FCLP andCARQUAL or ECCM training. Emergencies will not be simulated. The number of flights requiredto completethe flight evaluationshould be kept to a minimum, normally one flight. The areasandsubareasto be observedandgraded on a flight evaluationareoutlined in thegradingcriteria with critical areasmarkedby an asterisk(*). Gradeson subareaswill be assignedin accordancewitb thegrading criteria. Gradeson subareasshall be combinedto arrive at the overall grade for the flight. If desired,gradesof areasshall also be determined in this manner. At the discretionof thesquadronor unit commander,theevaluation may be conductedin WST, MFT, or COT.
39.2.4 Emergency. An aircraft component or system failure or condition that requiresinstantaneousrecognition, analysis,and properaction. 39.28 Malfunction. An aircraft componentor system failure or condition that requires recognition and analysis,but which permits more deliberateaction than that requiredfor an emergency. 39.2.8 MFT and WST Procedures Evaluation. An MFT and WST may be used to assistin measuring the flightcrewmember’s efficiency in the execution of normai operatingproceduresand reaction to emergencies and malfnnctions. In areasnot coveredby the OFT and WST facilities, this may be done by placing the
ORIGINAL
39-2
39.3.1 instrument Flight Evaluation. Annual NATOPS instrumentflight evaluationsandtheIFR portions ofNATOPS flight evaluations,whetherconducted in flight or in an approvedsimulator,must be conducted by a NATOPS-qualified pilot or RIO, who is designated in writing by the unit commanding officer. Suchinstrument fliaht evaluations must be conductedin accordance w;h the procedures outlined in the current OPNAVINST 3710. 39.4 OPERATIONAL DEPLOYABLE SQUADRONS Pilots and RIOs assignedto operationaldeployable squadronswill normally be checkedas a team,with the flight evaluationbeingconductedby thecheckcrewflying
NAVAlR 0%FI4AAD-1 wing. RIO commentarywill be transmitted on the GCI or CIC control tkequencyin use.
2. Takeoff (pilot) 3. Transition to climb schedule.
395 TRAlNlNG AND EVALUATlON SQUADRONS 39.6.4 Climb and Cruise Units with training or evaluation missions that are concernedwith individual instructorpilot or RIO standardization rather than with team standardizationmay conductthe flight evaluation with the checkcrew-pilot flying wing or on an individual basis. A pilot may be individually checkedwith the instructor-evaluatorconductingthe ilight evaluationfium the rear seat.The RIO may beindividually checkedby flying with theimtmctorevahtatorasthe pilot.
1. Departure(pilot) 2. Climb and level-off (pilot) 3. Proceduresen route @ilot) (*) Approachand landing 4. Radar,tacan(pilot)
39.6 FLIGHT EVALUATIONS 5. Recovery(Pilot). The areas and subareasin which pilots and RIOs may be observedand graded for adherenceto standardized operating proceduresare outlined in the following paragraphs.
39.6.5 Communlcatlons 1. Receiving and tmnsmitting pmcedmcs (pilot and RIO)
Note If&sired units with training missions may expandtheflight evaluationto include evaluation of standardixedtraining methods and techniques.
2. Visual signals (pilot and RIO) 3. IFF and SIP procedures(RIO).
(*) The IPR portionsof the flight evaluation shall be in accordance with the procedure outlined in the NATOPS Instrument Flight Manual.
39.6.6 (‘) Emergency and Malfunctlon Procedures. In this area,the pilot andRIO will be evaluated only in the caseof actualemergenciesunlessevaluation is conductedin the COT, WST, or OPT.
39.6.1 Mission Planning and Briefing
39.6.7 Posffllght Procedures
1. Flight plamting (pilot and RIO)
1. Taxi in (pilot)
2. Briefmg (pilot and RIO)
2. Shutdown(pilot and RIO)
3. Personalflying equipment(pilot and RIO).
3. Impection and records@dot andRIO)
39.6.2 Preflight and Llne Operations. Inasmuch aspreflight and line operationproceduresaregradedin detail during the ground evaluation, only those areas observedon the flight checkwill be graded.
4. Flight debriefmg (pilot and RIO).
1. Aircraft acceptance(pilot and RIO)
39.6.6 Mission Evaluation. This area includes missions coveredin the NATOPS flight manual, F- 14D tactical manual, and naval warfare publications for which standard&d procedures and techniques have beendeveloped.
2. start
39.7 RECORD AND REPORTS
3. Before-taxiing procedures(Pilot).
A NATOPS evaluation report (OPNAV Form 371017)shall he completed for eachevaluationand forwarded to the evaluee’s commanding officer only. This report shall be filed and retained in the individual’s NATOPS jacket. In addition, an entry shall bc
39.6.3 Taxi and Runup (2) Takeoff and transition 1. ATC clearance(pilot) 39.3
ORIGINAL
NAVAIR 0%Fl4AAD-1 ofs&areasgraded.Theadjectivegradeshallthenbe determinedon the basis of the following scale.
made in the pilot’s and RIO’s flight logbooks under “Qualifidons and Achie.vement.3”as follows: GUAUFICAltON
DATE
NATOPS EVALUATION (Aircmfl hbdel) (Crew Position)
1. O.Oto2.19-Unqualified
SIGNATURE
2.2.2 to 2.99-Conditionally
(Authenticating signature) I
3. 3.0 to 4.0 - Qualified.
(Unit that administered avalualion~
Example (addsubareanumerical equivalents): 4+2+4+2+4 5
39.7.1 Critique. The critique is the terminal point in the NATOPS evaluation and will be given by the evaluator-instructor administering the check. Preuaration for the critique involves p&es&g, reconstructing datacollected,andoral presentationof theNATOPS evaluation report. Deviations from standardoperating procedureswill be coveredin detail using all collected dataandworksheetsas a guide.Upon completion of the critique, the pilot and RIO will receive the completed copy of the NATOPS evaluationreport for certification and signature.The completedNATOPS evaluationreport will then be presented to the unit commanding officer.
16 = r = 3.20or Qualified
39.8.2 Flnal Grade Determination. The final NATOPSevaluationgmdeshallbethesameasthegrade assignedto the flight evaluation. An evalueewho receivesan Unqualified on anygroundexaminationor the flight ~aluati~shallbeplaced~~Unq~li~~s~~ until a gradeof Conditionally Qualified or Qualified is achievedon a reevaluation. 39.9 APPLICABLE
PUBLICATIONS
The NATOPS flight manual contains the standard operationscriteria for F-14D aircraft. Publications regarding environmental procedurespeculiar to shorebasedandshipboardoperationsandtacticalmissionsare listed below:
39.8 FLIGHT EVALUATION GRADING CRITERIA Only those subareasprovided or required shall be graded.Thegradesassignedforasubareashallbe.determined by comparing the degree of adherenceto standardoperating pmcedmes with adjectival ratings listed below. Momentary deviations fiom standardoperatingproceduresshould not be consideredasunqualifying provided such deviationsdo not jeopardize flight safetyand the evalueeappliedprompt correctiveaction.
1. F-14D tactical manuals 2. NWPS 3. NATOPS Air Refueling Manual
39.8.1 Flight Evaluation Grade Determination. The following procedureshall be used in determining the flight evaluation grade.A grade of Unqualified in any critical area and subareawill result in an overall grade of Unqualified for the flight. Otherwise, flight evaluation(or area)gradesshallbe de&mined by assigning the following numerical equivalentsto the adjective gmdeforeachsubareaOnlythenmneralsO,2,or4will be assignedin subareas.No interpolationis allowed. 1. Unqualified - 0.0 2. Conditionally Qualified - 2.0 3. Qualified - 4.0. To determinethe numerical gradefor each areaand the overall grade for the flight, add all the points assignedto the subareasanddivide this sumby thenumber ORIGINAL
Qualified.
39-4
4. Air TratFo Control NATOPS Msnual 5. LocalAirOperationsManual 6. Carrier Air OperationsManual. 39.10 NATOP!5EVALUAT0NQUEgTiON
BANK
The following bank of questionsis intendedto assist theunitNATOPS instructor-evaluatorinthepreparation of ground examinations and to provide an abbreviated study guide.The questionsfrom the bank may be combinedwith locally originatedquestionsin tbepreparation of ground examinations. The closed-bookexamination will consist of not less than 25 questionsnor more than 75 questions.The time limit for the closed-bookexamination is 1 hour and 30 minutes. The requirementsfor the open-bookexaminationarethe sameas thosefor the closed-bookexamination, exceptthere is no time lit.
NAVAIR 01.F14AAD-1 NATOPS EVALUATION QUESTION BANK 1. Theaimraftweighsappmximately 2. Theaircraftis
includingtrappedtiu& oi&Bun,PilokendRIO.
inlongthandhasawingspanof
at2ood
in oversweep.
3. TheL INLET andR LNLETcautionlightsindicate 4. Duringnormalsystemoperation,thestatusof AICSrampcontrolis asfollows: SPEED
RampHydraulicPower
Mc0.35
ON/OFF
Restrained by
M 0.35to 0.5
ON/OFF
commanded
M>O.S
ON/OFF
Pmgrammed asa timtion of
5. An AICSfailurethatcauses illuminationof anINLET and/orRAMPcautionlightresultsin thefollowing: SpeedRange
RampResultant
M > 0.9 6. DuringtheAICSportionof OBC,simulatedvariantflight conditionscyclethe theirfull rangeof operationin aboutseconds. Thisexercises the andensures
through
7. Operationof theL andR AICS is completelyindependent a. True b. False 8. AICSanti-iceis availablebetween
Machand
Mach.
9. With thegearhandledownandoneor momrampsnot inthe stowposition,theramplightwill beilluminated.
I
a. True b. False 10. Theinstalledthrustof the Fl lo-GE-400engineis MAXAA.
poundsat MRT and
11. In SEC mode,both main enginefuel flow and compressorVSVsam scheduled , andfan speedis liited by the
poundsat by the
12. A 3percentincreaseinwindmillrpm canbeachieved by selecting 13. Nonemergency selectionof theSECmodeshouldbeperformedin 39-5
ORIGINAL
NAVAIR 01.F14AAD-1 14. The augmenterfan temperatamcontrol systemregulatesfive parametersof the engineto provide stall-free operationfor any rate of throttle movement thmughoutthe flight envelope.Theseparametersare: a.
d. e. 15. The engine electrical control subsystemis poweredby an enginegearbox-mounted(ac or dc) alternatorthat contains separatewindings, which ale: a.
C.
d 16. What are the two power sourcesfor fan speedlimiting7 a. b. bus.
17. The backup ignition is poweredby the aircraft 18. Autorelight logic is provided by the 19. What are the throttle interlocks at the military power detent? a. b. C.
20. Autothmttle may be preflight groundt&cd on deck either in Indications that a malfonction exists in the autothrottlesystem are 21. Lit oil pressurereadings a. MRT b. Mium
ORIGINAL
psi at IDLE
psi
39-6
or or
NAVAIR 0%FWAADI 22. An enginestall with no overtemperaturewill illuminate the appropriateSTALL WARNING light in both PRl and SEC mode. a. True b. False 23. Normal rangesof nozzleposition are: a. IDLE weight on wheels b. In-flight MRT c. MNA/Ei d. MAXAD 24. What interlocks must be satisfiedto activatethe nozzle to the full-open position to reduceresidualthrust? a.
percentrpm.
25. Minimum rpm for ground startof the Fl lo-GE-400 engineis 26. Maximum allowable EGT for ground startingthe Fl IO-GE-400engine is
T.
27. The startingtemperaturelimits are the samefor both groundstartsand aimtarts. a. True b. False 28. At EGT readingsof 29. At
“C *lo, a warning tone is presentin the pilot earphones.
T, the EGT chevronsbegin to flash.
30. A hot engineshouldnot be starteduntil EGT is below 3 1. Zero- or negative-gflight is limited ,to a maximum of secondsin afterburnerin or&r not to 32. Above
T airborne. secondsin military power or less aud
rpm, the MEC should shut off ibe1flow to the Fl lO-GE-400 engine.
33. If thethrottle boostsystemfails, the throttlesautomaticallyrevertto manualmode, andthethrottle modeswitch returnsto MAN. a. True b. False 34. What pilot action is requiredto resetthe boostmode of throttle control subsequentto reversionto the manual mode? is the controllmg parameterfor theAPCS.
35. 39.7
ORIGINAL
NAVAIR Q1-Fl4AAD-1 percentrpm.
and
36. Autothrottle engagementrangeis between
37. If the autotbrottlesaredisengagedby any means,theAUTO THROT light illuminates for a lo-secondduration. a. True b. False 38. Engine rpmmust be above
percentto supplysuf6cient power forthe main engineignition system.
39. When attemptinga crossbleedor normal groundstart,the ENG CRANK switch will not reengageif the engine and percent is spooling down andenginerpm is between 40. During spooklown airstarts,hung starts in the low rpm range (less than 45 percent)can be assistedwith .Hung~inthemid-rpmrange(5Oto6opercent)canbecorrected by position, which is near normal for
41. If the IGV linkage breaks, the IGVs assume a power settings. 42. The number of delta Ps to cheekon eachengineduring preflight is
43. During an engine ground tire or abnormal start, be sure that the BACK UP IGNITION switch is in the position. 44. The L or R FIRE warning lights illuminate when the respectiveentire sensingloop is heatedapproximately OF. “F or when any 6-inch sectionis heatedto approximately 45. What proceduresshould be followed to check oil level if it was not checkedwithin 5 to 30 minutes after shutdown? 46. During preflight, the oil sight gaugeis always a reliable indicator of oil level. a. True b. False 47. TheNo.
bearingreceivespriority lubrication in the eventof a loss of oil. minute(s).
48. During cold starts,oil pressuregreaterthan80psi shouldnot be exceededfor more than 49. The electrical sourcefor the oil pressureindicator is 50. The OIL PRESSwarning light will illuminate.whenthepressuredropsbelow when pressurerises above psi.
psi andextinguishes
5 1. The L or R OIL HOT warning light indicatesthat the supply oil temperaturehas exceeded the scavengepump temperaturehas exceeded 52. The INLET ICE caution light illuminates when
or
53. In AUTO, pitot probe heat is available only with weight off wheels. a. ‘he b. False ORIGINAL
39-a
or
NAVAIR Ql-FMAAD-1 54. which of the following would result io illumination of the FUEL PRESS caution light? a. Failure of a motive flow pump. b. Failure of a main foe1pump stage. 56. Failure of the secondstageon the main enginefuel pump will have what effect on engineoperation? 55. Failure of a motive flow fuel pump will havewhat effect on the engine and fuel system operation? 57. The lossof an engine-drivenboost pump will have what effect on operationof both engines? 58. Selectingeither AFT or FWD with the foe1FEED switch performs what functions in the fuel system? a.
e.
C.
poundsremaining in the respective
59. The JJR FUEL LOW light ilhuninateswith approximately feed group.
60. AutomaticshutoffofwinganddroptrmkhansfaoccurswithwING/ExTTRANsswitchineitherA~orORIDE a. True b. False 61. The engineboostpump is poweredby 62. To increasebingo fuel specifications,the enginemode selectswitch may be placedin during descentsor 63. The BINGO cautionlight illuminates when 64. Is vent tank fuel quantity included in the fuel totaker on the AFT and L indicator readings7 65. When shouldthe FEED switch be activatedto FWD or AFT7 66. What medium is usedto actuatethe feed tank interco~ect dump valve7
valve, wing motive tlow shut-off valves, and fuel
67. Wing foe1is transferredby: a. Enginebleed air b. Motive flow fuel 68. The fuel thermistorsin the outboardsectionof the wing tanks perform what function? 69. The foe1thermistorsin fuel cell Nos. 2 and 5 perform thesefunctions when eitheris uncovered~ a.
d.
b.
e.
39-9
ORIGINAL
NAVAIR 01-MUAD-1
70. All fuel enteringtheventtankis ventedoverboard throughtheventmastin thetailhookattachment faking. a. True b. False 71. Fueltransferfrom theexternaldroptanksis accomplished by 72. ExternalAbeltransfercanbechecked on thedeckby
OI
73. Fueldumpisprohibitedwith speedbmkes openand/oraflerbumeroperation. a. ‘he b. False 74. Whenthe fueldumpcircuitis activated,wingandexternaldroptanktransferis automatically initiated. a. True b. False 75. Is it possibleto refuelin flight andaccomplish total fuel transferwithout electricalpoweror a combined hydraulicsystem?If not,why? 76. On enginestartwith thegeneratorswitchin normal,thegenerator is automatically excitedandthegenerator controlunit bringsit on thelinewhenenginerpm is approximately percent. stagebleedair is usedfor lDG oil groundccoling.
77.
78. If thethermalcutoutdecouples thedriveclutchto eithermaingenerator in flight, theIDG mayberecoupled (reset)a maximumof threetimes. a. True b. False 79. Failureof eitheracgenerator automatically connects theleg andrightmainacbusesto theoperative generator. cautionlight. Thecockpitindicatorwill bea 80. Theemergency generator is poweredby 81. If theemergency generator switchis inNORM, it will comeonthelineautomatically when 82. Whenoperatingontheemergency generator, thecockpitlightingavailable consistsof
and
83. A singleenginedrivenpumpon theleft powersthe combined hydraulicsystemanda singleengine-driven pumpontheright powerstheflight hydraulicsystem a. True b. False
ORIGINAL
39-10
NAVAIR Ql-l=l4AAD-1 84. If the pilot extinguishesthe MASTER CAUTION light after a failure of one main hydraulic system,fsil~re of the other system(will or will not) illuminate the MASTER CALJTION light. Why? 85. List the requirementsfor operationof DLC. 86. With the left engine shut down in flight and 0 percentwindmill rpm, the combmedhydraulic systemcan be poweredby 88. With total loss of fluid fmrn eithermain hydraulic system,thehydraulic transferpump will 89. The cockpit handpumpwill chargethebrakeaccumulatorin Sight if 90. Loss of all hydraulic fluid f?ornthe flight hydraulic systemwill meanloss of power to the right inlet ramps. a. Txue b. False 91. With loss of the combinedhydraulic system(combinedsystempressurezero),the main flaps are poweredby and the auxiliary flaps am 92. With the landing gear emergencyblown down the nosewheelsteeringand normal brakeswill operateafter touchdown. a. True b. False 93. The outboardspoiler module usescombined system fluid. a. ‘he b. False 94. Outboardspoilersare inoperativewith wing-sweepanglesatI of 95. The outboardspoilermodule thermal cutout is inhibited when 96. The ON-OFF flag in the spoiler window of the hydraulic indicator indicates: a. The outboardspoiler module is energized. b. The outboardspoiler system is pressmined. 97. With loss of the combined hydraulic system (combined system pressurezero) the inboard spoilers wilh 98. The backup flight control module powers the
andthe
99. With the backup Sight control module switch in AUTO, the module is automatically energizedwhen 100. The backupflight control moduleswitch hasthreepositions: AUTO,
39-11
and
ORIGINAL
NAVAIR Ql-Fl4AAD-l 101. The backup Sight control module operatesin the high-speed mode when 102. Operationalstatusof thebackupflight controlmodule is indicatedin the cockpit by 103. DLC requims an operableoutboardspoiler module. a. True b. False 104. Failure of either the combined or flight hydraulic systemwill have what effect on wing sweep? 105. On the wing-sweep indicator, there are three position indicators. These show and wing-sweepposition.
>
106. The aircraft is being operatedwith the wings afl of the forward limit. The wing-sweep control mode indicator readsMAN. If speedis now increasedbeyondwhere the wing-sweepangle and forward lit coincide, the andthewingswill control mode indicator will mad 107. The most forward wing-sweepangle allowed in bomb mode is 108. The emergencywing-sweep mode is a manual method of positioning the wings. This method incorporates locks every from ZOOto 68Oto preventrandom wing movement in this mode. 109. Illumination of the WING SWEEP warning light means: 110. Illumination of the WING SWEEP advisorylight means: 111. Transient failures in the CADC may be resetby: 112. The CADC is self-testedin 113. List the caution, advisory, andwarning lights activatedby the CADC directly or via the AFCS: a.
e.
d.
h.
114. When instrumentteathasbeenselectedon theMASTER TEST panel,theEIG indicationsafler 5 secondsare: a. RPM b. EGT c. FUEL d. FLOW ORIGINAL
39.12
NAVAIR 0%FMAAD-1
115.A degraded modeof EIG operationis indicated by 116.Maneuverflapscanbeloweredat anywing-sweep anglebetween20’ and , theauxiliatyflaps . . . , 117.Themaneuvering flap thumbwheel will lowerthemainflaps andtheslats . Useofthe maneuvering&vices (doesordoesnot)putmorerestrictiveg htahons on theaircraft. 118.Whatis themeaningof thefogowing(besides CADC failure)? a. FLAPcautionlight b. REDUCESPEEDwarning
(1) (3)
119.Powerfor emergency extension of thelandinggearissupplied by 120.Theminimumbottlepressure for accomplishing emergency extension of thelandinggearis minimumpreflightbottlepressure is psiat 70 OF(21.T).
psibut
121.Full lateraltrim in the directionof stick displacementwill reducemaximumspoilerdeflectionto outhatside. 122.Full slatasymmetryof 17’canresultin anout-of-controlsituationat evenwith 55Oof spoilersavailable.
unitsAOA or greater,
123.Therudderpedalshakeris armedwith mainflapsgreaterthan computeroperating.
Oandthe
124.WithDIG engaged, lbll-upDLC positionstheinboardspoilersat GP
0andthehorixontalstabtrailing
125.Theinitialpositionfor spoilenwhenDLC is engaged is 126.Thecorrectpositioningfor stabilizers whenDLC is givena fit&downcommand(from trim) is trailingedge ’ corresponds to finches of rudderpedaltravel.
127.Full rudderthrowofi
128.Controlsurfaceauthorityof thestabilityaugmentation systemis: Pitchi
0
Rollf
0
Yawl
0
129.Thegearhandleis downandthethreegearpositionindicatorsshowthegeardown,but thetransitionlight is illuminated.Whatdoesthisindicateandwhatactionshouldbetaken?
39-13
ORIGINAL
130. The ANTI SKID SPOILER BK switch is OFF andthe BRAKE light is illuminated. This would indicate: a. b. 131. The BRAKE light (ANTI SK.ID SPOILER BK switch OFF) operatesonly when thebrakesare depressedor the parking handle is pulled. a. True b. False or
132. The two proceduresfor lowering the launchbar are: 133. Nosewheelsteeringcannotbe engageduntil weight is on wheels. a. True b. False
134. With the nosewheel<70°, the nosewheel assumesthe position commanded by the rudder pedals when nosewheelsteeringis engaged. a. Tnre b. False OFbetweenengineandprimary heat 135. BLEED DUCT light indicatestemperaturesin excessof OFbetweenprimary heat exchangerand the ECS turbine. exchangeror greaterthan or
136. The ram air door can be openedonly if the control panel.
button is depressedon the ECS
137. TheramairdoorautomaticallycloseswithselectionofLENG,RENG,orBOTHENGontheECScontrolpanel. a. True b. False 138. The ram air door requires
secondsto go full open.
139. The RIO has a low-cockpit-pressurecaution light (CABIN PRESS) that illuminates if 140. With the OBOGS light on, each flightcrewmembershould have_ feet cabin altitude).
or
hours of oxygen at 20,000feat (8,000
141. Pullmg the emergencyoxygen actuatorreleasesgaseousoxygen chargedto psi and will provide approximately a -minute supply. 142. Windshield rain removal is accomplishedby blowing 390 OFair over the outsideof the windshield. If the tempemtute sensordetectsan overtempemturecondition, the.WSHLD HOT advisory light will ifhrminate and 143. Maximum allowable headwind for the open canopyis ORIGINAL
39-14
kllOtS.
NAVAIR 0%FUAAD-1
144.Whenthecanopyisjettisoned,the sill locksarereleased by 145.Thecanopypneumatic reservoirmustbeservicedby groundservicingunit. aTme b. Fslse 146.Thepilot cantell thepositionof thecommandejectionleverby 147.TheRIO canejectbothhimselfandthepilot with EJECTCMD handlesetto PILOT. a. True b. False 148.Thepilot canejectbothhimselfandtheRIO with theEJECTCMD handlesetto MCO. aTrue b. False 149.In the eventthe canopydoesnot separatetirn the aimraftwheneithertlightcmwmember hasinitiated ejection,‘Ytuwghthecanopy”ejectionwill not occur. a.True b. False 150.Tlleream
safetypinsperejectionseat.
151.Commandejectionby either flightcrewmemberwill eject the RIO in __ swondslater.
secondsandthe pilot feet.
152.For ahigh-altitodeejection,theseatis allowedto ike-fall to f.
lightarelocatedontheMASTERLIGHT panelonthe 153.All exteriorlightingcontrolsexceptfor the pilot console,andtheexteriorlightsmasterswitchontheoutboardthrottle. 154.Whenthewing.9aresweptaft of positionlightsareoperable. -
the
155.WhentheANTI-COLLISIONlightswitchis ON, the
positionlightsaredisabledandtheglovevane positionlightsflasherswitchis disabled.
156.A properindicatorlightstesthasthe MASTERCAUTION lightonsteady. a.TlUe b. False 157.TheRIO canmonitorSWtonesby selectionof
positionon theICS panel.
158.Thestandbyattitudeindicatoris capableof providingreliableattitudeinformationwithin minutesaftera completelossof power. upb 159.Ondecktbeallowable errorbetweenthepilotandRIO altimeterreadings is 39.15
for
feetat fieldelevation. ORIGINAL
160. The angle-of-attackindicator is checkedduring indications are:
and the indexer during
.proper
a. hiicator b. Indexer 161. In the landing cont&uration, 15 units AOA is equivalentin aimpeedfor: a 48,000pounds (DLC not engaged)=
KIAS
b. 48,000pounds (DLC engaged/neutral)=
KIAS
c. 50,000pounds(DLC not engaged)=
KL4s
162 . With an ahspeedindicator failure, list the angleof attack to fly for the following conditions (drag index 8): a. Catapult b. Climb (MIL) SL
to combat ceiling.
c. Cruise at OPT. ALT. d. Enduranceat OPT. ALT. 163. Storesjettison is controlled by which aircraft system? 164. ACM jettison requiresMASTER ARM ON. a True b. False 165. Selectivejettison can be completely controlled by either flightcmwmember. a. True b. False 166. In the emergencyjettison mode, the weight-on-wheelsinterlock is bypassed. a. True b. False 167.
Emergencyjettison mode will jettison Sidewinders. a. True b. False
168.
Sidewinder is jettisoned by ftig
the motor and sating the warhead.
a. True b. False ORIGINAL
39-16
NAVAIR WF14AAD-1 169. The pretaxi (weighton-wheels) OBC mastertest is a completecheck of the SMS. a. True b. False. 170. Selectionof any pulse dogfight mode automatically provides stabout aircmft reference. a. True b. False 171. The pilot must clear maintenancedisplay prior to running OBC for currenttest results a. True b. False 172. FornormalUHPoperationwiththeARC-182,theAMEMswitchshouldbeinthe position. 173. With track files establishedin TWS, the HUD andMPDs provide the pilot completesteeringinformation to the centroid of the targets. a. True b. False 174. The navigation systemmay be updatedby five methods;they are: a.
d.
b.
e.
C.
175. In TACAN BIT, the range and bearing on the HSD and BDHI should indicate 0
nm and
Ooff the nose.
176. The targetdesignator(diamond) is valid to f
177. With MASTER ARM OFF, the HUD and VDI armamentlegendwill appearwith 178. To obtain an attackpresentation,the air-to-air button must be selectedon the PDCP. a. True b. False 179. The COOLING AIR light refers to air cooling out of tolerancewhile the SENSOR COND light indicates liquid cooling out of tolerance. a. True b. False 39-l 7
ORIGINAL
NAVAlR 01.Fl4AAD-l 180. The TID is orieotedto
north, with selectionof GND STAB on the TID mode switch.
181. Which of tbe following presentationsare availableto tbe pilot: a. IRSTS b. PS c. PDS d. AU of tbe above. acronym indicates * failure of tbe SMS, thus preventingnormal separationof storesin any 182. A launch mode. 183. The RADAR COOLING switch in tbe RIO cockpit controls liquid coolant to 184. Hostile areaaltitude is enteredin tbe
pseudofile to properly reject eltitude line return.
185. Wind is automatically computedby the systemin the INS mode. a. True b. False 186. A wind of 35 lmots and 057” relative to the duty runway representsa headwind compone.ntof knots andcrosswind of ImOtS. 187. A blinking SHOOT cue indicates 188. Hydraulic power to drive tbe gun comesf?nrnthe
ORIGINAL
39-18
System.
PART XI
Performance
Data
Foraimaftperformamedataandchats,refertoNAVAIROl-F14AAP-l.l.
NAVAIR 01.F14AAP1
INDEX Page No.
Page No. A Abnormalstart. ................. Aborted takeoff ................. checklist ................... Accelemtionlimits ................. Accelemteddeparhaw ............ Afthungordnancelandings ........... Aftwing-sweephdings ........ After landing, cold-weather operatioru ................. i%hrbumm Puel control .................. Ignition .................... Airinletcontrolsystem .............. Malfunctions ................ Air-conditioning, cockpit ........... AilVd.. .................... Fuelsystem .................. Lighting during night formation flight. ..................... Self-test ................. Subsystems .................. Aircrew wordination .............. Single-e&e failure field/catapult launch/waveoff ............... Airspeed: Liitations ................... Subsonic ................... Aida&: .................
12-l 13-l 13-l 4-S .ll-13 IS-16 ll-25,15-11 18-6 2-23 2-32 2-l .14-16 .2-135 Part1 2-40 94 Chapter38 17-2 37-l 13-2
Angle-of-attack Limits ..................... System .................... htennss, wmmlmiwtions ............ Anti-ice, engine. ................. Antiskid. .................... APt3-71 PM acronym ............. Applicable publications ............ Approach: Lights .................... Pilot timctional checkfiightpro&ums ... RIO functional che&lightpmcedmea ... Approach power compensator: Performance .................. Tecbnique....................8Areaeroundeirc&impectionof ........ Arrested landing end exit ftom landingarea ................. Night. ..................... Arming hook Emeqency down .............. system. ................... Ascent checklist ................. Asymmetric&t...& -Et-hM
............
characteristics. .............. 4-l 11-4 2-34,14-I
External :::::::::::::::::::::‘zjz 20,000 feet,pilot flmctional checkfiight procedures ................ 10-18 All-weather operations ............ Pert VI ANIAPN-194(V) radar&meter system ... .2-234 ANIAPX-76 identification friend or foe interrogator. ................ 21-6 AN/APX-lOOidentiticationtmnsponder .... 21-1 AN/ARC-l82 VIUHP radio ........... 19-7 ANIARN-118 tactical air navigetion system ................... 20-S AN/ASN-139 inertialMvigationset ...... 20-l ANIASW-27C datalink ............. .20-10 ANAJRC-107 joint tactical infom&ion distributionsystem. ........ 20-5.20-10 AN/USN-203 standad attitude headingreferencesystem ......... 20-3
Incombatendcruiseconf?gumtion
.....
.4-5 2-236 19-l 2-27 2-122 14-28 39-20 2-239 IO-22 lo-27 17-3 7 .7-l .8-l S-12 IS-21 2-129 7-23 11-12
II-20 ...... 11-3 . . . 11-27,;;;;;
s&i : : : : : : : : . 17-2 Audio weming signals .............. 19-5 Authorized storesloading ............ 4-20 Automatic carrier lending system ........ 17-l Beaconaugmentor. .............. 17-2 Displays .................... 17-3 Pmwduma .................. 17-10 Automatic flight control system ........ 2-109 Test ..................... 2-116 Automatic fkel electrical controls ........ 2-59 Automaticlanding sy%em(AN/SPN-Q2) .... 17-S Autopilot .................... 2-l 10 Light ..................... 14-44 Limits ..................... .4-l Auxiliary brake ................. 2-124 Auxiliary canopyopencontrol .......... 2-76 Auxiliary flap feilure .............. 15-10 Avionic bit operation .............. 38-10
IndexI
ORIGINAL
Page No. 6
Backupflight controlsystem .......... 2-72 Backupflight modulemalfunction ...... .14-35 Backupignition ................. 2-32 Backupoxygensupplyservicingdata....... 3-8 Backupoxygensystem............ .2-143 Bannertowing................... 94 Restrictions.................. 4-19 Barricadearrestment .............. .15-18 Barricadeengagement limits .......... 4-17 Bearingdistanceheadingindicator ...... .20-10 Beforeleavinga&aft, cold-weather operation9................. 18-6 Binding/jammedflightcomrolsondeck .... 124 Bingofuel ..................... 8-8 Bleedair, engine................. 2-27 Blockmnnbers................... l-2 Blownthe: Durblgtakoff ................ 13-3 Landing................... .15-10 Boardingladder ................ .2-268 Bolter ...................... 8-11 8-8 Technique.................... Bothcombinedandflightpressurezero. .... M-33 Brake: characteristics................ 2-122 Failureattaxispeed ............. 124 BR4RESwarninglight ............ .2-124 Breakformation .................. 9-3 Briefing: Carrier-based procedures............ 8-l Mission .................... 39-3 Night flying .................. 8-11 6-l Preflight. .................... M-29,14-30 BAJOXYLOWlight .......... Built-intest: Description.................. 38-7 Engineinskumcntgroup ........... 2-37 C CABIN PRESSlight. .............. CADC light .................. Canopy: Control,normal................ L-gss...................... $m&ontrol, auxiliary ... ............................. carrier: Landingpattern(VPR) ............. htlight. ..................... carrier-basedpmcedums ......... ORIGINAL
14-28 .I443 2-76 14-30 2-76 2-240 8-5 8-1 .Chapter8
Page No.
Canier-comroRcd approaches.......... .8-9 catapult: Launch. ................. 8-4,8-11 System,nosegear.............. 2-127 Trim requirements ............... .84 Catapultabortprocedures: .Day ........................ 8-4 Night ...................... 8-11 Qtapult hookup: Day ....................... .8-3 Night. ..................... 8-11 Cautionlegends, multifunction displayengine ............... 2-38 Cautionlight, OIL HOT ............. 2-35 Ceiliivisibility requirements.......... .5-2 Centerof gravity: Positionlimits ................. 4-18 Lmations,tlight characteristics with . 1 . . 1l-33 Centralsir dstswmputcr ............. 20-S Checkftightprocedmes.............. 10-l Checkout,on-board................ 38-3 Cleanandsymmetricstoresloading ....... 4-13 cliimb:
-
Flightevaluation.. . . . . .......... 39-3 Pilottbuctionalchecktlight lo-13 procedmes. . . . . . . . ......... RIO timctionalcheckflight lo-24 pmcedures. . . . . . . . ......... Climbto 35,000feet: Pilotfunctionalchecktlight lo-18 procedmes. . . . . . . . ......... RIO timctionalcheckflight plDc&ms . . . . . . . . ......... lo-25 Closed-book ex&nation, NATOPS ...... 39-2 Cockpit ....................... l-l Air-conditioning............... 2-135 Overpressurizatjon on,deck......... 14-28 Temperature controlmaltursztion...... 14-28 Cold-weather operations............. 184 Combineddynamicandviscous hydroplaning................ 18-3 Combinedpressure approximately 2.4OOto2.6OOpsi ............. 14-31 Combinedpressure zero ............ 14-32 Commandejectionlever ............ 2-248 ccmlmlmications............. Chapter19 Andassociated equipment........... 19-1 Antennas .................... 19-1 Emergency procedmes ............ 14-1 Failure..................... 14-1 Flightevaluation................ 39-3 In-flight visual................ 19-26
Index-2
Page No.
pose No.
communications-navigatioll~ and,tlcadm ............. PartVII ctnnpressorstall................. 14-S Controlindicatorpowerdistriionunit .... 22-2 thddlability check ............. .14-35 Contro11erpnlWsorsigoallmit ......... 22-2 Converterin&face unit ............. 20-S COOLINGAIR LJGHT ............ .14-27 Cooling,electronicequipment......... .2-136
Distancemeamringequipmentfix........ Doublegcncmtcrhilurc ............ Dualhydraulicfailuresbackuptlight controlmoduleBight
~srativ&yptnt
Dynamich&&ii~:::::::::::::f ;;I; Dynamiclongitudinalresponse characteristics -
scfhvae aIrcrew .......................
Coupling.................... c&m&nginc .... ....... cros &
,38-32 37-l
. ll-13 . . . . . . . ;g :::: :::: 11-12 2-34 4-l
Crossbleed start ................. Cmsswindlimita .................. cruise: Andcombatflight characteristic withaftcg ................. Formation.................... Flightevaluation............... Cwscrcontrols. ................
1154 9-3 39-3 .2-158
. . . . . . . . . .
3-8
22-2 .2-225 17-2 .14-22 7-36 39-l 2-56 11-25 2-62
-:
Fromcontrolledflight , . . . . . . . . . . . 1l-9 Recovery .... , ............. . ll-13 spin ..................... .14-44 Descent ..................... 7-23 RIO functional chc&flight pmcsmaeS ...
Diamondfour-pbmeformation .......... I$$al~&~~~~
lo-25
93
. . . . . . . . . . . . . . .22-28 11-S
Dircctliftcon&l’ : : : : : : : : : : : : : : : : 2-109 Directional~w)contml ............ 11-l Dirwtionalstabiity ............... 11-S Dirwliv~,technical* ............... l-2 Displaysystem,TARPS............. 22-2 Displays ....................
Subsystem...................
11-29 15-l :;‘;
E Ejection: Envelope. extremeweather .......... 16-l Prggioq extremeweather. . . . ............. 16-5 2-243
D
Displaysystem ................ Entryuoit .................. Link ...................... Doubletransformer-rectifier failure ...... De&launchedinterceptpro&mes ...... Detinitions,NATOPSevaluation........ Defoeling .................... Degradedappmachcon6goratioo. ....... Bqradadelectricaloperation..........
enginesinseco&rymode......... DulJJiiil ...... ..... .........
.8-9 14-U)
.2-160
20-S h&r-3
Ejectioniniizoi: : : : : : : : : : : : Extremeweather. ............... Ejectionseat .................. Inspwtion....................7 Operationlimits................ Elect&alcontrols,automaticfuel ........ Electricalfailum ................ Total ..................... Electricaltire .................. Electricaloperation: DC-.
...................
2-248 16-5 2-243 -6 .4-l 2-59 14-20 14-24 14-22 2-62
Nod. .................... 2-59 Electricalpower: Distribution .................. 2-61 Supplysystem................. 2-59 Electronicequipment cooling ......... 2-136 Electronicnomenclature.............. l-2 Emcrgcncy cntranw ............... 12-2 Emcrgcncy gearextension........ 2-76,2-120 Emcrgcncy jettison ................ 14-2 EmcrJ3cncy oxygensupply ........... 2-144 Emergency pmcedums.......... PartV, 39-3 En-speeds ................ 15-18 Engine ................ .Chapterl,2-9 Anti-ice .................... 2-27 Bleedair .................... 2-27 x.u ventilation .. . . .. . . . . . 2-30 2-21 crsnk .... . . . . . . . . . . . . . . . . . 2-32 Emergencies .................. 14-S Feed ...................... 2-43 Fireonthedeck ................ 12-l Fuelboostpump................ 2-21 Fuelsystem .................. 2-21 Ignitionsystem ................ 2-30 ORIGINAL
Page No.
instruments.................. Liits ....... : .............. Monitcr displayformat ............ Overspeed.................. Ovcrtempcraturewarning .......... RPM Indicator ................
Rmmp,pilot tbnctionalcheckflight l3lQdum. ................ 1
Stall warning .................
stds ..................... STARTVALVE light ........... Starting system . .- ..............
TransfertoSECmode............ Engineinstmment Croupbuilt-intest .............. Croupself-test ................ Engineoil: Pressureindicator............... servicing data. ................. System ....................
Enginestart: Cold-weather operations........... Pilot ...................... RIO ......................
2-35 4-I 2-37 .14-12 2-38 2-35
lo-11 238
114 .14-12 232
14-12 237 2-37 2-37
3-4 2-34
18-5 7-11
Fifteen-thousand-foot checks: Pilottimctionalcheck&&t procedures... RIO ftmctionalchecktlightprocedums ... Finalgradedetermination........... Fire: Detectionsystem ............... In flight .................... Light in Sight ................. Electrical. .................. Flameout ..................... Flapandslat ................... Asymmetry ................. Landingemergencies............ Transitionlimits,takeoffandlanding ..... FLAPlight ................... Flap(s): Maneuveling .................. Up takeoff ................... Flatspin. .................... Flight: Andcombinedsystems ............ Crewmember flight equipment rtqlkements .................
F
Fatigueenginemonitoringsystem ....... Field arrestinggear ...............
Fieldarmstments................. Fieldcarrierlandingpractice ..........
2-16 15-17
15-17 7-37
10-15 10-24 39-20 2-39 14-4 14-I 14-22 114 2-88 14-41 15-10 4-13 14-41 11-5 7-21 11-16 2-68 .5-5
Equipment rtqGrements,flight
7-30
Enviromnental controlsystem......... .2-132 Leak&t&ion ................ 2-29 Malfbnctions/failures ............. 14-25 Equipment: Ciit breakers,TARPS ........... 22-9 Communications andassociated....... 19-1 Miscellaneous................ .2-268 Evaluation: Flight ..................... 39-2 Chapter39 NATOPS ................ 2-35 Exhaustgastempemtum indicator ....... Exhaustnozzle: Failed(nonozzleresponse to 14-15 throttlemovement) ............ Positionindicator............... 237 2-16 Variable. ................... Exteriorinspection................. 7-l Exteriorlights ................. .2-251 2-32 Extemalaimtart ................. Externalbaggagecontainer.......... .2-269 Externalstoreslimits 4-18 Extremeweather. .. : : : : ‘&p&r i6, Chapter18
ORIGINAL
Page No.
crcwmembcr ................. Instruments .................
5-5 2-234
Preparation ................ Chapter6 procedures....................9 4 Trainingsyllabus ............... .5-2 Flightcharacteristics........... Chapter11 Withattcglocations............. 11-33 Asymmetricthrust .............. 1l-20 Dualhydraulicfailuresbackup flight controlmodule............ 11-29 General .................... 11-2 Highangleofattack .............. 11-5 Singleengine ................ 14-11 Flightcontrolsystem(s) ............. 2-96 Backup, .................... 2-12 Failuresor malriumtions........... 14-37 Flightevaluation(s) ................ 39-2 Gradedetermination............. 39-19 Gradingcriteria.. ............ ..39 -4 Flightpressure: Approximately2,400to 2,600psi ...... 14-31 zero ..................... 14-33 Flightcrew: Attentionsignals. ............... 14-l Coordination.............. Chapter37 Flighttrainingsyllabus ............ .5-2 Forcedlanding ................. 15-21 Foreignobjectdamageandleak inspection.................. .7-l
Index-4
NAVAIR QMWAAB1
Page No.
9-2
Formationflight .................. Ailcmwcclmdhation
7-21
Takeoff ....................
.2-160
Formats ....................
Fuel: Boostpump.engine..............
2-21
Dump ..................... Flow indicator ................
2-55 237
Leak......................141 Mana8emcnt systemoperational check ....
9 9-7
.14-18 2-21 $i&i&&:::::::::::::: 2-54 2-42 s Tankage.. .. . : : : : : : : : : : : : : : : 2-40 l’rcssme caution lighti ...........
. .. .. . . . . .
i’ Maltimctions ....... . :: :: : : : : : 14-18 2-50 Fueltransfer ................... ~~inglecngine operation. ... .. .. 2-54 Fueling ..:
1: ::::::
1: 1:::
.... Functionalchccktlightpmcedures
1: 1::
14-18 2-56
Chapter10
Ailcrew coordination .............
Pilot ...................... RIO ......................
37-3
..................
Gaspurging .................
mxedul-es ...................
Hot switchprocedums.............. Hot-weather anddesertoperations........ Hydraulicpower: Distribution .................. Supplysystems ................ Hydraulicsystem: Maltimctions. ................ scrvicingdata................. Hydroplaning...................
3-8
.19-26 4-l 94 3-l
(ANM’X-76)
.2-138
................
......... Transponder(AN/APX-100) Ignitionsystem,engine.............. In chocks,RIO t?mctional chccktlight pnmdures
................
........... In-flightemergencies In-flighton-boardcheck ............. In-flightreconnaissance system check,RIO ................. In-flightretueling.............. Ill-flight visualcommunicBtions ........ Indicator(s): Lights .................... Engineoil pressure .............. EngineRPM .................. Exhaustgastcmpcrature ............ Exhaustnozzleposition ............
7-l 5-l 4-18 4-18
7-35
7-36 18.6
2-71 2-68 14-31 .3-o
18-2
I Ice. ........................ Identification............... Friendor foeintermgator
2-76 Gearextension, emergency........... ............... .14-20 Generatorfailure. .39-19 Gradcdctcrmbmtion, tlight evaluation.... 39-4 Oradingcriteria,flight evaluation........ 39-2 Oradinginstnwtions,groundevaluation.... Grossweightlimits,takeoWlaunchilanding . . 4-17 3-15 Groundclearances, towing .......... Groundegresswithoutparachute andsurvivalkit .............. 12-2 ............ Chapter12 Groundemergencies 39-l Groundevaluation, NATOPS.......... Signals ................... Groundopemtions limits ............. Groundprocedures ................ Groundrefueling .................. Groundsafetydevicesandcovers, inspcctionof ................. Groundtminingrequirements/syllabus ...... GulK Burstliits .................. Limits .....................
chapter3 Handling .................. Heads-up display................ 2-153 Heads-up displaysymbology ........... 22-14 Highangleof attackflight charac&istics.... 1l-5 Highspeeddash(35,000feet): RIO iimctionalcheckSight prucedures... lo-25 PilotCumtionalcheckflightprocedums ... IO-19 2-32 High-energy ignition,main. ........... .8-9 Holdphase.................... 2-129 Hoklbackfitting ................ Horizontaltail authorityfailure ........ 14-39 2-59 Hot rctiteling ...................
10-2 IO-23
0
Chmdhandling
H
37-4
.............
Fuelsystem: ~.::::::::::
Page No.
Fuelflow. ................... Multistatus. ................. oil
pressure
..................
18-l Chapter21 21-6
21-l 2-30 lo-28
chapter14 7-23 7-33 2-57,9-l 19-26 2-254 2-37 2-35 2-35
2-37 2-37 2-154 2-35
Chapter5 Indoctrination................ ...... 20-l Inertialnavigationset(AN/ASN-139) .22-2 Infimedlinescanuerset............
Index5
ORIGINAL
NAVAIR 0%FMAAD-1
Page
Page No. iiitE%&ght
nnaisancesct ..........................
Tzz? EF&io; ::::: lnstlumcnt:
.22-26 . 14-17
....................
::::::
Engine. .................... Flightevaluation...............
......... rnstNmcnt landing system: mfm-63 ................. Flowdmw
3::
2-35 39-2 . .....
17-5
17-8 17-3
scrvicingdata ................ ..............
3-4 2-96
Intcrcommuoications.............. Intcrfcmnce,mutual ...............
19-1 19-1
IntcrimAlM-7asballast ............ Interior inspection: Pilot ....................... RIO ...................... Interior lights .................
4-20 7-8 7-28 .2-251
Jmemaltankprcssmhationandvent ......
2-56
lnvcrtcddepartlue/spin ............ lnvcrtcdspin ..................
.14-45 .11-19
JnvertedstalVdepar&?............
.ll-19
.14-18 M-3414-31
Lading ..................... canicr-bascflp ............ Checklist ...................
7-24 8-5 7.26
Cold-weather operations........... Emergencies..............
18-5 Chapter15 ......
11-2
Grossweightlimits .............. Hotwcathcranddcscrtopcrations ...... Onwetrumvay ................ preparation, parachute............
4-17 18-6 18-4 168
ORIGINAL
Bar ...................... Carrier-based procedures ........... Grossweightlimits .............. Limits ..................... Singlecnginctbihuefield/catapult...... Leak(s) ......................
2-129 .8-l 4-17 4-18 13-2 .7-2
Detccti0~environmentalcontro1system . * . 2-29 Lightingsystem. ................ 2-251 Lights,approach................ 2-239 Limhtions .................... .4-l Lincalwvcrage
.................
22-23
15-18 22-25 2-96
Low bmkeaccumulator pmssure........ Lowsubsonicairspeed ..............
14-36 11-4
Y
L
F~s,shtp,anddkctlElumtrol
154
2-119 2-116 2-101 116 1l-9
Launch:
;;9-;
: : : : : : : : : :.. . .. 138-28
LorRPUELL0Wbght ........... LADKANOPY Light ..........
..................
Normaloperation .............. Systems ................... Lateralcontrol ................. Reversal.................... Lateral-stick-induced departures.........
Longitudinal contml ...............
14-2 4.19
. . lo-28 15-17 . . ll-a0 11-34 15-6 15-6 2-116
Long-Eeld-t ............. Long-range obliquephotography canma(lCS153Awith 610-mmlens). .............
J
Jettison: Emcrgcncy.................. Limits ..................... Jointtacticalinformationdistribution m~mae~l.i : : . . . . . . .. . : -..;
,
Withafthuugordmume........... Landingcontiguratiotttlightc~cs WithaAcg .................. Landinggear: Bmergencies .................. Emcrgcncylowering ............. Handle.................... lvfahlctions
Intc~titTimsystem
.
RIoEulctionalcheckfiightproceQres
ch4w17
AN/S%41 .................. Displays. ................... Intcgmtcddrivegcncratoroil
On-boardcheck
No.
Mainlandinggear ............... 2-116 Malliulctionprocedures............. 39-3 MWWVCliDg: Plapsandslats .............. 11-2.11-5 Liits ..................... 4.10 Stickforce ................... 11-2 Maneuvcqprohibited .............. 4-10 Man~approachtechnique ........... .8-7 Mammlbailout,exircmcwcathcr........ 165 Man~madscatscpad~extremewcathcr . . 16-8 Mastcrtestpanelchecks ............. 38-1 Mastertat switchoperation........... 383 Maximumainpeeds
...............
.4-s
Meatballcontact....... ; ......... Mcdiumandhigh-subsonicaimpeed ....... MFT prwedun?s evaluation ...........
.8-9 114 39-2
MinimumEightcmwrequiremen$.
.5-4
Index-6
.......
NAVAIR 0%FMAAD-1
Page No.
Minimumgroundtrainingsyllabus........ 5-l Miscellaneous equipment........... .2-268 Missioncommander............. 5-4,37-l Missioncomputersystem......... 2-76,204 Missionevaluation................ 39-3 Missionplanningandbrieting.......... 39-3 Motiveflow fuelpump ............. 2-21 Movablesmfaces,impectionof. ......... 7-2 Multifunctiondisplay(s)............ .2-158 Enginecautionlegends............ 2-38 Formats................... .2-181 Rcconnaissancedata statusformat ..... .22-10 Multistatusindicator. ............. .2-154 Mutualinterfe.mnce............... 19-l N
NATOPSevaluation.............. program. ................... Qualificationandcurrency requirements. .................
PartX 39-1
Page No.
Oil system: Engine..................... Mabbnction................. On-boardcheckout................ On-boardoxygengcncmtiugsystem...... On-deckemergencies............... Open-book examination, NATOPS ....... opcratingcriteria................. operatinglimitatiolls............ Operational deployable squadrons........ Oralexamination, NATOPS ........... Outboardspoilermodule: Failure .................... Malfunction ................. Outboardspoilersystem ............. Ovcrspeed, engine ............... Oxygensystem................. Failme. ....................
2-34 14-17 38-3 2-141 12-l 39-2 .5-2 Chapter4 39-2 39-2 11-25 14-36 2-72 14-12 2-141 14-29
P 53
Questionbank. ............... .39-20 Navigation................. Chapter20 Commandandcontrolgrid....... Chaptcr23 Navigationdata: Display..................... .20-l 1 Initialization ................. 20-5 Emergency procedures............ 14-l Navigationsystem................ 20-l Datadistriimion .............. .20-l 1 Operation.................. .20-14 Negativeangle-of-attack departmw....... 1I-19 Nightfieldwrier landingpractice ....... 7-38 Nightflying ................... 8-l 1 No-flapsandno-slatslanding .......... 15-10 Nomenclature, electronic ............. 1-2 Normalelcctricaloperation........... 2-59 Normalprocedures .............. PartIII Normalstalls. ................. . ll-20 Noschmdinggcar............... .2-118 Nosemdome.................. .2-268 Nosestrutkneel ................. 2-127 Nosegear catapultsystem ........... .2-127 Noscwheelsteeringsystem .......... .2-125
Panels,sccurityof ................ .7-2 Panoramic camera ............ 22-2,22-24 Parachute: Landingpreparation.............. 16-8 steering .................... 16-8 Paradeformation ................. .9-2 Parkingbrake.................. 2-124 Patternelltry .................. .7-24 Photographic film ............... 22-26 pilot: procedures....................7 -8 Rccomuhtmccoperation.......... 22-22 Reliefandguidancemodes ......... 2-l 14 Responsibilities................ 37-l Pitch Chaunelthilure ............... 14-37 Control. .................... 11-l Pitot-staticsystem ............... 2-144 Failures .................... 14-l Planning, mission. ................ 39-3 Platform. ..................... .8-9 Plottonevo1~tacan commandpanel ..... 19-7 F’ncum~~tic powersupplysystems ........ 2-76 Fncumatic systemsservicing data ........
0 OA-8697V/UHP automaticdirectionfinder . . 19-18 OBOGSlight ................. .14-29 Oil: Cooling .................... 2-35 Pressure indicators.............. 235 OIL HOT cautionlights ............. 2-35
Postflight: -s ................... RIO functionalcheckflightprocedures... Posthuming: Pilot ...................... RIO ......................
Poststart: carrier-based procedures...........
Index-7
.3-8
39-3 10-28 7-27
7-35
.8-l ORIGINAL
Page
Page No. Night flying .................. Pilot. ..................... p&t tilmtional cllcc~ght plocdlw *ofunc;idn;l....ti..~ .
8-11 7-13 .. 10-6 : : : .. 7-30 lo-23
Power supply eystem: Electlical ................... 2-59 Hydraulic ................... 2-68 Pnmnatic ................... 2-76 Prefli!&l.lt And line operations .............. 39-3 Briefing ..................... 6-l Carrier-basedprocedum ............ 8-1 Cold-weatheroperations ........... 18-5 Night flying .................. 8-11 Prcland ...................... 7-23 Ressorization ................. .2-136 Preatalt Pilot ...................... 7-10 Pilotfonctional&ecktlightpmcedum ... 10-2 RIO ...................... 7-29 RIO foncticmal checkflight pmcedms ... 10-23 Primarytlightcmro1s .............. 11-l Prcmxhm, techniques,and cheeklists, aircmvcoordination ............ 37-4 Prollibitcd manellvcrs .............. 4-10 Publications,applicable ............ .39-20 PUh4YPphasechcuitbreakempopped..... .14-28 Q Questionbank, NATOPS .........
Chapter39
R Radar:
Altimeter system,ANIAPN-194(V) ..... Beacon (ANKPN-154) ............ Radiationareas ................. Systembuilt-in test ............. ~~offi=~ ................................ Responsibili~e~ Rllftboarding .................. Rain ....................... Reemnakmce: Displays and formats ............. PaWproblem reporting .......... Steeringselection .............. Reconnaissancesystcm ............. operation.. ............... Reconis and reports ............... Recove-ly*stall ................. ORIGINAL
2-234 17-2 3-8 .38-39 7-28 37-l 16-9 18-l 22-9 .22-10 .22-10 22-l ..22-14 39-3 . ll-20 Iti-
No.
Re!Wing: Omlmd .................... Hot. ...................... In-flight .... Bet&mm$e$.ss”” flight phases .............. ..................... Roll: Channelfaihue ............... ContIol. .................... Performauce .................. zz ::::: :::::: :::: Rollinglimits .................. Rpmdecay,uuc.onmlandedsEcmodc Rudderaothority failme ............ Rudder-indueeddepa~W~. .......... Runup, flight evaluation .............
....
..3- 1 2-59 2-57 .5-4 18-3 14-37 11-l 11-2 :.$; .4-10 M-13 14-38 11-12 39-3
S Searchandrescue................. 374 SWt: Ejection ................... 2-243 Operationafter ejection ........... 2-250 secondarytlightumtrols ............. 11-l securityofpanels. ................ .7-2 Self-test,engineinstmment group ........ 2-37 Sensorcapabilities andlimitations ....... 22-23 SENSOR COND light illuminated. ...... 14-28 Serial frame camera ........... 22-2,22-23 servicing .................. Chapter3 shimmy dampiig ................ 2-127 shipboalKlprocedures .............. .9-4 Short-bad proceduieschecklists ........ .7-l Short-field an-estment ............. 15-18 Side&p limits. .................. 4-10 Signals: Audiowarning. ................ 19-5 Flightcrew attention .............. 14-l Groundhandling. .............. 19-26 Single-enginetkilurc field/catapult 13-2 launchkvaveoff Single-engineflightcharac&sGs ..... I : I I I I ‘M-11 Smglc-cnginelanding: Operationfoe1transfer/feed .......... 2-54 ymq~odc . . . .. .. . . .. . . . . 15-l 15-3,154 Six-mileDME’&’ : : : : : : : : : : : : : ...... 8-9 slats,mancuvcling ................ 11-5 Special considerations,aircrew coordination ................ 37-3 s@alprocehx ............. chapw9 Spcoitic responsibiis, ainxew ......... 37-1
NAVAIR 01-FlbUD-1
Page No.
Page NO. Speedbrakes................ spin: Flat ..................... Inverted ................... Spoiler: control
..................
Off
. ll-16 . ll-19 ..2-10
Malfunction .................. Stability augmentation.............. Transients .................. Stability augmentationsystem ...... Limits. .................... ....................
1
14-39 11-l . lC38 .2-109, 11-5 4-13 ..ll-2
5
Stability, wing-sweepeffects on ........ 1l-34 Stall(s): Chamcte.tistics ................ 11-6 compressor .................. 14-5 Normal .................. ..ll-2 0 Recovery ................... 1l-20 Warning, engine ............... 2-38 Vertical .................... 11-9 Standardattitudeheadingreference system(AN/USN-2(V)) .......... 20-3 Standardcentralair datacomputer ....... 2-78 Standbyairspeedindicator ........... 2-234 Standbyaltimeter ................ 2-234 Standbyattitudeindicator ............ 2-234 start: Abnormal ................... 12-1 Carrier-basedprocedures............ 8-1 Crossbleed .................. 2-34 Pilot functional cheoktlight procedures ... 10-3 START VALVE light, engine. ......... 14-12 AAerenginestart
...............
12-l
Starterlimits ... 4-l Static longitudinal stabiiity’ 1 1 1 1 1 1 1 1 1 1 1 . 1l-2 Store(s)...................... 11-5 Effects on cg location ............. 1l-33 Managementsystem/jettison ......... 2-263 Storesloading: Authorized .................. 4-20 Clean andsymmetric ............. 4-13 Stuck/jammedthrottle(s) ............ 14-15 Surfacecondition ................. 7-2 Surfacesubsystems ............... 17-8 Survival hit deployment ............. 16-8 SwivaVpostejection procedures, extremeweather .............. 16-5 Symbology....................2-16 HUDNDI...................22-14
Systems ................... Test and systempower groundpanel. ...............
T
2-94.1 l-2
0
Chapter2 .2-269
Tactical air navigation system (AN&RN-l 18) . . . . . . . . . . . . . . . 20-5 Tactical air reconnaissancepod system . . . . . 22-2 Checklist ........ Y ............ .7-l Degradedmode procedures .......... 7-33 Envhonmentalcontrol system ......... 22-2 Litatioas
...................
4-20
Subsystem ............... Chapter22 Tactical information display ........... 20-5 Takeoff ...................... 7-20 Aborted ................. 7-22,13-l Andlanding flap/slat transition liits ..... 4-13 Blown tire during ............... 13-3 Checklist. ................... 7-22 Cold-weatheroperations ........... 18-5 Emergencies.............. Chapter 13 Grossweight limits .............. 4-17 Hot weatheranddesertoperations ...... 18-6 Pilot functional checktlight procedures ... lo-13 RIO timctional checkflight procedures ... 10-24 Takeoff contigmation flight characteristics . . 1l-20 Withaftcg. ................. 11-34 TARPS ECS light illuminate .......... 14-27 Taxi: Flight evaluation................ 39-3 Night flying .................. 8-l 1 Pilot ...................... 7-19 Pilot fimctional checktlight procedures... 10-l 1 RIO
......................
7-33
RIO timctional checktlight procedures ... Taxiing ...................... Carrier-basedprocedures ........... Cold-weatheroperations ........... Hot-weatheranddesertoperations ...... Technical directives ................ Temperature.warning, engine .......... Ten-mile DME fix ................ Ten-thousand-footcheck,pilot functionalcheckflight procedures .... Test prerequisites/restrictions .......... Throttles ................... Stuck/jammed ................ Thundc~~torms ..................
Tiedown points .................. Total electrical failure ............. Touchdown,pilot functional checkflight procedures .......... Towingtumradiiandgroundclearances Training: Aircrew coordiition ............. Evaluation squadrons .............
Index-9
lo-23 7-17 .8-3 18-5 18-6 l-2 2-38 .8-9 lo-13 38-9 ..2-2 3 14-15 18-4
3-15 14-24 ....
10-23 3-15 374 39-2
ORIGINAL
Page NO. Transfer,fuel. ................ TRANS/RECT light ............. Trim characteristics ............. TSECXY-58 UHP voice security equipment Turbulence .................. Tumradii,towing .............. Twenty-thousand-footchecks: Pilot functional checkflight procedures . RIO functional checktlight procedures. .
2-50 14-22 113 19-18 184 3-15 10-20 lo-25
U UHP automaticdirection fmder ....... UHP voice security equipment (TSECIKY-58) ............. Uncommandeddump ............ Uncommandedengineacceleration: Airborne (no throttle movement) ..... On deck .................. Uncommandedroll antior yaw ....... UncommandedSECmoderpmdecay ... Unscheduledwing sweep .......... upright departure .............. Recovery .................
20-10 19-18 14-19 14-15 12-I 14-37 14-13 14-43 14-45 11-13
V Variable exhaustnozzle . . . . . . . Ventilation, enginecompartment . Vertical display indicator symbology Vertical recovery . . . . . . . . . Vertical stalls . , . . , . . , . . . . Viscous hydroplaning . . . . . . . . Voltage monitor control unit . . . . VAJHP automaticdirection finder (OA-8697) . . . . . . . . .~. . VAJHP radio (AN/ARC-182) . . . .
ORIGINAL
Page NO. W Waiving of minimum ground training requirements .......... Warning lights ............ Waveoff. ............... Singleengine failure field/ catapultlaunch .......... Technique ............. Weaponsystems ........... Proceduresevaluation ....... Weigh< aircraft ............ Weight on-off wheels switch maltimction ........... Wheel antirotation .......... Wheelbrakesystem .......... Windshield air and anti-ice ...... WING SWEEP advisory light and W/S caution legend ....... Wing-sweepdesignlimitations ... Wing-sweepeffectsonstability . . , Wing-sweepemergencies ...... Wing-sweepsystem ......... WSHLD HOT light. .........
5-1 . . . . 2-254 . . . . . 8-11 . . . . . .
. . . . . . . .
. . . .
. . 13-2 . . . 8-8 . PartIff . . 39-2 . . l-l
. 12-2,14-44 . . . 2-125 . . . . 2-120 . . . . 2-138 . . . .
. . . . .. .. . .. . ..
. . . . .
14-42 11-27 11-34 15-11 . 2-81 14-28
Y . . . . . . . . .
2-16 230 22-14 14-45 11-9 18-2 2-109
. . . . .
19-18 19-7
. . . . . . .
. . . .
Yaw: Channelfailure .......... Control ............... Uncommanded...........
14-37 . . . . 2-106 . . . . 14-37
. . . .
z Zoom (40,000feet), pilot fimctional checkflightpmcedures .....
. . . .
10-20