OptiX OSN 550 Multi-Service CPE Optical Transmission System V100R003C00
Configuration Guide Issue
02
Date
2011-06-30
HUAWEI TECHNOLOGIES CO., LTD.
Copyright © Huawei Technologies Co., Ltd. 2011. All rights reserved. No part of this document may be reproduced or transmitted in any form or by any means without prior written consent of Huawei Technologies Co., Ltd.
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OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide
About This Document
About This Document Related Versions The following table lists the product versions related to this document. Product Name
Version
OptiX OSN 550
V100R003C00
iManager U2000
V100R005C00
Intended Audience This document describes procedures for service configurations on the OptiX OSN 550, including basic concepts, networking diagrams, signal flow and timeslot allocation of services. This document is intended for: l
Data configuration engineer
l
Installation and commissioning engineer
Symbol Conventions The symbols that may be found in this document are defined as follows. Symbol
Description
DANGER
WARNING
CAUTION Issue 02 (2011-06-30)
Indicates a hazard with a high level of risk, which if not avoided, will result in death or serious injury. Indicates a hazard with a medium or low level of risk, which if not avoided, could result in minor or moderate injury. Indicates a potentially hazardous situation, which if not avoided, could result in equipment damage, data loss, performance degradation, or unexpected results.
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OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide
About This Document
Symbol
Description
TIP
Indicates a tip that may help you solve a problem or save time.
NOTE
Provides additional information to emphasize or supplement important points of the main text.
GUI Conventions The GUI conventions that may be found in this document are defined as follows. Convention
Description
Boldface
Buttons, menus, parameters, tabs, window, and dialog titles are in boldface. For example, click OK.
>
Multi-level menus are in boldface and separated by the ">" signs. For example, choose File > Create > Folder.
Change History Updates between document issues are cumulative. Therefore, the latest document issue contains all updates made in previous issues.
Changes in Issue 02 (2011-06-30) Based on Product Version V100R003C00 This document is the second issue for product version V100R003C00. The updates in this issue are described as follows: l
Related contents are updated based on the mapping NMS GUIs.
Changes in Issue 01 (2011-04-30) Based on Product Version V100R003C00 This document is the first issue for product version V100R003C00.
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Contents About This Document...................................................................................................................iii 1 Getting Started............................................................................................................................1-1 1.1 Starting or Shutting Down the U2000.............................................................................................................1-2 1.1.1 Starting the U2000 Server......................................................................................................................1-2 1.1.2 Logging In to the U2000 Client.............................................................................................................1-3 1.1.3 Exiting a U2000 Client...........................................................................................................................1-3 1.1.4 Shutting Down the U2000 Server..........................................................................................................1-3 1.2 Main Windows and Common Operations of the U2000.................................................................................1-4 1.2.1 Components of the Client GUI...............................................................................................................1-4 1.2.2 Key GUI Components............................................................................................................................1-6 1.2.3 Frequently Used Buttons........................................................................................................................1-7 1.2.4 Shortcut Icon..........................................................................................................................................1-9 1.2.5 Common Shortcut Keys.......................................................................................................................1-13 1.2.6 Main Windows.....................................................................................................................................1-14 1.2.6.1 Workbench........................................................................................................................................1-15 1.2.6.2 Main Topology..................................................................................................................................1-15 1.2.6.3 NE Explorer.......................................................................................................................................1-17 1.2.6.4 Clock View........................................................................................................................................1-18 1.2.6.5 NE Panel............................................................................................................................................1-19 1.2.6.6 Browse Alarm...................................................................................................................................1-19 1.2.6.7 Browse Event....................................................................................................................................1-19 1.2.6.8 Browse Performance Window..........................................................................................................1-20
2 Creating the Network................................................................................................................2-1 2.1 Creating NEs...................................................................................................................................................2-3 2.1.1 Creating a Single NE..............................................................................................................................2-3 2.1.2 Creating NEs in Batches........................................................................................................................2-5 2.2 Configuring the NE Data.................................................................................................................................2-6 2.2.1 Configuring the NE Data Manually.......................................................................................................2-6 2.2.2 Replicating the NE Data.........................................................................................................................2-8 2.2.3 Uploading the NE Data..........................................................................................................................2-8 2.3 Checking Board Parameters............................................................................................................................2-9 2.4 Creating Fibers..............................................................................................................................................2-11 Issue 02 (2011-06-30)
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OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide 2.4.1 Creating Fibers Automatically.............................................................................................................2-11 2.4.2 Creating Fibers Manually.....................................................................................................................2-12 2.4.3 Creating Virtual Fibers.........................................................................................................................2-13 2.4.4 Creating DCN Communication Cable..................................................................................................2-13
2.5 Creating a Topology Subnet..........................................................................................................................2-14 2.6 Configuring the Protection Subnet................................................................................................................2-14 2.6.1 Configuring a Non-Protection Chain...................................................................................................2-15 2.6.2 Configuring a Non-Protection Ring.....................................................................................................2-16 2.6.3 Creating an MS Ring Protection Subnet..............................................................................................2-16 2.6.4 Creating a Linear MS Protection Subnet..............................................................................................2-19 2.7 Configuring Clocks.......................................................................................................................................2-21 2.7.1 Configuring the NE Clock Source.......................................................................................................2-21 2.7.2 Configuring the Clock Source Protection............................................................................................2-22 2.8 Clock Configuration Parameters...................................................................................................................2-23 2.8.1 Managing External Clock Sources.......................................................................................................2-23 2.8.2 Configuring Clock Protection and Restoration....................................................................................2-27 2.8.3 Clock Quality and Status Management................................................................................................2-30 2.8.4 Retiming Management.........................................................................................................................2-32 2.9 Configuring the Orderwire Phone.................................................................................................................2-33 2.9.1 Configuring the Orderwire...................................................................................................................2-33 2.9.2 Configuring the Conference Calls........................................................................................................2-34 2.10 Configuring the Broadcast Data Service.....................................................................................................2-36 2.11 Configuring the F1 Data Service.................................................................................................................2-37 2.12 Orderwire Configuration Parameters..........................................................................................................2-37 2.12.1 Configuring Orderwire Phones..........................................................................................................2-37 2.12.2 Configuring F1 Data Interfaces..........................................................................................................2-39 2.12.3 Configuring Broadcast Data Interfaces..............................................................................................2-40
3 Configuring SDH Services.......................................................................................................3-1 3.1 Basic Concepts................................................................................................................................................3-3 3.2 Configuring Services on the Non-Protection Chain........................................................................................3-4 3.2.1 Networking Diagram..............................................................................................................................3-4 3.2.2 Signal Flow and Timeslot Allocation.....................................................................................................3-5 3.2.3 Per-NE Configuration Procedure...........................................................................................................3-5 3.2.4 End-to-End Configuration Process.........................................................................................................3-7 3.3 Configuring Services on the Non-Protection Ring......................................................................................... 3-9 3.3.1 Networking Diagram..............................................................................................................................3-9 3.3.2 Signal Flow and Timeslot Allocation...................................................................................................3-10 3.3.3 Per-NE Configuration Process.............................................................................................................3-10 3.3.4 End-to-End Configuration Process.......................................................................................................3-13 3.4 Configuring 1+1 Linear MSP Services.........................................................................................................3-15 3.4.1 Networking Diagram............................................................................................................................3-15 3.4.2 Signal Flow and Timeslot Allocation...................................................................................................3-15 vi
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3.4.3 Per-NE Configuration Process.............................................................................................................3-17 3.4.4 End-to-End Configuration Process.......................................................................................................3-19 3.5 Configuring 1:1 Linear MSP Services..........................................................................................................3-21 3.5.1 Networking Diagram............................................................................................................................3-21 3.5.2 Signal Flow and Timeslot Allocation...................................................................................................3-21 3.5.3 Per-NE Configuration Process.............................................................................................................3-22 3.5.4 End-to-End Configuration Process.......................................................................................................3-25 3.6 Configuring Two-Fiber Unidirectional MSP Services..................................................................................3-26 3.6.1 Networking Diagram............................................................................................................................3-27 3.6.2 Signal Flow and Timeslot Allocation...................................................................................................3-27 3.6.3 Per-NE Configuration Process.............................................................................................................3-29 3.6.4 End-to-End Configuration Process.......................................................................................................3-35 3.7 Configuring the Two-Fiber Bidirectional MSP Services..............................................................................3-37 3.7.1 Networking Diagram............................................................................................................................3-37 3.7.2 Signal Flow and Timeslot Allocation...................................................................................................3-38 3.7.3 Per-NE Configuration Process.............................................................................................................3-39 3.7.4 End-to-End Configuration Process.......................................................................................................3-42 3.8 Configuring Services on the SNCP Ring......................................................................................................3-44 3.8.1 Networking Diagram............................................................................................................................3-45 3.8.2 Signal Flow and Timeslot Allocation...................................................................................................3-45 3.8.3 Per-NE Configuration Process.............................................................................................................3-46 3.8.4 End-to-End Configuration Process.......................................................................................................3-49 3.9 Configuring Services on the SNCP Ring with a Non-Protection Chain.......................................................3-51 3.9.1 Networking Diagram............................................................................................................................3-52 3.9.2 Signal Flow and Timeslot Allocation...................................................................................................3-53 3.9.3 Per-NE Configuration Process.............................................................................................................3-54 3.9.4 End-to-End Configuration Process.......................................................................................................3-59 3.10 Configuring Service on the MSP Ring with a Non-Protection Chain.........................................................3-61 3.10.1 Networking Diagram..........................................................................................................................3-62 3.10.2 Signal Flow and Timeslot Allocation.................................................................................................3-63 3.10.3 Per-NE Configuration Process...........................................................................................................3-63 3.10.4 End-to-End Configuration Process.....................................................................................................3-66 3.11 Protection Configuration Parameters..........................................................................................................3-68 3.11.1 SNCP Configuration..........................................................................................................................3-68 3.11.2 Configuring the Multiplex Section Protection...................................................................................3-69
4 Configuring Ethernet Services................................................................................................4-1 4.1 Service Types..................................................................................................................................................4-3 4.2 Basic Concepts................................................................................................................................................4-7 4.2.1 Formats of Ethernet Frames...................................................................................................................4-8 4.2.2 Internal Ports and External Ports..........................................................................................................4-11 4.2.3 Auto-Negotiation..................................................................................................................................4-11 4.2.4 Flow Control........................................................................................................................................4-13 Issue 02 (2011-06-30)
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OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide 4.2.5 Encapsulation and Mapping Protocol..................................................................................................4-14 4.2.6 Virtual Concatenation..........................................................................................................................4-15 4.2.7 Tag Attribute........................................................................................................................................4-17 4.2.8 Bridge...................................................................................................................................................4-19
4.3 Flow of Configuring Ethernet Services.........................................................................................................4-22 4.3.1 Flow of Configuring EPL Services......................................................................................................4-23 4.3.2 Flow of Configuring EVPL Services...................................................................................................4-25 4.3.3 Flow of Configuring EPLAN Services................................................................................................4-27 4.3.4 Flow of Configuring EVPLAN Services.............................................................................................4-30 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board...............................................4-33 4.4.1 Networking Diagram............................................................................................................................4-34 4.4.2 Signal Flow and Timeslot Allocation...................................................................................................4-35 4.4.3 Configuration Process..........................................................................................................................4-36 4.5 Configuring EPL Services on an Ethernet Switching Board........................................................................4-43 4.5.1 Networking Diagram............................................................................................................................4-44 4.5.2 Signal Flow and Timeslot Allocation...................................................................................................4-45 4.5.3 Configuration Process..........................................................................................................................4-46 4.5.4 Configuration Process (End-to-End Mode)..........................................................................................4-56 4.6 Configuring PORT-Shared EVPL (VLAN) Services...................................................................................4-59 4.6.1 Networking Diagram............................................................................................................................4-60 4.6.2 Signal Flow and Timeslot Allocation...................................................................................................4-61 4.6.3 Configuration Process..........................................................................................................................4-63 4.7 Configuring VCTRUNK-Shared EVPL (VLAN) Services..........................................................................4-72 4.7.1 Networking Diagram............................................................................................................................4-73 4.7.2 Signal Flow and Timeslot Allocation...................................................................................................4-74 4.7.3 Configuration Process..........................................................................................................................4-75 4.8 Configuring EPLAN Services (IEEE 802.1d Bridge)...................................................................................4-83 4.8.1 Networking Diagram............................................................................................................................4-83 4.8.2 Signal Flow and Timeslot Allocation...................................................................................................4-84 4.8.3 Configuration Process..........................................................................................................................4-86 4.9 Configuring EVPLAN Services (IEEE 802.1q Bridge)................................................................................4-96 4.9.1 Networking Diagram............................................................................................................................4-97 4.9.2 Signal Flow and Timeslot Allocation...................................................................................................4-98 4.9.3 Configuration Process........................................................................................................................4-101 4.10 Configuring EVPLAN Services (IEEE 802.1ad Bridge)..........................................................................4-115 4.10.1 Networking Diagram........................................................................................................................4-115 4.10.2 Signal Flow and Timeslot Allocation...............................................................................................4-117 4.10.3 Configuration Process......................................................................................................................4-119 4.11 Ethernet Port Configuration Parameters...................................................................................................4-130 4.11.1 Basic Attributes................................................................................................................................4-131 4.11.2 Flow Control....................................................................................................................................4-132 4.11.3 Network Attributes...........................................................................................................................4-133 viii
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4.11.4 Advanced Attributes.........................................................................................................................4-134 4.11.5 TAG Attributes.................................................................................................................................4-137 4.11.6 Encapsulation/Mapping....................................................................................................................4-138 4.11.7 Bound Path.......................................................................................................................................4-139 4.12 Ethernet Service Configuration Parameters..............................................................................................4-140 4.12.1 Configuring Ethernet Private Line Services.....................................................................................4-140 4.12.2 Configuring Ethernet Private Network Services..............................................................................4-150
5 Modifying the Configuration Data.........................................................................................5-1 5.1 Changing the Values of NE Attributes............................................................................................................5-2 5.1.1 Changing the NE ID...............................................................................................................................5-2 5.1.2 Changing the NE Name..........................................................................................................................5-3 5.1.3 Deleting an NE.......................................................................................................................................5-3 5.1.4 Changing the Parameter Values of the Gateway NE............................................................................. 5-4 5.1.5 Changing the Gateway NE of a Non-Gateway NE................................................................................5-5 5.2 Modifying the Board Configuration Data.......................................................................................................5-6 5.2.1 Adding Boards........................................................................................................................................5-6 5.2.2 Deleting Boards......................................................................................................................................5-7 5.2.3 Modifying Board Configuration Parameters..........................................................................................5-7 5.3 Modifying the Fiber Configuration Data........................................................................................................ 5-8 5.3.1 Deleting Fibers.......................................................................................................................................5-8 5.3.2 Changing Fiber/Cable Information........................................................................................................ 5-8 5.3.3 Deleting DCN Communication Cables..................................................................................................5-9 5.4 Modifying the Service Configuration Data.....................................................................................................5-9 5.4.1 Modifying SDH Services.......................................................................................................................5-9 5.4.2 Deleting SDH Services.........................................................................................................................5-11 5.4.3 Deleting Ethernet Private Line Services..............................................................................................5-11 5.4.4 Deleting EPLAN Services....................................................................................................................5-12 5.4.5 Deleting EVPLAN Services.................................................................................................................5-13 5.5 Modifying the Protection Subnet..................................................................................................................5-13 5.5.1 Deleting Protection Subnets.................................................................................................................5-14 5.5.2 Changing the Values of Protection Subnet Parameters........................................................................5-14
6 Equipment Information............................................................................................................6-1 6.1 Service Support Capability of Ethernet Boards.............................................................................................. 6-2 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards........................................................6-2 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards...................................................6-3
7 List of Parameters.......................................................................................................................7-1 7.1 Port Attributes (Ethernet Port)........................................................................................................................ 7-6 7.2 Maximum Frame Length (Ethernet Port Attribute)........................................................................................ 7-7 7.3 Non-Autonegotiation Flow Control Mode (Ethernet Port Attribute)..............................................................7-8 7.4 Autonegotiation Flow Control Mode (Ethernet Port Attribute)......................................................................7-9 7.5 MAC Loopback (Ethernet Port Attribute)....................................................................................................7-10 Issue 02 (2011-06-30)
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7.6 PHY Loopback (Ethernet Port Attribute)......................................................................................................7-10 7.7 QinQ Type Area............................................................................................................................................7-11 7.8 Loop Detection (Ethernet Port Attribute)......................................................................................................7-12 7.9 Loop Port Shutdown (Ethernet Port Attribute).............................................................................................7-13 7.10 Traffic Threshold(Mbit/s)(External Ethernet Port Attribute)......................................................................7-13 7.11 Broadcast Packet Suppression Threshold (Ethernet Interface Attributes)..................................................7-14 7.12 Broadcast Packet Suppression (Ethernet Interface Attributes)...................................................................7-15 7.13 Zero-Flow Monitor (Ethernet Interface Attributes)....................................................................................7-15 7.14 Port Traffic Threshold Time Window(Min)...............................................................................................7-16 7.15 Jumbo Frame Type......................................................................................................................................7-17 7.16 Default VLAN ID (Ethernet Port Attribute)...............................................................................................7-17 7.17 VLAN Priority (Ethernet Port Attribute)....................................................................................................7-18 7.18 Entry Detection (Ethernet Port Attribute)...................................................................................................7-19 7.19 TAG.............................................................................................................................................................7-19 7.20 Mapping Protocol........................................................................................................................................7-21 7.21 Scramble......................................................................................................................................................7-22 7.22 Set Inverse Value for CRC..........................................................................................................................7-23 7.23 Check Field Length.....................................................................................................................................7-24 7.24 FCS Calculated Bit Sequence.....................................................................................................................7-25 7.25 Operation Type (EPL Service)....................................................................................................................7-26 7.26 Service Type (EPL Service)........................................................................................................................7-28 7.27 Encapsulation Format of P Port (Network Attributes)................................................................................7-28 7.28 C-VLAN and S-VLAN...............................................................................................................................7-30 7.29 VLAN ID (For Creation of Ethernet Virtual Private Lines).......................................................................7-31 7.30 Bridge Learning Mode (Ethernet LAN Service).........................................................................................7-31 7.31 MEP ID (Ethernet OAM)............................................................................................................................7-32 7.32 Maintenance Point Type (Ethernet OAM)..................................................................................................7-33 7.33 CC Status (Ethernet OAM).........................................................................................................................7-34 7.34 Test Result (LB and LT Test).....................................................................................................................7-34 7.35 Responding MP Type (Ethernet LT Test)...................................................................................................7-35 7.36 Hop Count (Ethernet LT Test)....................................................................................................................7-35 7.37 Packet Length (Ping Test)...........................................................................................................................7-36 7.38 Timeout (Ping Test)....................................................................................................................................7-37 7.39 Detect Attempts...........................................................................................................................................7-37 7.40 Send Direction (Ethernet Test)....................................................................................................................7-38 7.41 Error Frame Monitor Window (ms)............................................................................................................7-39 7.42 Error Frame Monitor Threshold(Entries)....................................................................................................7-39 7.43 Error Frame Period Window(Frames).........................................................................................................7-40 7.44 Error Frame Monitor Threshold(Frames)...................................................................................................7-41 7.45 Error Frame Second Window (s)................................................................................................................7-42 7.46 Error Frame Second Threshold(s)...............................................................................................................7-42 7.47 Enable OAM Protocol.................................................................................................................................7-43 x
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7.48 OAM Working Mode..................................................................................................................................7-43 7.49 Remote Alarm Support for Link Event.......................................................................................................7-44 7.50 Unidirectional Operation.............................................................................................................................7-45 7.51 Loopback Status (OAM Parameter)............................................................................................................7-46 7.52 Flow Type (Flow Configuration)................................................................................................................7-46 7.53 Bound CAR (Flow Configuration)..............................................................................................................7-47 7.54 Bound CoS (Flow Configuration)...............................................................................................................7-48 7.55 CAR ID (CAR Configuration)....................................................................................................................7-49 7.56 Enabled/Disabled (CAR Configuration).....................................................................................................7-49 7.57 Committed Information Rate (kbit/s) (CAR Configuration).......................................................................7-50 7.58 Committed Burst Size (kbyte) (CAR Configuration).................................................................................7-51 7.59 Peak Information Rate (kbit/s) (CAR Configuration).................................................................................7-51 7.60 Maximum Burst Size (kbyte) (CAR Configuration)...................................................................................7-52 7.61 CoS ID (CoS Configuration).......................................................................................................................7-53 7.62 CoS Type (CoS Configuration)...................................................................................................................7-53 7.63 CoS Priority (CoS Configuration)...............................................................................................................7-54 7.64 Port Priority (Link Aggregation).................................................................................................................7-56 7.65 System Priority (Link Aggregation)............................................................................................................7-56 7.66 Status (Link Aggregation)...........................................................................................................................7-57 7.67 Load Sharing(Ethernet Link Aggregation)..................................................................................................7-58 7.68 Protocol Enabled (Spanning Tree)..............................................................................................................7-59 7.69 Protocol Type (Spanning Tree Protocol)....................................................................................................7-59 7.70 Priority (Bridge Parameters).......................................................................................................................7-60 7.71 Max Age(s)..................................................................................................................................................7-61 7.72 Hello Time(s) (Spanning Tree)...................................................................................................................7-61 7.73 Forward Delay(s) (Spanning Tree).............................................................................................................7-62 7.74 TxHoldCount(per second) (Spanning Tree)................................................................................................7-63 7.75 Root Path Cost.............................................................................................................................................7-63 7.76 Hold Count (Spanning Tree).......................................................................................................................7-64 7.77 Port ID.........................................................................................................................................................7-64 7.78 Designated Path Cost..................................................................................................................................7-65 7.79 Designated Root Bridge Priority.................................................................................................................7-66 7.80 Designated Bridge Priority(Spanning Tree)................................................................................................7-67 7.81 Designated Bridge MAC Address (Spanning Tree)....................................................................................7-67 7.82 Edge Port Status (Spanning Tree)...............................................................................................................7-68 7.83 Point to Point Attributes(External Ethernet Port Attributes)......................................................................7-69 7.84 Enabling LCAS...........................................................................................................................................7-70 7.85 LCAS Mode................................................................................................................................................7-70 7.86 Hold-Off Time (ms) (LCAS)......................................................................................................................7-71 7.87 WTR Time (s) (LCAS)...............................................................................................................................7-72 7.88 TSD (LCAS)...............................................................................................................................................7-72 7.89 Min Members - Transmit Direction............................................................................................................7-73 Issue 02 (2011-06-30)
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7.90 LPT..............................................................................................................................................................7-74 7.91 Bearer Mode................................................................................................................................................7-74 7.92 Port-Type Port Hold-Off Time (ms)...........................................................................................................7-75 7.93 VCTRUNK Port Hold-off Time (ms).........................................................................................................7-76 7.94 Protocol Enable (IGMP Snooping Protocol)...............................................................................................7-76 7.95 Multicast Aging Time(Min)........................................................................................................................7-77 7.96 Frames to Send............................................................................................................................................7-78 7.97 Status...........................................................................................................................................................7-78 7.98 Set Frame Count..........................................................................................................................................7-79 7.99 Received Response Test Frame Count........................................................................................................7-80 7.100 Test Frames to Receive.............................................................................................................................7-80 7.101 Send Mode (Ethernet Test).......................................................................................................................7-81 7.102 Call Waiting Time(s).................................................................................................................................7-82 7.103 Conference Call.........................................................................................................................................7-82 7.104 Phone.........................................................................................................................................................7-83 7.105 Available Orderwire Port..........................................................................................................................7-84 7.106 No.(F1 Data Port)......................................................................................................................................7-85 7.107 Data Channel (F1 Data Port).....................................................................................................................7-85 7.108 Overhead Byte (Broadcast Data Port).......................................................................................................7-86 7.109 Working Mode (Broadcast Data Port)......................................................................................................7-87 7.110 Broadcast Data Source (Broadcast Data Port)..........................................................................................7-88 7.111 Broadcast Data Sink (Broadcast Data Port)..............................................................................................7-88 7.112 External Clock Output Mode When 2M Output Synchronous Source Is Invalid.....................................7-89 7.113 External Clock Output Mode....................................................................................................................7-90 7.114 External Clock Output Timeslot...............................................................................................................7-91 7.115 External Source Output Threshold............................................................................................................7-92 7.116 2M Phase-Locked Source Fail Condition.................................................................................................7-94 7.117 2M Phase-Locked Source Fail Action......................................................................................................7-95 7.118 Clock Source Threshold............................................................................................................................7-96 7.119 AIS Alarm Generated................................................................................................................................7-97 7.120 B1 BER Threshold-Crossing Generated...................................................................................................7-98 7.121 B2-EXC Alarm Generated........................................................................................................................7-99 7.122 Higher Priority Clock Source Reversion Mode......................................................................................7-100 7.123 Clock Source WTR Time........................................................................................................................7-101 7.124 Lock Status..............................................................................................................................................7-101 7.125 Synchronous Source................................................................................................................................7-102 7.126 S1 Byte Synchronization Quality Information........................................................................................7-103 7.127 NE Clock Working Mode.......................................................................................................................7-104 7.128 Data Output Method in Holdover Mode.................................................................................................7-105 7.129 Retiming Mode........................................................................................................................................7-106 7.130 Switching Mode (MSP)...........................................................................................................................7-107
A Glossary and Acronyms..........................................................................................................A-1 xii
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A.1 Numerics........................................................................................................................................................A-3 A.2 A....................................................................................................................................................................A-3 A.3 B....................................................................................................................................................................A-5 A.4 C....................................................................................................................................................................A-7 A.5 D....................................................................................................................................................................A-9 A.6 E...................................................................................................................................................................A-10 A.7 F...................................................................................................................................................................A-12 A.8 G..................................................................................................................................................................A-14 A.9 H..................................................................................................................................................................A-15 A.10 I..................................................................................................................................................................A-15 A.11 J..................................................................................................................................................................A-17 A.12 L.................................................................................................................................................................A-17 A.13 M................................................................................................................................................................A-18 A.14 N................................................................................................................................................................A-20 A.15 O................................................................................................................................................................A-21 A.16 P.................................................................................................................................................................A-22 A.17 Q................................................................................................................................................................A-24 A.18 R................................................................................................................................................................A-24 A.19 S.................................................................................................................................................................A-26 A.20 T.................................................................................................................................................................A-29 A.21 U................................................................................................................................................................A-30 A.22 V................................................................................................................................................................A-31 A.23 W...............................................................................................................................................................A-31
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Figures
Figures Figure 1-1 Client GUI..........................................................................................................................................1-5 Figure 1-2 Main Topology.................................................................................................................................1-16 Figure 3-1 Networking diagram of the non-protection chain...............................................................................3-4 Figure 3-2 Signal flow and timeslot allocation of the services on the non-protection chain...............................3-5 Figure 3-3 Networking diagram of the non-protection ring.................................................................................3-9 Figure 3-4 Signal flow and timeslot allocation of the services on the non-protection ring...............................3-10 Figure 3-5 Networking diagram of the 1+1 linear MSP services.......................................................................3-15 Figure 3-6 Signal flow and timeslot allocation of the 1+1 linear MSP services ...............................................3-16 Figure 3-7 Networking diagram of the 1:1 linear MSP services........................................................................3-21 Figure 3-8 Signal flow and timeslot allocation of the 1:1 linear MSP services.................................................3-22 Figure 3-9 Networking diagram of the services on the two-fiber unidirectional MSP ring ..............................3-27 Figure 3-10 Signal flow and timeslot allocation of the two-fiber unidirectional MSP services .......................3-29 Figure 3-11 Networking diagram of the services on the two-fiber bidirectional MSP ring...............................3-38 Figure 3-12 Signal flow and timeslot allocation................................................................................................3-39 Figure 3-13 Networking diagram of the services on the SNCP ring .................................................................3-45 Figure 3-14 Signal flow and timeslot allocation ...............................................................................................3-46 Figure 3-15 Networking diagram of the services on the SNCP ring with a non-protection chain ....................3-53 Figure 3-16 Signal flow and timeslot allocation................................................................................................3-54 Figure 3-17 Networking diagram of the services on the two-fiber bidirectional MSP ring with a non-protection chain ...................................................................................................................................................................3-62 Figure 3-18 Signal flow and timeslot allocation ...............................................................................................3-63 Figure 4-1 EPL services.......................................................................................................................................4-3 Figure 4-2 PORT-shared EVPL services ............................................................................................................4-4 Figure 4-3 VCTRUNK-shared EVPL services ...................................................................................................4-4 Figure 4-4 EPLAN services (IEEE 802.1d bridge) .............................................................................................4-5 Figure 4-5 EVPLAN services (IEEE 802.1q bridge) ..........................................................................................4-6 Figure 4-6 EVPLAN services (IEEE 802.1ad bridge).........................................................................................4-7 Figure 4-7 Formats of Ethernet frames................................................................................................................4-9 Figure 4-8 Positions of the TPID and TCI in the frame structure .......................................................................4-9 Figure 4-9 TCI structure of the C-TAG ............................................................................................................4-10 Figure 4-10 TCI structure of the S-TAG ...........................................................................................................4-10 Figure 4-11 External ports and internal ports on Ethernet boards .....................................................................4-11 Figure 4-12 Waveform of a single FLP .............................................................................................................4-12 Figure 4-13 Consecutive FLP and NLP bursts ..................................................................................................4-12 Issue 02 (2011-06-30)
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Figures
OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide Figure 4-14 Structure of the PAUSE frame....................................................................................................... 4-14 Figure 4-15 VC-3-Xv/VC4-Xv multiframe and sequence indicator .................................................................4-17
Figure 4-16 Relations between VBs, LPs, PORTs, and VCTRUNKs...............................................................4-19 Figure 4-17 Transparent bridge and virtual bridge.............................................................................................4-20 Figure 4-18 Flow of configuring EPL services .................................................................................................4-24 Figure 4-19 Flow of configuring EVPL services ..............................................................................................4-26 Figure 4-20 Flow of configuring EPLAN services............................................................................................4-28 Figure 4-21 Flow of configuring EVPLAN services ........................................................................................ 4-31 Figure 4-22 Networking diagram of the EPL services.......................................................................................4-34 Figure 4-23 Signal flow and timeslot allocation (Ethernet transparent transmission board).............................4-35 Figure 4-24 Networking diagram of the EPL services.......................................................................................4-44 Figure 4-25 Signal flow and timeslot allocation (Ethernet switching board) ................................................... 4-45 Figure 4-26 Networking diagram for configuring PORT-shared EVPL (VLAN) services ..............................4-60 Figure 4-27 Signal flow and timeslot allocation................................................................................................4-61 Figure 4-28 Networking diagram for configuring VCTRUNK-shared EVPL (VLAN) services .....................4-73 Figure 4-29 Signal flow and timeslot allocation................................................................................................4-74 Figure 4-30 Networking diagram for configuring EPLAN services (IEEE 802.1d bridge) ............................. 4-84 Figure 4-31 Signal flow of and timeslot allocation ...........................................................................................4-84 Figure 4-32 Networking diagram for configuring EVPLAN services (IEEE 802.1q bridge) ...........................4-97 Figure 4-33 Signal flow of and timeslot allocation to EVPLAN services (IEEE 802.1q bridge)......................4-98 Figure 4-34 Networking diagram for configuring EVPLAN services (IEEE 802.1ad bridge) .......................4-116 Figure 4-35 Signal flow of and timeslot allocation to EVPLAN services (IEEE 802.1ad bridge)..................4-117 Figure 7-1 Encapsulation format of MartinioE..................................................................................................7-29 Figure 7-2 Encapsulation format of Stack VLAN..............................................................................................7-30 Figure 7-3 An example of number of hops........................................................................................................ 7-36
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Tables
Tables Table 2-1 SDH board parameters.........................................................................................................................2-9 Table 2-2 PDH board parameters.......................................................................................................................2-10 Table 2-3 Parameters for configuring the output phase-locked source table of an external clock.....................2-24 Table 2-4 Parameters for configuring the 2M phase-locked source attributes of an external clock..................2-25 Table 2-5 Parameters used for configuring clock protection and restoration.....................................................2-27 Table 2-6 Parameter description: clock synchronization status.........................................................................2-30 Table 2-7 Parameters used for retiming.............................................................................................................2-32 Table 2-8 Parameters for configuring orderwire phones....................................................................................2-38 Table 2-9 Parameters for configuring F1 data interfaces...................................................................................2-39 Table 2-10 Parameters for configuring broadcast data interfaces......................................................................2-40 Table 3-1 Parameters for configuring the SNCP................................................................................................3-68 Table 3-2 Parameters for configuring the MSP..................................................................................................3-70 Table 4-1 Corresponding relations between the external ports and the VCTRUNKs (EPL services).................4-3 Table 4-2 Corresponding relations between the PORTs and the VCTRUNKs (PORT-shared EVPL services) ...............................................................................................................................................................................4-4 Table 4-3 Corresponding relations between the PORTs and the VCTRUNKs (VCTRUNK-shared EVPL services) ...............................................................................................................................................................................4-5 Table 4-4 Tag types defined by using the TPID...................................................................................................4-9 Table 4-5 Processing mode of data frames on ports with different tags............................................................4-18 Table 4-6 Transparent Bridge and Virtual Bridge..............................................................................................4-20 Table 4-7 Types of bridges supported by the Ethernet boards...........................................................................4-21 Table 4-8 Flow of configuring EPL services .....................................................................................................4-24 Table 4-9 Flow of configuring EVPL services ..................................................................................................4-26 Table 4-10 Flow of configuring EPLAN services..............................................................................................4-28 Table 4-11 Flow of configuring EVPLAN services ..........................................................................................4-32 Table 4-12 Parameters of external ports on the Ethernet boards........................................................................4-35 Table 4-13 Parameters of internal ports on the Ethernet boards........................................................................4-36 Table 4-14 Parameters of external ports on the Ethernet boards........................................................................4-45 Table 4-15 Parameters of internal ports on the Ethernet boards........................................................................4-46 Table 4-16 Parameters of the EPL services........................................................................................................4-46 Table 4-17 Parameters of the VC-4 server trail between user A1 and user A2..................................................4-57 Table 4-18 Parameters of the VC-4 server trail route between user A1 and user A2........................................4-57 Table 4-19 Parameters of the EPL services between user A1 and user A2........................................................4-58 Table 4-20 Parameters of port attributes for user A1 and user A2.....................................................................4-59 Issue 02 (2011-06-30)
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Tables
OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide Table 4-21 Parameters of external ports on the Ethernet boards........................................................................4-62 Table 4-22 Parameters of internal ports on the Ethernet boards........................................................................4-62 Table 4-23 Parameters of the PORT-shared EVPL (VLAN) services...............................................................4-62 Table 4-24 Parameters of external ports on the Ethernet boards........................................................................4-74 Table 4-25 Parameters of internal ports on the Ethernet boards........................................................................4-75 Table 4-26 Parameters of the VCTRUNK-shared EVPL (VLAN) services......................................................4-75 Table 4-27 Parameters of external ports on the Ethernet boards........................................................................4-85 Table 4-28 Parameters of internal ports on the Ethernet boards........................................................................4-85 Table 4-29 Parameters of Ethernet LAN services (IEEE 802.1d bridge)...........................................................4-86 Table 4-30 Parameters of external ports on the Ethernet boards........................................................................4-99 Table 4-31 Parameters of internal ports on the Ethernet boards........................................................................4-99 Table 4-32 Parameters of Ethernet LAN services (IEEE 802.1q bridge).........................................................4-100 Table 4-33 Parameters of external ports on the Ethernet boards......................................................................4-118 Table 4-34 Parameters of internal ports on the Ethernet boards......................................................................4-118 Table 4-35 Parameters of Ethernet LAN services (IEEE 802.1ad bridge).......................................................4-119 Table 4-36 Parameters for configuring the basic attributes of an Ethernet port...............................................4-131 Table 4-37 Parameters for configuring flow control of an Ethernet port.........................................................4-133 Table 4-38 Parameters for configuring network attributes of an Ethernet port................................................4-134 Table 4-39 Parameters for configuring the advanced attributes of an Ethernet port........................................4-134 Table 4-40 Parameters for configuring the tag attributes of an Ethernet port..................................................4-137 Table 4-41 Parameters for configuring the encapsulation and mapping of an Ethernet port...........................4-138 Table 4-42 Parameters for bound path.............................................................................................................4-139 Table 4-43 Parameters for configuring Ethernet private line services.............................................................4-141 Table 4-44 Parameters for configuring Ethernet private network services......................................................4-150 Table 4-45 Parameters for configuring service mount.....................................................................................4-151 Table 4-46 Parameters for configuring VLAN filtering...................................................................................4-153 Table 4-47 Parameters for configuring VLAN unicast....................................................................................4-153 Table 4-48 Parameters for configuring disable MAC address.........................................................................4-154 Table 4-49 Parameters for bound path.............................................................................................................4-154 Table 6-1 Service support capability of Ethernet boards......................................................................................6-2 Table 6-2 Requirements for binding paths with VCTRUNKs on Ethernet boards..............................................6-2 Table 7-1 The mapping protocol supported by each type of board....................................................................7-22 Table 7-2 Scramble supported by each type of board........................................................................................7-23 Table 7-3 The length of the CRC field supported by each type of board...........................................................7-24 Table 7-4 FCS calculated bit sequence supported by each type of boards.........................................................7-25 Table 7-5 CoS priority of the simple type..........................................................................................................7-54 Table 7-6 CoS priority of the VLAN Priority type............................................................................................7-55 Table 7-7 CoS priority of the DSCP type...........................................................................................................7-55 Table 7-8 CoS priority of the IPTOS type..........................................................................................................7-55 Table 7-9 Recommended values of the port path cost........................................................................................7-65
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1
Getting Started
About This Chapter The following topices introduce some preparation operations that will ensure a smooth, troublefree launch of the U2000. 1.1 Starting or Shutting Down the U2000 The U2000 uses the standard client/server architecture and multiple-user mode. So, you are recommended to start or shut down the U2000 by strictly observing the following procedure, in order not to affect other users that are operating the U2000. 1.2 Main Windows and Common Operations of the U2000 This topic describes the main windows of the U2000 client. Learning the main windows helps you to locate the entrances to operations quickly, which increased your operation efficiency.
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1.1 Starting or Shutting Down the U2000 The U2000 uses the standard client/server architecture and multiple-user mode. So, you are recommended to start or shut down the U2000 by strictly observing the following procedure, in order not to affect other users that are operating the U2000.
Context l
You are recommended to start the computer and theU2000 application in the following sequence: Start the computer, start theU2000 server, and then start theU2000 client.
l
You are recommended to shut down theU2000 application and the computer in the following sequence: Exit theU2000 client, stop theU2000 server, and then shut down the computer.
1.1.1 Starting the U2000 Server For network management first start theU2000 server, and then start theU2000 application. 1.1.2 Logging In to the U2000 Client To manage networks through the U2000 client graphical user interface, you need to use theU2000 client to log in to the U2000 server. 1.1.3 Exiting a U2000 Client Before shutting down the U2000 server, you must exit the U2000 client. 1.1.4 Shutting Down the U2000 Server When the U2000 server is managing the system normally, do not perform this operation. In special circumstances, for example, when modifying the system time of the computer where the U2000 resides, or when upgrading the version, you can use the System Monitor Client to shut down the U2000 server.
1.1.1 Starting the U2000 Server For network management first start theU2000 server, and then start theU2000 application.
Prerequisite l
The computer time must be set correctly.
l
The computer where theU2000 is installed must be started correctly.
l
The operating system of theU2000 server must be running correctly and the database must be started normally.
l
TheU2000 license must be in the server directory.
l
The instance must be deployed.
Procedure
Step 1 Double-click the shortcut icon
to start U2000 Server.
Step 2 In the Login dialog box, enter the user name and password. The user name is admin and the password is null by default. Change the password of the default user at the first login. Then, click Login to display the System Monitor window. 1-2
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NOTE
Periodically change the password and memorize it.
You can login to theU2000 client, checking whether the status of each process is Running. ----End
1.1.2 Logging In to the U2000 Client To manage networks through the U2000 client graphical user interface, you need to use theU2000 client to log in to the U2000 server.
Prerequisite The U2000 server must be started correctly.
Procedure Step 1 Double-click the U2000 Client shortcut icon. Step 2 In the Login dialog box, enter the user name and password. The user name is admin and the password is null by default. Change the password of the default user at the first login. Then, click Login. Step 3 Optional: For the first login, you need to configure the access control list of the system. ----End
1.1.3 Exiting a U2000 Client Before shutting down the U2000 server, you must exit the U2000 client.
Prerequisite The U2000 client must be started normally.
Procedure Step 1 Choose File > Exit from the main menu. Step 2 Click OK in the confirmation dialog box. NOTE
If the layout of the view is changed and not saved, the Confirm dialog box appears asking you whether to save the changes. After you confirm the dialog box, automatically exit the client.
----End
1.1.4 Shutting Down the U2000 Server When the U2000 server is managing the system normally, do not perform this operation. In special circumstances, for example, when modifying the system time of the computer where the U2000 resides, or when upgrading the version, you can use the System Monitor Client to shut down the U2000 server. Issue 02 (2011-06-30)
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Prerequisite All the U2000 clients connected to the U2000 server must be shut down.
Procedure Step 1 From the Main Menu of System Monitor Client, choose System > Stop All NMS Services to close all processes of the U2000 server. Step 2 Click OK in the confirmation dialog box. Wait until the U2000 core process, and the processes that are optional according to the actual situation are in the Stopped state. Now the U2000 server is shut down successfully. Now you cannot shut down the MDP process or initialize the database. Step 3 Click OK in the confirmation dialog box. Wait until the U2000 processes are all in Stopped status. Now the server is shut down successfully. Now you cannot shut down the MDP process or initialize the database. ----End
1.2 Main Windows and Common Operations of the U2000 This topic describes the main windows of the U2000 client. Learning the main windows helps you to locate the entrances to operations quickly, which increased your operation efficiency. 1.2.1 Components of the Client GUI This topic describes the components of the client GUI. 1.2.2 Key GUI Components The key U2000 GUI components are as follows: 1.2.3 Frequently Used Buttons The frequently used buttons on the U2000 GUI are as follows: 1.2.4 Shortcut Icon This topic describes the shortcut icons on the Main Topology. 1.2.5 Common Shortcut Keys This topic describes the common shortcut keys. Using shortcut keys, you can increase the operation efficiency. The shortcut keys include Enter, Ctrl, Esc, and Tab. 1.2.6 Main Windows This topic describes the main windows of the U2000 client. And tells you what you can do in the windows.
1.2.1 Components of the Client GUI This topic describes the components of the client GUI. Figure 1-1 shows the client GUI.
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Figure 1-1 Client GUI
1 2
3
6
4
5 1: Menu bar
2: Toolbar
3: Workbench list
4: Output pane
5: Status bar
6: Workbench
Menu Bar The menu bar provides the entries to all the functions of the U2000 client. It consists of the following menus: File, Fault, Performance,Configuration, Service, Inventory, Administration, Window, and Help. In the topology window, the menu bar also provides the Edit and View menu items.
Toolbar The toolbar provides the shortcut icons for major operation tasks. The shortcut icons are as follows: l l
: Accesses the favorites folder. : Deregister your account.
l
: Displays in full screen.
l
: Browse Current Alarm.
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l
: Locks the U2000 client.
l
: Creates fiber.
l
: NE Explorer.
l
: Main Topology.
l
: Views the SDH performance.
l
: Views the WDM performance.
l
: Maintains the SDH protection subnet.
l
: Manages WDM trails.
l
: Creates SDH trails.
l
: Manages SDH trails.
Workbench list You can create or modify a workbench through the shortcut icons.
Output Pane The output pane displays the returned information and other relevant information.
Status Bar The status bar displays the information such as the system status, the login users, and the IP address of the connected server. The information displayed from left to right is as follows: l
Coordinate information: Displays the current position of the cursor.
l
Connection information: Displays the name and IP address of the server.
l
Login user: Displays the name of the login user.
l
Connection duration: Displays the duration of the connection between the client and the server.
l
Login mode: Displays the login mode. It can be single-user mode and multi-user mode.
l
Operation prompt: Displays the result of the operation.
l
Logo: Displays the logo of Huawei Technologies Co., Ltd.
Workbench The shortcut icons on the workbench help you perform operations.
1.2.2 Key GUI Components The key U2000 GUI components are as follows: 1-6
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Component
1 Getting Started
Example
Button Shortcut icon Radio button Check box Tab Field
Drop-down menu
Menu Function Tree
Dialog box
1.2.3 Frequently Used Buttons The frequently used buttons on the U2000 GUI are as follows: Issue 02 (2011-06-30)
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Button
Functionality Selects the objects. Expands all available options. Collapses all available options. Displays or hides a dialog box.
Selects the objects.
Selects the objects as a batch.
Increases the priority of the selected object. Decreases the priority of the selected object. Displays a dialog box. Queries results from the NE. Imposes the current settings. Displays the latest result(s). Exports the selected scheduled tasks to the browser of the operating system for printing. Saves selected data to the specified file. Makes the current setting effective and closes the dialog box. Cancels the current setting and closes the dialog box.
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Button
1 Getting Started
Functionality Allows the user to view and select the board ports. Deletes the selected data or icon. Closes the operation wizard. Creates a new service, protection or physical inventory information etc. Proceeds to the next step. Returns to the previous step. Closes the dialog box. Expands the Object Tree. Collapses the Object Tree. Makes the current setting effective and closes the dialog box. Cancels the current setting and closes the dialog box. Search the correlative information. Sets the correlative condition.
1.2.4 Shortcut Icon This topic describes the shortcut icons on the Main Topology. You can customize the toolbar so that only the frequently-used buttons are displayed on the toolbar. To customize the toolbar, right-click the toolbar and choose a menu item from the shortcut menu. Button
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Name
Description
Favorites Folder
Adds the commonly used functions to the favorites folder.
Exit
Exits from the client.
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Button
1-10
Name
Description
Lock Terminal
Locks the current client.
Main Topology
Switches to the Main Topology.
Log Out
Logs out of the current session.
Views the topology in full screen.
Views the current window in full screen.
Browse Current Alarm
Displays the Current Alarms window.
SDH Protection Subnet Maintenance
Accesses the SDH Protection Subnet Common Attributes window.
SDH Trail Management
Accesses the SDH Trail Management window.
SDH Trail Creation
Accesses the SDH Trail Creation window.
WDM Trail Management
Accesses the WDM Trail Management window.
Verify Policy
Verifies the validity of a configuration policy before the policy is deployed on devices.
Deploy Policy
Deploys a policy to the selected devices or device groups.
Undeploy Policy
Undeploys all the policies in the current policy package from the selected devices and clear the related commands deployed on these devices.
Discover Policy
Policy auditing is to audit the policy configuration differences between the NMS and device, so as to determine whether the policy needs to be deployed or discovered.
Audit Policy
Policy discovery is to recover the data synchronized to the database to the NMS for management.
Save
Saves a policy package.
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Button
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Name
Description
View History Record
Queries the history record of policy deployment or undeployment according to the device name, device IP address, status, and operator.
NE Explorer
Accesses the NE Explorer window of the selected NE.
Create Link
Creates fiber and radio links.
Browse SDH Performance
Accesses the Browse SDH Performance window.
Browse WDM Performance
Accesses the Browse WDM Performance window.
Lay Out
Lays out the NEs in the topology.
Print and Preview
Prints and previews the current topology view.
New
Selects Custom View, NESubnet, or Link from the drop-down list box.
Creat Link
Creates a link in the Main Topology.
Print
Prints the current Main Topology.
Up
Returns to the previous level.
Zoom out
Zooms out the Main Topology.
Zoom in
Zooms in the Main Topology.
Zoom in Partially
Zooms in an area selected in the Main Topology.
View Move
Moves the Main Topology. When you click this icon, the Main Topology can be moved. When you click the icon again, the Main Topology cannot be moved.
Alarm List Area
Views the alarm list area in the lower part of the Main Topology.
Search NE
Searches for an NE in the view.
Select
Selects the NE in the Main Topology.
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Button
1-12
Name
Description
Topology Navigator
Views the navigation tree in the Topology.
View Navigator
Views the view navigation tree in the Topology.
Legend&Filter&At tribute
Opens the setting area of the view to display the attribute, filter plane and legends.
NE Statistics
Views the quantity of the NE on the network.
Save the Location of the Current Submap Icons
Saves the location of the current submap icons.
Refresh View
Refreshes the current view.
Lock View
Locks out the position of an NE icon in the active view.
Unlock View
Unlocks the position of an NE icon in the active view.
NE Time Sychronization
Synchronizes the NE time and NMS time.
Synchronize Current Alarms
Synchronizes the current alarms of an NE.
Browse Current ALarms
Browses the current alarms of an NE.
Clear ALarm Indication
Clears the current alarm indications of an NE.
Refresh NE Panel Status
Refreshes the NE panel status to make the NE panel display the latest data.
Verify Configuration
Verifies the configuration data. During the verification, two risky operation prompts are displayed.
Back Up NE Database To SCC
Backs up the NE data to the SCC.
Display/Hide Extended Slot
Displays or hides the extended slot on the Extended Slot tab page.
Legend
Displays a legend and its description.
Shrink all
Shrinks Alarm/Event Name.
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1 Getting Started
Name
Description
Classify by group id
Classifies alarms by group ID.
Classify by severity
Classifies alarms by severity.
Classify by type
Classifies alarms by type.
Classify by category
Classifies alarms by category.
1.2.5 Common Shortcut Keys This topic describes the common shortcut keys. Using shortcut keys, you can increase the operation efficiency. The shortcut keys include Enter, Ctrl, Esc, and Tab.
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Shortcut Key
Description
F1
Opens the Help.
Enter
Confirms the operation or moves downward to the next line. If the cursor is on a button, pressing Enter means to confirm the operation. If the cursor is in the list box, press Enter once and the cursor then moves downward to the next line.
Esc
Closes a dialog box.
Tab
Switches between buttons if the cursor is on a button. Switch between text boxes if the cursor is in the list box.
Ctrl+F
Searches resources such as the NEs, subnets, cards, frames, interfaces, and VLANs in basic and rapid modes by pressing Ctrl+F in all views.
Ctrl+A
Selects all NEs or selects all contents in the list. If the cursor is in the view, press Ctrl+A to select all NEs. If the cursor is in the list box, press Ctrl+A to select all contents in the list.
Ctrl+C
Quickly copies the table texts.
Ctrl+V
Pastes the copied data to another text area.
Alt+F
Opens the File menu from the Main Menu.
Alt+E
Opens the Edit menu from the Main Menu.
Alt+V
Opens the View menu from the Main Menu.
Alt+U
Opens the Fault menu from the Main Menu.
Alt+P
Opens the Performance menu from the Main Menu.
Alt+C
Opens the Configuration menu from the Main Menu.
Alt+R
Opens the Service menu from the Main Menu. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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Shortcut Key
Description
Alt+I
Opens the Inventory menu from the Main Menu.
Alt+S
Opens the Administration menu from the Main Menu.
Alt+W
Opens the Window menu from the Main Menu.
Alt+H
Opens the Help menu from the Main Menu.
1.2.6 Main Windows This topic describes the main windows of the U2000 client. And tells you what you can do in the windows. 1.2.6.1 Workbench This topic describes the workbench. After a client is started, the system automatically accesses the default workbench. The default shortcut icons are displayed on the workbench. 1.2.6.2 Main Topology This topic describes the items in the Main Topology. All topology management functions can be accessed through the Main Topology in . These functions include creating topological objects, subnets, searching for the existing equipment in the network. You can search, view, create, set, and manage subnets; and search, create, configure, and maintain management functions on trails. 1.2.6.3 NE Explorer The NE Explorer is the main user interface used to manage equipment. In the NE Explorer, a user can configure, manage and maintain the NE, boards, and ports on a per-NE basis. The NE Explorer is the main user interface for commissioning and configuration on a per-NE basis. The NE Explorer contains a Function Tree that makes the operations easy. To display the configuration window for an object, the user can just select the object and then choose a desired function in the Function Tree. 1.2.6.4 Clock View The Clock View provides a visible platform to enable NE clock settings, networkwide clock synchronization status query, and clock tracing and search functions, supports the synchronous Ethernet clock, SDH clock, TOP clock, ACR clock, TDM clock, PON clock, and E1 clock, and applies to the MSTP, RTN ,PTN and router NE40E V3R7 equipment. 1.2.6.5 NE Panel The NE Panel displays boards and ports in different colors depending on their current status. In the U2000, most operations such as equipment configuration, monitoring, and maintenance are performed in the NE Panel window. 1.2.6.6 Browse Alarm This topic describes the user interface for viewing the current and history alarms, Alarm Logs. In this user interface, buttons are provided, such as Filter, Synchronize, Refresh, and Acknowledge, to help you quickly locate the alarm cause. 1.2.6.7 Browse Event In the Browse Event window, you can view events at different levels. This window provides buttons, such as Filter by Template, Filter and Refresh, to help you to quickly locate the alarm cause. 1.2.6.8 Browse Performance Window 1-14
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You can view the current and history performance data, UAT events and performance threshold crossings.
1.2.6.1 Workbench This topic describes the workbench. After a client is started, the system automatically accesses the default workbench. The default shortcut icons are displayed on the workbench. l
In the main windows of the U2000, click the
l
You can do as follows to modify a workbench: Right-click the icon of the workbench and choose Modify Workbench from the shortcut menu to modify the name or description of a workbench.
l
You can expand and order workbenches to separate the customized workbenches from the default workbench.
l
You can view the description about the function of the workbench in the background picture of the workbench and press F1 to view the Help.
to access the workbench.
1.2.6.2 Main Topology This topic describes the items in the Main Topology. All topology management functions can be accessed through the Main Topology in . These functions include creating topological objects, subnets, searching for the existing equipment in the network. You can search, view, create, set, and manage subnets; and search, create, configure, and maintain management functions on trails.
GUI To open the Main Topology, log in to the U2000. If the preceding operation closes the Main Topology, you can choose View > Main Topology from the main menu to open the Main Topology. Figure 1-2 shows the Main Topology of the U2000.
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Figure 1-2 Main Topology
2
1
6
8
7
1: Network management system name
1-16
4
3
9
5
10
11 12
2: Menu bar
3: Shortcut button
You can operate the NM and the NE with submenu bar, include configure tasks, manage tasks and so on.
Click the button, you can perform a simple task quickly. For example: exit NM, lock terminal, log out, NMS user management, stop the current alarm sound, browse alarm, NE explorer, creating connections,, browse performance window.
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4: Shortcut button
5: Alarm button bar
6: NMS status bar
Click the button, you can perform a simple task quickly on the Main Topology. For example: zoom in or zoom out or refresh or save the view, show or hide the navigators, search objects, see object attributes, lock or unlock the view.
The Alarm buttons for alarms at different severity levels are in different colors. You can click the button to view the number of the alarms generated on the current U2000. You can click the button to view current alarms. For example: browsing the alarm list, show alarm panel.
Views the running information of the NMS. For example, NMS login, and loading of each module.
When the U2000 has abnormal events, the Abnormal event indicator turn to red from green. You can click the indicator to view current abnormal events. 7: Views the current location 8: Physical Map of the cursor in the Main Views the managed Topology. equipment. On the Physics Map, you can perform operations, such as creating NEs, deleting topology objects, NE explorer, creating connections, browsing fibers/cables, configuring the NE data, browse performance window, and so on. 10: Views user name of the logged-in U2000 user currently.
11: Filter Tree and Legend In this area, you can set the display types of the objects in a view, and view the descriptions of legends in the view. To locate an operation object quickly.
9: Views the name which is set by the current U2000 client, and views the IP address of the current U2000 server.
12: Total elapsed time after the current user is logged in to the U2000.
1.2.6.3 NE Explorer The NE Explorer is the main user interface used to manage equipment. In the NE Explorer, a user can configure, manage and maintain the NE, boards, and ports on a per-NE basis. The NE Explorer is the main user interface for commissioning and configuration on a per-NE basis. The NE Explorer contains a Function Tree that makes the operations easy. To display the configuration window for an object, the user can just select the object and then choose a desired function in the Function Tree. Issue 02 (2011-06-30)
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NOTE
You can open a maximum of five NE Explorer windows at the same time.
GUI l
Right-click an NE on the Main Topology and choose NE Explorer from the shortcut menu.
l
In the left-hand pane of the Main Topology, right-click an NE and choose NE Explorer from the shortcut menu.
Correlation operation l
Click the
in NE Explorer window, display the 1.2.6.5 NE Panel.
l
Click the
in NE Explorer window, switch to other NE.
1.2.6.4 Clock View The Clock View provides a visible platform to enable NE clock settings, networkwide clock synchronization status query, and clock tracing and search functions, supports the synchronous Ethernet clock, SDH clock, TOP clock, ACR clock, TDM clock, PON clock, and E1 clock, and applies to the MSTP, RTN ,PTN and router NE40E V3R7 equipment.
GUI Access the clock view. In the Main Topology window, select Clock View from the Current View drop-down list. Select the NE to be queried or configured from the object tree.
Legends
1-18
l
The Clock View uses continuous lines to represent the trace relations between NEs. Smaller number indicates higher priority. The number displayed on the continuous line indicates the priority of the traceable clock. The Clock View displays the line clock source numbers only. Internal and tributary clock sources are also numbered, but they are not displayed in the Clock View.
l
The arrow direction in the Clock View indicates the clock tracing direction. For example, if NE2 points to NE3, it indicates that NE3 traces the clock information transmitted from NE2, and that NE3 traces the primary PRC NE1-External 1.
l
The arrow direction in the Clock View indicates the clock tracing direction.
l
An internal clock source is the clock provided by an NE, and has no trace relations with other NEs. Therefore, internal clock sources are not displayed on the Clock View.
l
Tributary clock sources have no relation with the clock sources that are not provided by the U2000. Therefore, the clock trace relations are not displayed on the Clock View.
l
On the U2000, the four clock trace relations of free-run, tracing, holdover, and invalid are respectively identified in blue, green, yellow, and red.
l
In the Clock View, you can select multiple NEs, right-click, and query the clock synchronization status or search for clock trace relations. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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NOTE
The rule of verifying an invalid clock tracing relation is as follows: First, verify whether a clock source is in the SSM protocol mode. In the non-SSM protocol mode, verify the status of a clock source. The status directly determines whether a clock tracing relation is invalid. In the SSM protocol mode, verify the status of a clock source. If the status is unavailable, it indicates that the clock tracing relation is invalid. If the status is available, you also need to verify the S1 byte (clock quality). When you manually cancel settings of the quality of the S1 byte and the quality of the S1 byte is unknown, the clock tracing relation is invalid.
1.2.6.5 NE Panel The NE Panel displays boards and ports in different colors depending on their current status. In the U2000, most operations such as equipment configuration, monitoring, and maintenance are performed in the NE Panel window.
GUI Double-click an NE on the Main Topology to display the NE Panel. To add a new board, right-click an idle slot and choose a board type. NOTE
l Choose the Always On Top for the Slot Layout window to always remain on top. l When a board occupies multiple slots, the slot ID of the main slot is displayed in boldface, and the slot ID of the slave slot is grayed out. l In the NE panel, when you click the processing board that is accompanied by an interface board, the slot ID of this interface board is displayed in orange.
Click the icon on the toolbar, to view the legends of the boards and ports on the right of the Slot Layout. To select an operation related to an installed board, right-click the installed board and choose it from the shortcut menu. For example, right-click an AUX board and choose Path View to display the detailed path information.
1.2.6.6 Browse Alarm This topic describes the user interface for viewing the current and history alarms, Alarm Logs. In this user interface, buttons are provided, such as Filter, Synchronize, Refresh, and Acknowledge, to help you quickly locate the alarm cause.
GUI l
Choose Fault > Browse Current Alarm from the main menu.
l
Choose Fault > Browse History Alarm from the main menu.
l
Choose Fault > Browse Alarm Logs from the main menu.
1.2.6.7 Browse Event In the Browse Event window, you can view events at different levels. This window provides buttons, such as Filter by Template, Filter and Refresh, to help you to quickly locate the alarm cause. Issue 02 (2011-06-30)
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GUI Choose Fault > Browse Event Logs from the main menu.
1.2.6.8 Browse Performance Window You can view the current and history performance data, UAT events and performance threshold crossings.
GUI Choose Performance > Browse SDH Performance from the main menu.
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Creating the Network
About This Chapter NEs and fibers or cables can be managed on the U2000 only after their topologies are created. 2.1 Creating NEs Each piece of equipment is represented as an NE on the U2000. Before the U2000 manages the actual equipment, you need to create the corresponding NEs on the U2000. There are two NE creation methods, namely, creating a single NE and creating NEs in batches. When you need to create a large number of NEs, for example, during the deployment, it is recommended that you use the method of creating NEs in batches. When you need to create only a few NEs, it is recommended that you use the method of creating a single NE. 2.2 Configuring the NE Data After an NE is created, you need to configure the data of the NE on the U2000. Otherwise, the U2000 still cannot manage the NE. 2.3 Checking Board Parameters To learn about board parameter status, you can check board parameters. Before configuring the boards in actual networking, you need to check board parameters and ensure that the board parameters meet the requirements of actual networking. 2.4 Creating Fibers You can create fibers, serial port cables, extended ECC, and virtual fibers by using the U2000. 2.5 Creating a Topology Subnet To facilitate network management, you can assign the topology objects in the same network area or with similar attributes into the same topology subnet. 2.6 Configuring the Protection Subnet The OptiX OSN equipment supports various network level protection schemes, including the linear MSP. 2.7 Configuring Clocks A clock is the basis for the normal operation of an NE. You need to configure the clocks for all the NEs before configuring services. In addition, you need to configure the clock protection in the case of a complicated network. 2.8 Clock Configuration Parameters Issue 02 (2011-06-30)
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A clock is one of the basic configuration items of an NE. When configuring a clock, you need to set the parameters in terms of clock source, clock protection, clock quality, and retiming management. 2.9 Configuring the Orderwire Phone The orderwire phone provides an important communication tool for maintenance personnel. 2.10 Configuring the Broadcast Data Service To meet the requirements for the broadcast data services between the monitoring host and the environment monitors, you need to configure the broadcast data services of NE1-NE4. 2.11 Configuring the F1 Data Service The F1 data service is transparently transmitted in the point-to-point mode by using the F1 byte. 2.12 Orderwire Configuration Parameters The equipment supports various orderwire management, which involves orderwire phones and F1 data interfaces.
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2.1 Creating NEs Each piece of equipment is represented as an NE on the U2000. Before the U2000 manages the actual equipment, you need to create the corresponding NEs on the U2000. There are two NE creation methods, namely, creating a single NE and creating NEs in batches. When you need to create a large number of NEs, for example, during the deployment, it is recommended that you use the method of creating NEs in batches. When you need to create only a few NEs, it is recommended that you use the method of creating a single NE. 2.1.1 Creating a Single NE After an NE is created, you can use the U2000 to manage the NE. Creating a single NE is not as quick and accurate as creating NEs in batches. But you can create a single NE regardless of whether the data is configured on the NE side. 2.1.2 Creating NEs in Batches When the U2000 communicates with the gateway NE normally, you can create NEs in batches by searching for all the NEs that communicate with the gateway NE according to the IP address of the gateway NE, the network segment to which the IP address of the gateway NE belongs, or the NSAP addresses of the NEs. This method is quicker and more accurate than manual creation.
2.1.1 Creating a Single NE After an NE is created, you can use the U2000 to manage the NE. Creating a single NE is not as quick and accurate as creating NEs in batches. But you can create a single NE regardless of whether the data is configured on the NE side.
Prerequisite l
You must be an NM user with "NM operator" authority or higher.
l
The NE Explorer instance of the NEs must be created.
Background Information First create a gateway NE, and then create a non-gateway NE.
Procedure Step 1 Right-click in the blank area of the Main Topology and choose New > NE from the shortcut menu. Then, the Create NE dialog box is displayed. Step 2 Select the NE type from the Object Type drop-down list. Step 3 Set ID, Extended ID, Name, and Remarks
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Step 4 To create a gateway NE, proceed to Step 5. To create a non-gateway NE, go to Step 6. Step 5 Choose Gateway Type and Protocol, and set the IP address. 1.
Select Gateway from the Gateway Type drop-down list.
2.
Select the Protocol type. If ...
Then ...
The U2000 communicates with NEs through the IP protocol
Select IP from the Protocol drop-down list. Set IP Address of the gateway NE and use the default value of the Port number.
The U2000 communicates with NEs through the OSI protocol
Select OSI from the Protocol drop-down list. Set NSAP Address of the gateway NE.
Step 6 Select Non-Gateway from the Gateway Type drop-down list. Select the gateway NE to which the NE belongs from the Affiliated Gateway drop-down list. Step 7 Set NE User and Password. NOTE
The default NE user is root, and the default password is password.
Step 8 Optional: If you need not deliver the NE configuration data from the U2000 to the NE, select the NE Preconfiguration check box and set NE Software Version. NOTE
Do not deliver the NE preconfiguration data from the U2000 to the NE if the freconfiguration data is inconsistent with the actual configurations on the NE. Otherwise, the services on the NE are affected.
Step 9 Click OK. Click in the blank area of the Main Topology. Then, the NE icon is displayed at the position where you clicked. NOTE
If the NE creation is incorrect or if the communication between the NE and the U2000 is abnormal, the NE is displayed in grey.
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Result After an NE is successfully created, the system automatically saves the information, such as the IP address, NSAP address, subnet mask, and NE ID to the U2000 database.
Follow-up Procedure if you fail to log in to the created NE, the possible causes are listed as follows: l
The communication between the U2000 and the NE is abnormal. In this case, check the settings of communication parameters, such as the IP address and ID of the NE.
l
The NE user is invalid. Change to use a valid NE user.
2.1.2 Creating NEs in Batches When the U2000 communicates with the gateway NE normally, you can create NEs in batches by searching for all the NEs that communicate with the gateway NE according to the IP address of the gateway NE, the network segment to which the IP address of the gateway NE belongs, or the NSAP addresses of the NEs. This method is quicker and more accurate than manual creation.
Prerequisite l
You must be an NM user with "NE administrator" authority or higher.
l
The U2000 must communicate with the gateway NE normally.
l
The NE Explorer instance of the NEs must be created.
Procedure Step 1 Choose File > Discovery > NE from the Main Menu. Then, the NE Discovery window is displayed. Step 2 Choose Transport NE Search tab, Click Add. Then, the Input Search Domain dialog box is displayed. Step 3 Set Address Type to IP Address Range of GNE, IP Address of GNE, or NSAP Address. Enter Search Address. Then, Click OK.
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You can repeat Steps 2 and 3 to add more search domains. You can also delete the system default search domain. l If you search for the NEs according to the IP address of the gateway NE and if the IP address of the U2000 computer and the IP address of the gateway NE are within the same network segment, you can set Address Type to IP Address Range of GNE or IP Address of GNE. l If the IP addresses of the gateway NE and the U2000 computer are in two different network segments, you can set Address Type to IP Address of GNE only. l If you search the NEs according to the NSAP addresses of the NEs, you can set Address Type to NSAP address only.
Step 4 In the NE Discovery window, ClickNext. Step 5 After the search is complete, select the uncreated NEs from the Result list and then click Create. The Create dialog box is displayed. Step 6 Enter the NE user name and password. NOTE
l The default NE user is root. l The default password is password.
Step 7 Click OK. ----End
Follow-up Procedure If you fail to log in to the created NE, the possible causes are listed as follows: l
The password for the NE user is incorrect. In this case, enter the correct password for the NE user.
l
The NE user is invalid. Change to use a valid NE user.
2.2 Configuring the NE Data After an NE is created, you need to configure the data of the NE on the U2000. Otherwise, the U2000 still cannot manage the NE. 2.2.1 Configuring the NE Data Manually By configuring NE data manually, you can configure the slot layout information of an NE. 2.2.2 Replicating the NE Data You can directly replicate the data of an NE that is of the same NE type and NE version to the newly created NE. 2.2.3 Uploading the NE Data By uploading the NE data, you can synchronize the current NE configuration data to the U2000 directly.
2.2.1 Configuring the NE Data Manually By configuring NE data manually, you can configure the slot layout information of an NE. 2-6
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Prerequisite l
The NE must be created successfully.
l
You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 Double-click the unconfigured NE on the Main Topology. Then, the NE Configuration Wizard dialog box is displayed.
Step 2 Select Manual Configuration and click Next. Then, the Confirm dialog box is displayed, indicating that manual configuration clears the data on the NE. Step 3 Click OK. Then, the Confirm dialog box is displayed, indicating that manual configuration interrupts the service on the NE. Step 4 Click OK. Then, the Set NE Attribute dialog box is displayed. Step 5 Set NE Name, Equipment Type, NE Remarks, and Shelf Type and then click Next. The NE slot layout window is displayed. Step 6 Optional: Click Query Logical Information to query the logical boards of the NE. Step 7 Optional: Click Query Physical Information to query the physical boards of the NE. NOTE
The Query Logical Information and Query Physical Information operations cannot be performed for a preconfigured NE.
Step 8 Right-click the slot to which you need to add a board. Click Next. Then, the Send Configuration window is displayed. Step 9 Select Verify and Run according to the requirements and click Finish. NOTE
Verification is to run the verification command. Click Finish to deliver the configuration data to the NE, thus completing the basic configuration of the NEs. After the successful verification, the NEs start to work normally.
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2.2.2 Replicating the NE Data You can directly replicate the data of an NE that is of the same NE type and NE version to the newly created NE.
Prerequisite l
The NE must be created successfully.
l
The NE type and NE version of the source NE must be the same as the NE type and NE version of the newly created NE.
l
You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 Double-click the unconfigured NE on the Main Topology. Then, the NE Configuration Wizard dialog box is displayed. Step 2 Select Copy NE Data and click Next. Then, the NE Replication dialog box is displayed. Step 3 Select the NE from the drop-down list and click Start. Then, the Confirm dialog box is displayed, indicating that the replication operation copies all the data of the source NE.
NOTE
After the NE data is replicated, only the data on the U2000 is changed, but the data on the equipment is not changed.
Step 4 Click OK. Then, the Confirm dialog box is displayed, indicating that the replication operation results in the loss of the original data of the NE to which the data is replicated. Step 5 Click OK to start the replication. Step 6 Wait for several seconds. Then, in the Result dialog box indicating that the operation succeeded, click Close. ----End
2.2.3 Uploading the NE Data By uploading the NE data, you can synchronize the current NE configuration data to the U2000 directly. 2-8
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Prerequisite l
The NE must be created successfully.
l
You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 Double-click the unconfigured NE on the Main Topology. Then, the NE Configuration Wizard dialog box is displayed. Step 2 Select Upload and click Next. Then, the Confirm dialog box is displayed. Step 3 Click OK to start the upload. When the uploading is completed, the Operation Result dialog box is displayed, indicating that the operation succeeded. Step 4 Click Close. ----End
2.3 Checking Board Parameters To learn about board parameter status, you can check board parameters. Before configuring the boards in actual networking, you need to check board parameters and ensure that the board parameters meet the requirements of actual networking.
Procedure Step 1 Select the corresponding navigation path and check the related board parameters. 1.
Check the SDH board parameters. For the SDH board parameters, see Table 2-1. Table 2-1 SDH board parameters Boar d Type
SDH
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Paramet er
Navigation Path
Laser Switch
a. In the NE Explorer, select a board. b. Choose Configuratio n > SDH Interface from the Function Tree. c. Click By Board/Port (channel) and select Port from the
Application Scenario When configuring MSP shared services on an optical interface of a board, enable this parameter. When configuring services on an optical interface of a board, enable this parameter.
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Boar d Type
Paramet er Optical (Electrical )Interface Loopback
Navigation Path drop-down list.
Application Scenario l Non-loopback: It is the normal state. When the equipment runs normally, set this parameter to non-loopback. l Inloop: The loop is performed toward the local NE. l Outloop: The loop is performed toward the opposite NE. Inloop and outloop of an optical interface affect services. They are used to locate faults.
2.
Check the PDH board parameters. For the PDH board parameters, see Table 2-2. Table 2-2 PDH board parameters Boar d Type
Paramet er
Navigation Path
Tributary Loopback
PDH
Service Load Indication
a. In the NE Explorer, select a board. b. Choose Configuratio n > PDH Interface from the Function Tree. c. Click By Board/Port (channel) and select Port from the drop-down list.
Application Scenario l Non-loopback: It is the normal state. When the equipment runs normally, set this parameter to non-loopback. l Inloop: When input service signals reach the tributary board of the target NE, the signals revert to the original trail. This function is used to locate faults of each service path. l Outloop: When input service signals reach the tributary board through the input port of the local NE, the signals are looped back directly to the service output end. l Non-loaded: The service path does not process the services that are carried, to suppress alarms in non-loaded service paths. l Load: The service path processes the services that are carried. In the case of a tributary board that has services, set this parameter to Load.
Step 2 Change the values of the board parameters according to service planning and actual board configurations. For details, see 5.2.3 Modifying Board Configuration Parameters. ----End 2-10
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2.4 Creating Fibers You can create fibers, serial port cables, extended ECC, and virtual fibers by using the U2000. 2.4.1 Creating Fibers Automatically By using the fiber search feature, you can check whether a specified optical interface is connected to a fiber. Then, you can quickly create a fiber for this optical interface on the U2000. In the case of a newly created network, after configuring the boards on the U2000, you can search for all the optical interfaces and then create the fibers on the entire network. In this way, you can monitor the actual working status of each fiber. 2.4.2 Creating Fibers Manually Before you configure services, you need to create the required fibers. You can create a small number of fibers manually one after another. 2.4.3 Creating Virtual Fibers When the U2000 manages the SDH, PTN, and WDM equipment at the same time, you can create virtual fibers between the SDH or PTN equipment (with the WDM equipment in between), to facilitate network management. 2.4.4 Creating DCN Communication Cable The U2000 can communicate with NEs through the Ethernet port or serial port. The NEs can also communicate with each other through the extended ECC. Depending on the communication mode, different types of communication cables can be created on the U2000.
2.4.1 Creating Fibers Automatically By using the fiber search feature, you can check whether a specified optical interface is connected to a fiber. Then, you can quickly create a fiber for this optical interface on the U2000. In the case of a newly created network, after configuring the boards on the U2000, you can search for all the optical interfaces and then create the fibers on the entire network. In this way, you can monitor the actual working status of each fiber.
Prerequisite l
Fibers must be connected to the optical interfaces of each NE.
l
The boards of each NE must be created on the U2000.
l
You must be an NM user with "NE maintainer" authority or higher.
Precautions
CAUTION l If conflicting fibers are detected during the creation, delete the conflicting fibers on the U2000 before you start creating new fibers.
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Procedure Step 1 Choose File > Discovery > Fiber from the Main Menu. Step 2 In the pane on the left, select one or more ports of the NE and click Search. Then, the progress bar is displayed, indicating the progress of the search. NOTE
l If you select the Do not search the ports with Fibers/Cable created on NMS check box, the system only searches for the ports that do not have fibers. l To check whether the created fibers are consistent with the actual fiber connection, deselect the Do not search the ports with Fibers/Cable created on NMS check box. l If you select the Do not search the ports with Fibers/Cable created on NMS check box and if the fibers are created for all the selected ports, a dialog box is displayed indicating that the search domain is null.
Step 3 A dialog box is displayed, indicating that the operation is successful. Click Close. Step 4 Select one or more fibers from the Physical Fibers/Cable Link List list and click Create Fiber/ Cable. NOTE
l When one or more fibers are selected from the Physical Fibers/Cable Link List list, the fibers that conflict with the selected fibers are automatically displayed in the Logical Fibers/Cable Link List list. If there is any conflicting fiber, refer to Step 5 and delete the conflicting fiber before creating fibers. l During the fiber creation, if all the selected fibers are in Already created state, the system displays the message No fiber to create.
Step 5 Select one or more conflicting fibers (namely, the fibers of which the Conflict with logical link (Y/N) parameter is set to Yes in the Misconnected Fibers/Cable list) from the Logical Fibers/ Cable Link List list. Click Delete Fiber/Cable. ----End
2.4.2 Creating Fibers Manually Before you configure services, you need to create the required fibers. You can create a small number of fibers manually one after another.
Prerequisite l
You must be an NM user with "NE maintainer" authority or higher.
l
The required boards must be created on each NE.
Procedure Step 1 Right-click in the Main Topology and choose New > Link from the shortcut menu. Then, the Create Link dialog box is displayed. Step 2 Choose Fiber/Cable > Fiber from the left pane. Step 3 The parameter Create Ways can be set to Common Ways or Batch Ways. The default value is Common Ways. Step 4 Click the button in Source NE. Select the source board and source port in the Select Fiber/ Cable Source dialog box that is displayed. 2-12
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Step 5 Click OK. Step 6 Click the button in Sink NE. Select the sink board and sink port in the Select Fiber/Cable Sink dialog box that is displayed. Step 7 Click OK. Then, the created fiber is displayed between the source NE and the sink NE in the Main Topology. Step 8 Right-click the created fiber and choose Detect Link from the shortcut menu. The Operation Result dialog box is displayed, indicating the information on the fiber connections. ----End
2.4.3 Creating Virtual Fibers When the U2000 manages the SDH, PTN, and WDM equipment at the same time, you can create virtual fibers between the SDH or PTN equipment (with the WDM equipment in between), to facilitate network management.
Prerequisite l
You must create fiber connections according to the true fibers that connect the SDH and WDM or PTN equipment.
l
You must be an NM user with "NE maintainer" authority or higher.
Background Information l
In the case of SDH equipment, the virtual fibers ensure the automatic fiber search and SDH trail management functions are independent of each other.
l
The source and sink ports of the virtual fibers must be SDH ports. On the source and sink ports, there must be two physical fibers that are connected to the WDM or PTN equipment.
l
The virtual fibers do not support the expansion function.
Procedure Step 1 Right-click in the blank area of the Main Topology, and choose New > Link from the shortcut menu. Step 2 In the Create Link dialog box, choose Fiber/Cable > Virtual Fiber. Step 3 Set the fiber/cable attributes in the attribute list on the right. Step 4 Click OK. ----End
2.4.4 Creating DCN Communication Cable The U2000 can communicate with NEs through the Ethernet port or serial port. The NEs can also communicate with each other through the extended ECC. Depending on the communication mode, different types of communication cables can be created on the U2000.
Prerequisite You must be an NM user with "NE operator" authority or higher. Issue 02 (2011-06-30)
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Procedure Step 1 Right-click in the blank area of the Main Topology and choose New > Link from the shortcut menu. Then, the Create Link dialog box is displayed. Step 2 Choose Fiber/Cable > Cable from the left pane. Step 3 Enter the cable attributes in the panel on the right. Step 4 Click OK. The cable that is already created between the U2000 and the gateway NE is displayed on the Main Topology. ----End
2.5 Creating a Topology Subnet To facilitate network management, you can assign the topology objects in the same network area or with similar attributes into the same topology subnet.
Prerequisite You must be an NM user with "NM operator" authority or higher.
Background Information A topology subnet is created only to simplify the user interface and does not affect the operation of the NEs.
Procedure Step 1 Right-click in the blank area of the Main Topology and choose New > Subnet from the shortcut menu. Step 2 Click the Property tab in the Create Physical Subnet dialog box. Set the attributes of the subnet. Step 3 Click the Select Objects tab. Select the created NEs or subnet from the Available Objects column. Click
to add the selected objects to the Selected Objects column.
NOTE
The information about the provided as follows:
signs in a similar dialog box for selecting objects is
l
indicates adding the selected objects from the left column to the right column.
l
indicates adding all the objects from the left column to the right column.
Step 4 Click OK. ----End
2.6 Configuring the Protection Subnet The OptiX OSN equipment supports various network level protection schemes, including the linear MSP. 2-14
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2.6.1 Configuring a Non-Protection Chain If the services on a chain do not need to be protected, you can configure the chain as a nonprotection chain. In this case, all the timeslots on the chain can be used to transmit the services. 2.6.2 Configuring a Non-Protection Ring When services on a ring need not be protected, you can configure a non-protection (NP) ring. All timeslots on the ring can be used to transmit services. 2.6.3 Creating an MS Ring Protection Subnet Generally, the MS ring protection is configured on the public ring network whose protection paths are used to transmit extra services. By running the APS protocol, it achieves the MS level protection. 2.6.4 Creating a Linear MS Protection Subnet In a chain network, an NE can protect the services in different fiber sections after a linear MS protection subnet is created.
2.6.1 Configuring a Non-Protection Chain If the services on a chain do not need to be protected, you can configure the chain as a nonprotection chain. In this case, all the timeslots on the chain can be used to transmit the services.
Prerequisite l
The data of each NE must be configured and the fibers must be created on the U2000.
l
You must be an NM user with "network maintainer" authority or higher.
Procedure Step 1 Choose Service > SDH Protection Subnet > Create Unprotected Chain from the Main Menu. Then, the Create Protection Subnet dialog box is displayed. Step 2 Enter the name of the protection subnet. Generally, enter the default name, for example, NP_Chain_1. Step 3 Select the capacity level of the protection subnet, for example, STM-4. Step 4 Optional: Select Resource Sharing and Assigned by VC4 as needed. NOTE
l If multiple protection subnets uses one port of a board, you need to check the Resource Sharing check box. If different protection subnets use different ports of a board, do not check this check box. l Select the Assigned by VC4 option when there are different VC4s belonging to different protection subnets to achieve virtual optical path protection.
Step 5 Select the NEs where you need to create the non-protection chain. Double-click the NEs in the Main Topology and add them to the NE list on the left. At the same time, is displayed above the NE icons. You can cancel the selection by double-clicking the NE icons again to cancel the selection. Step 6 Click Next. Set the parameters such as Physical Link Information.
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Step 7 Click Finish to deliver the configuration data. Click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
2.6.2 Configuring a Non-Protection Ring When services on a ring need not be protected, you can configure a non-protection (NP) ring. All timeslots on the ring can be used to transmit services.
Prerequisite l
You must be an NM user with "NE maintainer" authority or higher.
l
The NE data must be configured, and fibers must be created properly.
Procedure Step 1 Choose Service > SDH Protection Subnet > Create Unprotected Ring from the Main Menu. Then, the Create Protection Subnet dialog box is displayed. Step 2 Enter the name of the protection subnet. Generally, the default name is used, for example, NP_Ring_1. Step 3 Select the capacity level of the protection subnet, for example, STM-4. Step 4 Select Resource Sharing and Assigned by VC4 according to the requirement. NOTE
l If multiple protection subnets uses one port of a board, you need to check the Resource Sharing check box. If different protection subnets use different ports of a board, do not check this check box. l Select the Assigned by VC4 option when there are different VC4s belonging to different protection subnets to achieve virtual optical path protection.
Step 5 Select the nodes that belong to the protection subnet that needs to be created. Double-click the selected NE in the Main Topology to add the NE to the NE list on the left. In addition, is displayed on the NE icon. If you need to cancel the selection, double-click the NE again. Step 6 Click Next. Set the parameters such as Physical Link Information in the window. Step 7 Click Finish to deliver the configuration data. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
2.6.3 Creating an MS Ring Protection Subnet Generally, the MS ring protection is configured on the public ring network whose protection paths are used to transmit extra services. By running the APS protocol, it achieves the MS level protection.
Prerequisite
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l
You must be an NM user with "NE maintainer" authority or higher.
l
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Precautions
CAUTION l The number of nodes in an MSP ring should not exceed 16. l Starting the protocol controller may interrupt the services.
Procedure Step 1 Choose Service > SDH Protection Subnet > Create 2f_MS_SPRing from the Main Menu. Click OK in the dialog box that is displayed. Then, the Create Protection Subnet window is displayed. NOTE
l To create a four-fiber bidirectional MS shared protection ring, choose Service > SDH Protection Subnet > Create 4f_MS_SPRing from the Main Menu. l To create a two-fiber bidirectional MS shared protection ring, choose Service > SDH Protection Subnet > Create 2f_MS_DPRing from the Main Menu. l The following part provides an example of configuring a common two-fiber bidirectional MS shared protection ring.
Step 2 Enter the name of the protection subnet. Generally, the default name is used, for example, 2f_MS_SPRing_1. Step 3 Select the capacity level of the protection subnet, for example, STM-4.
NOTE
Create a two-fiber bidirectional MSP ring. The capacity of the ring can be set to STM-4, STM-16.
Step 4 Choose Resource Sharing and Assigned by VC4 according to the requirement.
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l Resource Sharing indicates that a port is mapped into multiple protection subnets. When multiple protection subnets occupy the same port of a board, Resource Sharing must be selected. When different protection subnets occupy different ports of a board, Resource Sharing is not required. If multiple protection subnets use one port of a board, you need to select the Resource Sharing check box. If MSP Sharing is enabled, you can select the Resource Sharing check box to map a port of the board to multiple MSP subnets. l Assigned by VC4 indicates that different VC-4s belong to different protection subnets, therefore achieving virtual optical path protection. For example, in the case of an STM-4 fiber, the first and second VC-4s are allocated for the STM-4 MS shared protection, and the third and fourth VC-4s are allocated for the non-protection.
Step 5 Select the nodes that belong to the protection subnet that needs to be created. Double-click the selected NE in the Main Topology to add the NE to the NE list on the left. In addition, is displayed on the NE icon. If you need to cancel the selection, double-click the NE again. NOTE
To facilitate maintenance, it is recommended that you add the nodes anticlockwise to the protection subnet.
Step 6 Set the attribute of each node to MSP Node. Step 7 Click Next. Set the parameters such as Physical Link Information in the window. NOTE
l If there are multiple fibers between two NEs, select the required links from the Physical Link Information drop-down list. l If Assigned by VC4 is selected, you can Select the working and protection VC-4 timeslots according to the requirement.
Step 8 Click Finish to deliver the configuration data. Then, the Operation Result dialog box is displayed. Click Close. Step 9 Choose Service > SDH Protection Subnet > Search for SDH Protection Subnet from the Main Menu. Select the created protection subnet, right-click and choose Protection Subnet Attributes from the shortcut menu. Step 10 Click the Protection Subnet Maintenance tab to check whether the protocol controller is started. If the protocol controller is not started, select all the nodes of the protection subnet. Right-click and choose Start/Stop Protocol > Start from the shortcut menu. Click Yes in the dialog box that is displayed twice. Ensure that the status of all the values in the Protocol Controller column is Protocol Started. Step 11 Click the Protection Subnet Parameters tab. Set WTR time and SD Condition according to the requirement. Click Apply to deliver the configuration data. The WTR time of all NEs in the same protection subnet should be the same.
NOTE
The default value is 600s.
----End
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2.6.4 Creating a Linear MS Protection Subnet In a chain network, an NE can protect the services in different fiber sections after a linear MS protection subnet is created.
Prerequisite l
You must be an NM user with "NE maintainer" authority or higher.
l
The NE data must be configured and fibers must be created properly.
Precautions
CAUTION l Starting the protocol controller may interrupt the services. l Fibers that are used for the linear MSP cannot be used by other protection subnets. That is, a linear MS protection subnet and other subnets cannot be used together to form virtual fibers.
Procedure Step 1 Choose Service > SDH Protection Subnet > Create 1+1 linear MSP from the Main Menu. Then, the Create Protection Subnet window is displayed. NOTE
To create the M:N linear MS protection, choose Service > SDH Protection Subnet > Create M:N Linear MSP from the Main Menu. Then, the corresponding window is displayed. In the case of the M:N linear MS protection scheme, set the number of working links to N. M indicates the number of protection links and cannot be set manually. Currently, the value of M can be 1 only.
Step 2 Enter the name of the protection subnet. Generally, the default name is used, for example, 1+1_MSP_1. Step 3 Select the capacity level of the protection subnet, for example, STM-4.
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Step 4 Set Revertive Mode and Switching Mode according to the protection type and related requirements. NOTE
When setting the parameters, note the following points: l Revertive Mode indicates the handling strategy that is used after the faulty line is recovered. NonRevertive: The service is not automatically reverted to the working channel after the faulty line is recovered. Revertive: The service is automatically reverted to the working channel after the faulty line is recovered. l Switching Mode indicates the switching strategy that is used after a fault occurs in the line. Singleended switching: To protect services, a switching occurs at the receive end when the receive end is faulty and a switching occurs at the transmit end when the transmit end is faulty. Dual-ended switching: To protect services, a switching occurs at the receive and transmit ends when the receive end or transmit end is faulty.
Step 5 Select the nodes that belong to the protection subnet that needs to be created. Double-click the selected NE in the Main Topology to add the NE to the NE list on the left. In addition, is displayed on the NE icon. If you need to cancel the selection, double-click the NE again. Step 6 Click Next. Set Physical Link Information of Working Link and Protection Link. Step 7 Click Finish to deliver the configuration data. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. Step 8 Choose Service > SDH Protection Subnet > Search for SDH Protection Subnet from the Main Menu. Select the created protection subnet, right-click and choose Protection Subnet Attributes from the shortcut menu. Step 9 Click the Protection Subnet Maintenance tab to check whether the protocol controller is started.
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NOTE
If the protocol controller is not started, select all the NEs of the protection subnet. Right-click and choose Start/Stop Protocol > Start from the shortcut menu. Click Yes in the dialog box that is displayed twice. Ensure that the status of all the values in the Protocol Controller column is Protocol Started.
Step 10 Click the Protection Subnet Parameters tab. Set WTR time and SD Condition according to the requirement. Click Apply to deliver the configuration data.
NOTE
The WTR time of all NEs in the same protection subnet should be the same.
----End
2.7 Configuring Clocks A clock is the basis for the normal operation of an NE. You need to configure the clocks for all the NEs before configuring services. In addition, you need to configure the clock protection in the case of a complicated network. 2.7.1 Configuring the NE Clock Source Before configuring services, you must configure the NE clock source and specify the priority level to ensure that correct clock trace relations are created for all the NEs on the network. 2.7.2 Configuring the Clock Source Protection On a complicated clock network, you need to configure the clock protection for all the NEs. After you set the clock source and specify the clock priority level for the NEs, you can enable the standard SSM or extended SSM protocol to prevent the NEs from tracing an incorrect clock source.
2.7.1 Configuring the NE Clock Source Before configuring services, you must configure the NE clock source and specify the priority level to ensure that correct clock trace relations are created for all the NEs on the network.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Background Information To implement clock protection, you must configure at least two traceable clock sources for the equipment. Generally, the tributary clock is not used as the clock source for the equipment. After you set the clock sources for all the NEs, query the networkwide clock trace status again. For details, see Querying the Clock Trace Status. Issue 02 (2011-06-30)
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Procedure Step 1 In the NE Explorer, select an NE and choose Configuration > Clock > Physical Layer Clock > Clock Source Priority from the Function Tree.
Step 2 Click Query to query the existing clock source. Step 3 Click Create. In the Add Clock Source dialog box, select a new clock source and click OK. Step 4 Optional: If an external clock source is selected, select External Clock Source Mode according to the type of external clock signals. In the case of the 2 Mbit/s clock, specify the Synchronous Status Byte to deliver the SSM message. Step 5 Select a clock source and click or to adjust its priority level. The clock sources are arranged in the descending order. The clock source at top is the preferred clock source for the NE. NOTE
Internal clock sources have the lowest priority because of their low precision.
Step 6 Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. NOTE
If the clock trace relation changes according to the change of the clock source, the Prompt dialog box is displayed, asking you whether to refresh the clock trace relation. Click OK. If Disable Prompting Next Time is selected, the Prompt dialog box is not displayed even if the clock trace relation changes.
----End
2.7.2 Configuring the Clock Source Protection On a complicated clock network, you need to configure the clock protection for all the NEs. After you set the clock source and specify the clock priority level for the NEs, you can enable the standard SSM or extended SSM protocol to prevent the NEs from tracing an incorrect clock source.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 In the NE Explorer, select an NE and choose Configuration > Clock > Physical Layer Clock > Clock Subnet Configuration from the Function Tree. Step 2 Click the Clock Subnet tab. Click Query to query the existing parameter settings. Step 3 Select Start Standard SSM Protocol or Start Extended SSM Protocol. NOTE
The same SSM protection protocol must be used for the NEs within the same clock protection subnet.
Step 4 Set the subnet number of the clock subnet to which the NE is associated. 2-22
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NOTE
Allocate the same subnet number to the NEs that trace the same clock source.
Step 5 Optional: If the extended SSM protocol is enabled, set the clock ID of the clock source.
Step 6 Click Apply. Click Close in the Operation Result dialog box indicating that the operation succeeded. Step 7 Optional: If the clock ID is specified for the line clock of an NE, click the Clock ID Status tab, and set Enabled Status to Enabled. Click Apply. Click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
2.8 Clock Configuration Parameters A clock is one of the basic configuration items of an NE. When configuring a clock, you need to set the parameters in terms of clock source, clock protection, clock quality, and retiming management. 2.8.1 Managing External Clock Sources To use an external clock as the clock source, you need to set the relevant parameters such as the output mode, output timeslot, and output threshold of the external clock source. 2.8.2 Configuring Clock Protection and Restoration You need to configure necessary protection for the clock so that the NE can be synchronized normally. 2.8.3 Clock Quality and Status Management You can manage the quality and status of a clock to ensure the stability and precision of the clock source that is currently traced. 2.8.4 Retiming Management This topic describes the parameters that are used for setting the retiming clock source and the retiming mode.
2.8.1 Managing External Clock Sources To use an external clock as the clock source, you need to set the relevant parameters such as the output mode, output timeslot, and output threshold of the external clock source. Table 2-3 lists the parameters that are used for configuring the output phase-locked source table of an external clock.
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Table 2-3 Parameters for configuring the output phase-locked source table of an external clock Field
Value Range
Description
NE Name
For example: NE(9-1001)
Displays the name of the NE.
External Clock Output Mode When 2M Output Synchronous Source Is Invalid
Synchronization Quality Unavailable, Output AIS, Shut off
The External Clock Output Mode When 2M Output Synchronous Source Is Invalidparameter is used to specify an action to control the output mode of external clock source when all the clock sources in the 2M phase-locked source priority table become invalid or when the clock quality of the selected source is inferior to the output quality threshold of external clock source.
Default value: Shut off
You can click 7.112 External Clock Output Mode When 2M Output Synchronous Source Is Invalid to display the detailed information.
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Output Impedance of External Clock Source 1
For example: 120 ohms
The NE can provide two clocks for external outputs. You need to specify the output impedance of external clock 1.
Output Impedance of External Clock Source 2
For example: 120 ohms
The NE can provide two clocks for external outputs. You need to specify the output impedance of external clock 2.
Output Mode of External Clock Source 1
2 Mbit/s, 2 MHz
The NE can provide two clocks for external outputs. You need to specify the output mode of external clock 1.
Output Mode of External Clock Source 2
2 Mbit/s, 2 MHz
Default value: 2 Mbit/s
Default value: 2 Mbit/s
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Field
Value Range
Description
Clock Source Threshold
No Threshold Value, G.813 SETS Signal, G.812 Lock Clock Signal, G.812 Transit Clock Signal, G.811 Clock Signal
The Clock Source Threshold parameter indicates the lower quality threshold of 2M external clock source. When the clock quality level of the external clock source that is selected from the 2M phase-locked source priority table is inferior to the threshold, the 2M phase-locked source becomes invalid, and the action specified for 2M phase-locked source failure is invoked to control the external clock source output.
Default value: No Threshold Value
You can click 7.118 Clock Source Threshold to display the detailed information.
Table 2-4 lists the parameters that are used for configuring the 2M phase-locked source attributes of an external clock. Table 2-4 Parameters for configuring the 2M phase-locked source attributes of an external clock Field
Value Range
Description
2M Phase-Locked Source Number
For example: NE (9-5595)-2M phase-locked source 1
Displays the number of the external clock source output of the NE.
External Clock Output Switch
Open, Close
Specifies the output switch of the external clock source.
External Clock Output Mode
2 MHz, 2 Mbit/s
The External Clock Output Mode parameter is used to set the output mode of the external clock source to 2 Mbit/s or 2 MHz.
Default value: 2 Mbit/s
You can click 7.113 External Clock Output Mode to display the detailed information.
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Field
Value Range
Description
External Clock Output Timeslot
SA4, SA5, SA6, SA7, SA8, All versions
The External Clock Output Timeslot parameter is used to set the output timeslot for the S1 byte of the external clock source. The external clock source transmits the S1 overhead byte through certain timeslots. After starting the SSM protocol, make sure that the timeslot for receiving the S1 byte is consistent with the timeslot for transmitting the S1 byte so that the S1 byte can be received correctly.
Default value: All versions
You can click 7.114 External Clock Output Timeslot to display the detailed information. External Source Output Threshold
Threshold Disabled, Not Inferior to G.813 SETS Signal, Not Inferior to G.812 Local Clock Signal, Not Inferior to G.812 Transit Clock Signal, Not Inferior to G.811 Clock Signal Default value: Threshold Disabled
The External Source Output Threshold parameter is used to set the output quality threshold of the external clock source. When the output quality of the external clock source is inferior to the threshold, the action specified for 2M phase-locked source failure is invoked to control the external clock source output. You can click 7.115 External Source Output Threshold to display the detailed information.
2M Phase-Locked Source Fail Condition
No Failure Condition, AIS, LOF, AIS OR LOF Default value: No Failure Condition
The 2M Phase-Locked Source Fail Condition parameter is used to set the failure condition of the 2M phase-locked source. You can click 7.116 2M Phase-Locked Source Fail Condition to display the detailed information.
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Field
Value Range
Description
2M Phase-Locked Source Fail Action
Shut Down Output, Send AIS, 2M Output S1 Byte Unavailable
The 2M Phase-Locked Source Fail Action parameter is used to specify the action to be invoked in the case of 2M phase-locked source failure. When the reference clock signal for locking external clock output is invalid or inferior to the threshold, the specific action is invoked to control the external clock output by either shutting down the output or inserting an AIS alarm.
Default value: Shut Down Output
You can click 7.117 2M Phase-Locked Source Fail Action to display the detailed information.
2.8.2 Configuring Clock Protection and Restoration You need to configure necessary protection for the clock so that the NE can be synchronized normally. Table 2-5 lists the parameters that are used for configuring clock protection and restoration. Table 2-5 Parameters used for configuring clock protection and restoration Field
Value Range
Description
NE Name
For example: NE(9-5595)
Displays the name of the NE.
Higher Priority Clock Source Reversion Mode
Non-Revertive, AutoRevertive
The Higher Priority Clock Source Reversion Mode parameter specifies whether to switch from the lowerpriority clock source back to the higher-priority clock source after the higherpriority clock source is restored to normal.
Default value: AutoRevertive
You can click 7.122 Higher Priority Clock Source Reversion Mode to display the detailed information.
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Field
Value Range
Description
Clock Source WTR Time
0-12
The Clock Source WTR Time parameter is used to specify the wait-to-restore (WTR) time when the Higher Priority Clock Source Reversion Mode parameter is set to AutoRevertive. When a clock source is restored to its valid status, the system does not regard it as a valid source immediately but verifies the validity of the clock source in a specific period of time. The system regards the clock source as a valid source only if the clock source remains valid during the specific period of time. This specific period of time is called the WTR time of the clock source.
Default value: 5
You can click 7.123 Clock Source WTR Time to display the detailed information. Clock Source
For example: Internal Clock Source
Displays the name of the clock source.
AIS Alarm Generated
Yes, No
The AIS Alarm Generated parameter is used to specify whether an AIS alarm is a condition for triggering the switching of clock sources.
Default value: No
You can click 7.119 AIS Alarm Generated to display the detailed information.
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Field
Value Range
Description
B1 BER Threshold-Crossing Generated
Yes, No
The B1 BER ThresholdCrossing Generated parameter is used to specify whether a B1 BER thresholdcrossing alarm is a condition for triggering clock source switching. B1 BER Threshold-Crossing alarm is an index for measuring the performance of clock source signals.
Default value: No
You can click 7.120 B1 BER Threshold-Crossing Generated to display the detailed information. RLOS, RLOF and OOF Alarms Generated
Yes
Displays whether the switching condition is enabled. If the R_LOS, R_LOF, or OOF alarm is reported, the NE considers that the corresponding clock source is faulty. By default, this parameter is set to yes and cannot be changed.
CV Threshold-Crossing Generated
Yes, No
Sets the switching condition enable status. When CV threshold-crossing occurs in the NE, the NE thinks that the corresponding clock source fails.
CV Threshold
-
Displays the CV threshold.
B2-EXC Alarm Generated
Yes, No
The B2-EXC Alarm Generated parameter is used to specify whether a B2-EXC alarm is a condition for triggering clock source switching. B2-EXC alarm is an index for measuring the performance of clock source signals.
Default value: No
You can click 7.121 B2-EXC Alarm Generated to display the detailed information.
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Field
Value Range
Description
Effective Status
Valid, Invalid
Specifies whether the clock source is valid. This parameter is used for query only.
Lock Status
Lock, Unlock
The Lock Status parameter indicates the lock status of a clock source in the priority table.
Default value: Unlock
You can click 7.124 Lock Status to display the detailed information. Switching Source
For example: 1-SL1D-1 (SDH-1)
Displays the clock source to be traced by the NE after the switching.
Switching Status
Forced Switching, Manual Switching, Normal
Displays the switching status of the current clock source.
2.8.3 Clock Quality and Status Management You can manage the quality and status of a clock to ensure the stability and precision of the clock source that is currently traced. Table 2-6 lists the parameters that are used for managing the quality and status of a clock. Table 2-6 Parameter description: clock synchronization status Field
Value Range
Description
NE Name
For example: NE(9-5595)
Displays the name of the NE.
NE Clock Working Mode
Normal Mode, Holdover Mode, Free-Run Mode
The NE Clock Working Mode parameter is used to set the current working mode of the system clock to the normal, holdover or free-run mode.
Default value: -
You can click 7.127 NE Clock Working Mode to display the detailed information.
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Field
Value Range
Description
S1 Byte Synchronization Quality Information
Synchronous Source Unavailable, Quality Unknown, G.811 Reference Clock, G.812 Transit Clock, G.812 Local Clock, SDH equipment timing source (SETS) signal
The S1 Byte Synchronization Quality Information parameter indicates the synchronization quality information in the S1 byte that is output by the current traced synchronous source. The S1 byte defined by the ITUT is used to transmit the quality information about the clock sources. It indicates the quality information of 16 types of synchronous sources with bits 5-8 of the S1 byte in the section overhead. With this quality information and certain switching protocols, the automatic protection switching of the synchronization clock can be realized in the synchronous network.
Default value: -
You can click 7.126 S1 Byte Synchronization Quality Information to display the detailed information. S1 Byte Clock Synchronous Source
For example: Internal Clock Source
Displays the clock source that is traced by the clock of the current NE. This parameter is used for query only. The relevant information can be displayed only when the S1 byte is used. That is, the clock protection function is enabled. Similarly, the relevant information can be displayed only when you click Query. Otherwise, only NA is displayed.
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Field
Value Range
Description
Synchronous Source
For example: External Clock Source1
The Synchronous Source parameter indicates the synchronous clock source that is being traced. The synchronous clock source here refers to a certain clock source contained in the system clock priority table.
Clock Source in System Clock Priority Table Default value: None
You can click 7.125 Synchronous Source to display the detailed information. Data Output Method in Holdover Mode
Normal Data Output Mode, Keep the Latest Data Default value: Normal Data Output Mode
The Data Output Method in Holdover Mode parameter is used to specify whether the data is output normally or the latest data is kept when the NE clock is in the holdover mode. You can click 7.128 Data Output Method in Holdover Mode to display the detailed information.
2.8.4 Retiming Management This topic describes the parameters that are used for setting the retiming clock source and the retiming mode. Table 2-7 lists the parameters that are used for retiming. Table 2-7 Parameters used for retiming
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Field
Value Range
Description
Retiming Mode
Normal, Retiming Mode of Tributary Clock, Retiming Mode of Cross-Connect Clock Default value: Normal
The Retiming Mode parameter specifies whether the retiming clock, tributary clock, or cross-connect (external) clock is used.
NOTE For the OptiX OSN equipment, this parameter can be set to only Retiming Mode of Tributary Clock.
You can click 7.129 Retiming Mode to display the detailed information.
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2.9 Configuring the Orderwire Phone The orderwire phone provides an important communication tool for maintenance personnel. 2.9.1 Configuring the Orderwire The orderwire provides a dedicated communication channel that the network maintenance personnel can use in the case of emergencies. You can configure the orderwire after configuring the NEs and boards on the U2000. 2.9.2 Configuring the Conference Calls The conference calls ensure one or more dedicated communication channels that the network maintenance personnel can use in the case of emergencies.
2.9.1 Configuring the Orderwire The orderwire provides a dedicated communication channel that the network maintenance personnel can use in the case of emergencies. You can configure the orderwire after configuring the NEs and boards on the U2000.
Prerequisite You must be an NM user with "network operator" authority or higher.
Procedure Step 1 In the NE Explorer, click the NE, and then choose Configuration > Orderwire from the Function Tree. Click the General tab.
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Step 2 Click Query to query the related NE-side information. Step 3 Set Call Waiting Time(s), Telephone No. and the orderwire ports. NOTE
l Call Waiting Time should be set to the same value for all NEs that are involved in the orderwire communication. When the number of NEs is less than 30, set Call Waiting Time to 5s. Otherwise, set Call Waiting Time to 9s. l The orderwire phone numbers must be unique to each other in the same orderwire subnet. l Set the length of the telephone number according to the actual requirements. The maximum length is eight digits and the minimum length is three digits. In the same orderwire subnet, the number lengths of the orderwire phone numbers must be the same. l The length of the telephone number must be the same as the length of the conference call number. l If the length of the subnet number is 1, the first digits of the two orderwire numbers must be the same. If the length of the subnet number is 2, the first two digits of the two orderwire numbers must be the same.
Step 4 Click Apply. A dialog box is displayed, indicating that the operation is successful. Step 5 Click Close. ----End
2.9.2 Configuring the Conference Calls The conference calls ensure one or more dedicated communication channels that the network maintenance personnel can use in the case of emergencies.
Prerequisite You must be an NM user with "network operator" authority or higher.
Procedure Step 1 In the NE Explorer, select the NE, and then choose Configuration > Orderwire from the Function Tree. Click the Conference Call tab. Step 2 Click Query to query the conference call configuration of the NE. Step 3 Set Conference Call Authorities to Able to Listen and Speak or Able to Listen but not Speak.
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Step 4 In the Available Conference Call Port pane, select the port where you need to configure a conference call, and click
.
NOTE
If the optical interfaces that support conference calls form a loop, howler tone is generated. Hence, "releasing loop" is required, that is, only one optical port can be set for the conference calls on a certain node.
Step 5 Click Apply. A dialog box is displayed, indicating that the operation is successful. Step 6 Click Close. Step 7 Click the General tab. Set the Conference Call number. NOTE
The conference call numbers for all the NEs must be the same, and must have the same length as the corresponding orderwire phone numbers. If the orderwire phone number has four digits, it is recommended that you set the conference call number to 9999.
Step 8 Click Apply. ----End
Example You can follow the sample configuration to prevent a conference call loop.
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2 Creating the Network NM ID NM name IP address
U2000 NM 192.9.0.54
2-SL4D-1
2-SL4D-2
9-1 NE1 1001/9999
2-SL4D-2
2-SL4D-1
9-2 NE2 1002/9999
Two-fiber bidirectional MSP ring
2-SL4D-1
1-SL1D-1 9-4 NE4 1004/9999 2-SL4D-2
NE ID NE name Telephone No./ Conference Call No.
1-SL1D-1
Two-fiber bidirectional
9-5 NE5 1005/9999
9-3 NE3 1003/9999
2-SL4D-2
2-SL4D-1
As shown in the preceding figure, if conference calls are configured for all optical interfaces, howler tone is generated. You can configure a conference call for the optical interface NE3-2SL4D-2 only, instead of the optical interface NE3-2-SL4D-1.
2.10 Configuring the Broadcast Data Service To meet the requirements for the broadcast data services between the monitoring host and the environment monitors, you need to configure the broadcast data services of NE1-NE4.
Prerequisite l
The 2 Creating the Network task must be completed.
l
Understand the signal flow and timeslot allocation.
Precautions
CAUTION When you configure the broadcast data ports, ensure that the broadcast data ports do not form a loop. Certain optical ports cannot be configured as the broadcast data ports.
Procedure Step 1 Select NE in the NE Explorer, and then choose Configuration > Orderwire from the Function Tree. Step 2 Click the Broadcast Data Port tab and set the parameters as listed in the following table. Then, click Apply. For the values of specified parameters, see 2.12.3 Configuring Broadcast Data Interfaces. 2-36
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Step 3 See Setting Network-Wide Performance Monitoring and enable the performance monitoring function of the NEs. Step 4 Back up the configuration data of the NEs. For details, see Backing Up the NE Data to the System Control Board. ----End
2.11 Configuring the F1 Data Service The F1 data service is transparently transmitted in the point-to-point mode by using the F1 byte.
Prerequisite l
The 2 Creating the Network is completed.
l
Understand the signal flow and timeslot allocation.
Procedure Step 1 In the NE Explorer, select NE1 and choose Configuration > Orderwire from the Function Tree. Step 2 Click the F1 Data Port tab. After setting the parameters, click Apply. For the principles of setting the parameters, see 2.12.2 Configuring F1 Data Interfaces. Step 3 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 4 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
2.12 Orderwire Configuration Parameters The equipment supports various orderwire management, which involves orderwire phones and F1 data interfaces. 2.12.1 Configuring Orderwire Phones This topic describes the parameters that are used for configuring orderwire phones. 2.12.2 Configuring F1 Data Interfaces This topic describes the parameters that are used for configuring F1 data interfaces. 2.12.3 Configuring Broadcast Data Interfaces This topic describes the parameters that are used for configuring broadcast data interfaces.
2.12.1 Configuring Orderwire Phones This topic describes the parameters that are used for configuring orderwire phones. Table 2-8 lists the parameters that are used for configuring orderwire phones. Issue 02 (2011-06-30)
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Table 2-8 Parameters for configuring orderwire phones Field
Value Range
Description
Call Waiting Time(s)
1-9 Default value: 9
The Call Waiting Time(s) parameter specifies the timeout period of searching an orderwire route. If the period of searching an orderwire route exceeds the specified value, the orderwire phone changes to the busy tone status. You can click 7.102 Call Waiting Time(s) to display the detailed information.
Dialing Mode
Pulse, Dual-Tone Frequency
Displays the dialing mode of the orderwire phone.
Default: Dual-Tone Frequency Conference Call
100-99999999 Default value: 999
The Conference Call parameter specifies the phone numbers of networkwide orderwire calls. You can click 7.103 Conference Call to display the detailed information.
Phone 1, Phone 2, Phone 3
100-99999999
The Phone parameter specifies the phone numbers of orderwire addressing calls. An addressing call refers to a point-to-point call. Specifies the phone numbers of up to three orderwire phones supported by the overheads. Certain equipment supports one orderwire phone only. In this case, phones 2 and 3 are not required. If the value is null, the delivered configuration does not indicate that the corresponding data on the NE side needs to be cleared, but indicates that the corresponding data on the NE side is not changed.
NOTE OptiX OSN 550 equipment only supports Phone 1.
You can click 7.104 Phone to display the detailed information.
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Field
Value Range
Description
Selected Orderwire Port
Slot ID-Board Name-Port No.(Port Name)
Specifies the port on the line board for orderwire phone transmission.
Available Orderwire Port
Available Orderwire Port Default value: Bid-BidTypePortID
The Available Orderwire Port parameter specifies whether the optical interface is used to make orderwire calls. You can click 7.105 Available Orderwire Port to display the detailed information.
2.12.2 Configuring F1 Data Interfaces This topic describes the parameters that are used for configuring F1 data interfaces. Table 2-9 list the parameters that are used for configuring F1 data interfaces. Table 2-9 Parameters for configuring F1 data interfaces Field
Value Range
Description
No.
1-88
The No. (F1 Data Port) parameter specifies the numbers of the F1 data ports that have the same direction. You can click 7.106 No.(F1 Data Port) to display the detailed information.
Data Channel 1
-
The Data Channel (F1 Data Port) parameter specifies the uplink and downlink ports that pass through the F1 data. displays pass-through channel 1, namely, the source port of the data services at the local station. You can click 7.107 Data Channel (F1 Data Port) to display the detailed information.
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Field
Value Range
Description
Data Channel 2
-
The Data Channel (F1 Data Port) parameter specifies the uplink and downlink ports that pass through the F1 data. displays pass-through channel 2, namely, the sink port of the data services at the local station. You can click 7.107 Data Channel (F1 Data Port) to display the detailed information.
Available Data Channel
-
Displays all the available data interfaces or optical interfaces.
2.12.3 Configuring Broadcast Data Interfaces This topic describes the parameters that are used for configuring broadcast data interfaces. Table 2-10 list the parameters that are used for configuring broadcast data interfaces. Table 2-10 Parameters for configuring broadcast data interfaces Field
Value Range
Description
Overhead Byte
SERIAL1, SERIAL2, SERIAL3, SERIAL4
The Overhead Byte (Broadcast Data Port) parameter specifies the number of the overhead bytes, which are used to transmit orderwire broadcast data services, in the SDH frame header.
Default value: SERIAL1
You can click 7.108 Overhead Byte (Broadcast Data Port) to display the detailed information.
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Field
Value Range
Description
Working Mode
RS232
The Working Mode (Broadcast Data Port) parameter specifies the working mode of the local interface at which broadcast data services are added or dropped.
Default value: RS232
You can click 7.109 Working Mode (Broadcast Data Port) to display the detailed information.
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Broadcast Data Source
No Data, SERIALx, BidBidType-PortID Default value: -
The Broadcast Data Source (Broadcast Data Port) parameter specifies the source of the orderwire broadcast data service. You can click 7.110 Broadcast Data Source (Broadcast Data Port) to display the detailed information.
Broadcast Data Sink
SERIALx, Bid-BidTypePortID Default value: -
The Broadcast Data Sink (Broadcast Data Port) parameter specifies the sink of the orderwire broadcast data service. You can click 7.111 Broadcast Data Sink (Broadcast Data Port) to display the detailed information.
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3 Configuring SDH Services
Configuring SDH Services
About This Chapter This topic uses an example to describe how to configure SDH services on the U2000. 3.1 Basic Concepts The following basic concepts help you understand and configure the relevant SDH services correctly. 3.2 Configuring Services on the Non-Protection Chain Configure the protection subnet and the services on the non-protection chain separately. It is recommended that you configure the protection subnet before configuring the services on the non-protection chain. 3.3 Configuring Services on the Non-Protection Ring Configure the protection subnet and the services on the non-protection ring separately. It is recommended that you configure the protection subnet before configuring services on the nonprotection ring. 3.4 Configuring 1+1 Linear MSP Services In the case of the 1+1 linear multiplex section protection (MSP), services are transmitted on the working path and protection path at the same time. The sink NE selects the services from the working path in normal cases, and selects services from the protection path when the working path becomes faulty. 3.5 Configuring 1:1 Linear MSP Services In the case of the 1:1 linear MSP, services are transmitted on the working path and the sink NE receives the services from the working path in normal cases. When the working path becomes faulty, the services are switched to the protection path for transmission and the sink NE receives the services from the protection path. 3.6 Configuring Two-Fiber Unidirectional MSP Services The two-fiber unidirectional MSP services can provide network level protection for the services on NEs on the MSP ring. On the U2000, you can add all the NEs on the MSP ring into the protection subnet to create a two-fiber unidirectional MSP ring. 3.7 Configuring the Two-Fiber Bidirectional MSP Services To configure the two-fiber bidirectional MSP services, you need to create the MSP subnet protection and MSP services separately. There is no requirement for the configuration sequence. Issue 02 (2011-06-30)
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3.8 Configuring Services on the SNCP Ring Compared with the services on an MSP ring, the services on an SNCP ring have dedicated physical paths as the protection paths. In addition, the services on an SNCP ring are dually fed and selectively received. When you configure services on an SNCP ring, you need not configure the protection subnet and the services separately. When you configure services on an SNCP ring, however, you need to configure the working services and protection services separately. 3.9 Configuring Services on the SNCP Ring with a Non-Protection Chain To configure the services on the SNCP ring, you can directly configure the working service and protection service, without first configuring the protection subnet. To configure the services on the non-protection chain, you can configure the services only after the protection subnet is created. 3.10 Configuring Service on the MSP Ring with a Non-Protection Chain Configure the protection subnet for the MSP, Protection Subnet for the non-protection chain, and services on the MSP ring with a non-protection chain separately. It is recommended that you configure the protection subnets before configuring the services on the MSP ring with a non-protection ring chain. 3.11 Protection Configuration Parameters You need to set the necessary parameters when configuring the protection such as MSP, SNCP for an NE.
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3.1 Basic Concepts The following basic concepts help you understand and configure the relevant SDH services correctly.
Unidirectional Service The unidirectional service indicates the service that is received and transmitted on different paths. A unidirectional service created between NE A and NE B can only be transmitted from NE A (source) to NE B (sink) or only be transmitted from NE B (sink) to NE A (source).
Bidirectional Service The bidirectional service indicates the service that is received and transmitted on the same path. A bidirectional service created between NE A and NE B can be transmitted and received from NE A to NE B or from NE B to NE A.
MSP The multiplex section protection (MSP) provides a function that switches the signals from the working section to the protection section.
Shared MSP Ring As an SDH ring structure, the shared MSP protection ring provides the working and protection paths for each node in the ring network. When the service in the working path is abnormal or interrupted, the service is automatically switched to the protection path for further transmission. In this case, the service loss can be avoided.
Two-Fiber Shared MSP Ring To form a two-fiber shared MSP ring, you need to use two fibers. In each fiber, one half of channels are used as working timeslots, and the other half of channels are used as protection timeslots. For example, in the case of an STM-4 service, VC-4s numbered 1 to 2 are used as working timeslots and VC-4s numbered 3 to 4 are used as protection timeslots. When VC-4s numbered 1 to 2 is abnormal or faulty, the service is switched to the corresponding protection timeslots 3 to 4 for further transmission.
SNCP Principle The sub-network connection protection (SNCP) is defined by the ITU-T Recommendations. With 1+1 single-ended switching function, the SNCP is used for protecting services that travel across different subnets. The SNCP is characterized by the dual-fed and selective-receiving mode.
Principles for Generating SNCP Services The SNCP is characterized by the dual-fed and selective receiving mode. Thus, to configure the SNCP service, you should configure the dual-fed service and the selective receiving service. On the U2000, the service can be automatically created. When the selective receiving service is configured on the U2000, the dual-fed service of the NE can be automatically created. Thus, Issue 02 (2011-06-30)
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you only need to configure the selective receiving service in actual service configuration. That is, if the SNCP service pair is configured, the service configuration of the SNCP is complete.
3.2 Configuring Services on the Non-Protection Chain Configure the protection subnet and the services on the non-protection chain separately. It is recommended that you configure the protection subnet before configuring the services on the non-protection chain. 3.2.1 Networking Diagram You can configure a non-protection chain if the services on the chain need not be protected. In this case, all the timeslots on the chain can carry services. 3.2.2 Signal Flow and Timeslot Allocation To configure services on the non-protection chain, you need to plan the traffic direction and timeslot allocation for the services on the non-protection chain. 3.2.3 Per-NE Configuration Procedure The configuration of services on the non-protection chain is not related to the configuration of the protection subnet. To configure the services on the non-protection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs if the protection subnet is already created. 3.2.4 End-to-End Configuration Process The configuration of services on a non-protection chain is independent of the creation of the protection subnet. To configure the services on the non-protection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs if the protection subnet is already created.
3.2.1 Networking Diagram You can configure a non-protection chain if the services on the chain need not be protected. In this case, all the timeslots on the chain can carry services. Figure 3-1 shows a point-to-point non-protection chain. In this example, the SP3D boards are configured on the source NE (NE1) and the sink NE (NE2) as tributary boards to add and drop services, and the SL1D boards are used as line boards to transmit SDH services. Figure 3-1 Networking diagram of the non-protection chain 1-SL1D-1
1-SL1D-1
NE 1 Tributary board 3-SP3D
3-4
NE 2 Line board 1-SL1D
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Line board Tributary board 1-SL1D
3-SP3D
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3.2.2 Signal Flow and Timeslot Allocation To configure services on the non-protection chain, you need to plan the traffic direction and timeslot allocation for the services on the non-protection chain. Figure 3-2 shows the signal flow and timeslot allocation. In this example, five E1 services are added to or dropped from NE1 and NE2. Figure 3-2 Signal flow and timeslot allocation of the services on the non-protection chain 3-SP3D
5×E1
1-SL1D-1
3-SP3D
1-SL1D-1
线路 板
5×E1 VC4-1:15(VC12)
NE1 Tributary board 3-SP3D
Line board 1-SL1D
NE2 Line board Tributary board 1-SL1D
3-SP3D
Line Board Tributary Board Traffic direction of the non-protection chain
3.2.3 Per-NE Configuration Procedure The configuration of services on the non-protection chain is not related to the configuration of the protection subnet. To configure the services on the non-protection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs if the protection subnet is already created.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.1 Configuring a Non-Protection Chain.
l
You must be familiar with the information about 3.2.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure SDH services on the source NE (NE1). 1.
Select NE1 in the NE Explorer, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK,
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received over the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE1 is configured as the source tributary board. See Figure 3-2.
Source VC4
-
-
Source Timeslot Range (e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE2. Hence, the service source occupies VC-12s 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 of NE1 is configured as the sink line board. See Figure 3-2.
Sink VC4
VC4-1
The service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE 1 and NE2. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 2 Refer to Step 1 and configure SDH services on the sink NE (NE2). Set the parameters as follows.
3-6
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectional
In this example, the services are transmitted and received over the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE1 is configured as the source tributary board. See Figure 3-2.
Source VC4
-
-
Source Timeslot Range(e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE2. Hence, the service source occupies VC-12s 1-5.
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Parameter
Value in This Example
Description
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 of NE1 is configured as the sink line board. See Figure 3-2.
Sink VC4
VC4-1
The service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE2. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 3 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and need to be deleted, see Deleting SDH Services.
3.2.4 End-to-End Configuration Process The configuration of services on a non-protection chain is independent of the creation of the protection subnet. To configure the services on the non-protection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs if the protection subnet is already created.
Prerequisite l
The physical network topology must be set up.
l
The NEs, boards, and fibers must be successfully created on the U2000.
l
The protection subnet must be created and must be the same as the actual topology. For details about how to create the protection subnet, see 2.6.1 Configuring a Non-Protection Chain.
l
The operator must understand the information provided in 3.2.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create the VC-4 service-layer trail. Issue 02 (2011-06-30)
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1.
Configure the parameters as follows. Set Level to VC4 Server Trail. The other parameters take default values.
2.
Double-click the source NE (NE1) and sink NE (NE2) on the right of the main topology and click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded.
3.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 service-layer trail.
Step 3 Create VC12 services. 1.
In Create SDH Tail, configure the parameters as follows. Set Level to VC12. The other parameters take default values.
2.
Double-click the source NE on the right of the main topology. The Select Board PortSource dialog box is displayed. Select the required PDH board and Tributary Port. Click OK.
3.
Double-click the sink NE (NE2) on the right of the main topology. Configure NE2 in the same manner.
4.
Select Copy after Creation and click Apply. Click Close in the Operation Result dialog box indicating that the operation succeeded. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from NE1-Slot3-SP3D-2(SDH_TU-2) to NE2-Slot3-SP3D-5(SDH_TU-5), and click Add.
6.
In the Operation Result dialog box indicating that the operation succeeded, click Close.
7.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC12 services.
Step 4 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
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Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.3 Configuring Services on the Non-Protection Ring Configure the protection subnet and the services on the non-protection ring separately. It is recommended that you configure the protection subnet before configuring services on the nonprotection ring. 3.3.1 Networking Diagram You can configure a non-protection ring if the services on the ring need not be protected. In this case, all the timeslots on the ring can carry services. 3.3.2 Signal Flow and Timeslot Allocation To configure services on the non-protection ring, you need to plan the traffic direction and timeslot allocation for the services on the non-protection ring. 3.3.3 Per-NE Configuration Process The configuration of the services on the non-protection ring is not related to the configuration of the protection subnet. To configure the services on the non-protection ring, configure the SDH services from the tributary board to the line board on the source and sink NEs and the passthrough services on the intermediate NEs if the protection subnet is already created. 3.3.4 End-to-End Configuration Process The configuration of the services on the non-protection ring is not related to the configuration of the protection subnet. To configure the services on the non-protection ring, configure the SDH services from the tributary board to the line board on the source and sink NEs and the passthrough services on the intermediate NEs if the protection subnet is already created.
3.3.1 Networking Diagram You can configure a non-protection ring if the services on the ring need not be protected. In this case, all the timeslots on the ring can carry services. Figure 3-3 shows a non-protection ring consisting of four pieces of equipment. In this example, the SP3D boards are used on the source NE (NE1) and the sink NE (NE3) as tributary boards to add and drop services, and the SL1D boards are used as line boards to transmit SDH services. Figure 3-3 Networking diagram of the non-protection ring 3-SP3D 1-SL1D-1
NE1: Tributary board 3-SP3D
Line board 1-SL1D-1
NE1 1-SL1D-2 NE2 NE2:
Two-fiber bidirectional non-protection ring
1-SL1D-1
Line board
Line board
1-SL1D-2
1-SL1D-1
NE3 NE3:
1-SL1D-2
Tributary board
3-SP3D
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NE4
3-SP3D
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Line board 1-SL1D-2
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3.3.2 Signal Flow and Timeslot Allocation To configure services on the non-protection ring, you need to plan the traffic direction and timeslot allocation for the services on the non-protection ring. Figure 3-4 shows the signal flow and timeslot allocation. In this example, five E1 services are added to or dropped from NE1 and NE3, and they pass through NE2. Figure 3-4 Signal flow and timeslot allocation of the services on the non-protection ring VC4-1:1-5(VC12)
5×E1
3-SP3D NE1: Tributary board 3-SP3D
1-SL1D-1
Line board 1-SL1D-1
NE1
1-SL1D-2 VC4-1:1-5(VC12) Pass-through service
NE2
Two-fiber bidirectional non-protection ring
NE4
线路板
1-SL1D-1
NE2: Line board
Line board
1-SL1D-2
1-SL1D-1
NE3
NE3:
1-SL1D-2
Tributary board
VC4-1:1-5(VC12) Traffic direction
Line board
3-SP3D
3-SP3D
Line board 1-SL1D-2
5×E1
Tributary board
3.3.3 Per-NE Configuration Process The configuration of the services on the non-protection ring is not related to the configuration of the protection subnet. To configure the services on the non-protection ring, configure the SDH services from the tributary board to the line board on the source and sink NEs and the passthrough services on the intermediate NEs if the protection subnet is already created.
Prerequisite
3-10
l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.2 Configuring a Non-Protection Ring.
l
You must be familiar with the information about 3.3.2 Signal Flow and Timeslot Allocation. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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Procedure Step 1 Configure SDH services of the source NE (NE1). 1.
Select NE1 in the NE Explorer, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received over the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE1 is configured as the source tributary board. See Figure 3-4.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE3. Hence, the service source occupies VC-12s 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 of NE1 is configured as the sink line board. See Figure 3-4.
Sink VC4
VC4-1
The timeslots where the service sink is located belong to the first VC-4 (VC4-1).
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE2. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 2 Configure SDH services on the sink NE (NE3). Refer to Step 1. Set the parameters as follows.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
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Parameter
Value in This Example
Description
Direction
Bidirectional
In this example, the services are transmitted and received over the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE3 is configured as the source tributary board. See Figure 3-4.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE3. Hence, the service source occupies VC-12s 1-5.
Sink Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 of NE2 is configured as the sink line board. See Figure 3-4.
Sink VC4
VC4-1
The service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE3. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 3 Configure pass-through services on NE2.
3-12
1.
Select NE2 in the NE Explorer, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received over the same path. That is, the services are Bidirectional services.
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 of NE2 is configured as the source line board. See Figure 3-4.
Source VC4
VC4-1
The timeslots where the service source is located belong to the first VC-4 (VC4-1).
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Parameter
Value in This Example
Description
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE3. Hence, the service source occupies VC-12s 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 of NE2 is configured as the sink line board. See Figure 3-4.
Sink VC4
VC4-1
The service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE1 and NE3. Hence, the service source occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 4 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and need to be deleted, see Deleting SDH Services.
3.3.4 End-to-End Configuration Process The configuration of the services on the non-protection ring is not related to the configuration of the protection subnet. To configure the services on the non-protection ring, configure the SDH services from the tributary board to the line board on the source and sink NEs and the passthrough services on the intermediate NEs if the protection subnet is already created.
Prerequisite l
The physical network topology must be set up.
l
The NEs, boards, and fibers must be successfully created on the U2000.
l
The protection subnet must be created and must be the same as the actual topology. For details about how to create the protection subnet, see 2.6.2 Configuring a Non-Protection Ring.
l
The operator must understand the information provided in 3.3.2 Signal Flow and Timeslot Allocation.
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Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create the VC-4 service-layer trail. 1.
Configure the parameters as follows. Set Level to VC4 Server Trail. The other parameters take default values.
2.
Double-click the source NE (NE1) and sink NE (NE3) on the right of the main topology and click Apply. In the Operation Result dialog box that is displayed, click Close.
3.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC4 service-layer trail.
Step 3 Create VC12 services. 1.
In Create SDH Tail, configure the parameters as follows. Set Level to VC12 and set Direction to Bidirectional. The other parameters take default values.
2.
Double-click the source NE on the right of the main topology. The Select Board PortSource dialog box is displayed. Select the required PDH board and Tributary Port. Click OK.
3.
Double-click the sink NE (NE3) on the right of the main topology. Configure NE2 in the same manner.
4.
Select Copy after Creation and click Apply. In the Operation Result dialog box that is displayed, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from NE1-Slot3-SP3D-2(SDH_TU-2) to NE3-Slot3-SP3D-5(SDH_TU-5), and click Add.
6.
In the Operation Result dialog box that is displayed, click Close.
7.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC12 services.
Step 4 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE.
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Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.4 Configuring 1+1 Linear MSP Services In the case of the 1+1 linear multiplex section protection (MSP), services are transmitted on the working path and protection path at the same time. The sink NE selects the services from the working path in normal cases, and selects services from the protection path when the working path becomes faulty. 3.4.1 Networking Diagram The networking diagram of the point-to-point 1+1 linear MSP services is simple. Two NEs are connected with two pairs of optical fibers. 3.4.2 Signal Flow and Timeslot Allocation To configure the 1+1 linear MSP services, you can configure the services that need to be added to the source NE and dropped from the sink NE if the 1+1 linear MSP is already created. 3.4.3 Per-NE Configuration Process This topic describes how to configure the 1+1 linear MSP services. 3.4.4 End-to-End Configuration Process This topic describes how to configure the 11+1 linear MSP services.
3.4.1 Networking Diagram The networking diagram of the point-to-point 1+1 linear MSP services is simple. Two NEs are connected with two pairs of optical fibers. As shown in Figure 3-5, the SP3D boards are used on NE1 and NE2 as tributary boards to add and drop services, and the SL1D boards are used as line boards to transmit SDH services. Figure 3-5 Networking diagram of the 1+1 linear MSP services 1-SL1D-1
1-SL1D-1
1-SL1D-2
1-SL1D-2
NE2
NE1
Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
Line board Line board Tributary board 1-SL1D-2
1-SL1D-1
3-SP3D
3.4.2 Signal Flow and Timeslot Allocation To configure the 1+1 linear MSP services, you can configure the services that need to be added to the source NE and dropped from the sink NE if the 1+1 linear MSP is already created. Issue 02 (2011-06-30)
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As shown in Figure 3-6, the signal flow and timeslot allocation are as follows: l
Traffic direction from NE1 to NE2: NE1→NE2 Services are added to the source NE (NE1) and are transmitted to the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE2), which selects the services from the working path.
l
Traffic direction from NE2 to NE1: NE2→NE1 Services are added to the source NE (NE2) and are transmitted on the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE1), which selects the services from the working path.
l
The services between NE 1 and NE2 occupy VC-12s 1-5 of VC4-1 (VC4-1:VC-12:1-5) on the SDH link between NE1 and NE2. The capacity of the services is 5xE1.
When the working path from NE1 to NE2 becomes faulty, in the case of single-ended switching, the signal flow is as follows: l
Traffic direction from NE1 to NE2: NE1→NE2 Services are added to the source NE (NE1) and are transmitted on the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE2), which selects the services from the protection path.
l
The services from NE2 to NE1 are not affected, and the traffic direction is NE2→NE1. Services are added to the source NE (NE2) and are transmitted on the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE1), which selects the services from the working path.
When the working path from NE1 to NE2 becomes faulty, in the case of dual-ended switching, the signal flow is as follows: l
Traffic direction from NE1 to NE2: NE1→NE2 Services are added to the source NE (NE1) and are transmitted on the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE2), which selects the services from the protection path.
l
Traffic direction from NE2 to NE1: NE2→NE1 Services are added to the source NE (NE2) and are transmitted on the working path and protection path at the same time. Then, the services are dropped from the sink NE (NE1), which selects the services from the protection path.
Figure 3-6 Signal flow and timeslot allocation of the 1+1 linear MSP services 1-SL1D-1
1-SL1D-1 VC4-1:1-5(VC12)
VC4-1:1-5(VC12) 5xE1 services are added/dropped
5xE1 services are added/dropped
3-SP3D
3-SP3D NE2
1-SL1D-2
Tributary board Line board Line board 3-SP3D
3-16
1-SL1D-1
1-SL1D-2
Traffic direction of the working path
Line board
Traffic direction of the protection path
Tributary board
1-SL1D-2
NE1 Line board Line board Tributary board 1-SL1D-2
1-SL1D-1
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3-SP3D
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3.4.3 Per-NE Configuration Process This topic describes how to configure the 1+1 linear MSP services.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.4 Creating a Linear MS Protection Subnet.
l
You must be familiar with the information about 3.4.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure SDH services on the source NE (NE1). 1.
In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, services are transmitted and received over the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the source tributary board for the bidirectional services from NE1 to NE2. See Figure 3-6.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the service is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-6.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
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Parameter
Value in This Example
Description
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Step 2 Configure SDH services on the sink NE (NE2). , and select NE2 from the displayed NE Navigator. Configure NE2 in the same way Click that NE1 is configured. Then, click OK.
3-18
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectional
In this example, the services are transmitted and received over the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-6.
Source VC4
VC4-1
In this example, the service requires five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board for the bidirectional services from NE1 to NE2. See Figure 3-6.
Sink VC4
-
-
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
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Step 3 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.4.4 End-to-End Configuration Process This topic describes how to configure the 11+1 linear MSP services.
Prerequisite l
The physical network topology must be set up.
l
The NEs, boards, and fibers must be successfully created on the U2000.
l
The protection subnet must be created and must be the same as the actual topology. For details about how to create the protection subnet, see 2.6.4 Creating a Linear MS Protection Subnet.
l
The operator must understand the information provided in 3.4.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create the VC-4 service-layer trail. 1.
Configure the parameters as follows. Set Level to VC4 Server Trail. The other parameters take default values.
2.
Double-click the source NE (NE1) and sink NE (NE2) on the right of the main topology and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close.
3.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 service-layer trail.
Step 3 Create VC12 services. 1.
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2.
Double-click the source NE (NE1) on the right of the main topology. The Select Board Port-Source dialog box is displayed. Select the required SP3D board and Tributary Port. Click OK.
3.
Double-click the sink NE (NE2) on the right of the main topology. Configure NE2 in the same manner.
4.
Select Copy after Creation and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from NE2-Slot3-SP3D-2(SDH_TU-2) to NE1-Slot3-SP3D-5(SDH_TU-5), and click Add.
6.
In the Operation Result dialog box indicating that the operation succeeded, click Close.
7.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC12 services.
Step 4 Optional: Modify the parameters SD Condition, Revertive Mode, and Switching Mode for the linear MSP. NOTE
l The parameter settings of the sink NE must be the same as those of the source NE. l When modifying Switching Mode, l Ensure that the protection group is in a proper state. l Ensure that the protection protocol is disabled.
1.
Choose Service > SDH Protection Subnet > Maintenance SDH Protection Subnet from the Main Menu to display the SDH Protection Subnet Common Attributes window.
2.
Select the created linear MSP group. In the Protection Subnet Maintenance tab, select all nodes, right-click and choose Start/Stop Protocol > Stop from the shortcut menu.
3.
Click the Protection Subnet Parameters tab and modify the parameters SD Condition, Revertive Mode, and Switching Mode.
4.
Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded.
5.
After the parameters are modified, restart the protection protocol according to Step 4.2.
Step 5 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 6 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 7 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End 3-20
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3 Configuring SDH Services
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.5 Configuring 1:1 Linear MSP Services In the case of the 1:1 linear MSP, services are transmitted on the working path and the sink NE receives the services from the working path in normal cases. When the working path becomes faulty, the services are switched to the protection path for transmission and the sink NE receives the services from the protection path. 3.5.1 Networking Diagram The networking diagram of the point-to-point 1:1 linear LSP services is simple. Two NEs are connected with two pairs of optical fibers. 3.5.2 Signal Flow and Timeslot Allocation To configure the 1:1 linear MSP service, you can configure the services that need to be added to the source NE and dropped from the sink NE if the 1:1 linear MSP is already created. 3.5.3 Per-NE Configuration Process This topic describes how to configure the 1:1 linear MSP services. 3.5.4 End-to-End Configuration Process This topic describes how to configure 1:1 linear MSP services in an end-to-end manner.
3.5.1 Networking Diagram The networking diagram of the point-to-point 1:1 linear LSP services is simple. Two NEs are connected with two pairs of optical fibers. As shown in Figure 3-7, the SP3D boards are used on NE1 and NE2 as tributary boards to add and drop services, and the SL1D boards are used on NE1 and NE2 as line boards to transmit SDH services. Figure 3-7 Networking diagram of the 1:1 linear MSP services 1-SL1D-1
1-SL1D-1
1-SL1D-2
1-SL1D-2
NE2
NE1
Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
Line board Line board Tributary board 1-SL1D-2
1-SL1D-1
3-SP3D
3.5.2 Signal Flow and Timeslot Allocation To configure the 1:1 linear MSP service, you can configure the services that need to be added to the source NE and dropped from the sink NE if the 1:1 linear MSP is already created. As shown in Figure 3-8, the signal flow and timeslot allocation are as follows: l Issue 02 (2011-06-30)
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Services are added to the source NE (NE1) and then are dropped from the sink NE (NE2). The services are transmitted on the working path. l
Traffic direction from NE2 to NE1: NE2→NE1 Services are added to the source NE (NE2) and then are dropped from the sink NE (NE1). The services are transmitted on the working path.
l
The services between NE1 and NE2 occupy VC-12s 1-5 of VC4-1 (VC4-1:VC-12:1-5) on the SDH link between NE1 and NE2. The capacity of the services is 5xE1.
When the working path between NE1 and NE2 becomes faulty, the signal flow is as follows: l
Traffic direction from NE1 to NE2: NE1→NE2 Services are added to the source NE (NE1) and then are dropped from the sink NE (NE2). The services are transmitted on the protection path.
l
Traffic direction from NE2 to NE1: NE2→NE1 Services are added to the source NE (NE2) and then are dropped from the sink NE (NE1). The services are transmitted on the protection path.
The difference between the 1:1 linear MSP service and the 1+1 linear MSP service is as follows: l
In the case of the 1+1 linear MSP service, services are transmitted on the working path and protection path at the same time. The sink NE selects the services from the working path.
l
In the case of the 1:1 linear MSP service, services are transmitted only on the working path. Services are switched to the protection path for transmission only when the working path becomes faulty.
Figure 3-8 Signal flow and timeslot allocation of the 1:1 linear MSP services 1-SL1D-1
1-SL1D-1 VC4-1:1-5(VC12)
VC4-1:1-5(VC12) 5xE1 services are added/dropped
5xE1 services are added/dropped 3-SP3D
3-SP3D NE2
1-SL1D-2
Tributary board Line board Line board 3-SP3D Traffic direction of the working path Traffic direction of the protection path
1-SL1D-1
1-SL1D-2
1-SL1D-2
NE1
Line board Line board Tributary board 1-SL1D-2
1-SL1D-1
3-SP3D
Line board Tributary board
3.5.3 Per-NE Configuration Process This topic describes how to configure the 1:1 linear MSP services.
Prerequisite
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l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.4 Creating a Linear MS Protection Subnet.
l
You must be familiar with the information about 3.5.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure SDH services on the source NE (NE1). 1.
Select NE1 in the NE Explorer, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the source tributary board for the bidirectional services from NE1 to NE2. See Figure 3-8.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the service is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-8.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Step 2 Configure SDH services on the sink NE (NE2). Issue 02 (2011-06-30)
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Click
, and select NE2 from the displayed NE Navigator. Click OK.
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectional
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-8.
Source VC4
VC4-1
In this example, the service requires five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board for the bidirectional services from NE1 to NE2. See Figure 3-8.
Sink VC4
-
-
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Step 3 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
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3.5.4 End-to-End Configuration Process This topic describes how to configure 1:1 linear MSP services in an end-to-end manner.
Prerequisite l
The physical network topology must be set up.
l
NEs, boards, and fibers must be successfully created on the U2000.
l
A linear MSP subnet must be created and must be the same as the actual topology. For details about how to create a protection subnet, see 2.6.4 Creating a Linear MS Protection Subnet.
l
The operator must understand the information provided in 3.5.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create the VC-4 service-layer trail. 1.
Configure the parameters as follows. Set Level to VC4 Server Trail. The other parameters take default values.
2.
Double-click the source NE (NE1) and sink NE (NE2) on the right of the main topology and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close.
3.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 service-layer trail.
Step 3 Create VC12 services. 1.
In Create SDH Trail, configure the parameters as follows. Set Level to VC12. The other parameters take default values.
2.
Double-click the source NE (NE1) on the right of the main topology. The Select Board Port-Source dialog box is displayed. Select the required SP3D board and Tributary Port. Click OK.
3.
Double-click the sink NE (NE2) on the right of the main topology. Configure NE2 in the same manner.
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4.
Select Copy after Creation and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from NE2-Slot3-SP3D-2(SDH_TU-2) to NE1-Slot3-SP3D-5(SDH_TU-5), and click Add.
6.
In the Operation Result dialog box indicating that the operation succeeded, click Close.
7.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC12 services.
Step 4 Optional: Modify the parameters SD Condition, Revertive Mode, and Switching Mode for the linear MSP. NOTE
l The parameter settings of the sink NE must be the same as those of the source NE. l When modifying Switching Mode, l Ensure that the protection group is in a proper state. l Ensure that the protection protocol is disabled.
1.
Choose Service > SDH Protection Subnet > Maintenance SDH Protection Subnet from the Main Menu to display the SDH Protection Subnet Common Attributes window.
2.
Select the created linear MSP group. In the Protection Subnet Maintenance tab, select all nodes, right-click and choose Start/Stop Protocol > Stop from the shortcut menu.
3.
Click the Protection Subnet Parameters tab and modify the parameters SD Condition, Revertive Mode, and Switching Mode.
4.
Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded.
5.
After the parameters are modified, restart the protection protocol according to Step 4.2.
Step 5 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 6 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 7 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.6 Configuring Two-Fiber Unidirectional MSP Services The two-fiber unidirectional MSP services can provide network level protection for the services on NEs on the MSP ring. On the U2000, you can add all the NEs on the MSP ring into the protection subnet to create a two-fiber unidirectional MSP ring. 3.6.1 Networking Diagram The networking diagram of a single two-fiber unidirectional MSP ring is simple. When you construct the network, follow a certain order to create and name these NEs and ensure that the 3-26
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traffic flows in a proper direction. This helps when you plan the traffic direction planning and service configuration in future. 3.6.2 Signal Flow and Timeslot Allocation To configure the two-fiber unidirectional MSP service, you can configure the services that need to be added to the ring network on the source NE, to pass through the intermediate nodes, and to be dropped from the sink NE if the MSP protection subnet is already created. 3.6.3 Per-NE Configuration Process This topic describes how to configure the two-fiber unidirectional MSP service. 3.6.4 End-to-End Configuration Process This topic describes how to configure two-fiber unidirectional MSP services.
3.6.1 Networking Diagram The networking diagram of a single two-fiber unidirectional MSP ring is simple. When you construct the network, follow a certain order to create and name these NEs and ensure that the traffic flows in a proper direction. This helps when you plan the traffic direction planning and service configuration in future. As shown in Figure 3-9, the SP3D boards are used on NE1 and NE3 as tributary boards to add and drop services, and the SL1D boards are used as line boards to transmit SDH services. Figure 3-9 Networking diagram of the services on the two-fiber unidirectional MSP ring NE1: Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-1
1-SL1D-2
1-SL1D-2
NE1
1-SL1D-2
1-SL1D-1 NE2
Two-fiber unidirectional MSP ring
NE4
1-SL1D-1
NE2: Line board Line board 1-SL1D-2
1-SL1D-2
NE3
NE4: Line board Line board
1-SL1D-1
1-SL1D-2
1-SL1D-1
1-SL1D-1
1-SL1D-2
NE3: Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
3.6.2 Signal Flow and Timeslot Allocation To configure the two-fiber unidirectional MSP service, you can configure the services that need to be added to the ring network on the source NE, to pass through the intermediate nodes, and to be dropped from the sink NE if the MSP protection subnet is already created. As shown in Figure 3-10, the signal flow and timeslot allocation are as follows: l Issue 02 (2011-06-30)
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Services are added to the ring on the source NE (NE1), pass through NE2, and finally are dropped from the sink NE (NE3). The capacity of the services is 5xE1. l
Traffic direction from NE3 to NE1: NE3→NE4→NE1 Services are added to the ring on the source NE (NE3), pass through NE4, and finally are dropped from the sink NE (NE1). The capacity of the services is 5xE1.
l
VC-12s 1-5 of VC4-1 carry the five E1 services for transmission.
When the transmission path between NE1 and NE2 becomes faulty, the signal flow and timeslot allocation are as follows: l
Traffic direction from NE1 to NE3: NE1→NE4→NE3→NE2→NE3 Services are added to the ring on the source NE (NE1) and switched from the original working path to the protection path. Then, the services pass through NE4 and NE3. After that, the services are switched from the protection path to the working path on NE2. Finally, the services are dropped from NE3.
l
The services from NE3 to NE1 are not affected, and the traffic direction is NE3→NE4→ NE1.
The difference between the two-fiber unidirectional MSP service and the two-fiber bidirectional MSP service is as follows:
3-28
l
The two-fiber unidirectional MSP service uses the diverse routes, whereas the two-fiber bidirectional MSP service uses the uniform route.
l
In the case of the two-fiber unidirectional MSP service, different optical fibers are used for the working timeslot and protection timeslot. That is, one optical fiber is used for carrying the working service, and the other optical fiber is used for protection. In the case of the two-fiber bidirectional MSP service, the same optical fiber is used for the working timeslot and protection timeslot. That is, a certain capacity of the optical fiber is used for carrying the working service, and a certain capacity of the optical fiber is used for protection.
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Figure 3-10 Signal flow and timeslot allocation of the two-fiber unidirectional MSP services 5xE1services are added/dropped VC4-1:1-5(VC12)
NE1:
3-SP3D
Tributary board Line board Line board 1-SL1D-1
1-SL1D-2
3-SP3D
1-SL1D-1
1-SL1D-2
NE1
1-SL1D-2 VC4-1:1-5(VC12) Pass-through service
1-SL1D-1
NE2
Two-fiber unidirectional MSP ring
1-SL1D-2
1-SL1D-1 NE2: Line board Line board 1-SL1D-2
VC4-1:1-5(VC12) Pass-through service
线路 板
NE4
NE4: Line board Line board
NE3
1-SL1D-1
1-SL1D-2
1-SL1D-1
1-SL1D-2
1-SL1D-1 NE3:
VC4-1:1-5(VC12) Traffic direction of the working path Traffic direction of the protection path
3-SP3D
5xE1services are added/dropped
Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
Line board Tributary board
3.6.3 Per-NE Configuration Process This topic describes how to configure the two-fiber unidirectional MSP service.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.3 Creating an MS Ring Protection Subnet.
l
You must be familiar with the information about 3.6.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure unidirectional services from NE1 to NE3. 1.
Configure SDH services on the source NE (NE1). l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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2.
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirectio nal
In this example, the services are transmitted and received on different paths. That is, the services are unidirectional services. Hence, Direction of the services is set to Unidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the source tributary board for the unidirectional services from NE1 to NE2. See Figure 3-10.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-10.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Configure unidirectional pass-through services on NE2. Click
3-30
, and select NE2 from the displayed NE Navigator. Click OK.
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirection al
In this example, the services are transmitted and received on different paths. That is, the services are unidirectional services. Hence, Direction of the services is set to Unidirectional.
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Parameter
Value in This Example
Description
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-10. You can select different source boards depending on the actual situation.
Source VC4
VC4-1
In this example, the services require five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-10.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Configure SDH services on the sink NE (NE3). Click
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, and select NE2 from the displayed NE Navigator. Click OK.
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirection al
In this example, the services are transmitted and received on different paths. That is, the services are unidirectional services. Hence, Direction of the services is set to Unidirectional.
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-10.
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Parameter
Value in This Example
Description
Source VC4
VC4-1
In this example, the services require five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board for the unidirectional services from NE1 to NE3. See Figure 3-10.
Sink VC4
-
-
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the planning. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Step 2 Configure unidirectional services from NE3 to NE1. To configure unidirectional services from NE3 to NE1, refer to Step 1. 1.
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Configure SDH services on the source NE (NE3). Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirection al
In this example, the services are transmitted and received on different paths. That is, the services are unidirectional services. Hence, Direction of the services is set to Unidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the source tributary board for the unidirectional services from NE3 to NE1. See Figure 3-10.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
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Parameter
Value in This Example
Description
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-10.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Configure unidirectional pass-through services on NE4. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirection al
In this example, the services are transmitted and received on different paths. That is, the services are unidirectional services. Hence, Direction of the services is set to Unidirectional.
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-10.
Source VC4
VC4-1
In this example, the services require five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to1-5.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-10.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
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3.
Parameter
Value in This Example
Description
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Configure SDH services on the sink NE (NE1). Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Unidirection al
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-10.
Source VC4
VC4-1
In this example, the service requires five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5.
Sink VC4
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board for the unidirectional services from NE3 to NE1. See Figure 3-10.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The total capacity of the services is 5xE1 according to the plan. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5.
Activate Immediately
Yes
-
Step 3 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration.
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Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and need to be deleted, see Deleting SDH Services.
3.6.4 End-to-End Configuration Process This topic describes how to configure two-fiber unidirectional MSP services.
Prerequisite l
The physical network topology must be set up.
l
NEs, boards, and fibers must be successfully created on the U2000.
l
A linear MSP subnet must be created and must be the same as the actual topology. For details about how to create a protection subnet, see 2.6.3 Creating an MS Ring Protection Subnet.
l
The operator must understand the information provided in 3.6.2 Signal Flow and Timeslot Allocation.
Background Information In end-to-end mode, configuration of two-fiber unidirectional MSP services is similar to configuration of two-fiber bidirectional MSP services. The only difference is that you set Direction to Unidirectional for two-fiber unidirectional MSP services and set Direction to Bidirectional for two-fiber bidirectional MSP services.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create a VC4 server trail. 1.
Set associated parameters as follows. Set Direction to Unidirectional and Level to VC4 Server Trail, and take default values for other parameters.
2.
Double-click the source NE (NE1) and sink NE (NE3) on the right of the Main Topology and click Apply. Then, click Close in the Operation Result dialog box that is displayed, if the operation is successful. A unidirectional VC4 server trail is set up from NE1 to NE3.
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3.
Double-click the source NE (NE3) and sink NE (NE1) on the right of the Main Topology, and set up a unidirectional VC4 server trail from NE3 to NE1 using the same method.
4.
Optional: If the Operation Result dialog box indicates that the operation is successful, you can also click Browse Trail to query the created VC4 server trail.
Step 3 Create VC12 services after setting up VC4 server trails. 1.
In Create SDH Trail, configure associated parameters as follows. Set Level to VC12, set Direction to Bidirectional, and take default values for other parameters.
2.
Double-click the source NE (NE1) on the right of the Main Topology. The Select Board Port-Source dialog box is displayed. Select the required SP3D board and Tributary Port, and then click OK.
3.
Double-click the sink NE (NE3) on the right of the Main Topology, and configure NE3 using the same method.
4.
Select Copy after Creation and click Apply. If the Operation Result dialog box is displayed to indicate that the operation is successful, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from SP3D-2(SDH_TU-2) to SP3D-5 (SDH_TU-5), and click Add.
6.
If the Operation Result dialog box is displayed to indicate that the operation is successful, click Close.
7.
Optional: If the Operation Result dialog box is displayed to indicate that the operation is successful, you can also click Browse Trail to query the created VC12 services.
Step 4 Optional: Change WTR Time and SD Condition. NOTE
Parameter settings of the sink NE must be the same as those of the source NE.
1.
Choose Service > SDH Protection Subnet > Maintenance SDH Protection Subnet from the Main Menu to display the SDH Protection Subnet Common Attributes window.
2.
Click the Protection Subnet Parameters tab and change parameters such as WTR Time and SD Condition.
3.
Click Apply. If the Operation Result dialog box is displayed to indicate that the operation is successful, click Close.
Step 5 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 6 Enable the performance monitoring function for NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 7 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End 3-36
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Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.7 Configuring the Two-Fiber Bidirectional MSP Services To configure the two-fiber bidirectional MSP services, you need to create the MSP subnet protection and MSP services separately. There is no requirement for the configuration sequence. 3.7.1 Networking Diagram The networking diagram of a single two-fiber bidirectional MSP ring is simple. When you construct the network, follow a certain order to create and name the NEs and ensure that the traffic flows in a proper direction. This helps when you plan the traffic directions and configure services in future. 3.7.2 Signal Flow and Timeslot Allocation To configure the two-fiber bidirectional MSP service on a ring network, configure the services that need to be added to the ring network on the source NE, to pass through the intermediate nodes, and to be dropped from the sink NE, if the MSP protection subnet is already created. In the case of the ring network, more than one route is available from the source NE to the sink NE. In actual application scenarios, not all the routes need to be configured. Hence, you need to properly plan and configure the service directions and timeslots before the configuration. 3.7.3 Per-NE Configuration Process The configuration of the two-fiber bidirectional MSP services is independent of the configuration of the protection subnet. To configure the two-fiber bidirectional MSP service, if the protection subnet is configured, configure the SDH services from the tributary board to the line board on the source and sink NEs and configure the pass-through services on the intermediate NEs. 3.7.4 End-to-End Configuration Process The configuration of two-fiber bidirectional MSP services is independent of the configuration of a protection subnet. To configure two-fiber bidirectional MSP services, configure SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs if a protection subnet has already been configured. The following part describes how to configure two-fiber bidirectional MSP services in end-toend mode.
3.7.1 Networking Diagram The networking diagram of a single two-fiber bidirectional MSP ring is simple. When you construct the network, follow a certain order to create and name the NEs and ensure that the traffic flows in a proper direction. This helps when you plan the traffic directions and configure services in future. Figure 3-11 shows the networking of the two-fiber bidirectional MSP ring that comprises four pieces of OptiX OSN equipment. In this example, the SP3D boards are configured on the source NE (NE1) and the sink NE (NE3) as tributary boards to add and drop services, and the SL4D boards are used as line boards to transmit SDH services.
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Figure 3-11 Networking diagram of the services on the two-fiber bidirectional MSP ring NE1: Tributary board Line board Line board 3-SP3D
1-SL4D-1
1-SL4D-1
1-SL4D-2
1-SL4D-2
NE1
1-SL4D-2
1-SL4D-1 NE2
Two-fiber bidirectional MSP ring
NE4
1-SL4D-1 NE2: Line board Line board 1-SL4D-2
1-SL4D-2
NE3
NE4: Line board Line board
1-SL4D-1
1-SL4D-2
1-SL4D-1
1-SL4D-1
1-SL4D-2
NE3: Tributary board Line board Line board 3-SP3D
1-SL4D-1
1-SL4D-2
3.7.2 Signal Flow and Timeslot Allocation To configure the two-fiber bidirectional MSP service on a ring network, configure the services that need to be added to the ring network on the source NE, to pass through the intermediate nodes, and to be dropped from the sink NE, if the MSP protection subnet is already created. In the case of the ring network, more than one route is available from the source NE to the sink NE. In actual application scenarios, not all the routes need to be configured. Hence, you need to properly plan and configure the service directions and timeslots before the configuration. Figure 3-12 shows the service signal flow and timeslot allocation. In this example, five E1 services are configured so that the services enter the ring network from NE1, pass through NE2, and then are dropped on the sink NE (NE3).
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Figure 3-12 Signal flow and timeslot allocation 5xE1 services are added/dropped VC4-1:1-5(VC12)
NE1: Tributary board Line board Line board 3-SP3D
1-SL4D-1
1-SL4D-2
NE1
VC4-1:1-5(VC12) Pass-through service
MSP ring
NE2
线路 板
NE4
NE2: Line board Line board 1-SL4D-2
NE3
1-SL4D-1
NE3: Tributary board Line board Line board VC4-1:1-5(VC12) service route
Line board
3-SP3D
1-SL4D-1
1-SL4D-2
5xE1 services are added/dropped
Tributary board
3.7.3 Per-NE Configuration Process The configuration of the two-fiber bidirectional MSP services is independent of the configuration of the protection subnet. To configure the two-fiber bidirectional MSP service, if the protection subnet is configured, configure the SDH services from the tributary board to the line board on the source and sink NEs and configure the pass-through services on the intermediate NEs.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.3 Creating an MS Ring Protection Subnet.
l
You must be familiar with 3.7.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure the SDH services of the source NE (NE1). 1.
In the NE Explorer, select NE1, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the source tributary board. See Figure 3-12. You can select different source boards depending on the actual situation.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Sink Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 is configured as the sink line board. See Figure 3-12. You can select different sink boards depending on the actual situation.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Activate Immediately
Yes
-
Step 2 Configure the SDH services of the sink NE (NE3). Refer to Step 1 and configure the SDH services of NE3. Set the parameters as follows.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectional
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
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Parameter
Value in This Example
Description
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 is configured as the source line board. See Figure 3-12. You can select different source boards depending on the actual situation.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board. See Figure 3-12. You can select different sink boards depending on the actual situation.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink VC4
-
-
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Activate Immediately
Yes
-
Step 3 Configure the pass-through services of NE2. 1.
In the NE Explorer, select NE2 and then choose Communication > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 is configured as the source line board. See Figure 3-12. You can select different source boards depending on the actual situation.
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Parameter
Value in This Example
Description
Source VC4
VC4-1
In this example, the services require five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Sink Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 is configured as the sink line board. See Figure 3-12. You can select different sink boards depending on the actual situation.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-12.
Activate Immediately
Yes
-
Step 4 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.7.4 End-to-End Configuration Process The configuration of two-fiber bidirectional MSP services is independent of the configuration of a protection subnet. To configure two-fiber bidirectional MSP services, configure SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs if a protection subnet has already been configured. The following part describes how to configure two-fiber bidirectional MSP services in end-toend mode.
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Prerequisite l
The physical network topology must be set up.
l
NEs, boards, and fibers must be successfully created on the U2000.
l
An MSP subnet must be created and must be the same as the actual topology. For details about how to create a protection subnet, see 2.6.4 Creating a Linear MS Protection Subnet.
l
The operator must understand the information provided in 3.7.2 Signal Flow and Timeslot Allocation.
Background Information In end-to-end mode, configuration of two-fiber unidirectional MSP services is similar to configuration of two-fiber bidirectional MSP services. The only difference is that you set Direction to Unidirectional for two-fiber unidirectional MSP services and set Direction to Bidirectional for two-fiber bidirectional MSP services.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create the VC-4 service-layer trail. 1.
Configure the parameters as follows. Set Level to VC4 Server Trail. The other parameters take default values.
2.
Double-click the source NE (NE1) and sink NE (NE3) on the right of the main topology and click Apply. In the Operation Result dialog box that is displayed, click Close.
3.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC4 service-layer trail.
Step 3 Create VC12 services. 1.
In Create SDH Tail, configure the parameters as follows. Set Level to VC12 and set Direction to Bidirectional. The other parameters take default values.
2.
Double-click the source NE on the right of the main topology. The Select Board PortSource dialog box is displayed. Select the required PDH board and Tributary Port. Click OK.
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3.
Double-click the sink NE (NE3) on the right of the main topology. Configure NE2 in the same manner.
4.
Select Copy after Creation and click Apply. In the Operation Result dialog box that is displayed, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the ports from NE1-Slot3-SP3D-2(SDH_TU-2) to NE3-Slot3-SP3D-5(SDH_TU-5), and click Add.
6.
In the Operation Result dialog box that is displayed, click Close.
7.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC12 services.
Step 4 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.8 Configuring Services on the SNCP Ring Compared with the services on an MSP ring, the services on an SNCP ring have dedicated physical paths as the protection paths. In addition, the services on an SNCP ring are dually fed and selectively received. When you configure services on an SNCP ring, you need not configure the protection subnet and the services separately. When you configure services on an SNCP ring, however, you need to configure the working services and protection services separately. 3.8.1 Networking Diagram The creation of an SNCP ring network is similar to the creation of an MSP ring network. For example, the MSP and SNCP rings are constructed based on two fibers and their services must pass through the intermediate nodes for transmission from the source NE to the sink NE. The difference is that the SNCP protection and SNCP services can be created on the U2000 at a time. 3.8.2 Signal Flow and Timeslot Allocation Similar to the service configuration of an MSP ring, you need to plan proper traffic directions before configuring the services on an SNCP ring, if multiple service routes are available from the source end to the sink end. In the case of the services on the SNCP ring, allocate timeslots for the source slot of the working service and timeslots for the source slot of the protection service, when allocating timeslots for source slots. 3.8.3 Per-NE Configuration Process The SNCP protection and the services on the SNCP ring are configured on the U2000 at a time. To configure the SNCP services on the source and sink NEs, you need to determine the source boards and timeslots for the working service and protection service. In addition, you need to configure the pass-through service on the intermediate nodes. 3.8.4 End-to-End Configuration Process SNCP protection and services on an SNCP ring are configured on the U2000 at the same time. To configure SNCP services on the source and sink NEs, determine the source boards and 3-44
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timeslots for the working service and protection service, and configure pass-through services on the intermediate nodes. The following part describes how to configure services on an SNCP ring in an end-to-end manner.
3.8.1 Networking Diagram The creation of an SNCP ring network is similar to the creation of an MSP ring network. For example, the MSP and SNCP rings are constructed based on two fibers and their services must pass through the intermediate nodes for transmission from the source NE to the sink NE. The difference is that the SNCP protection and SNCP services can be created on the U2000 at a time. Figure 3-13 shows an SNCP ring that comprises four pieces of MSTP equipment. In this example, the SP3D boards are configured on the source NE (NE1) and the sink NE (NE3) as tributary boards to add and drop services, and the SL1D boards are used as line boards to transmit SDH services. Figure 3-13 Networking diagram of the services on the SNCP ring NE1: Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
3-SP3D 1-SL1D-1
1-SL1D-2
NE1
1-SL1D-2
1-SL1D-1
SNCP ring
NE2
NE4
1-SL1D-1
NE2: Line board Line board 1-SL1D-2
1-SL1D-2
NE3
NE4: Line board Line board
1-SL1D-1
1-SL1D-2 NE3:
1-SL1D-1
1-SL1D-1
1-SL1D-2
3-SP3D
Tributary board Line board Line board 3-SP3D
1-SL1D-1
1-SL1D-2
3.8.2 Signal Flow and Timeslot Allocation Similar to the service configuration of an MSP ring, you need to plan proper traffic directions before configuring the services on an SNCP ring, if multiple service routes are available from the source end to the sink end. In the case of the services on the SNCP ring, allocate timeslots for the source slot of the working service and timeslots for the source slot of the protection service, when allocating timeslots for source slots. Figure 3-14 shows the signal flow of the services on the SNCP ring and the timeslot allocation to the services on the SNCP ring. In the actual configuration, you can plan other proper working paths and protection paths according to the requirement. In this example, the working service route is NE1-NE2-NE3 and the protection service route is NE1-NE4-NE3. There are five E1 services.
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Figure 3-14 Signal flow and timeslot allocation NE1: SNCP protection group Group 1
5xE1 services are added/dropped VC4-1:1-5(VC12)
Service source 1-SL1D-1
Protection service source 1-SL1D-2
Service sink 3-SP3D
SDH service
Service source
Service sink
VC12
1-SL1D-2
VC4-1:1-5(VC12)
1-SL1D-1
1-SL1D-2 NE2 and NE4: NE1
1-SL1D-2
1-SL1D-1
VC4-1:1-5(VC12) Pass-through service
1-SL1D-1
NE2
SNCP ring
NE4
VC4-1:1-5(VC12)
线路 板
1-SL1D-1
Pass-through service 1-SL1D-2
NE3
1-SL1D-2 VC4-1:1-5(VC12)
Traffic direction of the working path Traffic direction of the protection path
1-SL1D-1 VC4-1:1-5(VC12) 5xE1 services are added/dropped
Line board Tributary board
NE3: SNCP protection group Group 1
Service source 1-SL1D-2
Protection service source 1-SL1D-1
Service sink 3-SP3D
3.8.3 Per-NE Configuration Process The SNCP protection and the services on the SNCP ring are configured on the U2000 at a time. To configure the SNCP services on the source and sink NEs, you need to determine the source boards and timeslots for the working service and protection service. In addition, you need to configure the pass-through service on the intermediate nodes.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
You must be familiar with 3.8.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure the SDH services of the source NE (NE1).
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1.
In the NE Explorer, select NE1, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create SNCP Service on the lower-right pane to display the Create SNCP Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Service Type
SNCP
In this example, Service Type adopts the default value, namely, SNCP.
Level
VC12
In this example, E1 services are configured on the ring. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectio nal
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the services is set to Bidirectional.
Revertive Mode
Revertive
This parameter indicates whether the services are switched back after the faulty line is recovered, that is, whether the switching is revertive or non-revertive. In this example, Revertive Mode is set to Revertive.
Hold-Off Time (100ms)
0
It is recommended that this parameter adopts the default value.
WTR Time (s)
600
After the working path is recovered to normal and the normal state lasts for 600s, the switching restoration occurs. This parameter is valid only when the Revertive Mode parameter is set to Revertive.
Working Service
Source Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the source line board of the working service. See Figure 3-14. You can select different source boards depending on the actual situation.
Source VC4
VC4-1
In this example, the working service source uses the timeslots of VC4-1.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range of the Working Service is set to 1-5. See Figure 3-14.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 is configured as the sink tributary board. See Figure 3-14. You can select different sink boards depending on the actual situation.
Sink VC4
-
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Parameter
Protection Service
Value in This Example
Description
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range of the Working Service is set to 1-5. See Figure 3-14
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source board of the protection service. See Figure 3-14. You can select different source boards depending on the actual situation.
Source VC4
VC4-1
In this example, the protection service source uses the timeslots of VC4-1.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range of the Protection Service is set to 1-5. See Figure 3-14.
Step 2 Configure the SDH services of the sink NE (NE3). Refer to Step 1 and configure the SDH services of NE3. The method and parameters for configuring the SDH services of NE3 are the same as the method and parameters for configuring the SDH services of NE1. Step 3 Configure the pass-through services of NE2.
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1.
In the NE Explorer, select NE2 and then choose Communication > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured on the ring. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received on the same path. That is, the services are bidirectional services. Hence, Direction of the E1 services is set to Bidirectional.
Source Slot
1-SL1D-2 (SDH-2)
In this example, the SL1D board in slot 1 is configured as the source line board. See Figure 3-14. You can select different source boards depending on the actual situation.
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Parameter
Value in This Example
Description
Source VC4
VC4-1
In this example, the services require five VC-12s. Source VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Source Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-14.
Sink Slot
1-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 1 is configured as the sink line board. See Figure 3-14. You can select different sink boards depending on the actual situation.
Sink VC4
VC4-1
In this example, the services require five VC-12s. Sink VC4 is set to VC4-1, because a VC-4 contains 63 VC-12s.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, the total capacity of the services is 5xE1 according to the plan. The service level is VC12. Hence, Sink Timeslot Range(e.g.1,3-6) is set to 1-5. See Figure 3-14.
Activate Immediately
Yes
-
Step 4 Configure the pass-through services of NE4. Refer to Step 3 and configure the pass-through services of NE4. The method and parameters for configuring the pass-through services of NE4 are the same as the method and parameters for configuring the pass-through services of NE2. Step 5 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 6 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 7 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.8.4 End-to-End Configuration Process SNCP protection and services on an SNCP ring are configured on the U2000 at the same time. To configure SNCP services on the source and sink NEs, determine the source boards and timeslots for the working service and protection service, and configure pass-through services on the intermediate nodes. The following part describes how to configure services on an SNCP ring in an end-to-end manner. Issue 02 (2011-06-30)
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Prerequisite l
The physical network topology must be set up.
l
NEs, boards, and fibers must be successfully created on the U2000.
l
The operator must understand the information provided in 3.8.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Choose Service > SDH Trail > Create SDH Trail from the Main Menu. Step 2 Create a VC4 server trail. 1.
Set associated parameters as follows. Set Level to VC4 Server Trail, and take default values for other parameters.
2.
Double-click the source NE (NE1) and sink NE (NE3) on the right of the Main Topology, and set up a VC4 server trail from NE1 to NE3 via NE2. a.
On the Route Constraint tab, right-click Explicit Node, and then choose Add.
b.
In the Add Explicit Node dialog box that is displayed, set Type and What for configuring the pass-through node NE2.
c.
Click OK. The VC4 server trail is sure to stretch from NE1 to NE3 via NE2
3.
Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded.
4.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 server trail.
Step 3 Set up a protection VC4 server trail using the same method as setting up a VC4 server trail. During the setup of a protection VC4 server trail, ensure that the originated node is NE1, the terminated node is NE3, and the pass-through node is NE4. Step 4 Create VC12 services.
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1.
In Create SDH Trail, set associated parameters as follows. Set Level to VC12, and take default values for other parameters.
2.
Double-click the source NE (NE1) on the right of the Main Topology. The Select Board Port-Source dialog box is displayed. Select the required SP3D board and Tributary Port, and then click OK. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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3.
Double-click the sink NE (NE3) on the right of the Main Topology, and use the same method to Tributary Port of NE3.
4.
In Create SDH Trail, click the SNCP Setting tab, right-click in the blank pane, and choose Add from the shortcut menu. In the Add the dual-fed and selective receiving node dialog box that is displayed, select NE1 as the dual-fed node and NE3 as the selective receiving node, and then click OK. In the Operation Result dialog box indicating that the operation succeeded, click Close.
5.
Optional: In the Create SDH Trail window, select Set Route Timeslot. In the dialog box that is displayed, you can modify the working server trail of VC12 services.
6.
Select Copy after Creation and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close. Then, the Copy dialog box is displayed.
7.
In Available Timeslots/Port, select the ports from NE1-Slot3-SP3D-2(SDH_TU-2) to NE3-Slot3-SP3D-5(SDH_TU-5), and click Add.
8.
Click OK. In the Operation Result dialog box indicating that the operation succeeded, click Close.
9.
Optional: In the Operation Result dialog box indicating that the operation succeeded, you can also click Browse Trail to query the created VC12 services.
Step 5 Optional: After configuring SNCP services in an end-to-end manner, you can browse the created VC4 server trails and VC12 services by choosing Service > SDH Trail > Manage SDH Trail from the Main Menu and specifying the filter conditions. Step 6 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 7 Enable the performance monitoring function for NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 8 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task To delete any service that is incorrectly configured, see Deleting SDH Services.
3.9 Configuring Services on the SNCP Ring with a NonProtection Chain To configure the services on the SNCP ring, you can directly configure the working service and protection service, without first configuring the protection subnet. To configure the services on the non-protection chain, you can configure the services only after the protection subnet is created. 3.9.1 Networking Diagram Issue 02 (2011-06-30)
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The networking of the SNCP ring in the case of configuring the services on the SNCP ring with a non-protection chain is similar to the networking in the case of configuring the services on the SNCP ring. The services from the SNCP ring to the non-protection chain pass through the intersecting node and are added to or dropped from the NE on the non-protection chain. 3.9.2 Signal Flow and Timeslot Allocation To configure services on the SNCP ring with a non-protection chain, you need to plan proper traffic directions for the services on the SNCP ring and the services on the non-protection chain. In the case of the services on the SNCP ring, allocate timeslots for the source slot of the working service and timeslots for the source slot of the protection service, when allocating timeslots for source slots. 3.9.3 Per-NE Configuration Process Before you configure the services on the SNCP ring with a non-protection chain, familiarize yourself with the information about the source slot, sink slot, and their corresponding timeslots of the working service and protection service on the source and sink NEs on the SNCP ring. You need to configure the pass-through services on the intersecting NE. 3.9.4 End-to-End Configuration Process Before configuring services on an SNCP ring with a non-protection chain, familiarize yourself with the information about the source slot, sink slot, and their corresponding timeslots of the working service and protection service on the source and sink NEs on the SNCP ring. You also need to configure pass-through services on the intersecting NE. The following part describes how to configure services on an SNCP ring with a non-protection chain in an end-to-end manner.
3.9.1 Networking Diagram The networking of the SNCP ring in the case of configuring the services on the SNCP ring with a non-protection chain is similar to the networking in the case of configuring the services on the SNCP ring. The services from the SNCP ring to the non-protection chain pass through the intersecting node and are added to or dropped from the NE on the non-protection chain. Figure 3-15 shows the networking diagram of the SNCP ring with a non-protection chain. The SNCP ring comprises five pieces of equipment. In this example, 5xE1 services are configured between NE3 and NE5. The SP3D boards are configured on the source NE (NE3) and the sink NE (NE5) as tributary boards to add and drop services. The SL4D and SL1D boards are used as the line boards for transmitting SDH services.
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Figure 3-15 Networking diagram of the services on the SNCP ring with a non-protection chain NE1: Line board Line board 1-SL4D-1
1-SL4D-2
1-SL4D-1
1-SL4D-2
NE5: Tributary board Line board 3-SP3D
NE1
1-SL4D-2
1-SL4D-1 2-SL1D-1
1-SL4D-1
1-SL4D-2
1-SL4D-2
NE3
NE2: Line board Line board
3-SP3D
2-SL1D-1
NE4
SNCP ring
NE2
2-SL1D-1
Non-protection chain
NE5
NE4: Line board Line board Line board
1-SL4D-1
1-SL4D-2 NE3:
1-SL4D-1
1-SL4D-1
1-SL4D-2 2-SL1D-1
3-SP3D
Tributary board Line board Line board 3-SP3D
1-SL4D-1
1-SL4D-2
3.9.2 Signal Flow and Timeslot Allocation To configure services on the SNCP ring with a non-protection chain, you need to plan proper traffic directions for the services on the SNCP ring and the services on the non-protection chain. In the case of the services on the SNCP ring, allocate timeslots for the source slot of the working service and timeslots for the source slot of the protection service, when allocating timeslots for source slots. Figure 3-16 shows the signal flow of the services on the SNCP ring with a non-protection chain and the timeslot allocation to the services on the SNCP ring with a non-protection chain . In this example, five E1 services are configured between NE3 and NE5. In this example, the traffic direction of the services on the SNCP ring, is configured as follows: l
Traffic direction of the working service between NE3 and NE4: NE3-NE4
l
Traffic direction of the protection service between NE3 and NE4: NE3-NE2-NE1-NE4
In the actual configuration, you can plan other proper working paths and protection paths according to the requirement.
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Figure 3-16 Signal flow and timeslot allocation NE1:VC4-1:1-5(VC12) Service pass through Service source
SDH service VC12 1-SL4D-1
1-SL4D-2
1-SL4D-2
VC12
Service source
SNCP protection group
1-SL4D-2
NE1
Service sink 1-SL4D-1
Group 1
SNCP ring
VC4-1:1-5(VC12) NE5: SDH service
NE3
1-SL4D-2
Line board
2-SL1D-1
3-SP3D
VC12
NE5 Service source
Service sink
2-SL1D-1
3-SP3D
1-SL4D-1
VC4-1:1-5(VC12) Traffic direction of the working path Traffic direction of the protection path Traffic direction of services on the non-protection chain
Service sink
5×E1 Non-protection chain
1-SL4D-2
1-SL4D-1
1-SL4D-2
Protection service source 1-SL4D-1
2-SL1D-1 2-SL1D-1
线路 线路 板 板
NE 4
Service source
VC4-1:1-5(VC12)
1-SL4D-1
1-SL4D-2 NE2
1-SL4D-1
NE4:
NE2: VC4-1:1-5(VC12) Service pass through SDH service
Service sink
VC4-1:1-5(VC12) 3NE3: SP3D 5×E1
Tributary board
SNCP protection group Group 1
Service source 1-SL4D-1
Protection service source 1-SL4D-2
Service sink 3-SP3D
3.9.3 Per-NE Configuration Process Before you configure the services on the SNCP ring with a non-protection chain, familiarize yourself with the information about the source slot, sink slot, and their corresponding timeslots of the working service and protection service on the source and sink NEs on the SNCP ring. You need to configure the pass-through services on the intersecting NE.
Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see 2.6.1 Configuring a Non-Protection Chain.
l
You must be familiar with 3.9.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure the SDH services of the source NE (NE3).
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1.
In the NE Explorer, select NE3, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create SNCP Service on the lower-right pane to display the Create SNCP Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Service Type
SNCP
In this example, Service Type is set to SNCP.
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Revertive Mode
Revertive
When an NE is in the switching state, the NE is restored from the switching state to the normal state some time after the working path is recovered to normal.
Direction
Bidirection al
In this example, the cross-connections are configured in the SNCP receive direction and in the SNCP transmit direction.
Hold-Off Time (100ms)
0
It is recommended that this parameter adopts the default value.
WTR Time (s)
600
After the working path is recovered to normal and the normal state lasts for 600s, the switching restoration occurs. This parameter is valid only when the Revertive Mode parameter is set to Revertive.
Wor king Ser vice
Source Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 of NE3 is configured as the source line board of the working service. See Figure 3-16.
Source VC4
VC4-1
In this example, the working service source uses the timeslots of VC4-1.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service source occupies VC-12s 1-5.
Sink Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE3 is configured as the sink line board of the working service. See Figure 3-16.
Sink VC4
-
-
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service source occupies VC-12s 1-5.
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 of NE3 is configured as the source line board of the protection service. See Figure 3-16.
Source VC4
VC4-1
In this example, the protection service source uses the timeslots of VC4-1.
Prot ecti on Ser vice
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Parameter
Source Timeslot Range(e.g. 1,3-6)
Value in This Example
Description
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the protection service source occupies VC-12s 1-5.
Step 2 Configure the SDH services of the sink NE (NE4).
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, and then select NE4. Click OK.
1.
In the NE Explorer, click
2.
Choose Configuration > SDH Service Configuration from the Function Tree.
3.
Click Create SNCP Service on the lower-right pane to display the Create SNCP Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Service Type
SNCP
In this example, Service Type is set to SNCP.
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Revertive Mode
Revertive
When an NE is in the switching state, the NE is restored from the switching state to the normal state some time after the working path is recovered to normal.
Direction
Bidirection al
In this example, the cross-connections are configured in the SNCP receive direction and in the SNCP transmit direction.
Hold-Off Time (100ms)
0
It is recommended that this parameter adopts the default value.
WTR Time (s)
600
After the working path is recovered to normal and the normal state lasts for 600s, the switching restoration occurs. This parameter is valid only when the Revertive Mode parameter is set to Revertive.
Wor king Ser vice
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 of NE4 is configured as the source line board of the working service. See Figure 3-16.
Source VC4
VC4-1
In this example, the working service source uses the timeslots of VC4-1.
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Parameter
Prot ecti on Ser vice
3 Configuring SDH Services
Value in This Example
Description
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service source occupies VC-12s 1-5.
Sink Slot
2-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 2 of NE4 is configured as the sink line board of the working service. See Figure 3-16.
Sink VC4
VC4-1
In this example, the working service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service sink occupies VC-12s 1-5.
Source Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 of NE3 is configured as the source line board of the protection service. See Figure 3-16.
Source VC4
VC4-1
In this example, the protection service source uses the timeslots of VC4-1.
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the protection service source occupies VC-12s 1-5.
Step 3 Configure the pass-through services of NE2. 1.
In the NE Explorer, click
2.
Choose Configuration > SDH Service Configuration from the Function Tree.
3.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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, and then select NE2. Click OK.
Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, Direction of the service is set to Bidirectional.
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 of NE2 is configured as the source line board. See Figure 3-16.
Source VC4
VC4-1
In this example, the working service source uses the timeslots of VC4-1.
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Parameter
Value in This Example
Description
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service source occupies VC-12s 1-5.
Sink Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 of NE2 is configured as the sink line board. See Figure 3-16.
Sink VC4
VC4-1
In this example, the service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 4 Configure the pass-through services of NE1. Refer to Step 3 and configure the SDH services of NE1. The method and parameters for configuring the pass-through services of NE1 are the same as the method and parameters for configuring the pass-through services of NE2. Step 5 Configure the services on the non-protection chain at NE5.
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, and then select NE5. Click OK.
1.
In the NE Explorer, click
2.
Choose Configuration > SDH Service Configuration from the Function Tree.
3.
Click Create on the lower-right pane to display the Create SDHP Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, Direction of the E1 services is set to Bidirectional.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE5 is configured as the source tributary board. See Figure 3-16.
Source VC4
-
-
Source Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the working service source occupies VC-12s 1-5.
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Parameter
Value in This Example
Description
Sink Slot
2-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 2 of NE5 is configured as the sink line board. See Figure 3-16.
Sink VC4
VC4-1
In this example, the service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 6 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 7 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 8 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.9.4 End-to-End Configuration Process Before configuring services on an SNCP ring with a non-protection chain, familiarize yourself with the information about the source slot, sink slot, and their corresponding timeslots of the working service and protection service on the source and sink NEs on the SNCP ring. You also need to configure pass-through services on the intersecting NE. The following part describes how to configure services on an SNCP ring with a non-protection chain in an end-to-end manner.
Prerequisite l
The physical network topology must be set up.
l
NEs, boards, and fibers must be successfully created on the U2000.
l
A protection subnet must be created and must be the same as the actual topology. For details about how to create a protection subnet, see 2.6.1 Configuring a Non-Protection Chain.
l
The operator must understand the information provided in 3.9.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Create a working VC-4 server trail. Issue 02 (2011-06-30)
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1.
Choose Service > SDH Trail > Create SDH Trail from the Main Menu.
2.
Set associated parameters as follows. Set Level to VC4 Server Trail, and take default values for other parameters.
3.
Double-click NE3 and NE4 on the right of the Main Topology, select the trail from NE3 to NE4 as the working, VC-4 server trail, and click Close. In the Operation Result dialog box indicating that the operation succeeded, click Close.
4.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 server trail.
Step 2 Create a protection VC-4 server trail, using the method described in Step 1. NOTE
When creating a protection VC-4 server trail, double-click NE3 and NE4 on the right of the Main Topology, and ensure that the traffic direction is NE3-NE2-NE1-NE4. On the Route Constraint tab, click the Explicit Node tab, right-click in the blank area, and then choose Add from the shortcut menu. In the Add Explicit Node dialog box that is displayed, set Type and What for configuring the pass-through node NE2, and then click OK.
Step 3 Create a VC-4 server trail without a protection chain. 1.
In Create SDH Tail, configure the parameters as follows. Set Level to VC4 Server Trail, and take default values for other parameters.
2.
Double-click NE4 and NE5 on the right of the Main Topology, and click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded.
3.
Optional: In the Operation Result dialog box indicating that the operation succeeded, click Browse Trail to query the created VC4 server trail.
Step 4 Create VC12 services after setting up a VC-4 server trail. 1.
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In Create SDH Tail, configure associated parameters as follows. Set Level to VC12, and take default values for other parameters.
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2.
Double-click the NE3 on the right of the Main Topology. The Select Board PortSource dialog box is displayed. Select the SP3D board to be configured and choose 1 on Tributary Port, and then click OK.
3.
Configure NE5 using the method described in Step 4.2.
4.
In Create SDH Trail, click the SNCP Setting tab, right-click in the blank area, and choose Add from the shortcut menu. In the Add the dual-fed and selective-receiving node dialog box that is displayed, select NE3 as the dual-fed node and NE4 as the selective receiving node, and then click OK. In the Operation Result dialog box indicating that the operation succeeded, click Close.
5.
Select Copy after Creation and click Apply. In the Operation Result dialog box indicating that the operation succeeded, click Close. Then, the Copy dialog box is displayed.
6.
In Available Timeslots/Port, select the ports from NE3-Slot5-SP3D-2(SDH_TU-2) to NE5-Slot5-SP3D-5(SDH_TU-5), and click Add.
7.
In the Operation Result dialog box indicating that the operation succeeded, click Close.
8.
Optional: In the Operation Result dialog box indicating that the operation succeeded, you can also click Browse Trail to query the created VC12 services.
Step 5 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Step 6 Enable the performance monitoring function for NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 7 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task To delete any service that is incorrectly configured, see Deleting SDH Services.
3.10 Configuring Service on the MSP Ring with a NonProtection Chain Configure the protection subnet for the MSP, Protection Subnet for the non-protection chain, and services on the MSP ring with a non-protection chain separately. It is recommended that you configure the protection subnets before configuring the services on the MSP ring with a non-protection ring chain. 3.10.1 Networking Diagram In the case of the MSP ring with a non-protection chain, the networking diagram of the MSP ring is similar to the networking diagram of the single two-fiber bidirectional MSP ring. The only difference is that one line board needs to be configured on the intersecting NE when the non-protection chain is added. This can realize the pass-through of the services when the services are required to be transmitted out of the MSP ring. 3.10.2 Signal Flow and Timeslot Allocation To configure the service on the MSP ring with a non-protection chain, you should plan a proper traffic direction and a timeslot allocation scheme for the services on the SNCP ring and the services on the non-protection chain. Issue 02 (2011-06-30)
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3.10.3 Per-NE Configuration Process The configuration of the services on the two-fiber bidirectional MSP ring with a non-protection chain is independent of the creation of the protection subnets for the MSP and for the nonprotection chain. To configure the services on the two-fiber bidirectional MSP ring with a nonprotection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs, if the protection subnet is already created. 3.10.4 End-to-End Configuration Process The configuration of services on a two-fiber bidirectional MSP ring with a non-protection chain is independent of the creation of protection subnets for the MSP and for the non-protection chain. To configure services on a two-fiber bidirectional MSP ring with a non-protection chain, configure SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs, if the protection subnet has already been created. The following part describes how to configure services on an MSP ring with a non-protection chain in an end-to-end manner.
3.10.1 Networking Diagram In the case of the MSP ring with a non-protection chain, the networking diagram of the MSP ring is similar to the networking diagram of the single two-fiber bidirectional MSP ring. The only difference is that one line board needs to be configured on the intersecting NE when the non-protection chain is added. This can realize the pass-through of the services when the services are required to be transmitted out of the MSP ring. Figure 3-17 shows the networking diagram of the MSP ring with a non-protection chain. The MSP ring comprises five pieces of equipment. In this example, the SP3D boards are configured on the source NE (NE3) and sink NE (NE5) as tributary boards to add and drop services, and the SL4D and SL1D boards are used as line boards to transmit SDH services. Figure 3-17 Networking diagram of the services on the two-fiber bidirectional MSP ring with a non-protection chain NE1: Line board Line board 1-SL4D-1
1-SL4D-2
1-SL4D-1
1-SL4D-2
NE5: Tributary board Line board 3-SP3D
NE1
1-SL4D-2 NE2
Two-fiber bidirectional MSP ring
1-SL4D-1 2-SL1D-1
1-SL4D-2
2-SL1D-1
NE4
1-SL4D-1 NE2: Line board Line board
2-SL1D-1
1-SL4D-2
NE3
Non-protection chain
NE5
NE4:
1-SL4D-1
Line board Line board Line board
1-SL4D-2
1-SL4D-1
1-SL4D-1
1-SL4D-2
2-SL1D-1
NE3: Tributary board Line board Line board 3-SP3D
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1-SL4D-2
1-SL4D-1
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3.10.2 Signal Flow and Timeslot Allocation To configure the service on the MSP ring with a non-protection chain, you should plan a proper traffic direction and a timeslot allocation scheme for the services on the SNCP ring and the services on the non-protection chain. Figure 3-18 shows the signal flow of the services on the MSP ring with a non-protection chain and the timeslot allocation to the services on the MSP ring with a non-protection chain. In this example, five E1 services are added to or dropped from NE3 and NE5, and these services pass through NE4. On the MSP ring, the services from NE3 to NE4 in this example are transmitted on the short path. In the actual configuration, you can plan other service paths according to the requirement. NOTE
On a ring network, the long path and short path do not actually refer to the geographical distance. They are determined by the number of intermediate NEs. As shown in Figure 3-18, when the service is transmitted from NE3 to NE4, NE3→NE4 is the short path, and NE3→NE2→NE1→NE4 is the long path.
Figure 3-18 Signal flow and timeslot allocation 1-SL4D-1
1-SL4D-2
NE4: NE1
Line board 1-SL4D-1
1-SL4D-2
Line board 1-SL4D-2
Line board 2-SL1D-1
1-SL4D-1 2-SL1D-1 2-SL1D-1
NE2
MSP ring
NE4
5×E1 Non-protection chain
1-SL4D-2
1-SL4D-1
3-SP3D
线路板
VC4-1:1-5(VC12)
NE5 Line board Tributary board 2-SL1D-1 3-SP3D
NE3
1-SL4D-2
1-SL4D-1 VC4-1:1-5(VC12)
Line board Tributary board
5×E1
Traffic direction of the MSP ring
NE3: Line board Tributary board 3-SP3D 1-SL4D-1
Traffic direction of the non-protection chain
3.10.3 Per-NE Configuration Process The configuration of the services on the two-fiber bidirectional MSP ring with a non-protection chain is independent of the creation of the protection subnets for the MSP and for the nonprotection chain. To configure the services on the two-fiber bidirectional MSP ring with a nonprotection chain, configure the SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs, if the protection subnet is already created.
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Prerequisite l
The physical topology of the network must be created.
l
The NEs, boards, and fibers must be created on the U2000.
l
The created protection subnet must be consistent with the actual network topology. For details about how to create the protection subnet, see2.6.1 Configuring a Non-Protection Chain and 2.6.3 Creating an MS Ring Protection Subnet.
l
You must be familiar with 3.10.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Configure the SDH services of the source NE (NE3). 1.
In the NE Explorer, select NE3, and then choose Configuration > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SNCP Service dialog box. Set the parameters that are required, and then click OK. Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received on the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE3 is configured as the source tributary board. See Figure 3-18.
Source VC4
-
-
Source Timeslot Range (e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service source occupies VC-12s 1-5.
Sink Slot
1-SL4D-1 (SDH-1)
In this example, the SL4D board in slot 1 of NE3 is configured as the sink line board. See Figure 3-18.
Sink VC4
VC4-1
In this example, the service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 2 Refer to Step 1 and configure the SDH services of NE5. Set the parameters as follows. 3-64
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectional
In this example, the services are transmitted and received on the same path. That is, the services are Bidirectional services.
Source Slot
3-SP3D
In this example, the SP3D board in slot 3 of NE5 is configured as the source tributary board. See Figure 3-18.
Source VC4
-
-
Source Timeslot Range(e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service source occupies VC-12s 1-5.
Sink Slot
2-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 2 of NE5 is configured as the sink line board. See Figure 3-18.
Sink VC4
VC4-1
In this example, the service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 3 Configure the pass-through services of NE4. 1.
In the NE Explorer, select NE4 and then choose Communication > SDH Service Configuration from the Function Tree.
2.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters that are required, and then click OK.
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Parameter
Value in This Example
Description
Level
VC12
In this example, E1 services are configured. Hence, Level of the E1 services is set to VC12.
Direction
Bidirectiona l
In this example, the services are transmitted and received on the same path. That is, the services are Bidirectional services.
Source Slot
1-SL4D-2 (SDH-2)
In this example, the SL4D board in slot 1 of NE4 is configured as the source line board. See Figure 3-18.
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Parameter
Value in This Example
Description
Source VC4
VC4-1
In this example, the service source uses the timeslots of VC4-1.
Source Timeslot Range (e.g.1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Sink Slot
2-SL1D-1 (SDH-1)
In this example, the SL1D board in slot 2 of NE5 is configured as the sink line board. See Figure 3-18.
Sink VC4
VC4-1
In this example, the service sink uses the timeslots of VC4-1.
Sink Timeslot Range(e.g. 1,3-6)
1-5
In this example, five E1 services are configured between NE3 and NE5. Hence, the service sink occupies VC-12s 1-5.
Activate Immediately
Yes
-
Step 4 Check whether the services are configured correctly. For details, see Verifying the Correctness of the SDH Service Configuration. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
3.10.4 End-to-End Configuration Process The configuration of services on a two-fiber bidirectional MSP ring with a non-protection chain is independent of the creation of protection subnets for the MSP and for the non-protection chain. To configure services on a two-fiber bidirectional MSP ring with a non-protection chain, configure SDH services from the tributary board to the line board on the source and sink NEs and configure pass-through services on the intermediate NEs, if the protection subnet has already been created. The following part describes how to configure services on an MSP ring with a non-protection chain in an end-to-end manner.
Prerequisite
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l
The physical network topology must be set up.
l
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l
A protection subnet must be created and must be the same as the actual topology. For details about how to create a protection subnet, see 2.6.1 Configuring a Non-Protection Chain and 2.6.4 Creating a Linear MS Protection Subnet.
l
The operator must understand the information provided in 3.10.2 Signal Flow and Timeslot Allocation.
Procedure Step 1 Create a VC-4 server trail. 1.
Choose Service > SDH Trail > Create SDH Trail from the Main Menu.
2.
Set associated parameters as follows. Set Level to VC4 Server Trail, and take default values for other parameters.
3.
Double-click NE3 and NE5 on the right of the Main Topology, and click Apply. Then, click Close in the Operation Result dialog box that is displayed.
4.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC4 server trail.
Step 2 Create VC12 services. 1.
In Create SDH Tail, configure associated parameters as follows. Set Level to VC12, and take default values for other parameters.
2.
Double-click the NE3 on the right of the Main Topology. The Select Board PortSource dialog box is displayed. Select the required PDH board and Tributary Port, and then click OK.
3.
Configure NE5 using the method described in Step 2.2.
4.
Select Copy after Creation and click Apply. In the Operation Result dialog box that is displayed, click Close. Then, the Copy dialog box is displayed.
5.
In Available Timeslots/Port, select the timeslots or ports to be duplicated, and click Add.
6.
In the Operation Result dialog box that is displayed, click Close.
7.
Optional: In the Operation Result dialog box that is displayed, you can also click Browse Trail to query the created VC12 services.
Step 3 Check whether the service configuration is correct. For details, see Verifying the Correctness of the SDH Service Configuration. Issue 02 (2011-06-30)
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Step 4 Enable the performance monitoring function for NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task To delete any service that is incorrectly configured, see Deleting SDH Services.
3.11 Protection Configuration Parameters You need to set the necessary parameters when configuring the protection such as MSP, SNCP for an NE. 3.11.1 SNCP Configuration You need to set the necessary parameters when configuring the SNCP for an NE. 3.11.2 Configuring the Multiplex Section Protection You need to set the necessary parameters when configuring the multiplex section protection (MSP).
3.11.1 SNCP Configuration You need to set the necessary parameters when configuring the SNCP for an NE. Table 3-1 lists the parameters for configuring the SNCP. Table 3-1 Parameters for configuring the SNCP Field
Value
Description
Service Type
SNCP
Specifies the type of the new SNCP service.
Revertive Mode
Non-Revertive, Revertive
Specifies whether the services can be switched from the protection channel to the working channel after the working channel is restored. If you set this field to Revertive, the services can be switched from the protection channel to the working channel. If you set this parameter to Non-Revertive, the services cannot be switched from the protection channel to the working channel.
Default: Non-revertive
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Field
Value
Description
WTR Time (s)
Example: 600
Specifies the wait-to-restore (WTR) time of the NE. When the time after the former working channel is restored to normal reaches the set WTR time, a revertive switching occurs. This field is available only when Revertive Mode is set to Revertive.
Hold-Off Time (100 ms)
0 to 100 Default: 0
Specifies the hold-off time of the NE. If Hold-Off Time (100 ms) is set to 0, you do not need to set a specific hold-off time.
Source Board
Example: 1-SL1D-1 (SDH-1)
Displays the slot ID, board name, port number, and port name at the source end.
Sink Board
Example: 3-SP3D
Displays the slot ID, board name, port number, and port name at the sink end.
Source VC4
Example: VC4-1
Specifies the VC-4 timeslot at the source end. One VC-4 timeslot can contain a maximum of 63 VC-12 timeslots.
Sink VC4
-
Specifies the VC-4 timeslot at the sink end.
Source Timeslot Range(eg.1, 3-6)
Example: 1-5
Specifies the timeslot range at the source end.
3.11.2 Configuring the Multiplex Section Protection You need to set the necessary parameters when configuring the multiplex section protection (MSP). Table 3-2 lists the parameters for configuring the MSP.
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Table 3-2 Parameters for configuring the MSP Field
Value
Description
Name
For Example: two-fiber bidirectional multiplex section shared protection ring_1
Indicates the name of the protection subnetwork. Th name of a new protection subnetwork is automatically generated. You can rename the protection subnetwork according to the requirements.
Level
If Assigned by VC4 is not selected, the values are STM-1, STM-4, STM-16, STM-64, and STM-256.
Indicates the new capacity level of a protection subnetwork. The new capacity level of a protection subnetwork must be the same as the transmission rate of the line boards that form the protection subnetwork.
If Assigned by VC4 is selected, the values are STM-2, STM-4, STM-6, ..., STM-254, and STM-256. NOTE l The OptiX OSN 550 supports only STM-1, STM-4 and STM-16 levels.
CAUTION When selecting an incorrect capacity level, you fail to create a protection subnetwork.
l For LMSP, Assigned by VC4 is not supported.
Resource Sharing
-
Resource sharing indicates that two protection subnetworks can share one physical resource. If multiple protection subnetworks are created on a fiber, the second and later protection subnetworks share the resources on the fiber. NOTE The OptiX OSN 550 does not support this parameter.
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Field
Value
Description
Assigned by VC4
Selected, Deselected
Indicates that different VC-4s correspond to different protection subnetworks. You can group VC-4s in the optical fiber into different protection subnets to protect virtual optical channels. This means that certain VC-4s in the fiber can be allocated to a protection subnetwork. For example, in the case of an STM-16 fiber, the former four VC-4s can be allocated for an STM-4 MSP, and the following four VC-4s can be allocated for channel protection. NOTE For LMSP, Assigned by VC4 is not supported.
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Node
For example: NE70
Displays the selected NE.
Link
For example: NE140-NE141 Ring 1
Displays the fiber link of the protection subnetwork.
Physical Information
For example: 1-SL1Q-1 (SDH-1)-1-SL1Q-2(SDH-1)
Displays the line board resource used by the fiber link.
VC4
For example: 1 to 4
If Assigned by VC4 is selected in Step 1, you can specify the VC-4 resource used by the protection subnetwork in Step 2.
Subnet Name
For example: Two-fiber bidirectional multiplex section shared protection ring_1
Displays the name of the protection subnetwork.
Subnet Type
2f_MS SPRing, 2f_MS DPRing, 1+1 Linear MSP, M:N Linear MSP, Unprotected Ring, Unprotected Chain
Displays the type of the protection subnetwork.
WTR Time (s)
For example: 600
Displays the switching WTR time of the protection subnetwork.
Revertive Mode
Non-Revertive, Revertive
Displays the revertive mode of the protection subnetwork.
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Field
Value
Description
Switching Mode
Single-Ended Switching, Dual-Ended Switching Default: Single-Ended Switching
The Switching Mode parameter specifies the switching mode of the linear MSP. You can click 7.130 Switching Mode (MSP) to display the detailed information.
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4 Configuring Ethernet Services
Configuring Ethernet Services
About This Chapter In compliance with ITU-T G.8011x/Y.1307x, Huawei MSTP equipment supports Ethernet private line (EPL), Ethernet virtual private line (EVPL), Ethernet private local area network (EPLAN), and Ethernet virtual private local area network (EVPLAN) services. 4.1 Service Types In compliance with ITU-T G.8011x/Y.1307x, Huawei MSTP equipment supports Ethernet private line (EPL), Ethernet virtual private line (EVPL), Ethernet private local area network (EPLAN), and Ethernet virtual private local area network (EVPLAN) services. 4.2 Basic Concepts Before you configure Ethernet boards with services, you need to learn the basic concepts including external port, internal port, logical port, and bridge so that you can understand the service configuration process and the signal flow when the boards process the services. 4.3 Flow of Configuring Ethernet Services This topic describes the configuration processes related to Ethernet services. Before you configure Ethernet services according to the flow, you need to complete the basic configurations of the NEs according to the flow of creating a network. 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board EPL services provide the point-to-point Ethernet transparent transmission solution with the bandwidth exclusively occupied. EPL services are applicable when the communication equipment that is used to access the client-side data in the transmission network does not support VLANs or when the VLAN planning must be kept secret to the network operator. 4.5 Configuring EPL Services on an Ethernet Switching Board EPL services provide the point-to-point Ethernet transparent transmission solution with the bandwidth exclusively occupied. EPL services are applicable when the communication equipment that is used to access the client-side data in the transmission network does not support VLANs or when the VLAN planning must be kept secret to the network operator. 4.6 Configuring PORT-Shared EVPL (VLAN) Services The PORT-shared EVPL (VLAN) service is applicable when the services of multiple users received from the same external port on the Ethernet board at a station are transmitted on different VCTRUNKs to another station or to another external port of the station. Issue 02 (2011-06-30)
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4.7 Configuring VCTRUNK-Shared EVPL (VLAN) Services When the data of multiple users without VLAN tags sent to a transmission network is transmitted on the same VCTRUNK, the VCTRUNK-shared EVPL (VLAN) service is used to isolate the data by adding VLAN tags. In this way, the bandwidth is shared on the SDH side. 4.8 Configuring EPLAN Services (IEEE 802.1d Bridge) The EPLAN service (IEEE 802.1d bridge) provides a LAN solution for multipoint-to-multipoint convergence. This service applies where the user-side data communication equipment connected to the transmission network does not support VLANs or where the VLAN planning is kept secret from the network operator. 4.9 Configuring EVPLAN Services (IEEE 802.1q Bridge) The EVPLAN service (IEEE 802.1q bridge) provides an LAN solution for multipoint-tomultipoint convergence. This service applies in cases where user-side data communication equipment connected to the transmission network does not support VLANs or where the VLAN planning is open to the network operator. 4.10 Configuring EVPLAN Services (IEEE 802.1ad Bridge) The QinQ technology provides a cheap and easy solution for Layer 2 virtual private networks (VPNs). The IEEE 802.1ad bridge uses the QinQ technology to provide the VPN solution, thus facilitating the identifying, differentiating and grooming EVPLAN services. 4.11 Ethernet Port Configuration Parameters Before configuring an Ethernet service, you need to configure the corresponding Ethernet ports. 4.12 Ethernet Service Configuration Parameters Ethernet services can be classified into Ethernet private line services and Ethernet private network services. Ethernet private line services include EPL services and EVPL services. Ethernet private network services include EPLAN services and EVPLAN services.
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4.1 Service Types In compliance with ITU-T G.8011x/Y.1307x, Huawei MSTP equipment supports Ethernet private line (EPL), Ethernet virtual private line (EVPL), Ethernet private local area network (EPLAN), and Ethernet virtual private local area network (EVPLAN) services.
EPL Services Two nodes are used to access EPL services and implement transparent transmission of the Ethernet services of the users. The service of one user occupies one VCTRUNK and need not share the bandwidth with the services of the other users. Hence, in the case of EPL services, a bandwidth is exclusively occupied by the service of a user and the services of different users are isolated. In addition, the extra QoS scheme and security scheme are not required. Figure 4-1 EPL services User A1
User A2
NE2
NE 1
User B1
Port1
VCTRUNK1
Port2
VCTRUNK2
Port1 Port2 User B2
The corresponding relations between the PORTs (namely, external ports) and the VCTRUNKs are listed in Table 4-1. Table 4-1 Corresponding relations between the external ports and the VCTRUNKs (EPL services) NE1
NE2
User A1
PORT1←→VCTRUNK1
VCTRUNK1←→PORT1
User A2
User B1
PORT2←→VCTRUNK2
VCTRUNK2←→PORT2
User B2
EVPL Services In the case of EVPL services, services of different users share the bandwidth. Hence, the VLAN/ QinQ scheme needs to be used for differentiating the services of different users. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme. EVPL services are classified into two types, depending on whether the PORT or VCTRUNK is shared. Issue 02 (2011-06-30)
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l
PORT-shared EVPL services
As shown in Figure 4-2, the services of different users are accessed through a PORT at a station, and are then isolated from each other by using the VLAN IDs. Services are transmitted to other PORTs at this station through different VCTRUNKs. Figure 4-2 PORT-shared EVPL services User C2 User C1 VLAN 100
Port1
NE 1
VLAN 200
NE2 VCTRUNK1
Port1
VCTRUNK2
Port2 User C3
The corresponding relations between the PORTs and the VCTRUNKs are provided in Table 4-2. Table 4-2 Corresponding relations between the PORTs and the VCTRUNKs (PORT-shared EVPL services) NE1 User C1
l
NE2 PORT1←→VCTRUNK1
VCTRUNK1←→PORT1
User C2
PORT1←→VCTRUNK2
VCTRUNK2←→PORT2
User C3
VCTRUNK-shared EVPL services Ethernet boards support the convergence and distribution of EVPL services by using the following modes: – VLAN tag-based convergence and distribution of EVPL services – QinQ technology-based convergence and distribution of EVPL services
As shown in Figure 4-3, the services of different users are isolated by using the VLAN/QinQ scheme. Hence, the services of different users can be transmitted in the same VCTRUNK. Figure 4-3 VCTRUNK-shared EVPL services User D1
User D2
NE2
NE 1 Port1
Port1 VCTRUNK1
Port2
User E2
User E1
4-4
Port2
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The corresponding relations between the PORTs and the VCTRUNKs are provided in Table 4-3. Table 4-3 Corresponding relations between the PORTs and the VCTRUNKs (VCTRUNKshared EVPL services) NE1
NE2
User D1
PORT1←→VCTRUNK1
VCTRUNK1←→PORT1
User D2
User E1
PORT2←→VCTRUNK1
VCTRUNK1←→PORT2
User E2
EPLAN Services The EPLAN services can be accessed from a minimum of two nodes. Hence, the services of different users need not share the bandwidth. That is, in the case of EPLAN services, a bandwidth is exclusively occupied by the service of a user and the services of different users are isolated. In addition, the extra QoS scheme and security scheme are not required. The EPLAN services have more than one node. Hence, the nodes need to learn the MAC addresses and forward data according to MAC addresses. Therefore, Layer 2 switching is realized. As shown in Figure 4-4, three branches of user F need to communicate with each other. On NE1, the IEEE 802.1d bridge is established to achieve EPLAN services. The IEEE 802.1d bridge can create the MAC address-based forwarding table, which is periodically updated by using the self-learning function of the system. The accessed data can be forwarded or broadcast within the domain of the IEEE 802.1d bridge according to the destination MAC addresses. Figure 4-4 EPLAN services (IEEE 802.1d bridge)
NE3
U2000
NE2
NE4 NE1
PORT1
PORT1
F2
F3
IEEE 802.1d bridge VCTRUNK2
VCTRUNK1 PORT5
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PORT5
VCTRUNK F1
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EVPLAN Services EVPLAN services of different users need to share the bandwidth. Hence, the VLAN/QinQ scheme needs to be used for differentiating the data of different users. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme. As shown in Figure 4-5, three branches of user G need to communicate with each other. Services of user G need to be isolated from the services of user H. Hence, the IEEE 802.1q bridge needs to be established on NE1 to achieve EVPLAN services. IEEE 802.1q bridge: IEEE 802.1q bridge supports isolation by using one layer of VLAN tags. This bridge checks the contents of the VLAN tags that are in the data frames and performs Layer 2 switching according to the destination MAC addresses and VLAN IDs. Figure 4-5 EVPLAN services (IEEE 802.1q bridge)
NE3
NM
H2
PORT2
NE2
NE4 NE1
PORT1
PORT2
H3 PORT1
G2
G3
H1
PORT6
PORT5
G1
VCTRUNK IEEE 802.1q bridge VLAN 200 VCTRUNK1
VCTRUNK2
IEEE 802.1q bridge VLAN 100 VCTRUNK1
PORT6
VCTRUNK2 PORT5
As shown in Figure 4-6, the VoIP services from user M and the HSI services from user N need to respectively access the VoIP server and the HSI server. In this case, the operator needs to separately groom the VoIP services and HSI services, and isolate the data on the transmission network side. On NE1, the IEEE 802.1ad bridge must be established to support the EVPLAN services. IEEE 802.1ad bridge: The IEEE 802.1ad bridge supports data frames with two layers of VLAN tags. This bridge adopts the outer S-VLAN tags to isolate different VLANs and supports only the mounted ports whose attributes are C-Aware or S-Aware. This bridge supports the following switching modes: l
4-6
This bridge does not check the contents of the VLAN tags that are in the packets and performs Layer 2 switching according to the destination MAC addresses of the packets.
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4 Configuring Ethernet Services
This bridge checks the contents of the VLAN tags that are in the packets and performs Layer 2 switching according to the destination MAC addresses and the S-VLAN IDs of the packets.
Figure 4-6 EVPLAN services (IEEE 802.1ad bridge)
NE3
NM Service C-VLAN 10 VoIP 20 HSI
Service C-VLAN VoIP 10 HSI 20
PORT1
User M
NE2
11 PORT5
IEEE 802.1ad bridge S-VLAN 100 VCTRUNK1
VCTRUNK2
User N
11
NE1
8 VoIP
PORT1
NE4
8
HSI PORT6
VCTRUNK
IEEE 802.1ad bridge S-VLAN 200 VCTRUNK1
PORT5
VCTRUNK2 PORT6
4.2 Basic Concepts Before you configure Ethernet boards with services, you need to learn the basic concepts including external port, internal port, logical port, and bridge so that you can understand the service configuration process and the signal flow when the boards process the services. 4.2.1 Formats of Ethernet Frames To implement the VLAN and QinQ functions, the IEEE 802.1q and IEEE 802.1ad protocols define different formats of the Ethernet frames, which contain different VLAN information. 4.2.2 Internal Ports and External Ports External ports on Ethernet boards are used to access the services on the user side. Internal ports on Ethernet boards are used to encapsulate and map the services to the transmission network for transparent transmission. 4.2.3 Auto-Negotiation The auto-negotiation function allows the network equipment to send information of its supported working mode to the opposite end on the network and to receive the corresponding information that the opposite end may transfer. 4.2.4 Flow Control When the data processing/transferring capability of the equipment fails to handle the flow received at the port, congestion occurs on the line. To reduce the number of discarded packets due to buffer overflowing, proper flow control measures must be taken. Issue 02 (2011-06-30)
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4.2.5 Encapsulation and Mapping Protocol To ensure that Ethernet frames can be transparently transmitted over the optical transmission network, the Ethernet frames need to be encapsulated and mapped into VC containers at the access point. The encapsulation and mapping protocols used by the Ethernet service board include the high-level data link control (HDLC), link access procedure - SDH (LAPS), and generic framing procedure (GFP). 4.2.6 Virtual Concatenation The rate of the Ethernet service does not adapt to the rate of the standard VC container. Hence, if you directly map the Ethernet service data into a standard VC container, there is a great waste of the transmission bandwidth. To solve the problem, use the virtual concatenation technology to concatenate many standard VC containers to a large VC container that adapts to the rate of the Ethernet service. 4.2.7 Tag Attribute When data frames are received on or transmitted from a port on an Ethernet board, the processing mode of the data frames is determined by the tag attributes of the port. 4.2.8 Bridge A bridge is a functional unit that is used to implement the interconnection between two or more LANs.
4.2.1 Formats of Ethernet Frames To implement the VLAN and QinQ functions, the IEEE 802.1q and IEEE 802.1ad protocols define different formats of the Ethernet frames, which contain different VLAN information. To implement the VLAN function, the IEEE 802.1q protocol defines the Ethernet frame format that contains the VLAN information. Compared with the ordinary Ethernet frame, the frame with the format defined by the IEEE 802.1q protocol is added with a four-byte header. To implement VLAN mesting (QinQ), the IEEE 802.1ad protocol defines two VLAN tag types. See Figure 4-7. The VLAN tag types are defined to differentiate the services on the client side and the services on the supplier service side.
4-8
l
The VLAN tag used on the client side is represented as C-VLAN, of which the frame format is the same as the frame format defined by the IEEE 802.1q protocol.
l
The VLAN tag used on the supplier service side is represented as S-VLAN.
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Figure 4-7 Formats of Ethernet frames 802.1q frame format Destination Source MAC Address MAC Address 6 bytes
VLAN
6 bytes
Length/Type
Data
FCS Check Character
2 bytes
Variable length
4 bytes
Length/Type
Data
FCS Check Character
2 bytes
Variable length
4 bytes
4 bytes
Format of the frame with one C-VLAN tag Destination Source MAC Address MAC Address 6 bytes
C-VLAN
6 bytes
4 bytes
Format of the frame with one S-VLAN tag nested with one C-VLAN tag Destination Source MAC MAC Address Address 6 bytes
S-VLAN
6 bytes
C-VLAN
4 bytes
Length/Type
4 bytes
2 bytes
Data
FCS Check Character
Variable length
4 bytes
The length of the data field is variable. maximum length of the data field depends on the maximum frame length that the ports of the equipment support. The four-byte S-VLAN or C-VLAN field is divided into two sub-fields: the tag protocol ID (TPID) and the tag control Information (TCI). Both the TPID and TCI consist of two bytes. See Figure 4-8. Figure 4-8 Positions of the TPID and TCI in the frame structure S-VLAN
Destination Source MAC TPID MAC Address Address 6 bytes
l
TCI
C-VLAN TPID
TCI
Length/Type
6 bytes 2 2 bytes 2 bytes 2 bytes 2bytes
2 bytes
Data Variable length
FCS Check Character 4 bytes
TPID structure
The TPID consists of two bytes and indicates the VLAN tag type. TPID of the C-VLAN is always 0x8100 whereas the TPID of the S-VLAN can be customized. Refer to Table 4-4. Table 4-4 Tag types defined by using the TPID
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Tag Type
Name
Value
C-VLAN Tag
802.1q Tag Protocol Type
0x8100
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Tag Type
Name
Value
S-VLAN Tag
802.1q Service Tag Type
Customizable
NOTE
The IEEE 802.1ad specifies the TPID of the S-VLAN to 0x88a8. In actual application, the setting of TPID for the S-VLAN tag varies according to the equipment manufacturer. To ensure compatibility between interconnected equipment, it is recommended that you set the TPIDs of the S-VLAN tags of the interconnected equipment to the same value within 0X600-FFFF.
l
TCI structure
The TCI structure of the S-TAG is basically the same as the TCI structure of the C-TAG. VLAN ID (VID) field consists of 12 bits and ranges from 0 to 4095. The difference is that the TCI of the S-TAG contains the drop eligible (DE) indication and works with the priority code point (PCP) to indicate the priority of the S-TAG frame. The TCI structures of the C-TAG and S-TAG are shown in Figure 4-9 and Figure 4-10. Figure 4-9 TCI structure of the C-TAG Octets:
1
2 PCP
Bits:
8
VID
CFI 6
5
4
VID 1
8
1
The TCI field of the C-TAG consists of the following bytes: l
PCP: three bits
l
CFI: one bit
Figure 4-10 TCI structure of the S-TAG Octets:
1
2 PCP
Bits:
8
VID
DE 6
5
4
VID 1
8
1
The TCI field of the S-TAG consists of the following bytes:
4-10
l
PCP: three bits
l
DE: one bit
l
VID: 12 bits
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4.2.2 Internal Ports and External Ports External ports on Ethernet boards are used to access the services on the user side. Internal ports on Ethernet boards are used to encapsulate and map the services to the transmission network for transparent transmission. External ports on Ethernet boards (that is, external physical ports) are also referred to as clientside ports or user-side ports, which are used to access the Ethernet services on the user side. Internal ports on Ethernet boards (that is, internal VCTRUNKs) are also referred to as systemside ports or backplane-side ports in certain cases, which are used to encapsulate and map the services to the SDH side. VCTRUNKs are VC-based transmission paths, which can be implemented by using the adjacent concatenation or virtual concatenation technology. On the U2000 window, paths are bound to specify the bandwidth of different granularities for a VCTRUNK port. Figure 4-11 External ports and internal ports on Ethernet boards External port
VCTRUNK port
Interface module
Service processing module
Encapsulation/ Mapping module
Backplane
Interface conversion module
Crossconnect unit Crossconnect unit
Ethernet board
4.2.3 Auto-Negotiation The auto-negotiation function allows the network equipment to send information of its supported working mode to the opposite end on the network and to receive the corresponding information that the opposite end may transfer. The working modes of the interconnected ports on the equipment at both ends must be the same. Otherwise, the services are affected. If the working mode of the port on the opposite equipment is full duplex and if the working mode of the port on the local equipment is auto-negotiation, the local equipment works in the half-duplex mode. That is, the working modes of the interconnected ports at both ends are different, and thus packets may be lost. Hence, when the working mode of the port on the opposite equipment is full duplex, you need to set working mode of the port on the local equipment to full duplex. NOTE
When the interconnected ports at both sides work in the auto-negotiation mode, the equipment at both sides can negotiate the flow control through the auto-negotiation function.
The auto-negotiation function uses fast link pulses (FLPs) and normal link pulses (NLPs) to transfer information of the working mode so that no packet or upper layer protocol overhead needs to be added. Issue 02 (2011-06-30)
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This topic considers FE electrical interfaces as an example to describe how to implement the auto-negotiation function.
The FLP is called the 100BASE-T link integrity test pulse sequence. Each set of equipment on the network must be capable of issuing FLP bursts in the case of power-on, issuing of management commands, or user interaction. The FLP burst consists of a series of link integrity test pulses that form an alternating clock/data sequence. Extraction of the data bits from the FLP burst yields a link code word that identifies the working modes supported by the remote equipment and certain information used for the negotiation and handshake mechanism. To maintain interoperability with the existing 100BASE-T equipment, the auto-negotiation function also supports the reception of 100BASE-T compliant link integrity test pulses. The 10BASE-T link pulse activity is referred to as the NLP sequence. equipment that fails to respond to the FLP burst sequence by returning only the NLP sequence is treated as the 100BASE-T compatible equipment. The first pulse in an FLP burst is defined as a clock pulse. Clock pulses within an FLP burst occur at intervals of 125 us. Data pulses occur in the middle of two adjacent clock pulses. The positive pulse represents logic "1" and the absence of a pulse represents logic "0". An FLP burst consists of 17 clock pulses and 16 data pulses (if all data bits are 1). The NLP waveform is simpler than the FLP waveform. NLP sends a positive pulse every 16 ms when no data frame needs to be transmitted. Figure 4-12 Waveform of a single FLP T3
Clock pulses
T1
T2
… First bit on wire Data Encoding
1 D 0
1 D 1
T1: 100 ns
0 D 2 T2: 62.5 us
1 D 3
… … T3: 125 us
Figure 4-13 Consecutive FLP and NLP bursts T5 T4
FLP bursts
NLPs T4: 2 ms
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4.2.4 Flow Control When the data processing/transferring capability of the equipment fails to handle the flow received at the port, congestion occurs on the line. To reduce the number of discarded packets due to buffer overflowing, proper flow control measures must be taken. The half-duplex Ethernet port applies the back-pressure mechanism to control the flow. The fullduplex Ethernet port applies PAUSE frames to control the flow. Currently, the half-duplex Ethernet function is not widely applied. Hence, the flow control function realized by Ethernet service boards is used for the full-duplex Ethernet ports. The flow control function realized by Ethernet service boards is classified into two types: autonegotiation flow control and non-auto-negotiation flow control.
Auto-Negotiation Flow Control When the Ethernet port works in the auto-negotiation mode, you can adopt the auto-negotiation flow control function. The auto-negotiation flow control modes include the following: l
Enable dissymmetric flow control The port can transmit PAUSE frames in the case of congestion but cannot process the received PAUSE frames.
l
Enable symmetric flow control The port can transmit PAUSE frames and process the received PAUSE frames.
l
Enable symmetric/dissymmetric flow control The port has the following abilities: – Transmits and processes PAUSE frames. – Transmits PAUSE frames but cannot process the received PAUSE frames. – Processes the received PAUSE frames but cannot transmit PAUSE frames.
l
Disable Disables the auto-negotiation flow control function.
Non-Auto-Negotiation Flow Control When the Ethernet port works in a fixed working mode, you can adopt the non-auto-negotiation flow control function. The non-auto-negotiation flow control modes include the following: l
Send only The port can transmit PAUSE frames in the case of congestion but cannot process the received PAUSE frames.
l
Receive only The port can process the received PAUSE frames but cannot transmit PAUSE frames in the case of congestion.
l
Send and receive The port can transmit PAUSE frames and process the received PAUSE frames.
l
Disable The port does not support the auto-negotiation flow control function.
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Realization Principle The realization principle of the flow control function is described as follows: 1.
When congestion occurs in the receive queue of an Ethernet port (the data in the receive buffer exceeding a certain threshold) and the port is capable of sending PAUSE frames, the port sends a PAUSE frame to the opposite end. pause-time value in the frame is N (0
2.
If the Ethernet port at the opposite end is capable of processing PAUSE frames, this Ethernet port stops sending data within a specified period of time N (the unit is the time needed for sending 521 bits) after receiving the PAUSE frame.
3.
If the congestion at the receive port is cleared (the data in the receive buffer is below a certain threshold) but the pause-time does not end, the port sends a PAUSE frame whose pause-time is 0 to notify the opposite end to send data.
IEEE 802.3 defines the format of the PAUSE frame as follows: l
Destination address: 01-80-C2-00-00-01 (multicast address)
l
Source address: MAC address of the source port
l
Type/Length: 88-08 (MAC control frame)
l
MAC control code: 00-01 (PAUSE frame)
l
MAC control parameter: pause-time (two bytes)
Figure 4-14 Structure of the PAUSE frame Destination address
01-80-C2-00-00-01
6 octets
XX-XX-XX-XX-XX-XX
6 octets
Type/Length
88-08
2 octets
MAC control opcode
00-01
2 octets
MAC control parameter (pause-time)
XX-XX
2 octets
Source address
Reserved
4.2.5 Encapsulation and Mapping Protocol To ensure that Ethernet frames can be transparently transmitted over the optical transmission network, the Ethernet frames need to be encapsulated and mapped into VC containers at the access point. The encapsulation and mapping protocols used by the Ethernet service board include the high-level data link control (HDLC), link access procedure - SDH (LAPS), and generic framing procedure (GFP).
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HDLC The HDLC is a general data link control procedure. When using the HDLC protocol, the system encapsulates data services into HDLC-like frames as information bits and maps the frames into SDH VC containers.
LAPS The LAPS is also a data link control procedure. It is optimized based on the HDLC. The LAPS complies with ITU-T X.86.
GFP The GFP is the most widely applied general encapsulation and mapping protocol. It provides a general mechanism to adapt higher-layer client signal flows into the transport network and can map the variable-length payload into the byte-synchronized transport path. The client signals can be protocol data units (PDU-oriented, such as IP/PPP and Ethernet), block code data (blockcode oriented, such as Fiber Channel and ESCON), or common bit data streams. The GFP protocol complies with ITU-T G.7041. The GFP defines the following modes to adapt client signals: l
Frame-mapped GFP (GFP-F) The GFP-F is a PDU-oriented processing mode. It encapsulates the entire PDU into the GFP payload area and makes no modification on the encapsulated data. It determines whether to add a detection area for the payload area, depending on requirements.
l
Transparent GFP (GFG-T) The GFP-T is a block-code (8B/10B code block) oriented processing mode. It extracts a single character from the received data block and maps the character into the fixed-length GFP frame.
4.2.6 Virtual Concatenation The rate of the Ethernet service does not adapt to the rate of the standard VC container. Hence, if you directly map the Ethernet service data into a standard VC container, there is a great waste of the transmission bandwidth. To solve the problem, use the virtual concatenation technology to concatenate many standard VC containers to a large VC container that adapts to the rate of the Ethernet service. The concatenation is defined in ITU-T G.707 and contains contiguous concatenation and virtual concatenation. Both concatenation methods provide concatenated bandwidth of X times Container-N at the path termination. Contiguous concatenation concatenates the contiguous VC-4s in the same STM-N into an entire structure to transport. It maintains the contiguous bandwidth throughout the whole transport. Virtual concatenation concatenates many individual VC containers (VC-12 containers, VC-3 containers, or VC-4 containers) into a bit virtual structure to transport. The virtual concatenation breaks the contiguous bandwidth into individual VCs, transports the individual VCs, and recombines these VCs to a contiguous bandwidth at the transmission termination point. In the case of virtual concatenation, transport of each VC container may occupy different paths and there may be a transport delay difference between VC containers. Hence, there are difficulties to restore the client signal. Virtual concatenation requires concatenation functionality only at the path termination equipment and it can flexibly allocate bandwidth. Hence, the virtual concatenation technology is widely used. Issue 02 (2011-06-30)
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Virtual concatenation is available in two types: virtual concatenation in a higher order path and virtual concatenation in a lower order path. A higher order virtual concatenation VC4-Xv provides a payload of X Container-4s (VC-4s). The payload is mapped individually into X independent VC-4s. Each VC-4 has its own POH. A lower order virtual concatenation VC-12Xv provides a payload of X Container-12s (VC-12s). The payload is mapped individually into X independent VC-12s. Each VC-12 has its own POH. It is the same case with the virtual concatenation of VC-3s.
VC4-Xv and VC-3-Xv The virtual container that is formed by a VC4-Xv/VC-3-Xv can be mapped into X individual VC-4/VC-3s that form the VC4-Xv/VC-3-Xv. Each VC-4/VC-3 has its own POH. POH has the same specifications as the ordinary VC-4 POH. The H4 byte in the POH is used for the virtual concatenation-specific multiframe indicator (MFI) and sequence indicator (SQ). MFI indicates the position of a frame in the multiframe. Each frame sent by the source carries the MFI information. The sink end combines the frames with the same MFI into the C-n-Xv. MFI includes MFI-1 and MFI-2. MFI-1 is transmitted by bits 5-8 of the H4 byte and ranges from 0 to 15. MFI-2 is transmitted by the two frames of which the MFI-1 is "0" and "1" in the multiframe. Bits 1-4 of the H4 bytes of the two frames indicate the higher four bits and lower four bits of the MFI-2 respectively. Hence, the MFI-2 ranges from 0 to 255. That is, a multiframe consists of 4096 frames and the period is 512 ms. SQ indicates the position of a frame in the C-n-Xv. The source end inserts the SQ information into the frame according to the payload allocation sequence. The sink end determines the sequence to extract the payload from the frames that form C-n-Xv according to the SQ. SQ is transmitted by the two frames of which the MFI-1 is "14" and "15" in the multiframe. Bits 1-4 of the H4 bytes of the two frames indicate the higher four bits and lower four bits of the SQ respectively.
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Figure 4-15 VC-3-Xv/VC4-Xv multiframe and sequence indicator
SQ = X-1 = 15 SQ = 0 = 255 MFI-1 = 15 MFI-2 = 255 X-1 =0 SQ = 0 =0 MFI-1 = 0 MFI-2 = 0
POH
POH
H
POH
POH
H
SQ = X-1 = 15 SQ = 0 MFI-1 = 15 = 0 MFI-2 = 0 X-1 SQ = 0 =0 MFI-1 = 0 = 15 MFI-2 = 1
Multiframe (MF)
POH
X
POH
1
C-3-Xv/C-4-Xv SQ = X-1 =0 SQ = 0 =0 MFI-1 = 0 X-1 MFI-2 = 0 =1 SQ = 0 =0 MFI-1 = 1 MFI-2 = 0 H
C-3-X/C-4-X
With the MFI and SQ, the sink end can correctly restore the position of each frame in the C-nXv to prevent the frame alignment problem due to the different propagation delays of the frames.
VC-12-Xv The virtual container that is formed by a VC-12-Xv can be mapped into X individual VC-12s which form the VC-12-Xv. Each VC-12 has its own POH. POH has the same specifications as the ordinary VC-12 POH. Bit 2 of the K4 byte in the POH is used for the virtual concatenationspecific frame count and sequence indicator. Bit2s of the K4 bytes in every 32 multiframes (one multiframe comprising four VC-12s) are extracted to form a 32-bit character string to express the frame count and sequence indicator. Bits 1-5 of the string express the frame count, whose value range is between 0 and 31. structure formed by 32 multiframes has 128 frames. Hence, the resulting overall multiframe is 4096 frames with the period of 512 ms. Bits 6-11 of the string express the sequence indicator. The frame count/sequence indicator in the VC-12-Xv has the same usage as the multiframe indicator/ sequence indicator in the VC4-Xv/VC-3-Xv.
4.2.7 Tag Attribute When data frames are received on or transmitted from a port on an Ethernet board, the processing mode of the data frames is determined by the tag attributes of the port. The tags for the port on an Ethernet board are available in three types: tag aware, access, and hybrid. Issue 02 (2011-06-30)
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Table 4-5 Processing mode of data frames on ports with different tags Direction
Data Frame Type
Ingress port
Egress port
Processing Mode Tag aware
Access
Hybrid
Data frames with VLAN tags
The data frames are transparently transmitted.
The data frames are discarded.
The data frames are transparently transmitted.
Data frames without VLAN tags
The data frames are discarded.
The VLAN tags that contain Default VLAN ID and VLAN Priority are added to the data frames, and then the data frames are transparently transmitted.
Data frames with VLAN tags
The data frames are transparently transmitted.
After the VLAN tags are stripped from the data frames, the data frames are transparently transmitted.
l If the VLAN IDs contained in the data frames are Default VLAN ID, the VLAN tags are stripped from the data frames, and then the data frames are transparently transmitted. l If the VLAN IDs contained in the data frames are not Default VLAN ID, the data frames are transparently transmitted.
NOTE
The tag setting is valid only when the following conditions are met: l Port Type of the port is set to PE or UNI. l The entry detection function is enabled. When the Ethernet switching board works in the Ethernet transparent transmission state and when the entry detection function is disabled, the port transparently transmits the received data frames regardless of whether the data frames carry VLAN tags.
Based on the features of tag aware, access, and hybrid, adhere to the following principles when setting the tag for a port:
4-18
l
If the data packets transmitted from the interconnected equipment carry VLAN tags, set TAG to Tag Aware.
l
If the data packets transmitted from the interconnected equipment do not carry VLAN tags, set TAG to Access.
l
If the data packets transmitted from the interconnected equipment may carry VLAN tags, set TAG to Hybrid. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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4.2.8 Bridge A bridge is a functional unit that is used to implement the interconnection between two or more LANs.
VB and LP The switching domain of an Ethernet board that has the Layer 2 switching capability can be divided into multiple sub-switching domains. As a result, if no services are interconnected, different various bridges (VBs) cannot access each other. Each VB has an independent configuration mode and uses an independent VLAN. Different VBs can use the same VLAN. A VB can contain a number of logical ports (LPs). By configuring the mounting relation, you can mount multiple PORTs and VCTRUNKs to the same VB. Figure 4-16 shows the relations between VBs, LPs, PORTs, and VCTRUNKs. Figure 4-16 Relations between VBs, LPs, PORTs, and VCTRUNKs
Ethernet Switching Board VB1 VCTRUNK1
PORT1
LP1
LP4
PORT2
LP2
LP5
VCTRUNK2
LP3
LP6
VCTRUNK3
PORT3
VB2 PORT4
LP1
LP4
VCTRUNK4
PORT5
LP2
LP5
VCTRUNK5
LP3
LP6
VCTRUNK6
PORT6
Transparent Bridge and Virtual Bridge l
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l
The services of different virtual bridges are isolated and the services with different VLAN IDs in the same virtual bridge are also isolated. The switching domain of the entire virtual bridge is divided into multiple sub-switching domains according to the VLAN IDs. NOTE
As shown in Figure 4-17, the same logical port may belong to one or more sub-switching domains with different VLAN IDs. On the U2000, the same logical port can belong to multiple filtering tables with different VLAN IDs.
Figure 4-17 Transparent bridge and virtual bridge
PORT1 PORT2 PORT3
VLAN1 VLAN2 VLAN3 ...
VCTRUNK1 VCTRUNK2
PORT1
VCTRUNK3 VCTRUNK4
PORT2
VCTRUNK5 VCTRUNK6
PORT3
Pure bridge
VCTRUNK1 VCTRUNK2
VLAN1 VLAN2
VCTRUNK3 VCTRUNK4 VCTRUNK5 VCTRUNK6
VLAN3 Virtual bridge
Logical port
Table 4-6 Transparent Bridge and Virtual Bridge
4-20
Item
Transparent Bridge
Virtual Bridge
VLAN filtering table
It is not configured.
It must be configured.
Ingress filter
Does not check the validity of VLAN tags. All data frames that enter the bridge are valid.
Check the validity of VLAN tags. If the VLAN ID is not the same as the VLAN ID defined in the VLAN filtering table, discard the data frame.
MAC address learning mode
SVL
IVL
Data frame forwarding mode
Query the MAC address table to obtain the forwarding port of the data frame according to the destination MAC address of the data frame.
Query the MAC address table to obtain the forwarding port of the data frame according to the destination MAC address and VLAN ID of the data frame.
Broadcast range
Forward broadcast data frames on all ports of a bridge.
Forward the broadcast data frames on the forwarding ports defined in the VLAN filtering table.
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NOTE
To forward a Layer 2 switching service, a bridge must learn the MAC address. A bridge learns the MAC address through one of the following methods: shared VLAN learning (SVL) and independent VLAN learning (IVL). l When the bridge adopts the SVL learning mode, the entry in the MAC address table is created according to the source MAC address and source port of the data frame. The entry is valid for all VLANs. l When the bridge adopts the IVL learning mode, the entry in the MAC address table is created according to the source MAC address, VLAN ID, and source port of the data frame. The entry is valid for only the VLAN.
Bridge Type As listed in Table 4-7, the Ethernet boards support three types of bridges. Table 4-7 Types of bridges supported by the Ethernet boards Bridge Type
Bridge Switch Mode
Bridge Learning Mode
Ingress Filter
IEEE 802.1d MAC bridge
SVL/Ingress Filter Disable
SVL
Disabled
IEEE 802.1q Virtual Bridge
IVL/Ingress Filter Enable
IVL
Enabled
IEEE 802.1ad Provider Bridge
1
SVL/Ingress Filter Disable
SVL
Disabled
2
IVL/Ingress Filter Enable
IVL
Enabled
l
IEEE 802.1d MAC bridge: The IEEE 802.1d MAC bridge does not check the contents of the VLAN tags that are in the data frames, but performs Layer 2 switching according to the destination MAC addresses of the data frames.
l
IEEE 802.1q bridge: The IEEE 802.1q bridge supports data isolation by using one layer of VLAN tags. This bridge checks the contents of the VLAN tags that are in the data frames and performs Layer 2 switching according to the destination MAC addresses and VLAN IDs.
l
The IEEE 802.1ad bridge: The IEEE 802.1ad bridge supports data frames with two layers of VLAN tags. This bridge adopts the outer S-VLAN tags to isolate different VLANs and supports only the mounted ports whose attributes are C-Aware or S-Aware. This bridge supports the following switching modes:
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1.
This bridge does not check the contents of the VLAN tags that are in the data frames, but performs Layer 2 switching according to the destination MAC addresses of the data frames.
2.
This bridge checks the contents of the VLAN tags that are in the data frames and performs Layer 2 switching according to the destination MAC addresses and the SVLAN IDs of the data frames.
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MAC Address Table The entries in the MAC address table reflect the corresponding relations between MAC addresses and ports. The MAC address table contains the following entries: l
Dynamic entry Indicates the entry that the bridge obtains by adopting the SVL/IVL learning mode. The dynamic entry ages and is even lost after the Ethernet switching board is reset.
l
Static entry Indicates the entry corresponding to the MAC address and the port that the network administrator manually adds in the MAC address table on the U2000. A static entry is a unicast entry. The static entry does not age and is not lost after the Ethernet switching board is reset.
l
Blackhole entry Indicates the entry used to discard the data frame that contains the specified destination MAC address, and is also referred to as the MAC address disable entry. The blackhole entry is configured by the network administrator. This entry does not age and is not lost after the Ethernet switching board is reset. NOTE
l If a routing entry is not updated within a specific period of time, that is, if the MAC address fails to be learnt because the new data frame from the MAC address is not received, this routing entry is deleted automatically. This mechanism is considered as aging, and this period of time is considered as the aging time. The aging time of the MAC address table is five minutes by default and can be set by using the U2000. l A limited number of MAC addresses can be learnt at a time.
Hub/Spoke Generally, the central station and non-central stations can access each other, but the non-central stations cannot access each other in the case of convergence services. Therefore, the ports mounted to the bridge need to be defined as Hub or Spoke ports. l
Hub port Hub ports can access each other. Hub ports and Spoke ports can also access each other.
l
Spoke port Spoke ports cannot access each other. Hub ports and Spoke ports can access each other.
The mounted ports are Hub ports by default.
4.3 Flow of Configuring Ethernet Services This topic describes the configuration processes related to Ethernet services. Before you configure Ethernet services according to the flow, you need to complete the basic configurations of the NEs according to the flow of creating a network. 4.3.1 Flow of Configuring EPL Services The EPL services feature simplicity, transparent transmission, and dedicated bandwidth. The configuration flow differs depending on whether Ethernet transparent transmission boards or Ethernet switching boards are configured. 4.3.2 Flow of Configuring EVPL Services In the case of EVPL services, services of different users share the bandwidth. Hence, the VLAN ID or other schemes need to be used for differentiating the services of different users. If the 4-22
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services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme. 4.3.3 Flow of Configuring EPLAN Services EPLAN services provide the customers with Layer 2 switching-based multipoint-connected LAN services. 4.3.4 Flow of Configuring EVPLAN Services EVPLAN services of different users need to share the bandwidth. Hence, the VLAN ID or other schemes need to be used for differentiating the services of different users. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme.
4.3.1 Flow of Configuring EPL Services The EPL services feature simplicity, transparent transmission, and dedicated bandwidth. The configuration flow differs depending on whether Ethernet transparent transmission boards or Ethernet switching boards are configured. Ethernet transparent transmission boards or Ethernet switching boards can be used to configure EPL services. The Ethernet transparent transmission boards and Ethernet switching boards are provided in Table 6-1.
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Figure 4-18 Flow of configuring EPL services
Start
Required Optional Ethernet transparent transmission board 1
2
Ethernet switching board
Configure Ethernet external ports
1
Configure Ethernet internal ports
2
Configure Ethernet external ports Configure Ethernet internal ports
3 Create EPL services
4
5
6
7
Create crossconnections Check service continuity Enable NE performance monitoring Back up NE configuration data
End
Table 4-8 Flow of configuring EPL services Step
Operation
Remarks
1
Configuring External Ports on Ethernet Boards
Required
4-24
When an NE accesses Ethernet services through the external ports on the Ethernet board, you need to configure the attributes of the external ports so that the external ports can work with the data communication equipment on the client side, thus ensuring the normal accessing of the Ethernet services.
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Step
Operation
Remarks
2
Configuring Internal Ports on Ethernet Boards
Required
Creating EPL Services
l If Ethernet transparent transmission boards are used, skip to Step 4. On Ethernet transparent transmission boards, the EPL service connections from the PORTs to the VCTRUNKs are considered to be created by default.
3
When an NE transmits Ethernet services through the internal ports (that is, VCTRUNK ports) on the Ethernet board to the SDH side, you need to configure the attributes of the VCTRUNK ports so that the VCTRUNK ports can work with the Ethernet board on the opposite equipment. This ensures that the transmission of the Ethernet services in the SDH network is normal.
l If Ethernet switching boards are used, the EPL service connections between the PORTs and the VCTRUNKs must be created. 4
Creating SDH Services
Required This topic describes how to create the timeslot connections between the bound paths and the line board, thus ensuring that the Ethernet services are transmitted in specified timeslots over the transmission line.
5
Testing Ethernet Service Channels
Required After the Ethernet services are created, test the service continuity.
6
7
Setting Performance Monitoring Parameters of an NE
Required
Backing Up the NE Database to the SCB Board
Required
Enable the performance monitoring function for a specific NE. Then, you can obtain detailed performance records during the operation process of this NE. These records can be used for monitoring and analyzing the running status of this NE.
Back up the NE database to ensure that the NE can be automatically recovered to normal operation after the SCC data is lost or after the equipment is powered off.
4.3.2 Flow of Configuring EVPL Services In the case of EVPL services, services of different users share the bandwidth. Hence, the VLAN ID or other schemes need to be used for differentiating the services of different users. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme. The Ethernet switching boards are required for configuring EVPL services. The Ethernet switching boards that support EVPL services are provided in Table 6-1.
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Figure 4-19 Flow of configuring EVPL services
Required Optional
Start 1
2
Configure Ethernet external ports Configure Ethernet internal ports
3 Create EPL services 4
Create crossconnections
5 Configure the QoS 6
7
8
Check service continuity Enable NE performance monitoring Back up NE configuration data
End
Table 4-9 Flow of configuring EVPL services Step
Operation
Remarks
1
Configuring External Ports on Ethernet Boards
Required
4-26
When an NE accesses Ethernet services through the external ports on the Ethernet board, you need to configure the attributes of the external ports so that the external ports can work with the data communication equipment on the client side, thus ensuring the normal accessing of the Ethernet services.
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Step
Operation
Remarks
2
Configuring Internal Ports on Ethernet Boards
Required
Creating EPL Services
Required
3
4 Configuring Ethernet Services
When an NE transmits Ethernet services through the internal ports (that is, VCTRUNK ports) on the Ethernet board to the SDH side, you need to configure the attributes of the VCTRUNK ports so that the VCTRUNK ports can work with the Ethernet board on the opposite equipment. This ensures that the transmission of the Ethernet services in the SDH network is normal.
When an Ethernet switching board carries private line services, the relevant information of the private line services, such as the service source and service sink, must be specified. 4
Creating SDH Services
Required This topic describes how to create the timeslot connections between the bound paths and the line board, thus ensuring that the Ethernet services are transmitted in specified timeslots over the transmission line.
5
Configuring QoS
Optional The services of different users need to share the bandwidth. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme.
6
Testing Ethernet Service Channels
Required After the Ethernet services are created, test the service continuity.
7
8
Setting Performance Monitoring Parameters of an NE
Required
Backing Up the NE Database to the SCB Board
Required
Enable the performance monitoring function for a specific NE. Then, you can obtain detailed performance records during the operation process of this NE. These records can be used for monitoring and analyzing the running status of this NE.
Back up the NE database to ensure that the NE can be automatically recovered to normal operation after the SCC data is lost or after the equipment is powered off.
4.3.3 Flow of Configuring EPLAN Services EPLAN services provide the customers with Layer 2 switching-based multipoint-connected LAN services. The Ethernet switching boards are required for configuring EPLAN services. The Ethernet switching boards that support EPLAN services are provided in Table 6-1.
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Figure 4-20 Flow of configuring EPLAN services Required Optional
Start 1
Configure Ethernet external ports
2
3
Configure Ethernet internal ports Create Ethernet LAN services
4
Modify Hub/Spoke attribute of mounted ports
5
6
Create crossconnections
Configure the Layer 2 switching feature
7
Check service continuity
8
9
Enable NE performance monitoring Back up NE configuration data
End
Table 4-10 Flow of configuring EPLAN services Step
Operation
Remarks
1
Configuring External Ports on Ethernet Boards
Required
4-28
When an NE accesses Ethernet services through the external ports on the Ethernet board, you need to configure the attributes of the external ports so that the external ports can work with the data communication equipment on the client side, thus ensuring the normal accessing of the Ethernet services.
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Step
Operation
Remarks
2
Configuring Internal Ports on Ethernet Boards
Required
Creating Ethernet LAN Services
Required
3
4 Configuring Ethernet Services
When an NE transmits Ethernet services through the internal ports (that is, VCTRUNK ports) on the Ethernet board to the SDH side, you need to configure the attributes of the VCTRUNK ports so that the VCTRUNK ports can work with the Ethernet board on the opposite equipment. This ensures that the transmission of the Ethernet services in the SDH network is normal.
When an Ethernet switching board carries LAN services, you need to create the bridge and set the attributes of the bridge and the port mounted to the bridge. 4
5
Modify Hub/Spoke attribute of mounted ports
Optional
Creating SDH Services
Required
In the case of Ethernet LAN services, you can modify the Hub/ Spoke attribute between access nodes from the default value of Hub to Spoke, thus disabling the communication between the access nodes; however, the communication between the access nodes and the convergence node is not disabled.
This topic describes how to create the timeslot connections between the bound paths and the line board, thus ensuring that the Ethernet services are transmitted in specified timeslots over the transmission line. 6
Configuring the Layer 2 switching feature l Creating MAC Address Entries l Modifying Aging Time of MAC Addresses l Configuring the Spanning Tree
Optional l You can manually specify the port for forwarding the MAC frames to create the VLAN unicast entries and you can suppress the forwarding of certain MAC frames to create the MAC address disabled entries. The manually created MAC entries are not affected by the aging time. l The aging time of the dynamic MAC address entries of an Ethernet switching board is five minutes by default. You can modify the aging time according to the actual requirements. l There may be loops in the network topology of Ethernet services. Hence, the STP/RSTP protocol is enabled to prevent packets from being proliferated and endlessly cycled in the loop network.
7
Testing Ethernet Service Channels
Required After the Ethernet services are created, test the service continuity.
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Step
Operation
Remarks
8
Setting Performance Monitoring Parameters of an NE
Required
Backing Up the NE Database to the SCB Board
Required
9
Enable the performance monitoring function for a specific NE. Then, you can obtain detailed performance records during the operation process of this NE. These records can be used for monitoring and analyzing the running status of this NE.
Back up the NE database to ensure that the NE can be automatically recovered to normal operation after the SCC data is lost or after the equipment is powered off.
4.3.4 Flow of Configuring EVPLAN Services EVPLAN services of different users need to share the bandwidth. Hence, the VLAN ID or other schemes need to be used for differentiating the services of different users. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme. The Ethernet switching boards are required for configuring EVPLAN services. The Ethernet switching boards that support EVPLAN services are provided in Table 6-1.
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Figure 4-21 Flow of configuring EVPLAN services Required Optional
Start 1
2
3
4
Configure Ethernet external ports Configure Ethernet internal ports Create Ethernet LAN services Create the VLAN filtering table
5 Modify the Hub/Spoke attribute of mounted ports
6
7
Create crossconnections
Configure the Layer 2 switching feature
8 Configure the QoS 9
10
11
Check service continuity Enable NE performance monitoring Back up NE configuration data
End
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Table 4-11 Flow of configuring EVPLAN services Step
Operation
Remarks
1
Configuring External Ports on Ethernet Boards
Required
Configuring Internal Ports on Ethernet Boards
Required
Creating Ethernet LAN Services
Required
2
3
When an NE accesses Ethernet services through the external ports on the Ethernet board, you need to configure the attributes of the external ports so that the external ports can work with the data communication equipment on the client side, thus ensuring the normal accessing of the Ethernet services.
When an NE transmits Ethernet services through the internal ports (that is, VCTRUNK ports) on the Ethernet board to the SDH side, you need to configure the attributes of the VCTRUNK ports so that the VCTRUNK ports can work with the Ethernet board on the opposite equipment. This ensures that the transmission of the Ethernet services in the SDH network is normal.
When an Ethernet switching board carries LAN services, you need to create the bridge and set the attributes of the bridge and the port mounted to the bridge. 4
Creating VLANs Filtering
Required In the case of Ethernet LAN services, when the type of the bridge is IEEE 802.1q or IEEE 802.1ad, the VLAN filtering table needs to be created for the bridge if VLANs are used to isolate the data of different users.
5
6
Modify Hub/Spoke attribute of mounted ports
Optional
Creating SDH Services
Required
In the case of Ethernet LAN services, you can modify the Hub/ Spoke attribute between access nodes from the default value of Hub to Spoke, thus disabling the communication between the access nodes; however, the communication between the access nodes and the convergence node is not disabled.
This topic describes how to create the timeslot connections between the bound paths and the line board, thus ensuring that the Ethernet services are transmitted in specified timeslots over the transmission line.
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Step
Operation
Remarks
7
Configuring the Layer 2 switching feature
Optional
l Creating MAC Address Entries l Modifying Aging Time of MAC Addresses l Configuring the Spanning Tree
4 Configuring Ethernet Services
l You can manually specify the port for forwarding the MAC frames to create the VLAN unicast entries and you can suppress the forwarding of certain MAC frames to create the MAC address disabled entries. The manually created MAC entries are not affected by the aging time. l The aging time of the dynamic MAC address entries of an Ethernet switching board is five minutes by default. You can modify the aging time according to the actual requirements. l There may be loops in the network topology of Ethernet services. Hence, the STP/RSTP protocol is enabled to prevent packets from being proliferated and endlessly cycled in the loop network. l When a multicast router is located on the network, the IEEE 802.1q or IEEE 802.1ad bridge can enable the IGMP Snooping protocol to work with the router, thus implementing the multicast function.
8
Configuring QoS
Optional The services of different users need to share the bandwidth. If the services of different users need to be configured with different quality levels, you need to adopt the corresponding QoS scheme.
9
Testing Ethernet Service Channels
Required After the Ethernet services are created, test the service continuity.
10
11
Setting Performance Monitoring Parameters of an NE
Required
Backing Up the NE Database to the SCB Board
Required
Enable the performance monitoring function for a specific NE. Then, you can obtain detailed performance records during the operation process of this NE. These records can be used for monitoring and analyzing the running status of this NE.
Back up the NE database to ensure that the NE can be automatically recovered to normal operation after the SCC data is lost or after the equipment is powered off.
4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board EPL services provide the point-to-point Ethernet transparent transmission solution with the bandwidth exclusively occupied. EPL services are applicable when the communication equipment that is used to access the client-side data in the transmission network does not support VLANs or when the VLAN planning must be kept secret to the network operator. 4.4.1 Networking Diagram
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The completely isolated data services of two users at a station must be transported to another station. 4.4.2 Signal Flow and Timeslot Allocation Ethernet services are received from an external port, encapsulated through an internal port, and mapped to the SDH network for transparent transmission. In this way, the node communicates with a remote node. 4.4.3 Configuration Process The Ethernet transparent transmission boards support only EPL services. The EPL are already created by default and hence you need not configure the Ethernet transparent transmission boards on the U2000.
4.4.1 Networking Diagram The completely isolated data services of two users at a station must be transported to another station.
Service Requirement In the network as shown in Figure 4-22, the service requirements are as follows: l
The two branches of user A that are located at NE1 and NE3 need to communicate with each other over Ethernet. A 10 Mbit/s bandwidth is required.
l
The two branches of user B that are located at NE1 and NE3 need to communicate with each other over Ethernet. A 20 Mbit/s bandwidth is required.
l
The services of user A must be isolated from the services of user B.
l
The Ethernet equipment of user A and user B provides 100 Mbit/s Ethernet ports of which the working mode is auto-negotiation, and does not support VLANs.
Figure 4-22 Networking diagram of the EPL services User A2
PORT1
User B2
PORT1 NE3: Ethernet board
NM
3-EGT1
5-SL4D-2 5
Ethernet board Line board 4-EGT1
5-SL4D-1
NE3
5-SL4D-1 NE2
NE4
5-SL4D-2
NE2: Line board
Line board
5-SL4D-1
5-SL4D-2
5-SL4D-1
NE1 NE1: Ethernet board
PORT1
PORT1
3-EGT1
Ethernet board Line board 4-EGT1
5-SL4D-2
VCTRUNK
User A1
4-34
User B1
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Board Configuration Information Ethernet transparent transmission boards or Ethernet switching boards can be used for configuring EPL services. In this example, NE1 and NE3 are configured with two EGT1 boards respectively, which occupy logical slots 3 and 4.
4.4.2 Signal Flow and Timeslot Allocation Ethernet services are received from an external port, encapsulated through an internal port, and mapped to the SDH network for transparent transmission. In this way, the node communicates with a remote node. Figure 4-23 shows the signal flow and timeslot allocation of the EPL services. For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-23 Signal flow and timeslot allocation (Ethernet transparent transmission board) NOTE
The EGT1 board supports transparent transmission of Ethernet services, the link capacity adjustment scheme (LCAS), test frames, and other functions. NE2
NE1 PORT1 User A1 PORT1 User B1
NE3
3-EGT1
3-EGT1
VCTRUNK1
4-EGT1
VC4-4:VC12:1-5
VCTRUNK1 VC4-4:VC12:1-5
VC4-1:VC12:1-5
VCTRUNK1
VCTRUNK1
VC4-4:VC12:1-10
VC4-4:VC12:1-10
VC4-1:VC12:6-15
4-EGT1
PORT1 User A2 PORT1 User B2
SDH
l
The EPL services of user A: – Occupy the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link between NE1 and NE3 and pass through NE2. – Are added and dropped by using the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the 3-EGT1 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the 3-EGT1 board of NE3.
l
The EPL services of user B: – Occupy the sixth to fifteenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:6-15) on the SDH link between NE1 and NE3 and pass through NE2. – Are added and dropped by using the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the 4-EGT1 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the 4-EGT1 board of NE3.
Table 4-12 Parameters of external ports on the Ethernet boards
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Parameter
NE1
Board
3-EGT1
NE3 4-EGT1
3-EGT1
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Parameter
NE1
NE3
Port
PORT1
PORT1
PORT1
PORT1
Enabled/ Disabled
Enabled
Enabled
Enabled
Enabled
Working Mode
AutoNegotiation
AutoNegotiation
AutoNegotiation
AutoNegotiation
Maximum Frame Length
1522
1522
1522
1522
Table 4-13 Parameters of internal ports on the Ethernet boards Parameter
NE1
NE3
Board
3-EGT1
4-EGT1
3-EGT1
4-EGT1
Internal Port
VCTRUNK1
VCTRUNK1
VCTRUNK1
VCTRUNK1
Mapping Protocol
GFP
GFP
GFP
GFP
Bound Path
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-1 -VC12-10
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-1 -VC12-10
4.4.3 Configuration Process The Ethernet transparent transmission boards support only EPL services. The EPL are already created by default and hence you need not configure the Ethernet transparent transmission boards on the U2000.
Prerequisite You must be familiar with 4.3.1 Flow of Configuring EPL Services.
Background Information By default, EPL service connections from external ports to internal ports are already created for Ethernet transparent transmission boards. The EPL service connections can be queried on the U2000, but cannot be created, modified, or deleted on the U2000. If the Ethernet transparent transmission boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards.
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l
For the EPL services supported by Ethernet transparent transmission boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet transparent transmission boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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4 Configuring Ethernet Services
Procedure Step 1 Configure the EPL services of user A1 and user B1 on NE1. 1.
Set the attributes of the external ports (PORT1 of 3-EGT1 board and PORT1 of the 4-EGT1 board) used by the services of user A1 and user B1. l In the NE Explorer, select the EGT1 and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply.
2.
Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
PORT1 is used by the service of user A1. PORT2 is used by the service of user B1. In this example, Enabled/Disabled is set to Enabled for PORT1 and PORT2.
Workin g Mode
PORT1: AutoNegotiation
In this example, the Ethernet service access equipment of user A1 and user B1 supports the auto-negotiation mode. Hence, Working Mode is set to Auto-Negotiation for PORT1 and PORT2.
Maximu m Frame Length
PORT1: 1522
Generally, this parameter adopts the default value 1522.
MAC Loopba ck
PORT1: Non-Loopback
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback.
PHY Loopba ck
PORT1: Non-Loopback
The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
Set the attributes of the internal ports (VCTRUNK1 of 3-EGT1 board and VCTRUNK1 of the 4-EGT1 board) used by the services of user A1 and user B1. l Select Internal Port. l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
In this example, the EFS8 board is used. This parameter adopts the default value GFP. Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
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Parame ter
Value in This Example
Description
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Check Field Length
VCTRUNK1: FCS32
In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Set Inverse Value for CRC
VCTRUNK1: -
When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l Click the Bound Path tab. Click the Configuration button. Set the following parameters in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
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User
Parameter
Value in This Example
Description
User A1← →user A2
Configurab le Ports
VCTRUN K1 (3EGT1)
As shown in Figure 4-23, VCTRUNK1 of the 3-EGT1 board is used by the service between user A1 and user A2.
Avai lable Bou nd Path s
VC12-xv
The service between user A1 and user A2 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards.
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User
Parameter
User B1← →user B2
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Value in This Example
Description
Ser vice Dir ecti on
Bidirection al
The service between user A1 and user A2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by the specific boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Av aila ble Ti mes lots
VC12-1 to VC12-5
Five VC-12s need to be bound for the service from user A1 to user A2. In this example, the first to the fifth VC-12 need to be selected in sequence.
Configurab le Ports
VCTRUN K1 (4EGT1)
As shown in Figure 4-23, VCTRUNK1 of the 4-EGT1 board is used by the service between user B1 and user B2.
Avai lable Bou nd Path s
VC12-xv
The service between user B1 and user B2 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vice Dir ecti on
Bidirection al
The service between user B1 and user B2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by the specific boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
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User
Parameter
Av aila ble Ti mes lots
3.
Value in This Example
Description
VC12-1 to VC12-10
Ten VC-12s need to be bound for the service from user B1 to user B2. In this example, the first to the tenth VC-12 need to be selected in sequence.
Configure the cross-connections from the Ethernet services to the SDH links for user A1 and user B1. l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User A1
Level
VC12
The timeslot bound with the service of user A1 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service of user A1 is a bidirectional service.
Source Slot 3-EGT1-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-5
The value range of the source timeslot is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-5.
Sink Slot
5-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
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User
User B1
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4 Configuring Ethernet Services
Paramete r
Value in This Example
Description
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslot can be the same as or different from the value range of the source timeslot. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
Activate Immediatel y
Yes
-
Level
VC12
The timeslot bound with the service of user B1 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service of user B1 is a bidirectional service.
Source Slot 4-EGT1-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-10
The value range of the source timeslot is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-10.
Sink Slot
5-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
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User
Paramete r
Value in This Example
Description
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
6-15
The value range of the sink timeslot can be the same as or different from the value range of the source timeslot. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are 10 VC-12s, the sink timeslots must be 10 VC-12s.
Activate Immediatel y
Yes
-
Step 2 Configure the pass-through services of user A1 and user B1 on NE2.
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. Select NE2 in the Navigation Tree that is displayed. Then, click OK.
1.
Click
2.
In the NE Explorer, select NE2 and then choose Configuration > SDH Service Configuration from the Function Tree.
3.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows. Parameter
Value in This Example
Description
Level
VC12
The SDH service of NE1, which passes through NE2, is at the VC-12 level.
Service Direction
Bidirectional
As shown in Figure 4-23, the SDH service from NE1 to NE2 is a bidirectional service.
Source Slot
5-SL4D-1 (SDH-1)
As shown in Figure 4-23, the service signals are transmitted from 5-SL4D-1(SDH-1) to 5-SL4D-2 (SDH-2). In this example, Source Slot is set to 5-SL4D-1 (SDH-1).
Source VC4
VC4-1
VC4-1 is allocated to the service from NE1 to NE2.
Source Timeslot Range(e.g. 1,3-6)
1-15
The service between user A1 and user B1 uses timeslots 1-15.
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Parameter
Value in This Example
Description
Sink Slot
5-SL4D-2 (SDH-2)
As shown in Figure 4-23, the service signals are transmitted from 5-SL4D-2(SDH-2) to 5-SL4D-1 (SDH-1). In this example, Sink Slot is set to 5-SL4D-2 (SDH-2).
Sink VC4
VC4-1
It is recommended that you set Sink Slot to be the same as Source Slot.
Sink Timeslot Range(e.g. 1,3-6)
1-15
The service between user A1 and user B1 uses timeslots 1-15.
Activate Immediatel y
Yes
-
Step 3 Configure the EPL services of user A2 and user B2 on NE3. Refer to Step 1 and configure the EPL services for users A2 and B2. Step 4 Check whether the service between user A1 and user A2 and the service between user B1 and user B2 are correct. For the operation procedure, see Testing Ethernet Service Channels. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see 5.4.3 Deleting Ethernet Private Line Services.
4.5 Configuring EPL Services on an Ethernet Switching Board EPL services provide the point-to-point Ethernet transparent transmission solution with the bandwidth exclusively occupied. EPL services are applicable when the communication equipment that is used to access the client-side data in the transmission network does not support VLANs or when the VLAN planning must be kept secret to the network operator. 4.5.1 Networking Diagram The completely isolated data services of two users at a station must be transported to another station. 4.5.2 Signal Flow and Timeslot Allocation Issue 02 (2011-06-30)
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Ethernet services are received from an external port, encapsulated through an internal port, and mapped to the SDH network for transparent transmission. In this way, the node communicates with a remote node. 4.5.3 Configuration Process This topic describes the process of configuring Ethernet private line services for Ethernet switching boards. 4.5.4 Configuration Process (End-to-End Mode) During the configuration of EPL services on Ethernet switching boards, you need to configure Ethernet private line services. This topic describes the process of configuring EPL services for Ethernet switching boards in end-to-end mode.
4.5.1 Networking Diagram The completely isolated data services of two users at a station must be transported to another station.
Service Requirement In the network as shown in Figure 4-24, the service requirements are as follows: l
The two branches of user A that are located at NE1 and NE3 need to communicate with each other over Ethernet. A 10 Mbit/s bandwidth is required.
l
The two branches of user B that are located at NE1 and NE3 need to communicate with each other over Ethernet. A 20 Mbit/s bandwidth is required.
l
The services of user A must be isolated from the services of user B.
l
The Ethernet equipment of user A and user B provides 100 Mbit/s Ethernet ports of which the working mode is auto-negotiation, and does not support VLANs.
Figure 4-24 Networking diagram of the EPL services User A2
User B2
PORT1
PORT2
NE3: Ethernet board Line board
NM
4-EFS8
6-SL4D-2
6-SL4D-1
NE3
6-SL4D-1 NE2
NE4
6-SL4D-2 NE2: Line board
Line board
6-SL4D-1
6-SL4D-2
6-SL4D-1
NE1 NE1: Ethernet board Line board
PORT1
PORT2
4-EFS8
6-SL4D-2
VCTRUNK
User A1
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User B1
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4 Configuring Ethernet Services
Board Configuration Information Ethernet transparent transmission boards or Ethernet switching boards can be used to configure EPL services. The Ethernet switching processing board is displayed as the EFS8 on the U2000, which occupies logical slot 4. In this example, NE1 and NE3 each are configured with one EFS8 board, which is an Ethernet switching board.
4.5.2 Signal Flow and Timeslot Allocation Ethernet services are received from an external port, encapsulated through an internal port, and mapped to the SDH network for transparent transmission. In this way, the node communicates with a remote node. Figure 4-25 shows the signal flow and timeslot allocation of the EPL services. For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-25 Signal flow and timeslot allocation (Ethernet switching board) NE1:EFS8 PORT1 User A1 PORT2 User B1
NE2
NE3 :EFS8
VCTRUNK1 VC4-4:VC12:1-5
VCTRUNK1 VC4-4:VC12:1-5
VC4-1:VC12:1-5
VCTRUNK2
VCTRUNK2
VC4-4:VC12:6-15
VC4-4:VC12:6-15
VC4-1:VC12:6-15
PORT1 User A2 PORT2 User B2
SDH
l
The EPL services of user A: – Occupy the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link between NE1 and NE3 and pass through NE2. – Are added and dropped by using the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EFS8 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EFS8 board of NE3.
l
The EPL services of user B: – Occupy the sixth to fifteenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:6-15) on the SDH link between NE1 and NE3 and pass through NE2. – Are added and dropped by using the sixth to fifteenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:6-15) on the EFS8 board of NE1 and the sixth to fifteenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:6-15) on the EFS8 board of NE3.
Table 4-14 Parameters of external ports on the Ethernet boards
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Parameter
NE1
NE3
Board
EFS8
EFS8
Port
PORT1
PORT2
PORT1
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Parameter
NE1
NE3
Enabled/ Disabled
Enabled
Enabled
Enabled
Enabled
Working Mode
AutoNegotiation
AutoNegotiation
AutoNegotiation
AutoNegotiation
Maximum Frame Length
1522
1522
1522
1522
Table 4-15 Parameters of internal ports on the Ethernet boards Parameter
NE1
NE3
Board
EFS8
EFS8
Internal Port
VCTRUNK1
VCTRUNK2
VCTRUNK1
VCTRUNK2
Mapping Protocol
GFP
GFP
GFP
GFP
Bound Path
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-6 -VC12-15
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-6 -VC12-15
Entry Detection
Disabled
Disabled
Disabled
Disabled
Port Type
UNI
UNI
UNI
UNI
Table 4-16 Parameters of the EPL services Parameter
EPL Services of User A
Board
EFS8
Service Type
EPL
Service Direction
Bidirectional
Source Port
PORT1
PORT2
Source C-VLAN (e.g. 1,3-6)
Null
Null
Sink Port
VCTRUNK1
VCTRUNK2
Sink C-VLAN (e.g. 1,3-6)
Null
Null
EPL Services of User B
4.5.3 Configuration Process This topic describes the process of configuring Ethernet private line services for Ethernet switching boards. 4-46
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Prerequisite You must be familiar with 4.3.1 Flow of Configuring EPL Services.
Background Information If the Ethernet switching boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
For the EPL services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EPL services for users A1 and B1 on NE1. 1.
Set the attributes of the external ports (PORT1 and PORT2 on the EFS8 board) used by the services of users A1 and B1. l In the NE Explorer, select the EFS8 and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
PORT1 is used by the service of user A1. PORT2 is used by the service of user B1. In this example, Enabled/Disabled is set to Enabled for PORT1 and PORT2.
Workin g Mode
PORT1: AutoNegotiation
PORT2: Enabled
PORT2: AutoNegotiation
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Maximu m Frame Length
PORT1: 1522
MAC Loopba ck
PORT1: Non-Loopback
PHY Loopba ck
PORT1: Non-Loopback
PORT2: 1522
PORT2: Non-Loopback
PORT2: Non-Loopback
In this example, the Ethernet service access equipment of user A1 and user B1 supports the auto-negotiation mode. Hence, Working Mode is set to Auto-Negotiation for PORT1 and PORT2. Generally, this parameter adopts the default value 1522.
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback. The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
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l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
TAG
PORT1: Access
The access equipment of user A1 and user B1 does not support the VLAN. Hence, the access equipment transmits only the packet without the VLAN tag. In this example, it is recommended that you set the TAG flags at PORT1 and PORT2 to Access.
PORT2: Access
Default VLAN ID
PORT1: 1
VLAN Priority
PORT1: 0
Entry Detectio n
PORT1: Disabled
PORT2: 1
PORT2: 0
PORT2: Disabled
The services of user A1 and user B1 exclusively occupy the PORTs and VCTRUNKs. Hence, the VLAN ID is not required for isolating the services. In this example, Default VLAN ID adopts the default value. Both the VLAN ID and VLAN priority are unnecessary for users A1 and B1. In this example, VLAN Priority adopts the default value. The services of user A1 and user B1 are EPL transparent transmission services. Hence, you need not enable the entry detection function to check the VLAN tags of the packets. In this example, Entry Detection need to be set to Disabled. When Entry Detection is set to Disabled, the parameters of TAG, Default VLAN ID, and VLAN Priority are invalid.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal ports (VCTRUNK1 and VCTRUNK2 of the EFS8 board) used by the services of user A1 and user B1. l Select Internal Port. l Click the TAG Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Entry Detectio n
VCTRUNK1: Disabled
The services of user A1 and user B1 are EPL transparent transmission services. Hence, you need not enable the entry detection function to check the VLAN tags of the packets. In this example, Entry Detection need to be set to Disabled. When Entry Detection is set to Disabled, the parameters of TAG, Default VLAN ID, and VLAN Priority are invalid.
VCTRUNK2: Disabled
l Click the Network Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Port Attribut es
VCTRUNK1: UNI
UNI indicates the user-network interface, namely, the interface of the service provider located near the user side. The UNI interface processes the tag attribute of IEEE 802.1Qcompliant packets. That is, the UNI interface processes and identifies the VLAN information of the accessed user packets, according to the supported tag flag, namely, Tag Aware, Access, and Hybrid.
VCTRUNK1: UNI
l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
In this example, the EFS8 board is used. This parameter adopts the default value GFP. Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
VCTRUNK2: GFP
VCTRUNK2: Scrambling mode [X43 +1] Check Field Length
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VCTRUNK1: FCS32 VCTRUNK2: FCS32
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
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Parame ter
Value in This Example
Description
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Set Inverse Value for CRC
VCTRUNK1: -
VCTRUNK2: Big endian
VCTRUNK2: -
When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l Click the Bound Path tab. Click the Configuration button. Set the following in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
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User
Paramete r
Value in This Example
Description
User A1← →user A2
Configura ble Ports
VCTRUN K1
As shown in Figure 4-25, VCTRUNK1 is used by the service between user A1 and user A2.
Ava ilab le Bou nd Pat hs
VC12-xv
The service between user A1 and user A2 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
Bidirectio nal
The service between user A1 and user A2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
The fourth VC-4 of the EFS8 board can be bound with VC-12s. In this example, Available Resources is set to VC4-4. For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
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User
Paramete r
User B1← →user B2
3.
4 Configuring Ethernet Services
Value in This Example
Description
Av aila ble Ti me slot s
VC12-1 to VC12-5
Five VC-12s need to be bound for the service from user A1 to user A2. In this example, the first to the fifth VC-12s need to be selected in sequence.
Configura ble Ports
VCTRUN K2
As shown in Figure 4-25, VCTRUNK2 is used by the service between user B1 and user B2.
Ava ilab le Bou nd Pat hs
VC12-xv
The service between user B1 and user B2 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
Bidirectio nal
The service between user B1 and user B2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
The fourth VC-4 of the EFS8 board can be bound with VC-12s. In this example, Available Resources is set to VC4-4.
Av aila ble Ti me slot s
VC12-6 to VC12-15
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards. Ten VC-12s need to be bound for the service from user B1 to user B2. In this example, the sixth to the fifteenth VC-12s need to be selected in sequence.
Configure the Ethernet private line services for user A1 and user B1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Service > Ethernet Line Service from the Function Tree. l Click New on the lower-right pane to display the Create Ethernet Line Service dialog box. Set the following parameters, and then click OK. The Operation Result dialog box is displayed, indicating that the operation is successful. Click Close.
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User
Parameter
Value in This Example
Description
User A1
Service Type
EPL
The service of user A1 is an EPL service.
Service Direction
Bidirection al
The service of user A1 is a bidirectional service.
Source Port
PORT1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. In this example, the service of user A1 occupies PORT1.
Source CVLAN (e.g. 1, 3-6)
Blank
In this example, the EPL service does not carry the VLAN tag.
Sink Port
VCTRUN K1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. In this example, the service of user A1 occupies VCTRUNK1.
Sink CVLAN (e.g. 1, 3-6)
Blank
In this example, the EPL service does not carry the VLAN tag.
Service Type
EPL
The service of user B1 is an EPL service.
Service Direction
Bidirection al
The service of user B1 is a bidirectional service.
Source Port
PORT2
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. In this example, the service of user B1 occupies PORT2.
Source CVLAN (e.g. 1, 3-6)
Blank
In this example, the EPL service does not carry the VLAN tag.
Sink Port
VCTRUN K2
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. In this example, the service of user B1 occupies VCTRUNK2.
Sink CVLAN (e.g. 1, 3-6)
Blank
In this example, the EPL service does not carry the VLAN tag.
User B1
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4 Configuring Ethernet Services
Configure the cross-connections from the Ethernet services to the SDH links for user A1 and user B1. l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User A1
Level
VC12
The timeslot bound with the service of user A1 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service of user A1 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-5
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-5.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
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User
User B1
4-54
Paramete r
Value in This Example
Description
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
Activate Immediatel y
Yes
-
Level
VC12
The timeslot bound with the service of user B1 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service of user B1 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
6-15
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK2. In this example, the value range of Available Timeslots is from VC12-6 to VC12-15.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
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4 Configuring Ethernet Services
Paramete r
Value in This Example
Description
Sink Timeslot Range(e.g. 1,3-6)
6-15
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are 10 VC-12s, the sink timeslots must be 10 VC-12s.
Activate Immediatel y
Yes
-
Step 2 Configure the EPL services for users A1 and B1 on NE2. 1.
Click
2.
In the NE Explorer, select NE2, and then choose Configuration > SDH Service Configuration from the Function Tree.
3.
Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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. Select NE2 in the Navigation Tree that is displayed. Then, click OK.
Parameter
Value in This Example
Description
Level
VC12
The SDH service of NE1, which passes through NE2, is at the VC-12 level.
Service Direction
Bidirectional
As shown in Figure 4-25, the SDH service from NE1 to NE2 is a bidirectional service.
Source Slot
6-SL4D-1 (SDH-1)
As shown in Figure 4-25, the service signals are transmitted from 6-SL4D-1(SDH-1) to 6-SL4D-2 (SDH-2). In this example, Source Slot is set to 6-SL4D-1 (SDH-1).
Source VC4
VC4-1
VC4-1 is allocated to the service from NE1 to NE2.
Source Timeslot Range(e.g. 1,3-6)
1-15
The service between user A1 and user B1 uses timeslots 1-15.
Sink Slot
6-SL4D-2 (SDH-2)
As shown in Figure 4-25, the service signals are transmitted from 6-SL4D-1(SDH-1) to 6-SL4D-2 (SDH-2). In this example, Sink Slot is set to 6-SL4D-2 (SDH-2).
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Parameter
Value in This Example
Description
Sink VC4
VC4-1
It is recommended that you set Sink Slot to be the same as Source Slot.
Sink Timeslot Range(e.g. 1,3-6)
1-15
The service between user A1 and user B1 uses timeslots 1-15.
Activate Immediatel y
Yes
-
Step 3 Configure the EPL services for users A2 and B3 on NE3. Refer to Step 1 and configure the EPL services for users A2 and B2. The parameter values of user A2 and user B2 must be consistent with the parameter values of user A1 and user B1. Step 4 Check whether the service between user A1 and user A2 and the service between user B1 and user B2 are correct. For the operation procedure, see Testing Ethernet Service Channels. Step 5 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 6 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see 5.4.3 Deleting Ethernet Private Line Services.
4.5.4 Configuration Process (End-to-End Mode) During the configuration of EPL services on Ethernet switching boards, you need to configure Ethernet private line services. This topic describes the process of configuring EPL services for Ethernet switching boards in end-to-end mode.
Prerequisite You must understand the information provided in 4.5.2 Signal Flow and Timeslot Allocation.
Background Information If in the actual application you use an Ethernet switching board different from the one described in this example, learn about the requirements for configuring that specific as follows: 4-56
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l
For the EPL services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of the Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EPL services between user A1 and user A2 in end-to-end mode. 1.
Create a VC-4 server trail. l Choose Service > SDH Trail > Create SDH Trail from the Main Menu and set parameters for the VC-4 server trail. Table 4-17 Parameters of the VC-4 server trail between user A1 and user A2 Parameter
Value in This Example
Direction
Bidirectional
Level
VC4 Server Trail
Service Domain
SDH&RTN
Resource Usage Strategy
Protected Resource
Protection Priority Strategy
Trail Protection First
l Double-click NE1 (source) and NE3 (sink) on the main topology to configure the source and sink of the VC-4 server trail. l In the Trail Settings tab, configure Explicit Node and Set Route Timeslot. Table 4-18 Parameters of the VC-4 server trail route between user A1 and user A2 Parameter Explicit Node
Value in This Example NE
NE2 NOTE Right-click and choose Add from the shortcut menu. In the Add Explicit Node dialog box that is displayed, select NE2.
Set Route Timeslot
Timeslot
1 NOTE Click Set Route Timeslot. In the Set Route Timeslot dialog box that is displayed, set the VC-4 server trail from NE1 to NE3 to VC4-1.
Other parameters
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l Click Apply. The Operation Result dialog box is displayed indicating that the operation is successful. Click Close or Browse Trail to query the created VC-4 server trail. 2.
Create a trunk link. l Choose Service > MSTP Trail > Create Trunk Link from the Main Menu. l Set Bandwidth to 5 X: VC12. Select Auto Create Server Trails. NOTE
If you do not select Auto Create Server Trails, refer to Step 1.1 to create cross-connections of Ethernet services between NE1 and NE3 to SDH links. Set Level to VC12. Set Server Layer Trail to the created link when creating trunk links.
l Configure bound timeslots for the source NE. Click Browse. In the dialog box that is displayed, select NE1 and set NE Panel to EFS8, VCTRUNK Port to 1, and Lower Order to VC4:4-VC12:1 to VC4:4-VC12:5. Click OK. l Configure bound timeslots for the sink NE. Click Browse and select NE3. Set NE Panel to EFS8, VCTRUNK Port to 1, and Lower Order to VC4:4-VC12:1 to VC4:4VC12:5. Click OK. l Select Activate the trail and click Apply. 3.
Create EPL services. l Choose Service > MSTP Trail > Create EPL from the Main Menu. l Double-click NE1 (source) and NE3 (sink) on the main topology to configure the source and sink of the EPL services. Table 4-19 Parameters of the EPL services between user A1 and user A2 Parameter Source
Sink
Value in This Example Port Usage Strategy
Port
Port
NE1-4-EFS8-PORT1
Port Usage Strategy
Port
Port
NE3-4-EFS8-PORT1
l Set trunk link routing policies using the existing trunk link. Select the trunk link created in step 1 b. Click Next. NOTE
l To create EPL services in end-to-end mode, complete the following recommended steps: first create a server trail, then create a trunk link, and finally create EPL services. When creating EPL services, select Use Existing Trunk Link. l Alternatively, create the trunk link when creating the EPL services. In this case, select Create Trunk Link Manually or Create Trunk Link Automatically.
l In the Port Attribute Setting dialog box, set port attributes.
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Table 4-20 Parameters of port attributes for user A1 and user A2 Parameter Source NE
Sink NE
Value in This Example PORT1
Entry Detection
Disabled
VCTRUNK1
Entry Detection
Disabled
PORT1
Entry detection
Disabled
VCTRUNK1
Entry Detection
Disabled
Other parameters
Default values
l Select Activate the trail and click Finish. Step 2 Repeat Step 1.2 to Step 1.3 configure EPL services between user B1 and user B2 according to service planning. Step 3 Check whether the services between user A1 and user A2 and the services between user B1 and user B2 are proper. For details, see Testing Ethernet Service Channels. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Related Task If the services are configured incorrectly, see 5.4.3 Deleting Ethernet Private Line Services for the deletion method.
4.6 Configuring PORT-Shared EVPL (VLAN) Services The PORT-shared EVPL (VLAN) service is applicable when the services of multiple users received from the same external port on the Ethernet board at a station are transmitted on different VCTRUNKs to another station or to another external port of the station. 4.6.1 Networking Diagram The services of multiple users received from the same external port on an Ethernet board of a station are transmitted to different stations on different VCTRUNKs. 4.6.2 Signal Flow and Timeslot Allocation Ethernet services wherein different VLAN IDs are used to isolate the data of different users are received from the same external port of NE1, encapsulated through an internal port, and transparently transmitted on the SDH network. In this way, the node communicates with a remote node. 4.6.3 Configuration Process Ethernet switching boards are required for creating EVPL services of different VLAN IDs on NE1. In this way, the data of different users received from the same external port can be Issue 02 (2011-06-30)
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differentiated. Ethernet transparent transmission boards are required for creating EPL transparent transmission services on NE2 and NE4.
4.6.1 Networking Diagram The services of multiple users received from the same external port on an Ethernet board of a station are transmitted to different stations on different VCTRUNKs.
Service Requirement In the network as shown in Figure 4-26, the service requirements are as follows: l
The headquarters C1 of user C is located at NE1. Two branches (C2 and C3) of user C are located at NE2 and NE4. The services between C1 and C2 are transmitted in the VLAN of which the VLAN ID is 100. The services between C1 and C3 are transmitted in the VLAN of which the VLAN ID is 200.
l
The services of C2 are isolated from the services of C3. The services of C2 and C3 require a 20 Mbit/s bandwidth respectively.
l
The Ethernet equipment of C1, C2, and C3 provides 100 Mbit/s Ethernet electrical interfaces that work in auto-negotiation mode. The Ethernet equipment of C1 supports VLANs, but the Ethernet equipment of C2 and C3 does not support VLANs. – The VLAN ID used by the Ethernet services between C1 and C2 is 100. – The VLAN ID used by the Ethernet services between C1 and C3 is 200.
Figure 4-26 Networking diagram for configuring PORT-shared EVPL (VLAN) services
NM NE2: Ethernet board Line board
NE4: Line board Ethernet board
NE3
6-SL4D-2
4-EGT1
6-SL4D-1
NE2
NE4
PORT1 User C2
4-EGT1
PORT1
6-SL4D-2
User C3
6-SL4D-1 NE1
6-SL4D-2
6-SL4D-1 VLAN 100 VLAN 200
VCTRUNK
PORT1
NE1: Ethernet board Line board 4-EFS8
6-SL4D-1
Line board 6-SL4D-2
User C1
Board Configuration Information In this example, NE1 is configured with an EFS8 board. VLAN IDs are used to isolate the data of different users received from the same port. NE2 and NE4 are each configured with an EGT1 4-60
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board. The EPL services are configured to implement service transparent transmission from NE2 and NE4 to NE1. In this example, NE1 is configured with an EFS8 board. NE2 and NE4 are each configured with an EGT1 board.
4.6.2 Signal Flow and Timeslot Allocation Ethernet services wherein different VLAN IDs are used to isolate the data of different users are received from the same external port of NE1, encapsulated through an internal port, and transparently transmitted on the SDH network. In this way, the node communicates with a remote node. Figure 4-27 shows the signal flow of the PORT-shared EVPL (VLAN) services and the timeslot allocation to the PORT-shared EVPL (VLAN) services . For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-27 Signal flow and timeslot allocation NE2:EGT1 NE1:EFS8
PORT1 User C1
EVPL1 EVPL2
C1 2 -1:V VC4
0 :1-1
VCTRUNK1
EPL
VC4-4:VC12:1-10
PORT1 User C2
VCTRUNK1 VC4-4:VC12:1-10 VCTRUNK2 VC4-4:VC12:11-20
VC 4-1
: VC 12
NE4:EGT1 :11
0
VCTRUNK1 VC4-4:VC12:1-10
EPL
PORT1 User C3
SDH
l
The EVPL service from C1 to C2: – Occupies the first to tenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-10) on the SDH link from NE1 to NE2. – Is added and dropped by using the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the EFS8 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the EGT1 board of NE2.
l
The EVPL service from C1 to C3: – Occupies the first to tenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-10) on the SDH link from NE1 to NE4. – Is added and dropped by the using the eleventh to twentieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:11-20) on the EFS8 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the EGT1 board of NE4.
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Table 4-21 Parameters of external ports on the Ethernet boards Parameter
NE1
NE2
NE4
Board
EFS8
EGT1
EGT1
Port
PORT1
PORT1
PORT1
Enabled/Disabled
Enabled
Enabled
Enabled
Working Mode
Auto-Negotiation
Auto-Negotiation
Auto-Negotiation
Maximum Frame Length
1522
1522
1522
TAG
Tag Aware
-
-
Table 4-22 Parameters of internal ports on the Ethernet boards Parameter
NE1
NE2
NE4
Board
EFS8
EGT1
EGT1
Port
VCTRUNK1
VCTRUNK2
VCTRUNK1
VCTRUNK1
Mapping Protocol
GFP
GFP
GFP
GFP
TAG
Access
Access
-
-
Entry Detection
Enabled
Enabled
-
-
Default VLAN ID
100
200
-
-
VLAN Priority
0
0
-
-
Bound Path
VC4-4:VC12-1 to VC12-10
VC4-4:VC12-1 1 to VC12-20
VC4-4:VC12-1 to VC12-10
VC4-4:VC12-1 to VC12-10
Port Type
UNI
UNI
-
-
Table 4-23 Parameters of the PORT-shared EVPL (VLAN) services Parameter
4-62
NE1 EVPL1
EVPL2
(PORT1←→ VCTRUNK1)
(PORT1←→VCTRUNK2)
Board
EFS8
Service Type
EVPL
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NE1 EVPL1
EVPL2
(PORT1←→ VCTRUNK1)
(PORT1←→VCTRUNK2)
Service Direction
Bidirectional
Source Port
PORT1
PORT1
Source C-VLAN (e.g. 1,3-6)
100
200
Sink Port
VCTRUNK1
VCTRUNK2
Sink C-VLAN (e.g. 1,3-6)
100
200
4.6.3 Configuration Process Ethernet switching boards are required for creating EVPL services of different VLAN IDs on NE1. In this way, the data of different users received from the same external port can be differentiated. Ethernet transparent transmission boards are required for creating EPL transparent transmission services on NE2 and NE4.
Prerequisite You must be familiar with 4.3.2 Flow of Configuring EVPL Services.
Background Information If the Ethernet boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
For the EVPL services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EVPL services for user C1 on NE1. 1.
Set the attributes of the external port (PORT1 of the EFS8 board) used by the service of user C1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
The service of user C1 occupies PORT1. In this example, Enabled/Disabled is set to Enable.
Workin g Mode
PORT1: AutoNegotiation
The Ethernet service access equipment of user C1 supports the auto-negotiation mode. In this example, Working Mode is set to Auto-Negotiation.
Maximu m Frame Length
PORT1: 1522
Generally, this parameter adopts the default value 1522.
MAC Loopba ck
PORT1: Non-Loopback
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback.
PHY Loopba ck
PORT1: Non-Loopback
The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the TAG Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
TAG
PORT1: Tag Aware
When the port is set to Tag Aware, all data frames transmitted and received at the port must have VLAN tags. In this example, TAG is set to Tag Aware.
Default VLAN ID
-
When TAG is set to Tag Aware, you need not set Default VLAN ID.
VLAN Priority
-
When TAG is set to Tag Aware, you need not set VLAN Priority.
Entry Detectio n
PORT1: Enabled
The equipment of user C1 supports VLANs. Hence, the entry detection function must be enabled to check the VLAN tag. In this way, the user data frames with different VLAN tags can be distinguished at one port. In this example, Entry Detection of PORT1 is set to Enabled.
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l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal ports (VCTRUNK1 and VCTRUNK2 of the EFS8 board) used by the services between user C1 and user C2 and between user C1 and user C3. l Select Internal Port. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
TAG
VCTRUNK1: Access
This parameter is set to Access if the Ethernet equipment of users C2 and C3 does not support VLANs and if the transmitted packets do not carry VLAN tags.
VCTRUNK2: Access
Default VLAN ID
VCTRUNK1: 100 VCTRUNK2: 200
According to the plan, the VLAN ID is set to 100 on the transmission network side for Ethernet services between user C1 and user C2. The VLAN ID is set to 200 on the transmission network side for Ethernet services between user C1 and user C3.
VLAN Priority
VCTRUNK1: 0
Entry Detectio n
VCTRUNK1: Enabled
VCTRUNK2: 0
VCTRUNK2: Enabled
In this example, this parameter adopts the default value. VCTRUNK1 is used by the service between user C1 and user C2. VCTRUNK2 is used by the service between user C1 and user C3. Then, you need to enable the entry detection function to detect the VLAN tags of the received packets.
l Click the Network Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Port Attribut es
VCTRUNK1: UNI
UNI indicates the user-network interface, namely, the interface of the service provider located near the user side. The UNI interface processes the tag attribute of IEEE 802.1Qcompliant packets. That is, the UNI interface processes and identifies the VLAN information of the accessed user packets, according to the supported tag flag, namely, Tag Aware, Access, and Hybrid.
VCTRUNK2: UNI
l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
VCTRUNK2: GFP
In this example, this parameter adopts the default value Scrambling mode [X43+1].
VCTRUNK2: Scrambling mode [X43 +1] Check Field Length
VCTRUNK1: FCS32
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
Set Inverse Value for CRC
VCTRUNK1: No
VCTRUNK2: FCS32
VCTRUNK2: Big endian
VCTRUNK2: No
In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l Click the Bound Path tab. Click the Configuration button. Set the following parameters in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
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User
Paramete r
Value in This Example
Description
User C1 ←→ user C2
Configurab le Ports
VCTRUN K1
As shown in Figure 4-27, VCTRUNK1 is used by the service between user C1 and user C2.
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User
User C1 ←→ user C3
Paramete r
Value in This Example
Description
Avai lable Bou nd Path s
VC12-xv
The service between user C1 and user C2 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
Bidirectio nal
The service between user C1 and user C2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
Select VC4-4.
Av aila ble Ti me slot s
VC12-1 to VC12-10
Ten VC-12s need to be bound. In this example, the first to the tenth VC-12s need to be selected in sequence.
Configurab le Ports
VCTRUN K2
As shown in Figure 4-27, VCTRUNK2 is used by the service between user C1 and user C3.
Avai lable Bou nd Path s
VC12-xv
The service between user C1 and user C3 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Lev el
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
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Bidirectio nal
The service between user C1 and user C3 is a bidirectional service.
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User
3.
Paramete r
Value in This Example
Description
Av aila ble Res our ces
VC4-4
Select VC4-4.
Av aila ble Ti me slot s
VC12-11 to VC12-20
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Ten VC-12s need to be bound. In this example, the eleventh to the twentieth VC-12s need to be selected in sequence.
Configure the Ethernet private line services between user C1 and user C2 and between user C1 and user C3. l In the NE Explorer, select the EFS8 board and then choose Configuration > Ethernet Service > Ethernet Line Service from the Function Tree. l Click New on the lower-right pane to display the Create Ethernet Line Service window. Set the following parameters and then click OK. The Operation Result dialog box is displayed, indicating that the operation is successful. Click Close.
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User
Parameter
Value in This Example
Description
User C1 ←→user C2
Service Type
EPL
The service between user C1 and C2 is a pointto-point Ethernet private line service.
Service Direction
Bidirection al
The service between user C1 and user C2 is a bidirectional service.
Source Port
PORT1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. PORT1 is the external port used by the service between user C1 and user C2.
Source CVLAN (e.g. 1, 3-6)
100
According to the plan, the VLAN ID is set to 100 for the Ethernet service between user C1 and user C2.
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User
User C1 ←→user C3
4.
4 Configuring Ethernet Services
Parameter
Value in This Example
Description
Sink Port
VCTRUN K1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. VCTRUNK1 is the internal port used by the service between user C1 and user C2.
Sink CVLAN (e.g. 1, 3-6)
100
According to the plan, the VLAN ID is set to 100 for the Ethernet service between user C1 and user C2.
Service Type
EPL
The service between user C1 and C3 is a pointto-point Ethernet private line service.
Service Direction
Bidirection al
The service between user C1 and user C3 is a bidirectional service.
Source Port
PORT1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. PORT1 is the external port used by the service between user C1 and user C3.
Source CVLAN (e.g. 1, 3-6)
200
According to the plan, the VLAN ID is set to 200 for the Ethernet service between user C1 and user C3.
Sink Port
VCTRUN K2
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. VCTRUNK2 is the internal port used by the service between user C1 and user C2.
Sink CVLAN (e.g. 1, 3-6)
200
According to the plan, the VLAN ID is set to 200 for the Ethernet service between user C1 and user C3.
Configure the cross-connections from the Ethernet service between user C1 and user C2 to the SDH link and the Ethernet service between user C1 and user C3 to the SDH link. l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User C1 ←→ user C2
Level
VC12
The timeslots bound with the service between user C1 and user C2 is at the VC-12 level. The service level must be consistent with the level of the paths bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service between user C1 and user C2 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In this example, Source VC4 is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-10
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-10.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-10
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are ten VC-12s, the sink timeslots must be ten VC-12s.
Activate Immediatel y
Yes
-
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User
Paramete r
Value in This Example
Description
User C1 ←→ user C3
Level
VC12
The timeslots bound with the service between user C1 and user C3 is at the VC-12 level. The service level must be consistent with the level of the paths bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service between user C1 and user C3 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In this example, Source VC4 is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
11-20
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK2. In this example, the value range of Available Timeslots is from VC12-11 to VC12-20.
Sink Slot
6-SL4D-2 (SDH-2)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-10
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are ten VC-12s, the sink timeslots must be ten VC-12s.
Activate Immediatel y
Yes
-
Step 2 Configure the EPL services on NE2 and NE4. Issue 02 (2011-06-30)
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OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide
NOTE
The Ethernet services of NE2 and NE4 are point-to-point transparent transmission services. See 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board to set the parameters.
Step 3 Check whether the services are configured correctly. For the operation procedures, see Testing Ethernet Service Channels. l Before testing the service connectivity between headquarters C1 and branch C2, set TAG of PORT1 on the EFS8 board to Access and Default VLAN ID to 100. l Before testing the service connectivity between headquarters C1 and branch C3, set TAG of PORT1 on the EFS8 board to Access and Default VLAN ID to 200. NOTE
After the test, change the modified parameter values to the values specified in the service configuration.
Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see 5.4.3 Deleting Ethernet Private Line Services.
4.7 Configuring VCTRUNK-Shared EVPL (VLAN) Services When the data of multiple users without VLAN tags sent to a transmission network is transmitted on the same VCTRUNK, the VCTRUNK-shared EVPL (VLAN) service is used to isolate the data by adding VLAN tags. In this way, the bandwidth is shared on the SDH side. 4.7.1 Networking Diagram The data of multiple Ethernet users received from the same station is transmitted on the same VCTRUNK and isolated by using different VLAN IDs. In this way, the bandwidth is shared on the SDH side. 4.7.2 Signal Flow and Timeslot Allocation The services of multiple users that are received from different external ports on an Ethernet board are tagged with different VLAN IDs and then transmitted on the same VCTRUNK. In this way, the data of different users is isolated. After the data arrives at the sink node, the VLAN tags are stripped. 4.7.3 Configuration Process Ethernet switching boards are required on both the source and sink nodes for creating EVPL services of different VLAN IDs. In this way, the packets received from different external ports are added with different VLAN tags. As a result, the packets are isolated when they are transmitted on the same VCTRUNK.
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4.7.1 Networking Diagram The data of multiple Ethernet users received from the same station is transmitted on the same VCTRUNK and isolated by using different VLAN IDs. In this way, the bandwidth is shared on the SDH side.
Service Requirement In the network as shown in Figure 4-28, the service requirements are as follows: l
Two branches of user D are located at NE1 and NE2, and need to communicate with each other.
l
Two branches of user E are located at NE1 and NE2, and need to communicate with each other.
l
The services of user D need to be isolated from the services of user E. The traffic of user D and user E, however, are complementary in terms of time and can share a 20 Mbit/s bandwidth.
l
The Ethernet equipment of user D and user E provides 100 Mbit/s Ethernet ports of which the working mode is auto-negotiation, and does not support VLAN tags.
Figure 4-28 Networking diagram for configuring VCTRUNK-shared EVPL (VLAN) services
NM NE2:
Ethernet Board 4-EFS8
PORT1
User D2
NE3
Line Board 6-SL4D NE2
PORT2
NE4
6 NE1
User E2
PORT1
6
PORT2
User E1
NE1: VCTRUNK User D1
Ethernet Board 4-EFS8
Line Board 6-SL4D
Board Configuration Information The Ethernet switching boards that support EVPL services are provided in Table 6-1. In this example, NE1 and NE2 each are configured with an EFS8 board. Different VLAN IDs are used to isolate the data of different users transmitted on the same VCTRUNK. l
When the data of user D arrives at the transmission network, the VLAN ID of 100 is added to the data. When the data leaves the transmission network, the VLAN tag is stripped.
l
When the data of user E arrives at the transmission network, the VLAN ID of 200 is added to the data. When the data leaves the transmission network, the VLAN tag is stripped.
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4.7.2 Signal Flow and Timeslot Allocation The services of multiple users that are received from different external ports on an Ethernet board are tagged with different VLAN IDs and then transmitted on the same VCTRUNK. In this way, the data of different users is isolated. After the data arrives at the sink node, the VLAN tags are stripped. Figure 4-29 shows the signal flow of the VCTRUNK-shared EVPL (VLAN) services and the timeslot allocation to the VCTRUNK-shared EVPL (VLAN) services. For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-29 Signal flow and timeslot allocation NE2:EFS8
NE1:EFS8 PORT1 User D1
EVPL1
PORT2 User E1
EVPL2
VC4-4:VC12:1-10
EVPL1
PORT1 User D2
EVPL2
PORT2 User E2
VCTRUNK1
VCTRUNK1 VC4-1:VC12:1-10
VC4-4:VC12:1-10
SDH
l
The EVPL services of user D and user E that share VCTRUNK1 occupy the first to tenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-10) on the SDH link from NE1 to NE2.
l
The services are added and dropped by using the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-1:VC12:1-10) on the EFS8 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-1:VC12:1-10) on the EFS8 board of NE2.
Table 4-24 Parameters of external ports on the Ethernet boards
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Parameter
NE1
NE2
Board
EFS8
EFS8
Port
PORT1
PORT2
PORT1
PORT2
Enabled/ Disabled
Enabled
Enabled
Enabled
Enabled
Working Mode
AutoNegotiation
AutoNegotiation
AutoNegotiation
AutoNegotiation
Maximum Frame Length
1522
1522
1522
1522
TAG
Access
Access
Access
Access
Entry Detection
Enabled
Enabled
Enabled
Enabled
Default VLAN ID
100
200
100
200
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Parameter
NE1
VLAN Priority
0
4 Configuring Ethernet Services
NE2 0
0
0
Table 4-25 Parameters of internal ports on the Ethernet boards Parameter
NE1
NE2
Board
EFS8
EFS8
Port
VCTRUNK1
VCTRUNK1
Mapping Protocol
GFP
GFP
TAG
Tag Aware
Tag Aware
Entry Detection
Enabled
Enabled
Bound Path
VC4-4:VC12-1-VC12-10
VC4-4:VC12-1-VC12-10
Port Type
UNI
UNI
Table 4-26 Parameters of the VCTRUNK-shared EVPL (VLAN) services Parameter
NE1
NE2
EVPL1
EVPL2
EVPL1
EVPL2
PORT1←→ VCTRUNK1
PORT2←→ VCTRUNK1
PORT1←→ VCTRUNK1
PORT2←→ VCTRUNK1
Board
EFS8
EFS8
Service Type
EVPL
EVPL
Service Direction
Bidirectional
Bidirectional
Source Port
PORT1
PORT2
PORT1
PORT2
Source CVLAN (e.g. 1,3-6)
100
200
100
200
Sink Port
VCTRUNK1
VCTRUNK1
VCTRUNK1
VCTRUNK1
Sink C-VLAN (e.g. 1,3-6)
100
200
100
200
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are added with different VLAN tags. As a result, the packets are isolated when they are transmitted on the same VCTRUNK.
Prerequisite You must be familiar with 4.3.2 Flow of Configuring EVPL Services.
Background Information If the Ethernet boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
The Ethernet switching boards that support EVPL services are provided in 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EVPL services for users D1 and E1 on NE1. 1.
Set the attributes of the external ports (PORT1 and PORT2 of the EFS8 board) used by the service of user D1 and user E1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
The service of user D1 occupies PORT1 and the service of user E1 occupies PORT2. In this example, Enabled/Disabled is set to Enabled.
Workin g Mode
PORT1: AutoNegotiation
PORT2: Enabled
PORT2: AutoNegotiation
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Maximu m Frame Length
PORT1: 1522
MAC Loopba ck
PORT1: Non-Loopback
PHY Loopba ck
PORT1: Non-Loopback
PORT2: 1522
PORT2: Non-Loopback
PORT2: Non-Loopback
The Ethernet access equipment of user D1 and user E1 supports the auto-negotiation mode. Working Mode of PORT1 and PORT2 is set to Auto-Negotiation. Generally, this parameter adopts the default value 1522.
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback. The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
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l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
TAG
PORT1: Access
This parameter is set to Access if the Ethernet equipment of user D1 and user E1 does not support VLANs and if the transmitted packets do not carry VLAN tags.
PORT2: Access
Default VLAN ID
PORT1: 100 PORT2: 200
According to the plan, the VLAN ID is set to 100 on the transmission network side for Ethernet services between user D1 and user D2. The VLAN ID is set to 200 on the transmission network side for Ethernet services between user E1 and user E2.
VLAN Priority
PORT1: 0
Entry Detectio n
PORT1: Enabled
PORT2: 0
PORT2: Enabled
In this example, this parameter adopts the default value. If the equipment of users D1 and E1 does not support VLANs, you need to enable the entry detection function to detect wether the received packets contain VLAN tags. In this case, Entry Detection is set to Enabled.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal port (VCTRUNK1 on the EFS8 board) used by the services between user D1 and user D2 and between E1 and user E2. l Select Internal Port. l Click the TAG Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
TAG
VCTRUNK1: Tag Aware
When the port is set to Tag Aware, all data frames transmitted and received at the port must have VLAN tags. In this example, TAG is set to Tag Aware.
Default VLAN ID
-
When TAG is set to Tag Aware, you need not set Default VLAN ID.
VLAN Priority
-
When TAG is set to Tag Aware, you need not set VLAN Priority.
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Parame ter
Value in This Example
Description
Entry Detectio n
VCTRUNK1: Enabled
VCTRUNK1 is used by the service between user D1 and user D2 and the service between user E1 and user E2. Then, you need to enable the entry detection function to detect the VLAN tags of the received packets.
l Click the Network Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Port Attribut es
VCTRUNK1: UNI
UNI indicates the user-network interface, namely, the interface of the service provider located near the user side. The UNI interface processes the tag attribute of IEEE 802.1Qcompliant packets. That is, the UNI interface processes and identifies the VLAN information of the accessed user packets, according to the supported tag flag, namely, Tag Aware, Access, and Hybrid.
l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Check Field Length
VCTRUNK1: FCS32
In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
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Parame ter
Value in This Example
Description
Set Inverse Value for CRC
VCTRUNK1: -
When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l Click the Bound Path tab. Click the Configuration button. Set the following parameters in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
3.
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User
Parameter
Value in This Examp le
Description
User D1 ←→user D2 User E1 ←→user E2
Configurab le Ports
VCTR UNK1
As shown in Figure 4-29, VCTRUNK1 is used by the service between user D1 and user D2 and the service between user E1 and user E2.
Av aila ble Bo und Pat hs
VC12xv
The service between user D1 and user D2 and the service between user E1 and user E2 share a 20 Mbit/s bandwidth. Ten VC-12s need to be bound.
Leve l
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Serv ice Dire ction
Bidirect ional
The service between user D1 and user D2 and the service between user E1 and user E2 are bidirectional services.
Avai lable Reso urce s
VC4-4
Select VC4-4.
Avai lable Tim eslot s
VC12-1 to VC12-1 0
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards. Ten VC-12s need to be bound. In this example, the first to the tenth VC-12s need to be selected in sequence.
Configure the Ethernet private line services between user D1 and user D2 and between user E1 and user E2.
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l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Service > Ethernet Line Service from the Function Tree. l Click New on the lower-right pane to display the Create Ethernet Line Service window. Set the following parameters and then click OK. The Operation Result dialog box is displayed, indicating that the operation is successful. Click Close. User
Parameter
Value in This Example
Description
User D1 ←→user D2
Service Type
EPL
The service between user D1 and user D2 is a point-to-point EVPL service.
Service Direction
Bidirection al
The service between user D1 and user D2 is a bidirectional service.
Source Port
PORT1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. In this example, PORT1 is the external port used by the service between user D1 and user D2.
Source CVLAN (e.g. 1, 3-6)
100
According to the plan, the VLAN ID is set to 100 on the transmission network side for Ethernet service between user D1 and user D2.
Sink Port
VCTRUN K1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. In this example, VCTRUNK1 is the internal port used by the service between user D1 and user D2.
Sink CVLAN (e.g. 1, 3-6)
100
According to the plan, the VLAN ID is set to 100 on the transmission network side for Ethernet services between user D1 and user D2.
Service Type
EPL
The service between user E1 and E2 is a pointto-point Ethernet private line service.
Service Direction
Bidirection al
The service between user E1 and user E2 is a bidirectional service.
Source Port
PORT2
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific PORT as the source port. In this example, PORT2 is the external port used by the service between user E1 and user E2.
Source CVLAN (e.g. 1, 3-6)
200
According to the plan, the VLAN ID is set to 200 on the transmission network side for Ethernet service between user E1 and user E2.
User E1 ←→user E2
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4 Configuring Ethernet Services
Parameter
Value in This Example
Description
Sink Port
VCTRUN K1
When creating the bidirectional Ethernet service from a PORT to a VCTRUNK, it is recommended that you use a specific VCTRUNK as the sink port. In this example, VCTRUNK1 is the internal port used by the service between user E1 and user E2.
Sink CVLAN (e.g. 1, 3-6)
200
According to the plan, the VLAN ID is set to 200 on the transmission network side for Ethernet service between user E1 and user E2.
Configure the cross-connections from the Ethernet services to the SDH links for user D1 and user E1. l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User D1 ←→ user D2 user E1 ←→ user E2
Level
VC12
The timeslots bound with the service between user D1 and user D2 and the service between user E1 and user E2 are at the VC-12 level. The service level must be consistent with the level of the paths bound with the VCTRUNK.
Service Direction
Bidirectiona l
The service between user D1 and user D2 and the service between user E1 and user E2 are bidirectional services.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In this example, Source VC4 is set to VC4-4.
VC4-4
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User
Paramete r
Value in This Example
Description
Source Timeslot Range(e.g. 1,3-6)
1-10
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-10.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-10
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of sink timeslots must be, however, consistent with the number of sink timeslots.
Activate Immediatel y
Yes
-
Step 2 Configure the EVPL service on NE2. Refer to Step 1 and configure the EVPL service of NE2. Step 3 Check whether the services are configured correctly. For the operation procedures, see Testing Ethernet Service Channels. l Test the service connectivity between user D1 and user D2. l Test the service connectivity between user E1 and user E2. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see 5.4.3 Deleting Ethernet Private Line Services.
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4.8 Configuring EPLAN Services (IEEE 802.1d Bridge) The EPLAN service (IEEE 802.1d bridge) provides a LAN solution for multipoint-to-multipoint convergence. This service applies where the user-side data communication equipment connected to the transmission network does not support VLANs or where the VLAN planning is kept secret from the network operator. 4.8.1 Networking Diagram The convergence node needs to exchange Ethernet services with two access nodes at Layer 2. The two access nodes need not communicate with each other. 4.8.2 Signal Flow and Timeslot Allocation The Ethernet services of the convergence node are received from an external port, forwarded to an internal port through Layer 2 switching, encapsulated, and transparently transmitted on the SDH network. In this way, the node communicates with a remote node. 4.8.3 Configuration Process At the convergence node NE1, you need to create an EPLAN service (IEEE 802.1d bridge). At the access nodes NE2 and NE4, you need to configure only transparent transmission EPL services.
4.8.1 Networking Diagram The convergence node needs to exchange Ethernet services with two access nodes at Layer 2. The two access nodes need not communicate with each other.
Service Requirement In the network as shown in Figure 4-30, the service requirements are as follows: l
Three branches (F1, F2, and F3) of user F are located at NE1, NE2, and NE4. F1 needs to communicate with F2 and F3, and requires a 10 Mbit/s bandwidth for communication with each branch.
l
The Ethernet equipment of user F provides 100 Mbit/s Ethernet electrical interfaces that work in auto-negotiation mode and support VLANs. The VLAN IDs and the number of VLANs, however, are unknown and may change. NOTE
The application scenarios where one branch needs to communicate with other branches are as follows: l Branches F2 and F3 need to communicate with each other. l Branches F2 and F3 need not communicate with each other. If branches F2 and F3 need to communicate with each other, skip Step 1.4 in which you change the Hub/ Spoke attributes of ports connected to the bridge.
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Figure 4-30 Networking diagram for configuring EPLAN services (IEEE 802.1d bridge) NE3
NM
NE4:
NE2: Ethernet board Line board
Line board Ethernet board 6-SL4D-1
6-SL4D-2
4-EGT1
NE2
PORT1
NE4 PORT1
NE1 6-SL4D-2
6-SL4D-1
F2
6-SL4D-1
NE1: Ethernet board Line board
VCTRUNK2 PORT1
F3
6-SL4D-2 PORT1
VB VCTRUNK1
4-EGT1
4-EFS8
F1
6-SL4D-1
Line board 6-SL4D-2
VCTRUNK
Board Configuration Information For the EPLAN (IEEE 802.1d bridge) services supported by Ethernet switching boards, refer to Table 6-1. In this example, the convergence node NE1 is configured with an EFS8 board that supports the IEEE 802.1d bridge to implement EPLAN services wherein user VLANs are not limited. The access nodes NE2 and NE4 each are configured with an EGT1 board. The EPL services are configured to be transparently transmitted from NE2 and NE4 to NE1.
4.8.2 Signal Flow and Timeslot Allocation The Ethernet services of the convergence node are received from an external port, forwarded to an internal port through Layer 2 switching, encapsulated, and transparently transmitted on the SDH network. In this way, the node communicates with a remote node. Figure 4-31 shows the signal flow of the EPLAN services (IEEE 802.1d bridge) and the timeslot allocation to the EPLAN services (IEEE 802.1d bridge). For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-31 Signal flow of and timeslot allocation NE2:EGT1 VCTRUNK1
NE1:EFS8 VCTRUNK1
PORT1 User F1
VC4-4:VC12:1-5 VCTRUNK2 VC4-4:VC12:6-10
VB1
VC
VC4
4
VC -1 :
-1:V
: 112
C12 :1
5
VC4-4:VC12:1-5
PORT1 User F2
NE4:EGT1 -5 VCTRUNK1 VC4-4:VC12:1-5
PORT1
User F3
SDH
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l
The Ethernet LAN service of user F occupies the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link from NE1 to NE2 and the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link from NE1 to NE4.
l
The Ethernet LAN service from NE1 to NE2 is added and dropped by using the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EFS8 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EGT1 board of NE2.
l
The Ethernet LAN service from NE1 to NE4 is added and dropped by using the sixth to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:6-10) on the EFS8 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EGT1 board of NE4.
Table 4-27 Parameters of external ports on the Ethernet boards Parameter
NE1
NE2
NE4
Board
EFS8
EGT1
EGT1
Port
PORT1
PORT1
PORT1
Enabled/Disabled
Enabled
Enabled
Enabled
Working Mode
Auto-Negotiation
Auto-Negotiation
Auto-Negotiation
Maximum Frame Length
1522
1522
1522
Entry Detection
Enabled
-
-
TAG
Tag Aware
-
-
Table 4-28 Parameters of internal ports on the Ethernet boards
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Parameter
NE1
NE2
NE4
Board
EFS8
EGT1
EGT1
Port
VCTRUNK1
VCTRUNK2
VCTRUNK1
VCTRUNK1
Mapping Protocol
GFP
GFP
GFP
GFP
Entry Detection
Enabled
Enabled
-
-
TAG
Tag Aware
Tag Aware
-
-
Bound Path
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-6 -VC12-10
VC4-4:VC12-1 -VC12-5
VC4-4:VC12-1 -VC12-5
Port Type
UNI
UNI
-
-
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Table 4-29 Parameters of Ethernet LAN services (IEEE 802.1d bridge) Parameter
Ethernet LAN Service of NE1
Board
EFS8
VB Name
VB1
Bridge Type
IEEE 802.1d
Bridge Switch Mode
SVL/Ingress Filter Disable
Bridge Learning Mode
SVL
Ingress Filter
Disabled
VB Mount Port
PORT1, VCTRUNK1, VCTRUNK2
Hub/Spoke
PORT1
Hub
VCTRUNK1
Spoke
VCTRUNK2
Spoke
4.8.3 Configuration Process At the convergence node NE1, you need to create an EPLAN service (IEEE 802.1d bridge). At the access nodes NE2 and NE4, you need to configure only transparent transmission EPL services.
Prerequisite You must be familiar with 4.3.3 Flow of Configuring EPLAN Services.
Background Information If the Ethernet boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
For the EPLAN services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EPLAN services for users F1, F2, and F3 on NE1. 1.
Set the attributes of the external port (PORT1 of the EFS8 board) used by the service of user F1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port.
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l Click the Basic Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
In this example, PORT1 carries the services and is set to Enabled.
Workin g Mode
PORT1: AutoNegotiation
The Ethernet service access equipment of user F1 supports the auto-negotiation mode. In this example, Working Mode is set to Auto-Negotiation.
Maximu m Frame Length
PORT1: 1522
Generally, this parameter adopts the default value 1522.
MAC Loopba ck
PORT1: Non-Loopback
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback.
PHY Loopba ck
PORT1: Non-Loopback
The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the TAG Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Entry Detectio n
PORT1: Enabled
If the packets of user F1 carry VLAN tags, you need to enable the entry detection function to detect the VLAN tags of packets. In this example, Entry Detection is set to Enabled.
TAG
PORT1: Tag Aware
The service access equipment of user F1 supports VLANs and the transmitted data frames carry VLAN tags. In this example, Tag is set to Tag Aware for PORT1.
Default VLAN ID
-
When TAG is set to Tag Aware, you need not set Default VLAN ID.
VLAN Priority
-
When TAG is set to Tag Aware, you need not set VLAN Priority.
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l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal ports (VCTRUNK1 and VCTRUNK2 of the EFS8 board) used by the services of user F2 and user F3 on NE1. l Select Internal Port. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Entry Detectio n
VCTRUNK1: Enabled
If the packets of user F2 and user F3 carry VLAN tags, you need to enable the entry detection function to detect the VLAN tags of the packets. In this example, Entry Detection is set to Enabled.
TAG
VCTRUNK1: Tag Aware
VCTRUNK2: Enabled
VCTRUNK2: Tag Aware
The service access equipment of user F2 and user F3 supports VLANs and the transmitted data frames carry VLAN tags. In this example, Tag is set to Tag Aware for VCTRUNK1 and VCTRUNK2.
Default VLAN ID
-
When TAG is set to Tag Aware, you need not set Default VLAN ID.
VLAN Priority
-
When TAG is set to Tag Aware, you need not set VLAN Priority.
l Click the Network Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Port Attribut es
VCTRUNK1: UNI
UNI indicates the user-network interface, namely, the interface of the service provider located near the user side. The UNI interface processes the tag attribute of IEEE 802.1Qcompliant packets. That is, the UNI interface processes and identifies the VLAN information of the accessed user packets, according to the supported tag flags, namely Tag Aware, Access, and Hybrid.
VCTRUNK2: UNI
l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
In this example, the EFS4 board is used. This parameter adopts the default value GFP. Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
VCTRUNK2: GFP
VCTRUNK2: Scrambling mode [X43 +1] Check Field Length
VCTRUNK1: FCS32
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
Set Inverse Value for CRC
VCTRUNK1: -
VCTRUNK2: FCS32
VCTRUNK2: Big endian
VCTRUNK2: -
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l This operation is optional. Click the LCAS tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enablin g LCAS
VCTRUNK1: Enabled
In this example, the LCAS function is enabled.
LCAS Mode
VCTRUNK1: Huawei Mode
VCTRUNK2: Enabled
VCTRUNK2: Huawei Mode
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In this example, this parameter adopts the default value Huawei Mode. When Huawei equipment is used at both ends, LCAS Mode of the equipment at both ends is set to Huawei Mode.
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Parame ter
Value in This Example
Description
Holdoff Time (ms)
VCTRUNK1: 2000
In this example, this parameter adopts the default value 2000. This parameter can also be set according to the requirement of the user.
WTR Time(s)
VCTRUNK1: 300
TSD
VCTRUNK1: Disabled
VCTRUNK2: 2000
VCTRUNK2: 300
VCTRUNK2: Disabled Min. Member sTransmi t Directio n
VCTRUNK1: 256
Min. Member sReceive Directio n
VCTRUNK1: 256
VCTRUNK2: 256
VCTRUNK2: 256
In this example, this parameter adopts the default value 300. This parameter can also be set according to the requirement of the user. In this example, the TSD function is disabled. The LCAS does not check the B3 bit error or BIP status of the VCTRUNK members. Sets the min. members - transmit direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
Sets the min. members - receive direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
l Click the Bound Path tab. Click the Configuration button. Set the following parameters in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
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User
Paramete r
Value in This Example
Description
User F1← →user F2
Configura ble Ports
VCTRUN K1
As shown in Figure 4-31, VCTRUNK1 of the EFS8 board is used by the service between user F1 and user F2.
Ava ilab le Bou nd Pat hs
VC12-xv
The service between user F1 and user F2 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards.
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User
Paramete r
User F1← →user F3
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Value in This Example
Description
Ser vic e Dir ecti on
Bidirection al
The service between user F1 and user F2 is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Av aila ble Ti me slot s
VC12-1 to VC12-5
Five VC-12s need to be bound for the service between user F1 and user F2. In this example, the first to the fifth VC-12s need to be selected in sequence.
Configura ble Ports
VCTRUN K2
As shown in Figure 4-31, VCTRUNK2 of the EFS8 board is used by the service between user F1 and user F3.
Ava ilab le Bou nd Pat hs
VC12-xv
The service between user F1 and user F3 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
Bidirection al
The service between user F1 and user F3 is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
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User
Paramete r Av aila ble Ti me slot s
Value in This Example
Description
VC12-6 to VC12-10
Five VC-12s need to be bound for the service between user F1 and user F3. In this example, the sixth to the tenth VC-12s need to be selected in sequence.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 3.
Create a bridge for the EFS8 board on NE1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Service > Ethernet LAN Service from the Function Tree. l Click New. l Set the parameters in the Create Ethernet LAN Service dialog box that is displayed.
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Parameter
Value in This Example
Description
VB Name
VB1
This parameter is a character string used to describe the bridge. It is recommended that you set this parameter to a character string that contains the information about the detailed application of the bridge.
VB Type
802.1d
The IEEE 802.1d MAC bridge learns and forwards the packets according to the MAC addresses of the user packets. The information in the VLAN tags of the user packets, however, is not considered in the learning and forwarding process. The IEEE 802.1d MAC bridge is used when the entire information of the VLANs used by the client cannot be learned or when the data between the VLANs of the client need not be isolated.
Bridge Switch Mode
SVL/Ingress Filter Disable
When the bridge adopts the SVL learning mode, all the VLANs share the same MAC address table. That is, the bridge learns and forwards the packets according to the MAC addresses of the user packets only. The information in the VLAN tags of the user packets, however, is not considered in the learning and forwarding process.
Bridge Learning Mode
SVL
-
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Parameter
Value in This Example
Description
Ingress Filter
Disabled
The IEEE 802.1d MAC bridge does not detect the VLAN tags of the received packets.
l Click Configure Mount. l In the Available Mounted Ports window, select PORT1, VCTRUNK1, and VCTRUNK2. Then, click
.
l Click OK. l In the Create Ethernet LAN Service dialog box, click OK. 4.
Change the Hub/Spoke attribute of the port that is mounted to the bridge. NOTE
If normal communication is required between user F2 and user F3, go to Step 1.5.
l Select the created bridge and click the Service Mount tab. l Change the Hub/Spoke attribute of the port that is mounted to the bridge. After setting the parameters, click Apply. Parameter
Value in This Example
Description
Hub/Spoke
PORT1: Hub
If user F1 needs to communicate with user F2 and user F3, PORT1 that accesses the services of user F1 is set to Hub. A port of the Hub attribute can communicate with a port of the Spoke or Hub attribute.
VCTRUNK 1: Spoke VCTRUNK 2: Spoke
5.
If user F2 need not communicate with user F3, set the two VCTRUNKs that receive the services of users F2 and F3 to Spoke. Ports of the Spoke attribute cannot communicate with each other.
Configure the cross-connections from Ethernet services (between user F1 to user F2 and between user F1 to user F3) to the SDH links. l In the NE Explorer, select NE1 and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User F1 ←→ user F2
Level
VC12
The timeslot bound with the service between user F1 and user F2 is at the VC-12 level. The service level must be consistent with the level of the paths bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user F1 and user F2 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-5
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK1. In this example, the value range of Available Timeslots is from VC12-1 to VC12-5.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
Activate Immediatel y
Yes
-
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User
Paramete r
Value in This Example
Description
User F1 ←→ user F3
Level
VC12
The timeslot bound with the service between user F1 and user F3 is at the VC-12 level. The service level must be consistent with the level of the paths bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user F1 and user F3 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, the value of Available Resources is VC4-4.
Source Timeslot Range(e.g. 1,3-6)
6-10
The value range of the source timeslots is consistent with the value range of Available Timeslots, which is set for the paths bound with VCTRUNK2. In this example, the value range of Available Timeslots is from VC12-6 to VC12-10.
Sink Slot
6-SL4D-2 (SDH-2)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
Activate Immediatel y
Yes
-
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4 Configuring Ethernet Services
OptiX OSN 550 Multi-Service CPE Optical Transmission System Configuration Guide
Step 2 Configure the EPL services on NE2 and NE4. NOTE
The Ethernet services of NE2 and NE4 are point-to-point transparent transmission EPL services. See 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board to set the parameters.
Step 3 Check whether the services are configured correctly. For the operation procedures, see Testing Ethernet Service Channels. l Before testing the service connectivity between F1 and F2, set TAG to Access and set Default VLAN ID to 1 for PORT1 and VCTRUNK1, which receive the services of F1 and F2 respectively, on the EFS8 board. l Before testing the service connectivity between F1 and F3, set TAG to Access and Default VLAN ID to 1 for PORT1 and VCTRUNK2, which receive the services of F1 and F3 respectively, on the EFS8 board. NOTE
After the test, change the modified parameter values to the values specified in the service configuration.
Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see 5.4.4 Deleting EPLAN Services.
4.9 Configuring EVPLAN Services (IEEE 802.1q Bridge) The EVPLAN service (IEEE 802.1q bridge) provides an LAN solution for multipoint-tomultipoint convergence. This service applies in cases where user-side data communication equipment connected to the transmission network does not support VLANs or where the VLAN planning is open to the network operator. 4.9.1 Networking Diagram The convergence node needs to exchange Ethernet services with two access nodes at Layer 2. LAN services of the two users (H and G) need to be isolated. 4.9.2 Signal Flow and Timeslot Allocation The Ethernet services of the convergence node are received from an external port and tagged with the corresponding VLAN IDs. After the services are forwarded to an internal port through Layer 2 switching, the VLAN IDs are stripped and then the services are transparently transmitted in the SDH network. In this way, the node communicates with a remote node. 4.9.3 Configuration Process At the convergence node NE1, you need to create An EVPLAN service (IEEE 802.1q bridge) and a VLAN filtering table need to be created for the convergence node NE1. The access nodes NE2 and NE4 need to be configured with EPL transparent transmission services only.
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4.9.1 Networking Diagram The convergence node needs to exchange Ethernet services with two access nodes at Layer 2. LAN services of the two users (H and G) need to be isolated.
Service Requirement In the network shown in Figure 4-32, the service requirements are as follows: l
Three branches (G1, G2, and G3) of user G are located at NE1, NE2, and NE4 respectively. The branches need to form a LAN and share a 10 Mbit/s bandwidth. G2 and G3 do not need to communicate with each other.
l
Three branches (H1, H2, and H3) of user H are located at NE1, NE2, and NE4 respectively. The branches need form a LAN and share a 20 Mbit/s bandwidth. H2 and H3 need to communicate with each other.
l
The service of user G needs to be isolated from the service of user H.
l
The Ethernet equipment of user G and user H provides 100 Mbit/s Ethernet electrical interfaces that work in auto-negotiation mode and do not support VLANs.
Figure 4-32 Networking diagram for configuring EVPLAN services (IEEE 802.1q bridge) NE2: Line board Ethernet board Ethernet board 3-EGT1 6-SL4D-2 4-EGT1 NE4: Line board Ethernet board Ethernet board 3-EGT1 6-SL4D-1 4-EGT1
NE3
NM
3-EGT1-PORT1
3-EGT1-PORT1
H2
H3 NE2
4-EGT1-PORT1
NE4
4-EGT1-PORT1
G3
NE1 6-SL4D-2
6-SL4D-1
G2 6-SL4D-1 PORT2
H1
6-SL4D-2 PORT1
G1
VCTRUNK
NE1: Ethernet board Line board 4-EFS8
VB1 VLAN 200 VCTRUNK3
VCTRUNK4 PORT2
VB1
6-SL4D-1
Line board 6-SL4D-2
VLAN 100
VCTRUNK1
VCTRUNK2 PORT1
Board Configuration Information For the EVPLAN (IEEE 802.1q bridge) services supported by Ethernet switching boards, refer to Table 6-1. Issue 02 (2011-06-30)
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In this example, the convergence node NE1 is configured with an EFS8 board that supports the IEEE 802.1q bridge to implement EVPLAN services in which user data is isolated. The access nodes NE2 and NE4 each are configured with two Ethernet transparent transmission boards respectively, which occupy logical slots 3 and 4. The EPL services are configured to implement transparent transmission from NE2 and NE4 to NE1.
4.9.2 Signal Flow and Timeslot Allocation The Ethernet services of the convergence node are received from an external port and tagged with the corresponding VLAN IDs. After the services are forwarded to an internal port through Layer 2 switching, the VLAN IDs are stripped and then the services are transparently transmitted in the SDH network. In this way, the node communicates with a remote node. Figure 4-33 shows the signal flow of the EVPLAN services (IEEE 802.1q bridge) and the timeslot allocation to the EVPLAN services (IEEE 802.1q bridge). For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-33 Signal flow of and timeslot allocation to EVPLAN services (IEEE 802.1q bridge) NE2 3-EGT1 NE1:EFS8 VLAN 100 PORT1 User G1
VC
VCTRUNK1
1 VC 1: 4C V V C4 -1
VCTRUNK2 VC4-4:VC12:6-10 PORT2 User H1
2:1
VCTRUNK3 VC4-4:VC12:11-20
VC 4-1
VCTRUNK4 VC4-4:VC12:21-30
VC4-4:VC12:1-5
10
:V C1
: VC 12
VB1
VCTRUNK1
5
PORT1 User G2 PORT1 User H2
VCTRUNK1
12:
VC4-4:VC12:1-5
VLAN 200
4
1 VC -1 :
VC4-4:VC12:1-10
4-EGT1
NE4 2: 1-
:11
0
5
3-EGT1 VCTRUNK1 VC4-4:VC12:1-5
PORT1 User G3 PORT1 User H3
VCTRUNK1 VC4-4:VC12:1-10
4-EGT1 SDH PORT Strip VLAN Label
l
VCTRUNK Add VLAN Label
Strip VLAN Label
Data(User G)
VLAN(100)
Data(User G)
Data(User G)
Data(User H)
VLAN(200)
Data(User H)
Data(User H)
The Ethernet LAN services of user G: – Occupy the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link from NE1 to NE2 and the first to fifth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-5) on the SDH link from NE1 to NE4. – Are added and dropped by using the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the EFS8 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the 3-EGT1 board of NE2. – Are added and dropped by using the sixth to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:6-10) on the EFS8 board of NE1 and the first to fifth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-5) on the 3-EGT1 board of NE4.
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4 Configuring Ethernet Services
The Ethernet LAN services of user H: – Occupy the first to tenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-10) on the SDH link from NE1 to NE2 and the first to tenth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-10) on the SDH link from NE1 to NE4. – Are added and dropped by using the eleventh to twentieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:11-20) on the EFS8 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-10) on the 4-EGT1 board of NE2. – Are added and dropped by using the twenty-first to thirtieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:21-20) on the EFS8 board of NE1 and the first to tenth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:6-15) on the 4-EGT1 board of NE3.
Table 4-30 Parameters of external ports on the Ethernet boards Paramete r
NE1
NE2
NE4
Board
EFS8
3-EGT1
4-EGT1
3-EGT1
4-EGT1
Port
PORT1
PORT2
PORT1
PORT1
PORT1
PORT1
Enabled/ Disabled
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Working Mode
AutoNegotiatio n
AutoNegotiatio n
AutoNegotiatio n
AutoNegotiatio n
AutoNegotiatio n
AutoNegotiatio n
Maximum Frame Length
1522
1522
1522
1522
1522
1522
TAG
Access
Access
-
-
-
-
Entry Detection
Enabled
Enabled
-
-
-
-
Default VLAN ID
100
200
-
-
-
-
VLAN Priority
0
0
-
-
-
-
Table 4-31 Parameters of internal ports on the Ethernet boards
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Param eter
NE1
NE2
Board
EFS8
3EGT1
4EGT1
3EGT1
4EGT1
Port
VCTR UNK1
VCTR UNK1
VCTR UNK1
VCTR UNK1
VCTR UNK1
VCTR UNK2
VCTR UNK3
VCTR UNK4
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Param eter
NE1
NE2
NE3
Mappin g Protoco l
GFP
GFP
GFP
GFP
GFP
GFP
GFP
GFP
TAG
Access
Access
Access
Access
-
-
-
-
Entry Detecti on
Enable d
Enable d
Enable d
Enable d
-
-
-
-
Default VLAN ID
100
100
200
200
-
-
-
-
VLAN Priority
0
0
0
0
-
-
-
-
Bound Path
VC4-4: VC121VC125
VC4-4: VC126VC1210
VC4-4: VC1211VC1220
VC4-4: VC1221VC1230
VC4-4: VC121VC125
VC4-4: VC121VC1210
VC4-4: VC121VC125
VC4-4: VC121VC1210
Port Type
UNI
UNI
UNI
UNI
-
-
-
-
Table 4-32 Parameters of Ethernet LAN services (IEEE 802.1q bridge) Parameter
Ethernet LAN Service of NE1
Board
EFS8
VB Name
VB1
Bridge Type
IEEE 802.1q
Bridge Switch Mode
IVL/Ingress Filter Enable
Bridge Learning Mode
IVL
Ingress Filter
Enabled
VB Mount Port
PORT1, PORT2, VCTRUNK1, VCTRUNK2, VCTRUNK3, VCTRUNK4
VLAN Filtering
4-100
VLAN Filtering
VLAN filter table 1
VLAN filter table 2
VLAN ID
100
200
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Parameter
Ethernet LAN Service of NE1 Forwarding PORT1, VCTRUNK1, Physical Port VCTRUNK2
Hub/Spoke
4 Configuring Ethernet Services
PORT1
Hub
PORT2
Hub
VCTRUNK 1
Spoke
VCTRUNK 2
Spoke
VCTRUNK 3
Hub
VCTRUNK 4
Hub
PORT2, VCTRUNK3, VCTRUNK4
4.9.3 Configuration Process At the convergence node NE1, you need to create An EVPLAN service (IEEE 802.1q bridge) and a VLAN filtering table need to be created for the convergence node NE1. The access nodes NE2 and NE4 need to be configured with EPL transparent transmission services only.
Prerequisite You must be familiar with 4.3.4 Flow of Configuring EVPLAN Services.
Background Information If the Ethernet switching boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
For the EVPLAN services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet switching boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Procedure Step 1 Configure the EVPLAN services for user G1 and user H1 on NE1. 1.
Set the attributes of the external ports (PORT1 and PORT2 on the EFS8 board) used by the services of user G1 and user H1. l In the NE Explorer, select the EFS8, and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Enabled / Disable d
PORT1: Enabled
In this example, PORT1 and PORT2 carry the services and are set to Enabled.
Workin g Mode
PORT1: AutoNegotiation
PORT2: Enabled
PORT2: AutoNegotiation Maximu m Frame Length
PORT1: 1522
MAC Loopba ck
PORT1: Non-Loopback
PHY Loopba ck
PORT1: Non-Loopback
PORT2: 1522
PORT2: Non-Loopback
PORT2: Non-Loopback
In this example, the Ethernet service access equipment of user G1 and user H1 supports the auto-negotiation mode. Hence, Working Mode is set to Auto-Negotiation for PORT1 and PORT2. Generally, this parameter adopts the default value 1522.
The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback. The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Entry Detectio n
PORT1: Enabled
The packets of user G1 and user H1 do not carry VLAN tags. You need to enable the entry detection function to detect whether the packets carry VLAN tags. In this example, Entry Detection is set to Enabled.
TAG
PORT1: Access
PORT2: Enabled
PORT2: Access
Default VLAN ID
4-102
PORT1: 100 PORT2: 200
If the service access equipment of user G1 and user H1 does not support VLANs and if the transmitted packets do not carry VLAN tags, TAG is set to Access for PORT1 and PORT2. According to the plan, the VLAN ID is set to 100 on the transmission network side for EVPLAN services between user G1, user G2, and user G3. The VLAN ID is set to 200 on the transmission network side for EVPLAN services between user H1, user H2, and user H3. In this case, the service data is isolated.
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Parame ter
Value in This Example
Description
VLAN Priority
0
This parameter adopts the default value.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal ports (VCTRUNK1, VCTRUNK2, VCTRUNK3, and VCTRUNK4 on the EFS8 board) used by the service between user G1 and user G2, the service between user G1 and user G3, the service between user H1 and user H2, and the service between user H1 and user H3. l Select Internal Port. l Click the TAG Attributes tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Entry Detectio n
VCTRUNK1: Enabled
The packets of user G2, user G3, user H2, and user H3 do not carry VLAN tags. You need to enable the entry detection function to detect the VLAN tags of the packets. In this example, Entry Detection is set to Enabled.
VCTRUNK2: Enabled VCTRUNK3: Enabled VCTRUNK4: Enabled
TAG
VCTRUNK1: Access VCTRUNK2: Access VCTRUNK3: Access VCTRUNK4: Access
Default VLAN ID
VCTRUNK1: 100 VCTRUNK2: 100 VCTRUNK3: 200 VCTRUNK4: 200
VLAN Priority
VCTRUNK1: 0
If the service access equipment of user G2, user G3, user H2, and user H3 does not support VLANs and if the transmitted packets do not carry VLAN tags, TAG is set to Access for the four VCTRUNKs. According to the plan, the VLAN ID is set to 100 on the transmission network side for EVPLAN services between user G1, user G2, and user G3. The VLAN ID is set to 200 on the transmission network side for EVPLAN services between user H1, user H2, and user H3. In this case, the service data is isolated. This parameter adopts the default value.
VCTRUNK2: 0 VCTRUNK3: 0 VCTRUNK4: 0
l Click the Network Attributes tab. After setting the parameters, click Apply.
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Parameter
Value in This Example
Description
Port Attributes
VCTRUNK1: UNI
UNI indicates the user-network interface, namely, the interface of the service provider located near the user side. The UNI interface processes the tag attribute of IEEE 802.1Q-compliant packets. That is, the UNI interface processes and identifies the VLAN information of the accessed user packets, according to the supported tag flag, namely, Tag Aware, Access, and Hybrid.
VCTRUNK2: UNI VCTRUNK3: UNI VCTRUNK4: UNI
l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
In this example, the EFS8 board is used. This parameter adopts the default value GFP. Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
VCTRUNK2: GFP VCTRUNK3: GFP VCTRUNK4: GFP
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1] VCTRUNK2: Scrambling mode [X43 +1]
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
VCTRUNK3: Scrambling mode [X43 +1] VCTRUNK4: Scrambling mode [X43 +1] Check Field Length
VCTRUNK1: FCS32 VCTRUNK2: FCS32 VCTRUNK3: FCS32 VCTRUNK4: FCS32
FCS Calculat ed Bit Sequenc e
4-104
VCTRUNK1: Big endian VCTRUNK2: Big endian VCTRUNK3: Big endian VCTRUNK4: Big endian
In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
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Parame ter
Value in This Example
Description
Set Inverse Value for CRC
VCTRUNK1: -
When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
VCTRUNK2: VCTRUNK3: VCTRUNK4: -
l This operation is optional. Click the LCAS tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enablin g LCAS
VCTRUNK1: Enabled
In this example, Enabling LCAS is set to Enabled.
LCAS Mode
VCTRUNK1: Huawei Mode
VCTRUNK2: Enabled
VCTRUNK2: Huawei Mode
Holdoff Time (ms)
VCTRUNK1: 2000
WTR Time(s)
VCTRUNK1: 300
TSD
VCTRUNK1: Disabled
VCTRUNK2: 2000
VCTRUNK2: 300
VCTRUNK2: Disabled
Min. Member sTransmi t Directio n
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VCTRUNK1: 256 VCTRUNK2: 256
In this example, this parameter adopts the default value Huawei Mode. If the interconnected equipment at both ends is Huawei equipment, LCAS Mode is set to Huawei Mode for the interconnected equipment. In this example, this parameter adopts the default value 2000. You can set this parameter according to the expected hold off time of LCAS switching. In this example, this parameter adopts the default value 300. You can set this parameter according to the expected WTR duration of LCAS recovery. In this example, TSD is set to Disabled. In this case, the LCAS protocol does not monitor the status of the B3 or BIP bit errors of a VCTRUNK member. Sets the min. members - transmit direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
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Parame ter
Value in This Example
Description
Min. Member sReceive Directio n
VCTRUNK1: 256
Sets the min. members - receive direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
VCTRUNK2: 256
l Click the Bound Path tab. Click the Configuration button. Set the following in the Bound Path Configuration dialog box that is displayed. Then, click Apply. User
Paramete r
Value in This Example
Description
User G1←→ user G2
Configura ble Ports
VCTRUN K1
As shown in Figure 4-33, VCTRUNK1 of the EFS8 board is used by the service between user G1 and user G2.
Av aila ble Bo un d Pat hs
VC12-xv
The service between user G1 and user G2 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
user G1 ←→ user G3
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Leve l
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Serv ice Dire ction
Bidirectio nal
The service between user G1 and user G2 is a Bidirectional service.
Avai lable Reso urce s
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Avai lable Tim eslot s
VC12-1 to VC12-5
Five VC-12s need to be bound for user G2. In this example, the first to the fifth VC-12s need to be selected in sequence.
VCTRUN K2
As shown in Figure 4-33, VCTRUNK2 of the EFS8 board is used by the service between user G1 and user G3.
Configura ble Ports
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User H1←→ user H2
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4 Configuring Ethernet Services
Paramete r
Value in This Example
Description
Av aila ble Bo un d Pat hs
VC12-xv
The service between user G1 and user G3 uses a 10 Mbit/s bandwidth. Hence, five VC-12s need to be bound.
Leve l
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Serv ice Dire ction
Bidirectio nal
The service between user G1 and user G3 is a Bidirectional service.
Avai lable Reso urce s
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Avai lable Tim eslot s
VC12-6 to VC12-10
Five VC-12s need to be bound for the service between user G1 and user G3. In this example, the sixth to the tenth VC-12s need to be selected in sequence.
Configura ble Ports
VCTRUN K3
As shown in Figure 4-33, VCTRUNK3 of the EFS8 board is used by the service between user H1 and user H2.
Av aila ble Bo un d Pat hs
VC12-xv
The service between user H1 and user H2 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Leve l
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Serv ice Dire ction
Bidirectio nal
The service between user H1 and user H2 is a Bidirectional service.
Avai lable Reso urce s
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
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User
User H1←→ user H3
Paramete r
Value in This Example
Description
Avai lable Tim eslot s
VC12-11 to VC12-20
Ten VC-12s need to be bound for the service between user H1 and user H2. In this example, the eleventh to the twentieth VC-12s need to be selected in sequence.
Configura ble Ports
VCTRUN K4
As shown in Figure 4-33, VCTRUNK4 of the EFS8 board is used by the service between user H1 and user H3.
Av aila ble Bo un d Pat hs
VC12-xv
The service between user H1 and user H3 uses a 20 Mbit/s bandwidth. Hence, 10 VC-12s need to be bound.
Leve l
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Serv ice Dire ction
Bidirectio nal
The service between user H1 and user H3 is a Bidirectional service.
Avai lable Reso urce s
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Avai lable Tim eslot s
VC12-21 to VC12-30
Ten VC-12s need to be bound for the service between user H1 and user H3. In this example, the twenty-first to the thirtieth VC-12s need to be selected in sequence.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 3.
Create a bridge for the EFS8 board on NE1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Service > Ethernet LAN Service from the Function Tree. l Click New. l Set the required parameters in the Create Ethernet LAN Service dialog box that is displayed.
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Parameter
Value in This Example
Description
Board
NE1-4-EFS8
-
VB Name
VB1
This parameter is a character string used to describe the bridge. It is recommended that you set this parameter to a character string that contains the information about the detailed application of the bridge.
VB Type
802.1q
IEEE 802.1q bridge supports isolation by using one layer of VLAN tags. This bridge checks the contents of the VLAN tags that are in the packets and performs Layer 2 switching according to the destination MAC addresses and the VLAN IDs of the packets.
Bridge Switch Mode
IVL/Ingress Filter Enable
When the bridge adopts the IVL learning mode, the entry in the MAC address table is created according to the source MAC address, VLAN ID, and source port of the data frame. The entry is not valid for all the VLANs..
Bridge Learning Mode
IVL
-
Ingress Filter
Enabled
This parameter checks the validity of VLAN tags. If the VLAN ID is not the same as the VLAN ID defined in the VLAN filtering table, the data frame is discarded.
MAC Address SelfLearning
Enabled
-
l Click Configure Mount. l In Available Mounted Ports, select PORT1, PORT2, VCTRUNK1, VCTRUNK2, VCTRUNK3, and VCTRUNK4. Then, click
.
l OK. l In the Create Ethernet LAN Service dialog box, click OK. 4.
Create a VLAN filtering table. l Select the created bridge and click the VLAN Filtering tab. l Click New. l Create the VLAN filtering table for user G1, user G2, and user G3.
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Parameter
Value in This Example
Description
VLAN ID (e.g.1,3-6)
100
According to the plan, the VLAN ID is set to 100 on the transmission network side for EVPLAN services between user G1, user G2, and user G3.
l In Available Forwarding Ports, select PORT1, VCTRUNK1, and VCTRUNK2. Click . Then, click Apply. l Create the VLAN filtering table for user H1, user H2, and user H3. Parameter
Value in This Example
Description
VLAN ID (e.g.1,3-6)
200
According to the plan, the VLAN ID is set to 200 on the transmission network side for EVPLAN services between user H1, user H2, and user H3.
l In Available Forwarding Ports, select PORT2, VCTRUNK3, and VCTRUNK4. Click . Then, click OK. 5.
Change the Hub/Spoke attribute of the ports mounted to the bridge. l Select the created bridge and click the Service Mount tab. l Change the Hub/Spoke attribute of the port mounted to the bridge. After setting the parameters, click Apply. Parameter
Value in This Example
Description
Hub/Spoke
PORT1: Hub
If user G2 need not communicate with user G3, set VCTRUNK1 and VCTRUNK2 ports that receive the services of user G2 and user G3 to Spoke. Ports of the Spoke attribute cannot communicate with each other. A port of the Hub attribute can communicate with a port of the Spoke or Hub attribute.
VCTRUNK1: Spoke VCTRUNK2: Spoke PORT2: Hub VCTRUNK3: Hub VCTRUNK4: Hub 6.
Configure the cross-connections from the Ethernet service to the SDH link for user G2, user G3, user H2, and user H3. l In the NE Explorer, select NE1, and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User G1 ←→ user G2
Level
VC12
The timeslot bound with the service between user G1 and user G2 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user G1 and user G2 is a Bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-5
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Timeslot is from VC12-1 to VC12-5.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
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User
Paramete r
Value in This Example
Description
User G1 ←→ user G3
Level
VC12
The timeslot bound with the service between user G1 and user G3 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user G1 and user G3 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
6-10
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, the value of Available Timeslot is from VC12-6 to VC12-10.
Sink Slot
6-SL4D-2 (SDH-2)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-5
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are five VC-12s, the sink timeslots must be five VC-12s.
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User
Paramete r
Value in This Example
Description
User H1 ←→ user H2
Level
VC12
The timeslot bound with the service between user H1 and user H2 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user H1 and user H2 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK3. In the case of VCTRUNK3, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
11-20
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK3. In the case of VCTRUNK3, the value of Available Timeslot is from VC12-11 to VC12-20.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
6-15
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are 10 VC-12s, the sink timeslots must be 10 VC-12s.
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User
Paramete r
Value in This Example
Description
User H1 ←→ user H3
Level
VC12
The timeslot bound with the service between user H1 and user H3 is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service between user H1 and user H3 is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK4. In the case of VCTRUNK4, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
21-30
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK4. In the case of VCTRUNK4, the value of Available Timeslot is from VC12-21 to VC12-30.
Sink Slot
6-SL4D-2 (SDH-2)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
6-15
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots. For example, if the source timeslots are 10 VC-12s, the sink timeslots must be 10 VC-12s.
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Step 2 Configure the EPL services on NE2 and NE4. NOTE
The Ethernet services of NE2 and NE4 are point-to-point transparent transmission services. See 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board to set the parameters.
Step 3 Check whether the services are configured correctly. For the operation procedures, see Testing Ethernet Service Channels. Step 4 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 5 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
4.10 Configuring EVPLAN Services (IEEE 802.1ad Bridge) The QinQ technology provides a cheap and easy solution for Layer 2 virtual private networks (VPNs). The IEEE 802.1ad bridge uses the QinQ technology to provide the VPN solution, thus facilitating the identifying, differentiating and grooming EVPLAN services. 4.10.1 Networking Diagram A network operator requires that the voice over IP (VoIP) and high speed Internet (HSI) services sent to the transmission network be uniformly labeled and groomed at the convergence node. 4.10.2 Signal Flow and Timeslot Allocation The services of user M and user N are transmitted from the access nodes NE2 and NE4 respectively to the convergence node NE1 through the Ethernet transparent transmission boards. VoIP and HSI services carrying different C-VLAN IDs are tagged with different S-VLAN IDs. The service data is isolated and exchanged at Layer 2 through S-VLAN filtering. 4.10.3 Configuration Process An EVPLAN service (IEEE 802.1ad bridge) and the corresponding S-VLAN filtering table need to be created for the convergence node NE1. The access nodes NE2 and NE4 need to be configured with EPL transparent transmission services only.
4.10.1 Networking Diagram A network operator requires that the voice over IP (VoIP) and high speed Internet (HSI) services sent to the transmission network be uniformly labeled and groomed at the convergence node.
Service Requirement As shown in Figure 4-34, the transmission network is required to carry the VoIP and HSI services. User requirements:
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l
The VoIP services of user M and user N are sent to the transmission network at NE2 and NE4 respectively and to the VoIP server at the convergence node NE1. The services share a 20 Mbit/s bandwidth.
l
The HSI services of user M and user N are sent to the transmission network at NE2 and NE4 respectively and to the HSI server at the convergence node NE1. The services share a 40 Mbit/s bandwidth.
l
The VoIP services need to be isolated from the HSI services.
l
The data communication equipment of user M and user N provides 100 Mbit/s Ethernet electrical interfaces of which the working mode is auto-negotiation, and does not support VLAN. – C-VLAN ID of the VoIP services: 10 – C-VLAN ID of the HSI services: 20 NOTE
The application scenarios where one branch needs to communicate with other branches are as follows: l User M needs to communicate with user N. l User M need not communicate with user N. If user M and user N need to communicate with each other, skip Step 1.5 in which you change the Hub/ Spoke attributes of ports connected to the bridge.
Requirement of the operator: The operator requires that all services received from the user side should be uniformly labeled and groomed through planned S-VLANs. l
S-VLAN ID of the VoIP services: 100
l
S-VLAN ID of the HSI services: 200
Figure 4-34 Networking diagram for configuring EVPLAN services (IEEE 802.1ad bridge) NE4:
NE2: Ethernet board Line board 4-EGT1
Line board Ethernet board
6-SL4D-2
6-SL4D-1
NE3
NM
4-EGT1
Service C-VLAN 10 VoIP 20 HSI
Service C-VLAN 10 VoIP 20 HSI
PORT1
PORT1
NE2
User M
NE4 NE1
User N
VoIP server PORT1
HSI server
PORT2
NE1:
VCTRUNK
Ethernet board Line board 4-EFS8 6-SL4D-1
VB1
S-VLAN 100
VCTRUNK1
VCTRUNK2 PORT1
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VB1
Line board 6-SL4D-2
S-VLAN 200
VCTRUNK1
VCTRUNK2 PORT2
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Board Configuration Information For the EVPLAN (IEEE 802.1ad bridge) services supported by Ethernet switching boards, refer to Table 6-1. In this example, the convergence node NE1 is configured with an EFS8 board that supports the IEEE 802.1ad bridge to implement EVPLAN services in which VoIP data is isolated from HSI data. l
The VoIP services tagged with C-VLAN ID 10 from NE2 and NE4 are further tagged with S-VLAN ID 100 when they arrive at the IEEE 802.1ad bridge of NE1. Then, the services are forwarded to the VoIP server through Layer 2 switching.
l
The HSI services tagged with C-VLAN ID 20 from NE2 and NE4 are further tagged with S-VLAN ID 200 when they arrive at the IEEE 802.1ad bridge of NE1. Then, the services are forwarded to the HSI server through Layer 2 switching.
The access nodes NE2 and NE4 each are configured with an EGT1 board. The EPL services are configured to implement transparent transmission from NE2 and NE4 to NE1.
4.10.2 Signal Flow and Timeslot Allocation The services of user M and user N are transmitted from the access nodes NE2 and NE4 respectively to the convergence node NE1 through the Ethernet transparent transmission boards. VoIP and HSI services carrying different C-VLAN IDs are tagged with different S-VLAN IDs. The service data is isolated and exchanged at Layer 2 through S-VLAN filtering. Figure 4-35 shows the signal flow of the EVPLAN services (IEEE 802.1ad bridge) and the timeslot allocation to the EVPLAN services (IEEE 802.1ad bridge). For the method of calculating the bandwidth of the Ethernet services carried by a VCTRUNK, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Figure 4-35 Signal flow of and timeslot allocation to EVPLAN services (IEEE 802.1ad bridge) NE2:EGT1
NE1:EFS8 SVLAN 100 VoIP Server
VC4
PORT1
12:1
-30
VCTRUNK1 VC4-4:VC12:1-30
VCTRUNK1
VCTRUNK2
PORT2
VC 4
VC4-4:VC12:31-60
-1:VC
NE4:EGT1 12:1
-30
VCTRUNK1 VC4-4:VC12:1-30
PORT Strip S-VLAN Label
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PORT1 User N
SDH
VB1
VCTRUNK Add S-VLAN Label
Strip S-VLAN Label
C-VLAN(10)
Data(VoIP)
S-VLAN(100) C-VLAN(10) Data(VoIP)
C-VLAN(10)
Data(VoIP)
C-VLAN(20)
Data(HSI)
S-VLAN(200) C-VLAN(20)
C-VLAN(20)
Data(HSI)
l
PORT1 User M
VC4-4:VC12:1-30
SVLAN 200 HSI Server
-1:VC
Data(HSI)
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– Occupy the first to thirtieth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-30) on the SDH link from NE1 to NE2. – Are added and dropped by using the first to thirtieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-30) on the EFS8 board of NE1 and the first to thirtieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-30) on the EGT1 board of NE2. l
The services of user N: – Occupy the first to thirtieth VC-12 timeslots of the first VC-4 (VC4-1:VC12:1-30) on the SDH link from NE1 to NE4. – Are added and dropped by the using the thirty-first to sixtieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:31-60) on the EFS8 board of NE1 and the first to thirtieth VC-12 timeslots of the fourth VC-4 (VC4-4:VC12:1-30) on the EGT1 board of NE4.
Table 4-33 Parameters of external ports on the Ethernet boards Parameter
NE1
NE2
NE4
Board
EFS8
EGT1
EGT1
Port
PORT1
PORT2
PORT1
PORT1
Enabled/ Disabled
Enabled
Enabled
Enabled
Enabled
Working Mode
AutoNegotiation
AutoNegotiation
AutoNegotiation
AutoNegotiation
Maximum Frame Length
1522
1522
1522
1522
Port Type
C-Aware
C-Aware
C-Aware
C-Aware
Table 4-34 Parameters of internal ports on the Ethernet boards
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Parameter
NE1
NE2
NE3
Board
EFS8
EGT1
EGT1
Port
VCTRUNK1
VCTRUNK2
VCTRUNK1
VCTRUNK1
Mapping Protocol
GFP
GFP
GFP
GFP
Port Type
C-Aware
C-Aware
-
-
Bound Path
VC4-4:VC12-1 -VC12-30
VC4-4:VC12-3 1-VC12-60
VC4-4:VC12-1 -VC12-30
VC4-4:VC12-1 -VC12-30
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Table 4-35 Parameters of Ethernet LAN services (IEEE 802.1ad bridge) Parameter
Ethernet LAN Service of NE1
Board
EFS8
VB Name
VB1
Bridge Type
IEEE 802.1ad
Bridge Switch Mode
IVL/Ingress Filter Enable
Bridge Learning Mode
IVL
Ingress Filter
Enabled
Operation Type
Add S-VLAN base for Port and C-VLAN
VB Port
1
2
3
4
Mount Port
PORT1
PORT2
VCTRUNK1
VCTRUNK2
C-VLAN
10
20
10
20
10
20
S-VLAN
100
200
100
200
100
200
VLAN Filterin g
VLAN Filtering
VLAN filter table 1
VLAN filter table 2
VLAN ID
100
200
Forwarding PORT1, VCTRUNK1, Physical Port VCTRUNK2 Hub/ Spoke
PORT1
Hub
PORT2
Hub
VCTRUNK 1
Spoke
VCTRUNK 2
Spoke
PORT2, VCTRUNK1, VCTRUNK2
4.10.3 Configuration Process An EVPLAN service (IEEE 802.1ad bridge) and the corresponding S-VLAN filtering table need to be created for the convergence node NE1. The access nodes NE2 and NE4 need to be configured with EPL transparent transmission services only.
Prerequisite You must be familiar with 4.3.1 Flow of Configuring EPL Services.
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Background Information If the Ethernet switching boards in the actual application scenarios are different from the boards in this example, you need to learn about the requirements for configuring specific boards. l
For the EVPLAN services supported by Ethernet switching boards, see 6.1 Service Support Capability of Ethernet Boards.
l
For the VCTRUNK binding requirements of Ethernet transparent transmission boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
The IEEE 802.1ad provider bridge supports ports with the C-Aware and S-Aware attributes only. The C-Aware ports are used to add and strip the S-VLAN tags. The S-Aware ports are used to transparently transmit the S-VLAN tag. The IEEE 802.1ad provider bridge supports the following operation types: l
Adding the S-VLAN tag based on the port
l
Adding the S-VLAN tag based on the port and C-VLAN
l
Performing port mounting based on the port
l
Performing port mounting based on the port and the S-VLAN
This topic describes the four operation types when Bridge Switch Mode of the IEEE 802.1ad provider bridge is set to IVL/Ingress Filter Enabled. l
Adding the S-VLAN based on the port: The packets that enter the C-Aware port are added with the preset S-VLAN tag, and are forwarded in the bridge according to the S-VLAN filtering table. Before the packets leave the C-Aware port, the S-VLAN tag is stripped.
l
Adding the S-VLAN tag based on the port and C-VLAN: The entry detection is performed for the packets that enter the C-Aware port. Then, the corresponding S-VLAN tags are added to the packets according to the mapping relation between the C-VLAN tags and the S-VLAN tags of the packets. If the mapping relation does not exist, the packets are discarded. After the S-VLAN tags are added, the packets enter the bridge, where the packets are forwarded according to the S-VLAN filtering table. Before the packets leave the CAware port, the S-VLAN tag is stripped. NOTE
l The same C-Aware port supports different C-VLAN tags being mapped to different S-VLAN tags, but does not support the same C-VLAN tag being mapping to multiple S-VLAN tags.
l
Performing port mounting based on the port: The packets that enter the S-Aware port are not filtered. Instead, the S-VLAN switch is performed directly. The packets must have the S-VLAN tags. Otherwise, the packets are discarded. When the packets leave the S-Aware port, the packets are transparently transmitted.
l
Performing port mounting based on the port and the S-VLAN: The entry filtering is performed according to the preset S-VLAN tag. The packets that do not belong to the SVLAN are discarded. Then, the packets are forwarded according to the S-VLAN filtering table. When the packets leave the S-Aware port, the packets are transparently transmitted.
In the case of the four operation types, the following conditions must be met before the packets leave a port:
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The port is contained in the S-VLAN filtering table that is created by the user.
l
The S-VLAN ID corresponding to the port must be specified when the user manually mounts the port to the bridge. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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– In the case of a C-Aware port, the S-VLAN ID corresponding to the port is the S-VLAN ID that is added when the packets enter the port. – In the case of an S-Aware port, the S-VLAN ID corresponding to the port is the S-VLAN ID that is set when the user mounts the port to the bridge. If the S-Aware port is mounted based on the port, the S-VLAN ID is considered to contain all the legal S-VLAN IDs.
Procedure Step 1 Configure the EVPLAN services on NE1. 1.
Set the attributes of the external ports (PORT1 and PORT2 on the EFS8 board) used by the VoIP server and HSI server. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Interface Management > Ethernet Interface from the Function Tree. l Select External Port. l Click the Basic Attributes tab. After setting the parameters, click Apply. Parameter
Value in This Example
Description
Enabled/ Disabled
PORT1: Enabled
In this example, PORT1 and PORT2 carry the services and Enabled/Disabled is set to Enabled for PORT1 and PORT2.
Working Mode
PORT1: AutoNegotiation
PORT2: Enabled
PORT2: AutoNegotiation Maximum Frame Length
PORT1: 1522
MAC Loopback
PORT1: Non-Loopback
PHY Loopback
PORT1: Non-Loopback
PORT2: 1522
PORT2: Non-Loopback
PORT2: Non-Loopback
In this example, the VoIP server and HSI server support the auto-negotiation mode. Hence, Working Mode is set to AutoNegotiation for PORT1 and PORT2. Generally, this parameter adopts the default value 1522. The MAC loopback setting is used for fault diagnosis. In this example, MAC Loopback is set to Non-Loopback. The PHY loopback setting is used for fault diagnosis. In this example, PHY Loopback is set to Non-Loopback.
l Click the Flow Control tab. The parameters in the Flow Control tab page adopt the default values. l Click the Network Attributes tab. After setting the parameters, click Apply.
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Parameter
Value in This Example
Description
Port Attributes
PORT1: C-Aware
The C-Aware or S-Aware attribute must be selected for the port when you configure the IEEE 802.1ad bridge. The C-Aware port connects to the port in the client network, identifies and processes the packets that contain CVLAN tags (namely, client tags). The S-Aware port connects to the port on the network side, identifies and processes the packets that contain SVLAN tags (namely, service tags of the network operator).
PORT2: C-Aware
l It is unnecessary to set the parameters on the TAG Attributes tab. If the port type is set to C-Aware or S-Aware, the parameters on the TAG Attributes are meaningless. l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 2.
Set the attributes of the internal ports (VCTRUNK1 and VCTRUNK2 on the EFS8 board) used by the services of user M and N. l Select Internal Port. l Click the Network Attributes tab. After setting the parameters, click Apply. Paramet er
Value in This Example
Description
Port Attributes
VCTRUNK1: C-Aware
The C-Aware or S-Aware attribute must be selected for the port when you configure the IEEE 802.1ad bridge. The C-Aware port connects to the port in the client network, identifies and processes the packets that contain C-VLAN tags (namely, client tags). The S-Aware port connects to the port on the network side, identifies and processes the packets that contain S-VLAN tags (namely, service tags of the network operator).
VCTRUNK2: C-Aware
l It is unnecessary to set the parameters on the TAG Attributes tab. If the port type is set to C-Aware or S-Aware, the parameters on the TAG Attributes are meaningless. l Click the Encapsulation/Mapping tab. After setting the parameters, click Apply.
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Parame ter
Value in This Example
Description
Mappin g Protocol
VCTRUNK1: GFP
In this example, the EFS4 board is used. This parameter adopts the default value GFP. Mapping Protocol of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
Scrambl e
VCTRUNK1: Scrambling mode [X43 +1]
VCTRUNK2: GFP
VCTRUNK2: Scrambling mode [X43 +1] Check Field Length
VCTRUNK1: FCS32
FCS Calculat ed Bit Sequenc e
VCTRUNK1: Big endian
Set Inverse Value for CRC
VCTRUNK1: -
VCTRUNK2: FCS32
VCTRUNK2: Big endian
VCTRUNK2: -
In this example, this parameter adopts the default value Scrambling mode [X43+1]. Scramble of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. In this example, this parameter adopts the default value FCS32. Check Field Length of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, FCS Calculated Bit Sequence is set to Big endian. FCS Calculated Bit Sequence of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value. When Mapping Protocol is set to GFP, this parameter is valid and adopts the default value -. Set Inverse Value for CRC of the VCTRUNKs on the Ethernet boards of the interconnected equipment at both ends must be set to the same value.
l This operation is optional. Click the LCAS tab. After setting the parameters, click Apply. Parame ter
Value in This Example
Description
Enablin g LCAS
VCTRUNK1: Enabled
In this example, Enabling LCAS is set to Enabled.
LCAS Mode
VCTRUNK1: Huawei Mode
VCTRUNK2: Enabled
VCTRUNK2: Huawei Mode
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In this example, this parameter adopts the default value Huawei Mode. If the interconnected equipment at both ends is Huawei equipment, LCAS Mode is set to Huawei Mode for the interconnected equipment.
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Parame ter
Value in This Example
Description
Holdoff Time (ms)
VCTRUNK1: 2000
In this example, this parameter adopts the default value 2000. You can set this parameter according to the expected hold off time of LCAS switching.
WTR Time(s)
VCTRUNK1: 300
TSD
VCTRUNK1: Disabled
VCTRUNK2: 2000
VCTRUNK2: 300
VCTRUNK2: Disabled
Min. Member sTransmi t Directio n
VCTRUNK1: 256
Min. Member sReceive Directio n
VCTRUNK1: 256
VCTRUNK2: 256
VCTRUNK2: 256
In this example, this parameter adopts the default value 300. You can set this parameter according to the expected WTR duration of LCAS recovery. In this example, TSD is set to Disabled. In this case, the LCAS protocol does not monitor the status of the B3 or BIP bit errors of a VCTRUNK member. Sets the min. members - transmit direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
Sets the min. members - receive direction. When the LCAS is enabled and the number of available members is smaller than this value, an alarm is reported.
l Click the Bound Path tab. Click the Configuration button. Set the following in the Bound Path Configuration dialog box that is displayed. Then, click Apply.
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User
Paramet er
Value in This Example
Description
User M
Configura ble Ports
VCTRUN K1
As shown in Figure 4-35, VCTRUNK1 of the EFS8 board is used by the service of user M.
Av aila ble Bo und Pat hs
VC12-xv
The service of user M uses a 60 Mbit/s bandwidth. Hence, 30 VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards.
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User
Paramet er
User N
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Value in This Example
Description
Ser vic e Dir ecti on
Bidirection al
The service of user M is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
Av aila ble Ti me slot s
VC12-1 to VC12-30
Thirty VC-12s need to be bound for user M. In this example, the first to the thirtieth VC-12s need to be selected in sequence.
Configura ble Ports
VCTRUN K2
As shown in Figure 4-35, VCTRUNK2 of the EFS8 board is used by the service of user N.
Av aila ble Bo und Pat hs
VC12-xv
The service of user N uses a 60 Mbit/s bandwidth. Hence, 30 VC-12s need to be bound.
Lev el
For the method of computing the bound timeslots based on the service bandwidth, see 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards. Ser vic e Dir ecti on
Bidirection al
The service of user N is a bidirectional service.
Av aila ble Res our ces
VC4-4
For the resources used by other boards, see 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards.
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User
Paramet er Av aila ble Ti me slot s
Value in This Example
Description
VC12-31 to VC12-60
Thirty VC-12s need to be bound for user N. In this example, the thirty-first to the sixtieth VC-12s need to be selected in sequence.
l Click the Advanced Attributes tab. The parameters in the Advanced Attributes tab page adopt the default values. 3.
Create a bridge for the EFS8 board on NE1. l In the NE Explorer, select the EFS8 board, and then choose Configuration > Ethernet Service > Ethernet LAN Service from the Function Tree. l Click New. l Set the required parameters in the Create Ethernet LAN Service dialog box that is displayed.
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Parameter
Value in This Example
Description
Board
NE1-4-EFS8
-
VB Name
VB1
This parameter is a character string used to describe the bridge. It is recommended that you set this parameter to a character string that contains the information about the detailed application of the bridge.
VB Type
802.1ad
The IEEE 802.1ad bridge supports data frames with two layers of VLAN tags. This bridge adopts the outer S-VLAN tags to isolate different VLANs and supports only the mounted ports whose attributes are C-Aware or S-Aware.
Bridge Switch Mode
IVL/Ingress Filter Enable
This bridge checks the contents of the VLAN tags that are in the packets and performs Layer 2 switching according to the destination MAC addresses and the S-VLAN IDs of the packets.
Bridge Learning Mode
IVL
-
Ingress Filter
Enabled
-
MAC Address SelfLearning
Enabled
-
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l Click Configure Mount. l Set the parameters for service mounting in the Service Mount Configuration dialog box that is displayed. Attribute
Attribute Value
Operation Type
Adding S-VLAN tags based on Port and C-VLAN
VB Port
1
2
3
4
Mount Port
PORT1
PORT2
VCTRUNK1
VCTRUNK2
C-VLAN
10
20
10
20
10
20
S-VLAN
100
200
100
200
100
200
l Click OK. l In the Create Ethernet LAN Service dialog box, click OK. 4.
Create a VLAN filtering table. l Select the created bridge and click the VLAN Filtering tab. l Click New. l Create the VLAN filtering table of the VoIP service. Parameter
Value in This Example
Description
VLAN ID (e.g.1,3-6)
100
According to the plan, the S-VLAN ID is 100 for the VoIP service.
l In Available Forwarding Ports, select PORT1, VCTRUNK1, and VCTRUNK2. Click . Then, click Apply. l Create the VLAN filtering table of the HSI service. Parameter
Value in This Example
Description
VLAN ID (e.g.1,3-6)
200
According to the plan, the S-VLAN ID is 200 for the HSI service.
l In Available Forwarding Ports, select PORT2, VCTRUNK1, and VCTRUNK2. Click . Then, click OK. 5.
Change the Hub/Spoke attribute of the ports mounted to the bridge. NOTE
If user M and user N need to communicate with each other, proceed to Step 1.6.
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l Select the created bridge and click the Service Mount tab. l Change the Hub/Spoke attribute of the port mounted to the bridge. Parameter
Value in This Example
Description
Hub/Spoke
PORT1: Hub
User M and user N need not communicate with each other. In this case, set VCTRUNK1 and VCTRUNK2 that access the services of user M and user N to the Spoke attribute. Ports of the Spoke attribute cannot communicate with each other.
PORT2: Hub VCTRUNK1: Spoke VCTRUNK2: Spoke
6.
A port of the Hub attribute can communicate with a port of the Spoke or Hub attribute.
Configure the cross-connections from the Ethernet service to the SDH link for user M and user N. l In the NE Explorer, select NE1, and then choose Configuration > SDH Service Configuration from the Function Tree. l Click Create on the lower-right pane to display the Create SDH Service dialog box. Set the parameters as follows.
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User
Paramete r
Value in This Example
Description
User M
Level
VC12
The timeslot bound with the service of user M is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service of user M is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
1-30
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK1. In the case of VCTRUNK1, the value of Available Timeslot is from VC12-1 to VC12-30.
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User
User N
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Paramete r
Value in This Example
Description
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-30
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of sink timeslots must be, however, consistent with the number of sink timeslots.
Activate Immediatel y
Yes
-
Level
VC12
The timeslot bound with the service of user N is at the VC-12 level. The service level must be consistent with the level of the path bound with the VCTRUNK.
Direction
Bidirectiona l
The service of user N is a bidirectional service.
Source Slot 4-EFS8-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the Ethernet board as the source slot.
Source VC4
VC4-4
The value range of Source VC4 is consistent with the value range of Available Resources, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, Available Resources is set to VC4-4.
Source Timeslot Range(e.g. 1,3-6)
31-60
The value range of the source timeslots is consistent with the value range of Available Timeslot, which is set for the paths bound with VCTRUNK2. In the case of VCTRUNK2, the value of Available Timeslot is from VC12-31 to VC12-60.
Sink Slot
6-SL4D-1 (SDH-1)
When you create a bidirectional SDH service from an Ethernet board to a line board, it is recommended that you set the slot of the line board as the sink slot.
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User
Paramete r
Value in This Example
Description
Sink VC4
VC4-1
In this example, VC4-1 is specified as the VC-4 timeslot of the Ethernet service on the line board.
Sink Timeslot Range(e.g. 1,3-6)
1-30
The value range of the sink timeslots can be the same as or different from the value range of the source timeslots. The number of source timeslots must be, however, the same as the number of sink timeslots.
Activate Immediatel y
Yes
-
Step 2 Configure the EPL services on NE2 and NE4. NOTE
The Ethernet services of NE2 and NE4 are point-to-point transparent transmission services. See 4.4 Configuring EPL Services on an Ethernet Transparent Transmission Board to set the parameters.
Step 3 Enable the performance monitoring function of the NEs. For details, see Setting Performance Monitoring Parameters of an NE. Step 4 Back up the configuration data of the NEs. For details, see Backing Up the NE Database to the SCB Board. ----End
Relevant Task If the services are configured incorrectly and thus need to be deleted, see Deleting SDH Services.
4.11 Ethernet Port Configuration Parameters Before configuring an Ethernet service, you need to configure the corresponding Ethernet ports. 4.11.1 Basic Attributes This topic describes the parameters, such as the port attribute, port enabling status, and maximum frame length, that are used for configuring the basic attributes of an Ethernet port. 4.11.2 Flow Control This topic describes the parameters, such as autonegotiation and non-autonegotiation, which are used for configuring flow control function of an Ethernet port. 4.11.3 Network Attributes This topic describes the parameters, such as port attribute and P port encapsulation format, which are used for configuring network attributes of an Ethernet port. 4.11.4 Advanced Attributes This topic describes the parameters, such as the loop detection, loop port shutdown, and traffic threshold (Mbit/s), which are used for configuring the advanced attributes of an Ethernet port. 4-130
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4.11.5 TAG Attributes Tag attributes are important attributes that are used for configuring Ethernet services, including the parameters such as the default VLAN ID, VLAN priority, ingress detection setting, and tag ID. 4.11.6 Encapsulation/Mapping The equipment supports the setting of encapsulation and mapping protocols for Ethernet packets, including the parameters such as mapping protocol, scrambling code, and CRC or not. 4.11.7 Bound Path This topic describes the parameters, such as available resources, available timeslots, and service direction, which are used for binding a path with an Ethernet port.
4.11.1 Basic Attributes This topic describes the parameters, such as the port attribute, port enabling status, and maximum frame length, that are used for configuring the basic attributes of an Ethernet port. Table 4-36 lists the parameters that are used for configuring the basic attributes of an Ethernet port. Table 4-36 Parameters for configuring the basic attributes of an Ethernet port Field
Value Range
Description
Port
PORTn
Displays all the available ports on an Ethernet port. The letter n indicates the number of the PORT port.
Name
For example: PORT-1
Specifies the name of a PORT port. The name can contain up to 32 characters in English or 16 characters in Chinese.
Enabled/Disabled
Disabled, Enabled
Enabled indicates that this port is used and services are available. Disabled indicates that the services on this port are not processed. Hence, when configuring a service, you need to enable the port to be used.
Default value: Disabled
Working Mode
Auto-Negotiation, 100M FullDuplex, 1000M Full-Duplex Default value: AutoNegotiation NOTE l The EGT1 board supports only Auto-Negotiation, and 1000M Full-Duplex. l The EFS8 board supports Auto-Negotiation, and 100M Full-Duplex.
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Specifies the working mode of the Ethernet port on a board. This parameter determines the maximum transmission rate and communication mode of the Ethernet port. When setting this parameter, you must ensure the working modes of the interconnected ports are the same. Otherwise, the services are not available.
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Field
Value Range
Description
Maximum Frame Length
1518-9600
The Maximum Frame Length (Ethernet Port Attribute) parameter specifies the maximum frame length that is supported at an Ethernet port. You can click 7.2 Maximum Frame Length (Ethernet Port Attribute) to display the detailed information.
Default value: 1522
Port Physical Parameters
Displays the value that is queried.
Displays the actual working status of the port.
MAC Loopback
Non-Loopback, Inloop
The MAC Loopback (Ethernet Port Attribute) parameter specifies the MAC loopback state at an Ethernet port. Port loopback setting is applied to locating faults only. You can click 7.5 MAC Loopback (Ethernet Port Attribute) to display the detailed information.
Default value: Non-Loopback
PHY Loopback
Non-Loopback, Inloop Default value: Default Value
The PHY Loopback (Ethernet Port Attribute) parameter specifies the PHY loopback state at an Ethernet port. Port loopback setting is applied to locating faults only. You can click 7.6 PHY Loopback (Ethernet Port Attribute) to display the detailed information.
4.11.2 Flow Control This topic describes the parameters, such as autonegotiation and non-autonegotiation, which are used for configuring flow control function of an Ethernet port. Table 4-37 lists the parameters that are used for configuring flow control of an Ethernet port.
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Table 4-37 Parameters for configuring flow control of an Ethernet port Field
Value Range
Description
Port
PORTn
Displays all the available MAC ports on an Ethernet board. Specifies the PORT port. The letter n indicates the number of the PORT port.
Non-Autonegotiation Flow Control Mode
Disabled, Enable Symmetric Flow Control, Send Only, Receive Only Default value: Disable
Autonegotiation Flow Control Mode
Disabled, Enable Dissymmetric Flow Control, Enable Symmetric Flow Control, Enable Symmetric/ Dissymmetric Flow Control Default value: Disabled
The Non-Autonegotiation Flow Control Mode (Ethernet Port Attribute) specifies the flow control mode adopted when an Ethernet port works in nonauto-negotiation mode. You can click 7.3 NonAutonegotiation Flow Control Mode (Ethernet Port Attribute) to display the detailed information. The Autonegotiation Flow Control Mode (Ethernet Port Attribute) specifies the flow control mode adopted when an Ethernet port works in auto-negotiation mode. You can click 7.4 Autonegotiation Flow Control Mode (Ethernet Port Attribute) to display the detailed information.
4.11.3 Network Attributes This topic describes the parameters, such as port attribute and P port encapsulation format, which are used for configuring network attributes of an Ethernet port. Table 4-38 lists the parameters that are used for configuring network attributes of an Ethernet port.
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Table 4-38 Parameters for configuring network attributes of an Ethernet port Field
Value Range
Description
Port
PORTn or VCTRUNKn
Specifies the PORT or VCTRUNK port. The letter n indicates the number of the port.
Port Attributes
The value ranges of the parameters are different from each other for different boards and products. You can click the hyperlink in the description to display the specific information.
The Port Attributes (Ethernet Port) parameter specifies the position of a port in the network. Different port attributes support different packets. You can click 7.1 Port Attributes (Ethernet Port) to display the detailed information.
4.11.4 Advanced Attributes This topic describes the parameters, such as the loop detection, loop port shutdown, and traffic threshold (Mbit/s), which are used for configuring the advanced attributes of an Ethernet port. Table 4-39 lists the parameters that are used for configuring the advanced attributes of an Ethernet port. Table 4-39 Parameters for configuring the advanced attributes of an Ethernet port
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Field
Value Range
Description
Port
PORTn
Indicates the PORT. The letter n indicates the number of the PORT port.
Transmitting Rate (kbit/s)
For example: 0
Indicates the Transmitting Rate.
Receiving Rate (kbit/s)
For example: 0
Indicates the Receiving Rate.
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Field
Value Range
Description
Broadcast Packet Suppression
Enabled, Disabled
The Broadcast Packet Suppression (Ethernet Interface Attributes) parameter specifies whether to enable the function for a port to suppress the broadcast packets and to control the traffic of the broadcast data packets that enter the port. If the broadcast packet suppression function is enabled, and if the broadcast traffic exceeds the specified threshold value, the broadcast packets that enter the port are discarded.
Default value: Disabled
You can click 7.12 Broadcast Packet Suppression (Ethernet Interface Attributes) to display the detailed information. Broadcast Packet Suppression Threshold
10%-100% Default value: 30%
The Broadcast Packet Suppression Threshold (Ethernet Interface Attributes) parameter allocates the specified bandwidth to the broadcast packets. The bandwidth is allocated on the basis of the traffic proportion at the port. If the bandwidth allocated to the broadcast packets reaches the specified threshold, the port discards the broadcast data packets that are received. You can click 7.11 Broadcast Packet Suppression Threshold (Ethernet Interface Attributes) to display the detailed information.
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Field
Value Range
Description
Traffic Threshold(Mbit/s)
0-100 (FE), 0-1000 (GE), in step length of 1
The Traffic Threshold (Mbit/s) (External Ethernet Port Attribute) parameter specifies the data flow threshold at external physical ports.
Default value: 100 (FE), 1000 (GE)
You can click 7.10 Traffic Threshold(Mbit/s) (External Ethernet Port Attribute) to display the detailed information. Port Traffic Threshold Time Window(Min)
0-30 Default value: 0
The Port Traffic Threshold Time Window (Min) parameter specifies the duration for a VCTRUNK or a IP port to monitor the traffic after the zero traffic monitoring function of the port is enabled. You can click 7.14 Port Traffic Threshold Time Window(Min) to display the detailed information.
Loop Detection
Enabled, Disabled Default value: Disabled
The Loop Detection (Ethernet Port Attribute) parameter specifies the function of reporting the self-loop alarms after one of the following loopback cases is detected. You can click 7.8 Loop Detection (Ethernet Port Attribute) to display the detailed information.
Loop Port Shutdown
Enabled, Disabled Default value: Enabled
The Traffic Threshold (Mbit/s) (External Ethernet Port Attribute) parameter specifies the data flow threshold at external physical ports. You can click 7.9 Loop Port Shutdown (Ethernet Port Attribute) to display the detailed information.
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4.11.5 TAG Attributes Tag attributes are important attributes that are used for configuring Ethernet services, including the parameters such as the default VLAN ID, VLAN priority, ingress detection setting, and tag ID. Table 4-40 lists the parameters that are used for configuring the tag attributes of an Ethernet port. Table 4-40 Parameters for configuring the tag attributes of an Ethernet port Field
Value Range
Description
Port
PORTn
Specifies the PORT. The letter n indicates the number of the port.
TAG
Access, Tag Aware, Hybrid
The Tag Identifier parameter indicates that the Ethernet port supports IEEE 802.1Q Ethernet packets that contain VLAN tags. You can set three attributes to differentiate the packets from each other so that these packets can be transmitted efficiently.
Default value: Tag Aware
You can click 7.19 TAG to display the detailed information. Default VLAN ID
1-4095 Default value: 1
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The Default VLAN ID (Ethernet Port Attribute) parameter specifies the default VLAN ID of a port. You can click 7.16 Default VLAN ID (Ethernet Port Attribute) to display the detailed information.
VLAN Priority
0-7 Default value: 0
The VLAN Priority (Ethernet Port Attribute) parameter specifies the priority of the default VLAN ID of a port. It indicates the priority of the service quality. You can click 7.17 VLAN Priority (Ethernet Port Attribute) to display the detailed information.
Entry Detection
Enabled, Disabled Default value: Enabled
The Entry Detection (Ethernet Port Attribute) parameter specifies whether to identify the tag labels in the data packets. You can click 7.18 Entry Detection (Ethernet Port Attribute) to display the detailed information.
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4.11.6 Encapsulation/Mapping The equipment supports the setting of encapsulation and mapping protocols for Ethernet packets, including the parameters such as mapping protocol, scrambling code, and CRC or not. Table 4-41 lists the parameters that are used for configuring the encapsulation and mapping of an Ethernet port. Table 4-41 Parameters for configuring the encapsulation and mapping of an Ethernet port Field
Value Range
Description
Port
VCTRUNKn
Indicates the VCTRUNK port. The letter n indicates the number of the VCTRUNK port.
Mapping Protocol
GFP, LAPS, HDLC
The Mapping Protocol parameter specifies the mapping protocol of the VCTRUNK port. You can click 7.20 Mapping Protocol to display the detailed information.
Default value: GFP
Unscrambled, Scrambling mode[X43+1], Scrambling mode[X48+1]
Scramble
Default value: Scrambling mode[X43+1] NOTE The OptiX OSN 550 does not support Scramble mode[X48 +1].
The Scramble parameter specifies whether to scramble the payload area of the encapsulation protocol and the scramble mode. You can set this parameter only when the mapping protocol is GFP, HDLC, or LAPS. You can click 7.21 Scramble to display the detailed information.
Set Inverse Value for CRC
Yes, No Default value: Yes
The Set Inverse Value for CRC parameter specifies whether to set an inverse value for the CRC field of the HDLC or LAPS protocol. You can set this parameter only when the mapping protocol is HDLC or LAPS. You can click 7.22 Set Inverse Value for CRC to display the detailed information.
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Field
Value Range
Description
Check Field Length
The value ranges of the parameters are different from each other for different boards and products. You can click the hyperlink in the description to display the specific information.
The Check Field Length parameter specifies the length of the CRC field of the mapping protocol. You can set this parameter only when the mapping protocol is GFP, HDLC, or LAPS. You can click 7.23 Check Field Length to display the detailed information.
FCS Calculated Bit Sequence
The value ranges of the parameters are different from each other for different boards and products. You can click the hyperlink in the description to display the specific information.
The FCS Calculated Bit Sequence parameter specifies the sequence of storing the bits in the CRC field of the mapping protocol. You can set this parameter only when the mapping protocol is GFP, HDLC, or LAPS. You can click 7.24 FCS Calculated Bit Sequence to display the detailed information.
4.11.7 Bound Path This topic describes the parameters, such as available resources, available timeslots, and service direction, which are used for binding a path with an Ethernet port. Table 4-42 lists the parameters that are used for binding a path. Table 4-42 Parameters for bound path
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Field
Value Range
Description
Configurable Ports
For example: VCTRUNKn
Displays all the available VCTRUNK ports on the board.
Available Resources
For example: VC4-1
Displays all the available VC-4s.
Available Timeslots
For example: VC12-1
Displays all the available timeslots.
VCTRUNK Port
VCTRUNKn
Displays the number (n) of the VCTRUNK port.
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Field
Value Range
Description
Level
For example: VC12-xv
Specifies the level of a path that is bound with the VCTRUNK.
Service Direction
Bidirectional, Uplink, Downlink
Specifies the direction of the Ethernet service.
Default value: Bidirectional Bound Path
For example: VC4-1-VC12 (1-3)
Specifies the number of the path to be bound.
Bound Path Count
For example: 3
Displays the number of VCTRUNKs to be bound.
Used Channel
For example: Uplink:VC4-3VC3(1-3):3 Downlink:VC4-3-VC3(1-3): 3
Displays the actually used channel.
Activation Status
Active, Deactive
Displays whether the path is active.
Display in Combination
-
If you select Display in Combination, the bound paths are displayed in a centralized manner. Otherwise, the bound paths are displayed in a distributed manner.
4.12 Ethernet Service Configuration Parameters Ethernet services can be classified into Ethernet private line services and Ethernet private network services. Ethernet private line services include EPL services and EVPL services. Ethernet private network services include EPLAN services and EVPLAN services. 4.12.1 Configuring Ethernet Private Line Services This topic describes the parameters, such as operation type, service type, and encapsulation format of the P port, that are used for configuring Ethernet private line services. 4.12.2 Configuring Ethernet Private Network Services This section describes the parameters for configuring Ethernet private network services.
4.12.1 Configuring Ethernet Private Line Services This topic describes the parameters, such as operation type, service type, and encapsulation format of the P port, that are used for configuring Ethernet private line services. Table 4-43 lists the parameters that are used for configuring Ethernet private line services.
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Table 4-43 Parameters for configuring Ethernet private line services Field
Value Range
Description
Board
For example: NE501-5-EFS8
Displays the name of the board.
Service Type
The value ranges of the parameters are different from each other for different boards and products. You can click the hyperlink in the description to display the specific information.
The Service Type (EPL Service) parameter specifies the Ethernet private line service type. You can click 7.26 Service Type (EPL Service) to display the detailed information.
Service Direction
Bidirectional, Unidirectional
Specifies the transmission direction of the service.
Default value: Bidirectional
A bidirectional service refers to the two services that are transmitted from the source port to the sink port and from the sink port to the source port. A unidirectional service refers to the service that is transmitted from the source port to the sink port. Source Port
PORTn, RPRn For example: PORT3
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Specifies the name of the source port.
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Field
Value Range
Description
Source C-VLAN
Empty, 1-4095 Default value: Empty
The C-VLAN and S-VLAN parameter specifies the two types of VLAN tags defined in the QinQ service and IEEE 802.1ad. C-VLAN is taken as the client VLAN tag. SVLAN is taken as the service VLAN tag. C-VLAN Tag (C-TAG) indicates the VLAN tag on the client side, and S-VLAN Tag (STAG) indicates the VLAN tag at the service layer of the carrier. This parameter is applicable to the QinQ services. You can click 7.28 C-VLAN and SVLAN to display the detailed information.
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Field
Value Range
Description
Source S-VLAN
Empty, 1-4095 Default value: Empty
The C-VLAN and S-VLAN parameter specifies the two types of VLAN tags defined in the QinQ service and IEEE 802.1ad. C-VLAN is taken as the client VLAN tag. SVLAN is taken as the service VLAN tag. C-VLAN Tag (C-TAG) indicates the VLAN tag on the client side, and S-VLAN Tag (STAG) indicates the VLAN tag at the service layer of the carrier. This parameter is applicable to the QinQ services. You can click 7.28 C-VLAN and SVLAN to display the detailed information.
Sink Port
PORTn, RPRn For example: PORT3
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Specifies the name of the sink port.
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Field
Value Range
Description
Sink C-VLAN
Empty, 1-4095 Default value: Empty
The C-VLAN and S-VLAN parameter specifies the two types of VLAN tags defined in the QinQ service and IEEE 802.1ad. C-VLAN is taken as the client VLAN tag. SVLAN is taken as the service VLAN tag. C-VLAN Tag (C-TAG) indicates the VLAN tag on the client side, and S-VLAN Tag (STAG) indicates the VLAN tag at the service layer of the carrier. This parameter is applicable to the QinQ services. You can click 7.28 C-VLAN and SVLAN to display the detailed information.
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Field
Value Range
Description
Sink S-VLAN
Empty, 1-4095 Default value: Empty
The C-VLAN and S-VLAN parameter specifies the two types of VLAN tags defined in the QinQ service and IEEE 802.1ad. C-VLAN is taken as the client VLAN tag. SVLAN is taken as the service VLAN tag. C-VLAN Tag (C-TAG) indicates the VLAN tag on the client side, and S-VLAN Tag (STAG) indicates the VLAN tag at the service layer of the carrier. This parameter is applicable to the QinQ services. You can click 7.28 C-VLAN and SVLAN to display the detailed information.
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Activation Status
Active, Inactive
Displays the service status.
Operation Type
The value ranges of the parameters are different from each other for different boards and products. You can click the hyperlink in the description to display the specific information.
The Operation Type (EPL Service) parameter specifies whether to add, strip, translate or transparently transmit VLAN labels for service packets at a port when Service Type is set to EVPL(QinQ). You can click 7.25 Operation Type (EPL Service) to display the detailed information.
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Field
Value Range
Description
Port
For example: PORT3, VCTRUNK1
Displays the port name.
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Field
Value Range
Description
Port Type
l If a board supports the MPLS function, its port type can be set to PE or P. Default value: PE.
Specifies the network attribute of a port.
l If a board supports the QinQ function, its port type can be set to UNI, C-Aware, or S-Aware. Default value: UNI.
A provider edge (PE) port refers to the edge port that is provided by the service provider. A PE port can transmit and receive standard Ethernet frames, because its default MPLS encapsulation type is invalid. A provider (P) port refers to the port on the core network of the service provider. A P port can transmit and receive the packets that contain MPLS labels, because its default tag attribute is invalid. If a port is in UNI mode and processes 802.1Q tag attribute, this port has the Tag Aware, Access, and Hybrid attributes. If a port is in CAware mode, this port does not process the packets with 802.1Q tag attributes. In this case, this port considers that the accessed packets contain C-VLAN tags rather than SVLAN tags. If a port is in SAware mode, this port does not
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Value Range
Description process the packets with 802.1Q tag attributes. In this case, this port considers that the accessed packets contain S-VLAN tags rather than CVLAN tags.
Port Enabled
Enabled, Disabled Default value: Disabled
Indicates whether a port is enabled. Enabled: The port can access services. Disabled: The port cannot access services.
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Field
Value Range
Description
TAG
Tag Aware, Access, Hybrid
Specifies the type of a packet to be processed. If you set this parameter to be a Tag Aware port, the port processes only the packets that contain tags and discards the packets that do not contain tags. If you set this parameter to be an Access port, the port processes only the packets that do not contain tags and discards the packets that contain tags. If you set this parameter to be a Hybrid port, the port processes all the packets regardless of tags and adds tags to the received packets that do not contain tags according to the VLAN ID of the local port.
Default value: Tag Aware
You can click 7.19 TAG to display the detailed information. VCTRUNK Port
For example: VCTRUNK1
Displays the name of the VCTRUNK.
Level
VC12-xv, VC3-xv
Specifies the level of a path that is bound with the VCTRUNK.
Service Direction
Bidirectional, Uplink, Downlink
Indicates the direction of the Ethernet service.
Default value: Bidirectional
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Field
Value Range
Description
Bound Path
For example: VC4-4-VC12(1-2,4)
Specifies the number of a path to be bound, including the numbers of the VC-4, VC-12 or VC-3, and GE paths.
Bound Path Count
For example: 3
Displays the number of bound paths.
4.12.2 Configuring Ethernet Private Network Services This section describes the parameters for configuring Ethernet private network services. Table 4-44 lists the parameters that are used for configuring Ethernet private network services. Table 4-44 Parameters for configuring Ethernet private network services Field
Value Range
Description
Board
NE Name-Slot ID-Board Name
Displays the name of the board.
For example: NE(9-1)-4EFS8 VB ID
For example: 1
The VB ID is allocated automatically when you create a LAN service.
VB Name
Contains up to 16 characters or numerals in English or eight characters in Chinese.
Specifies the name of the VB.
For example: VB1 Bridge Type
802.1q, 802.1d, 802.1ad
Specifies the type of the VB.
Default value: 802.1q Bridge Switch Mode
IVL/Ingress Filter Enable, SVL/Ingress Filter Disable
Specifies the switching mode of the VB.
Default value: IVL/ Ingress Filter Enable
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Field
Value Range
Description
Bridge Learning Mode
IVL, SVL
Bridge Learning Mode (Ethernet LAN Service) indicates how the bridge learns the MAC address. Bridge Learning Mode is classified into the shared VLAN learning and independent VLAN learning modes. The shared VLAN learning mode indicates learning and forwarding based on the MAC address. The independent VLAN learning mode indicates learning and forwarding based on the VLAN and MAC address. You can click 7.30 Bridge Learning Mode (Ethernet LAN Service) to Displays the detailed information.
Ingress Filter
Enabled
Default value: IVL (The bridge type is compliant with IEEE 802.1q or IEEE 802.1ad), SVL (The bridge type is compliant with IEEE802.1d or IEEE 802.1ad)
Default value: Enabled
Displays the status of the ingress filter function. Enabled: The ingress port checks the validity of VLAN IDs based on the VB. If the packets received on the ingress port do not belong to the VLAN of the VB port, these packets are discarded.
MAC Address SelfLarning
Enabled Default value: Disabled
Indicates whether the MAC address learning function is enabled. Enabled: MAC addresses can be learnt.
Active
Active
Displays the activation status of the VB.
Table 4-45 Parameters for configuring service mount Field
Value Range
Description
VB Port
For example: 1
Displays the VB port. Allocated automatically when the VB mount port is configured.
Mount Port
For example: PORT1
Displays the mount port. The mount port may be the PORT port or VC trunk port.
Port Type
For example: UNI
Displays the network attributes for a port. Value Range: UNI, C-Aware, SAware. Default value: UNI
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Field
Value Range
Description
Encapsulation Format
MartinioE, stack VLAN
Displays the encapsulation format for a port of the P type. NOTE The OptiX OSN 550 does not support this parameter.
Port Enabled
Enabled, Disabled
Enables or disables a port. l Enabled: This port can access services. l Disabled: This port cannot access services.
Hub/Spoke
Hub, Spoke Default value: Hub
Hub/Spoke (Ethernet LAN Service) is used to separate packets between the logical ports in the network bridge. In the same VB VLAN filter or plain bridge: l Communication is available between ports configured with Hub. l Communication is available between a port configured with Spoke and a port configured with Hub. l Communication is unavailable between ports both configured with Spoke. Set this parameter according to the isolation domain range of the user.
TAG
Access, Tag Aware, Hybrid
Displays the tag attribute of the VB.
Default VLAN ID
For example: 1
Displays the VLAN ID.
Working Mode
Auto-Negotiation, 10M Half-Duplex, 10M FullDuplex, 100M Half-Duplex, 100M Full-Duplex, 1000M Half-Duplex, 1000M FullDuplex, 10G Full-Duplex LAN, 10G Full-Duplex WAN
Displays the working modes of the Ethernet port. Auto-Negotiation can automatically determine the optimized working modes of the connected ports. This mode is easy to maintain and is recommended.
NOTE l The EFS8 board supports Auto-Negotiation, and 100M Full-Duplex.
Active
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For example: Active
During configuration, make sure that working modes of the connected ports are consistent. If the working modes are different, the services are down.
Displays the activation status.
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Field
Value Range
Description
Service Direction
For example: Bidirectional
Displays the working modes of the Ethernet port.
C-VLAN
1 to 4095
Displays the C-VLAN value.
S-VLAN
1 to 4095
Displays the S-VLAN value.
C-VLAN Priority
-
Displays the priority of C-VLAN.
S-VLAN Priority
-
Displays the priority of S-VLAN.
Table 4-46 Parameters for configuring VLAN filtering Field
Value Range
Description
VLAN ID
1 to 4095
Displays the VLAN ID and configures the forwarding filter table.
VB Port
For example: (1,3-4)
Allocated automatically when the VB mount port is configured.
Forwarding Physical Port
For example: PORT1, VCTRUNK(5,8)
Displays the physical port that is actually attached to the VB link.
Activation Status
For example: Active
Activation Status (Ethernet LAN Service) indicates that the service at the port is in activation status.
Table 4-47 Parameters for configuring VLAN unicast
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Field
Value Range
Description
VLAN ID
1 to 4095
Only the VLAN ID specified in the forwarding filter table can be selected.
MAC Address
00-00-00-00-00-01 to FEFF-FF-FF-FF-FF
Displays the MAC address of VLAN unicast.
VB Port
For example: 1
Allocated automatically when the VB mount port is configured.
Physical Port
For example: PORT1
Displays the name of the port.
Aging Status
For example: Static
Displays the aging status of unicast items, including static and dynamic.
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Table 4-48 Parameters for configuring disable MAC address Field
Value Range
Description
VLAN ID
1 to 4095
Inhibits a MAC address in the VLAN of a certain VB.
MAC Address
00-00-00-00-00-01 to FEFF-FF-FF-FF-FF
Enters a MAC address that is to be inhibited. Hence, enters a MAC address that is not associated to the VLAN unicast of this VLAN.
Table 4-49 Parameters for bound path Field
Value Range
Description
Configurable Ports
For example: VCTRUNKn
Displays all the available VCTRUNK ports on the board.
Available Resources
For example: VC4-1
Displays all the available VC-4s.
Available Timeslots
For example: VC12-1
Displays all the available timeslots.
VCTRUNK Port
VCTRUNKn
Displays the number (n) of the VCTRUNK port.
Level
For example: VC12-xv
Specifies the level of a path that is bound with the VCTRUNK.
Service Direction
Bidirectional, Uplink, Downlink
Specifies the direction of the Ethernet service.
Default value: Bidirectional
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Bound Path
For example: VC4-1-VC12 (1-3)
Specifies the number of the path to be bound, for example, VC4-1-VC12(1-3).
Bound Path Count
For example: 3
Displays the number of VCTRUNKs to be bound.
Activation Status
Active, Deactive
Displays whether the path is active.
Display in Combination
-
If you select Display in Combination, the bound paths are displayed in a centralized manner. Otherwise, the bound paths are displayed in a distributed manner.
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5 Modifying the Configuration Data
Modifying the Configuration Data
About This Chapter You can modify the existing configuration data related to the topology and services. 5.1 Changing the Values of NE Attributes You can change the values of the NE attributes. 5.2 Modifying the Board Configuration Data You can modify the existing board configuration data. 5.3 Modifying the Fiber Configuration Data You can modify the existing fiber configuration data. 5.4 Modifying the Service Configuration Data You can modify the existing service configuration data according to the requirements. 5.5 Modifying the Protection Subnet This topic describes how to modify the configuration data of the existing protection subnet.
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5.1 Changing the Values of NE Attributes You can change the values of the NE attributes. 5.1.1 Changing the NE ID The ECC protocol uses the NE ID as the unique identifier of an NE. You need to assign a unique NE ID to each NE when planning a network. If an NE ID is the same as another NE ID, certain ECC routes conflict with each other. As a result, the U2000 fail to manage certain NEs. You can use the U2000 to change the NE ID when the original network planning needs to be modified during the system commissioning or expansion. 5.1.2 Changing the NE Name You can change the NE name according to the requirements. Changing the NE name does not affect the operation of the NE. 5.1.3 Deleting an NE If you have created a wrong NE, you can delete the NE from the U2000. Deleting an NE removes all the information about the NE from the U2000 but does not affect the operation of the equipment. 5.1.4 Changing the Parameter Values of the Gateway NE During the network optimization and adjustment, you may need to change the type of the gateway NE or modify the communication address of the gateway NE. 5.1.5 Changing the Gateway NE of a Non-Gateway NE When changes occur on the only gateway NE to which a non-gateway NE belongs, you need to assign this non-gateway NE to belong to another gateway NE. Otherwise, the communication between this NE and the U2000 fails. If a gateway NE manages more than 50 NEs, it is recommended that you assign certain NEs to belong to other gateway NEs to prevent the communication between the U2000 and the NEs from being affected.
5.1.1 Changing the NE ID The ECC protocol uses the NE ID as the unique identifier of an NE. You need to assign a unique NE ID to each NE when planning a network. If an NE ID is the same as another NE ID, certain ECC routes conflict with each other. As a result, the U2000 fail to manage certain NEs. You can use the U2000 to change the NE ID when the original network planning needs to be modified during the system commissioning or expansion.
Prerequisite l
The NE must be created.
l
You must be an NM user with "NE operator" authority or higher.
Precautions
CAUTION Changing the NE ID may interrupt the NE communication.
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Procedure Step 1 In the NE Explorer, select an NE and then choose Configuration > NE Attribute from the Function Tree. Step 2 Click Modify NE ID. Then, the Modify NE ID dialog box is displayed. Step 3 Enter New ID and New Extended ID. Then, click OK. Step 4 Click OK in the Warning dialog box that is displayed. ----End
5.1.2 Changing the NE Name You can change the NE name according to the requirements. Changing the NE name does not affect the operation of the NE.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 In the NE Explorer, click the NE and choose Configuration > NE Attribute from the Function Tree. Step 2 In NE Attribute list, enter a new NE name in Name. Click Apply. Then, a dialog box is displayed, indicating that the operation is successful. NOTE
An NE name can contain a maximum of 64 letters, symbols, and numerals, but cannot contain the following special characters: | : * ? " < >.
Step 3 Click Close. ----End
5.1.3 Deleting an NE If you have created a wrong NE, you can delete the NE from the U2000. Deleting an NE removes all the information about the NE from the U2000 but does not affect the operation of the equipment.
Prerequisite You must be an NM user with "NM maintainer" authority or higher.
Precautions
CAUTION If an NE is deleted, the links related to the NE are also deleted.
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Procedure l
l
Delete a single NE. 1.
Right-click the NE on the Main Topology and choose Delete from the shortcut menu. The Confirm dialog box is displayed.
2.
Click Yes. The Deletion Result dialog box is displayed.
3.
Click Close, The NE icon is deleted from the Main Topology.
Delete NEs in batches. 1.
Choose Configuration > NE Configuration Data Management from the Main Menu. Then, the NE Configuration Data Management window is displayed.
2.
. Then, the In the pane on the left, select multiple NEs and click Configuration Data Management List pane displays the configuration data of all the selected NEs.
3.
Right-click the NEs to be deleted and then choose Delete from the shortcut menu. The Delete the NE dialog box is displayed.
4.
Click OK to delete the selected NEs.
----End
5.1.4 Changing the Parameter Values of the Gateway NE During the network optimization and adjustment, you may need to change the type of the gateway NE or modify the communication address of the gateway NE.
Prerequisite You must be an NM user with "NE maintainer" authority or higher.
Precautions
CAUTION Changing the parameter values of the gateway NE may interrupt the communication.
Procedure Step 1 Choose Administration > DCN Management from the Main Menu. Step 2 In the Filter NE window that is displayed, choose the NEs. Click OK. Step 3 Click the GNE tab. Select the gateway NE whose parameter values need to be changed. Rightclick and choose Modify GNE from the shortcut menu. Step 4 In the Modify GNE dialog box that is displayed, set Gateway Type. l 5-4
When Gateway Type is set to IP Gateway, change IP Address. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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5 Modifying the Configuration Data
When Gateway Type is set to OSI Gateway, change NSAP Address.
NOTE
l It is recommended that you do not change Port No.. l Ensure that the IP address of the gateway NE is in the same network segment as the IP address of the U2000. If they are not in the same network segment, set the corresponding network ports so that the U2000 can log in to the gateway NE.
Step 5 Click OK. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
5.1.5 Changing the Gateway NE of a Non-Gateway NE When changes occur on the only gateway NE to which a non-gateway NE belongs, you need to assign this non-gateway NE to belong to another gateway NE. Otherwise, the communication between this NE and the U2000 fails. If a gateway NE manages more than 50 NEs, it is recommended that you assign certain NEs to belong to other gateway NEs to prevent the communication between the U2000 and the NEs from being affected.
Procedure Step 1 Choose Administration > DCN Management from the Main Menu. Step 2 Click the NE tab. Issue 02 (2011-06-30)
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Step 3 Double-click the Primary GNE1 field and select a gateway NE from the drop-down list. Step 4 Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. Step 5 Click Refresh. ----End
5.2 Modifying the Board Configuration Data You can modify the existing board configuration data. 5.2.1 Adding Boards When manually configuring the NE data, you need to add the boards to the NE panel. You can add the physical boards that actually operate on the NE or the logical boards that do not exist on the NE to the NE panel. 5.2.2 Deleting Boards To modify the network configuration or the NE configuration, you need to delete the boards from the NE panel. 5.2.3 Modifying Board Configuration Parameters You can modify the existing board configuration data.
5.2.1 Adding Boards When manually configuring the NE data, you need to add the boards to the NE panel. You can add the physical boards that actually operate on the NE or the logical boards that do not exist on the NE to the NE panel.
Prerequisite l
The NE must be created.
l
There must be idle slots on the NE panel.
l
You must be an NM user with "NE maintainer" authority or higher.
Background Information l
The physical boards are the actual boards inserted in the subrack. The logical boards are created on the U2000 and are saved on the SCB board, but they do not exist on the actual equipment.
l
The NE panel shows the mapping relations between the slots that house the processing boards and the slots that house the interface boards. If you click a processing board that is paired with an interface board on the NE panel, the ID of the slot that houses the mapping interface board is displayed in orange.
Procedure Step 1 Double-click the icon of the NE to open the NE panel. Step 2 Right-click the selected idle slot. Select the board you need to add from the drop-down list. 5-6
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NOTE
If the physical cross-connect board is installed in the subrack, add its corresponding logical board on the U2000.
----End
5.2.2 Deleting Boards To modify the network configuration or the NE configuration, you need to delete the boards from the NE panel.
Prerequisite l
The services and protection groups must be deleted.
l
You must be an NM user with "NE maintainer" authority or higher.
Procedure Step 1 Double-click the icon of the NE to display the NE Panel. Step 2 Right-click the board you need to delete and choose Delete from the shortcut menu. Step 3 Click OK in the Delete Board dialog boxes that are displayed sequentially. ----End
5.2.3 Modifying Board Configuration Parameters You can modify the existing board configuration data.
Prerequisite To change the values of different configuration parameters of different boards, you may need to operate as NM users with different authorities. You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 In the NE Explorer, select a board and choose the appropriate function entry from the Function Tree. Board Type
Parameter
SDH board
Laser Switch, Optical(Electrical) Interface Loopback, VC4 Loopback
PDH board
Tributary Loopback, Service Load Indication, Re-timing Mode
Step 2 In the pane on the right, modify the existing parameter settings and click Apply. ----End Issue 02 (2011-06-30)
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5.3 Modifying the Fiber Configuration Data You can modify the existing fiber configuration data. 5.3.1 Deleting Fibers If you need to delete an NE or change the links between NEs during network adjustment, delete the related fiber connections between the NEs. 5.3.2 Changing Fiber/Cable Information You can change the name, attenuation, length, and type of a fiber/cable according to its connection status and physical features. 5.3.3 Deleting DCN Communication Cables In certain scenarios such as network adjustment, you can delete the DCN communication cable that is not applicable.
5.3.1 Deleting Fibers If you need to delete an NE or change the links between NEs during network adjustment, delete the related fiber connections between the NEs.
Prerequisite You must be an NM user with "NE maintainer" authority or higher.
Procedure Step 1 Choose Inventory > Fiber/Cable > Fiber/Cable Management from the Main Menu. Step 2 Right-click the fiber you need to delete and then choose Delete Fiber/Cable from the shortcut menu. Then, the Warning dialog box is displayed. Click OK to delete the fiber. Step 3 Click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
5.3.2 Changing Fiber/Cable Information You can change the name, attenuation, length, and type of a fiber/cable according to its connection status and physical features.
Prerequisite You must be an NM user with "NE maintainer" authority or higher.
Procedure Step 1 Choose Inventory > Fiber/Cable > Fiber/Cable Management from the Main Menu. All the fiber information is displayed in the right pane. Step 2 Select a fiber, right-click and choose Modify Fiber/Cable from the shortcut menu. In the Modify Fiber/Cable dialog box, you can modify Name, Length(km), Attenuation, Medium Type, 5-8
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Maintainer, Remarks, and Disabled Status. Click OK. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
5.3.3 Deleting DCN Communication Cables In certain scenarios such as network adjustment, you can delete the DCN communication cable that is not applicable.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 On the Main Topology, right-click the cable and choose Delete from the shortcut menu. Step 2 Click Yes in the Confirm dialog box that is displayed. ----End
5.4 Modifying the Service Configuration Data You can modify the existing service configuration data according to the requirements. 5.4.1 Modifying SDH Services To modify an SDH service, you can use the modification function of the U2000, or delete the service and then create the cross-connection again. 5.4.2 Deleting SDH Services You can delete an existing SDH service. 5.4.3 Deleting Ethernet Private Line Services Ethernet private line services need to be deleted when the Ethernet boards that are configured with the Ethernet private line services need to be deleted or when the service configuration is incorrect. 5.4.4 Deleting EPLAN Services EPLAN services need to be deleted when the Ethernet boards that are configured with the EPLAN services need to be deleted or when the configuration of the EPLAN services is incorrect. 5.4.5 Deleting EVPLAN Services EVPLAN services need to be deleted when the Ethernet boards that are configured with the EVPLAN services need to be deleted or when the configuration of the EVPLAN services is incorrect.
5.4.1 Modifying SDH Services To modify an SDH service, you can use the modification function of the U2000, or delete the service and then create the cross-connection again.
Prerequisite You must be an NM user with "NE operator" authority or higher. Issue 02 (2011-06-30)
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Precautions
CAUTION Performing this operation interrupts the service that you modify.
Procedure Step 1 In the NE Explorer, select an NE and choose Configuration > SDH Service Configuration from the Function Tree. Step 2 Select a cross-connection and choose Display > Expand to Unidirectional. Step 3 If the service to be modified is active, you should deactivate the service. Select the service that you need to modify and then click Deactivate.
CAUTION Deactivation interrupts the services. Step 4 Click OK in the Confirm dialog box that is displayed third. The Operation Result dialog box is displayed, indicating that the operation is successful. Step 5 Click Close. Step 6 After the cross-connection is deactivated, modify the SDH service by using the method described in Step Step 7 or Step 8. NOTE
l By using the method described in Step Step 7, you can modify the source or sink of a service. Ensure that the service source and sink are located on the same board before and after the modification. l If the modification requirement cannot be met by using the method described in Step Step 7 (for example, a pass-through service needs to be configured to the local equipment through modification), you can delete the original service and create the cross-connection again by using the method described in Step Step 8.
Step 7 Optional: To modify the SDH service, choose Modify from the shortcut menu. 1.
Right-click the service that you need to modify and choose Modify from the shortcut menu. Then, the Modify SDH Service dialog box is displayed.
2.
Change Source VC4 or Sink VC4, Source Timeslot Range, and Sink Timeslot Range. NOTE
By using this method, you can change only Source VC4 or Sink VC4. The source VC-4 and sink VC-4 cannot be modified at the same time.
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3.
Click OK. Then, the Operation Result dialog box is displayed, indicating that the operation is successful.
4.
Click Close.
5.
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6.
Click OK. Then, the Operation Result dialog box is displayed, indicating that the operation is successful.
7.
Click Close.
Step 8 Optional: To modify the SDH service, delete the service and then create the service again. 1.
Select the service that you need to modify and click Delete.
2.
Click OK. Then, the Operation Result dialog box is displayed, indicating that the operation is successful.
3.
Click Close. The service is deleted.
4.
Create the service again according to the requirements. For details, see Creating SDH Services.
----End
5.4.2 Deleting SDH Services You can delete an existing SDH service.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 In the NE Explorer, select an NE and choose Configuration > SDH Service Configuration from the Function Tree. Step 2 Click Query to query the existing services. Step 3 If the service to be deleted is active, you should deactivate the service first. Select the service that you need to delete and click Deactivate.
CAUTION Deactivation interrupts the services. Step 4 Select the service to be deleted and click Delete. Step 5 Click OK in the Confirm dialog box that is displayed. Step 6 Click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
5.4.3 Deleting Ethernet Private Line Services Ethernet private line services need to be deleted when the Ethernet boards that are configured with the Ethernet private line services need to be deleted or when the service configuration is incorrect. Issue 02 (2011-06-30)
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Prerequisite You must be an NM user with "NE operator" authority or higher.
Procedure Step 1 In the NE Explorer, select an Ethernet board and then choose Configuration > Ethernet Service > Ethernet Line Service from the Function Tree. Step 2 Click Query. Step 3 Select the Ethernet private line service to be deleted and click Delete. Click OK in the Prompt dialog box that is displayed. Then, a dialog box is displayed, indicating that the operation is successful, that is, the Ethernet private line service is deleted successfully. Step 4 Click Query to check whether the Ethernet private line service is deleted. Step 5 See 5.4.2 Deleting SDH Services to delete the cross-connections of the Ethernet private line service. ----End
5.4.4 Deleting EPLAN Services EPLAN services need to be deleted when the Ethernet boards that are configured with the EPLAN services need to be deleted or when the configuration of the EPLAN services is incorrect.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Context
CAUTION When the EPLAN services are deleted, the VLAN unicast entries and disabled MAC address entries are deleted.
Procedure Step 1 In the NE Explorer, select an Ethernet board, and then choose Configuration > Ethernet Service > Ethernet LAN Service from the Function Tree. Step 2 Click Query. Step 3 Select the EPLAN service to be deleted and click Delete. Click OK in the Prompt dialog box that is displayed. Then, a dialog box is displayed, indicating that the operation is successful, that is, the EPLAN service is deleted successfully. Step 4 Click Query to check whether the EPLAN service is deleted. Step 5 See 5.4.2 Deleting SDH Services to delete the cross-connections of the EPLAN service. ----End 5-12
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5.4.5 Deleting EVPLAN Services EVPLAN services need to be deleted when the Ethernet boards that are configured with the EVPLAN services need to be deleted or when the configuration of the EVPLAN services is incorrect.
Prerequisite You must be an NM user with "NE operator" authority or higher.
Background Information Deleting an EVPLAN service involves the following: 1.
Deleting the VLAN filtering table
2.
Deleting the service mounting configurations
Context
CAUTION When the VLAN filtering table is deleted, the VLAN unicast entries and disabled MAC address entries are deleted.
Procedure Step 1 In the NE Explorer, select an Ethernet board and then choose Configuration > Ethernet Service > Ethernet LAN Service from the Function Tree. Step 2 Click Query. Step 3 Click the VLAN Filtering tab. Step 4 Select the VLAN filtering entry to be deleted and click Delete. Step 5 Click the Service Mount tab. Step 6 Select the EVPLAN service to be deleted and click Delete. Click OK in the Prompt dialog box that is displayed. Then, a dialog box is displayed, indicating that the operation is successful, that is, the EVPLAN service is deleted successfully. Step 7 Click Query to check whether the EVPLAN service is deleted. Step 8 See 5.4.2 Deleting SDH Services to delete the cross-connections of the EVPLAN service. ----End
5.5 Modifying the Protection Subnet This topic describes how to modify the configuration data of the existing protection subnet. 5.5.1 Deleting Protection Subnets Issue 02 (2011-06-30)
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Before you delete an NE or a fiber/cable connection on the U2000, you need to delete the related protection subnets. 5.5.2 Changing the Values of Protection Subnet Parameters In the case of the SDH equipment, you can set the parameters of the MSP protection subnet by using the protection subnet maintenance function.
5.5.1 Deleting Protection Subnets Before you delete an NE or a fiber/cable connection on the U2000, you need to delete the related protection subnets.
Prerequisite l
You must be an NM user with "network maintainer" authority or higher.
l
If trails are configured on the protection subnet that you need to delete, delete the trails first.
Procedure Step 1 Choose Service > SDH Protection Subnet > Manage SDH Protection Subnet from the Main Menu. Step 2 Right-click the protection subnet to be deleted and choose Delete from the NM, Delete from the NE, or Delete All from the NM from the short-cut menu. NOTE
The methods of deleting a protection subnet are as follows: l Delete from the NM: If Delete from the NM is selected, the relations between the protection subnet and each logical system on the NE side are deleted so that the fibers can be deleted and reloading can be performed. This command is not delivered to the NE and does not affect the services. The deleted protection subnet can be located by using the search feature. The U2000 locates it according to the NE layer protection information. l Delete from the NE: If Delete from the NE is selected, the protection subnet, logical systems on the NE side, and all the services on the protection subnet are deleted. The deleted protection subnet cannot be restored and needs to be created again. l Delete All from the NM: If Delete All from the NM is selected, the data of the protection subnet except the fibers at the network layer is deleted. The deleted protection subnet can be located by using the search feature. It is recommended that you do not select this option, because a large amount of data is deleted.
Step 3 Click Yes in the Operation Prompt dialog box indicating that the operation succeeded. Then, the Operation Result dialog box is displayed. NOTE
If Delete from the NE is selected, you need to confirm the operation again.
Step 4 Click Close. ----End
5.5.2 Changing the Values of Protection Subnet Parameters In the case of the SDH equipment, you can set the parameters of the MSP protection subnet by using the protection subnet maintenance function. 5-14
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Prerequisite l
You must be an NM user with "network maintainer" authority or higher.
l
The data of each NE must be configured and the fibers must be created on the U2000.
l
The MSP protection subnet must be configured.
Procedure Step 1 Choose Service > SDH Protection Subnet > Maintain SDH Protection Subnet from the Main Menu. Then, the SDH Protection Subnet Common Attributes dialog box is displayed. Step 2 Select an MSP protection subnet from the pane on the left. The attribute information of the protection subnet is displayed in the pane on the right. Step 3 Click the Protection Subnet Parameters tab. Step 4 Click Query to query the parameters of the protection subnet on the MSP ring. Step 5 Click the WTR Time(s) text box and enter a value. NOTE
The default WTR time is 600s. You can also set the WTR time to a value from 300s to 720s.
Step 6 Optional: Select SD Condition. Step 7 Click Apply. Then, click Close in the Operation Result dialog box indicating that the operation succeeded. ----End
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6 Equipment Information
Equipment Information
About This Chapter You need to consider the service support capability of the boards used by the equipment and the configuration requirements during the configuration process. 6.1 Service Support Capability of Ethernet Boards Ethernet boards are classified into Ethernet transparent transmission boards and Ethernet switching boards, based on the type of the accessed service. The Ethernet transparent transmission boards support only EPL services, whereas the Ethernet switching boards support EPL services, EVPL services, and Layer 2 switching function. 6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards One VCTRUNK on an Ethernet board can only be bound with timeslots of the same level. 6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards To determine the level of the bandwidths to be bound with a VCTRUNK and the number of paths that are required for an Ethernet service, you need to calculate the theoretical bandwidth of the Ethernet service that can be carried by a VCTRUNK.
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6.1 Service Support Capability of Ethernet Boards Ethernet boards are classified into Ethernet transparent transmission boards and Ethernet switching boards, based on the type of the accessed service. The Ethernet transparent transmission boards support only EPL services, whereas the Ethernet switching boards support EPL services, EVPL services, and Layer 2 switching function. Table 6-1 Service support capability of Ethernet boards Board Type
Board Name
Supported EPL Service
Supported EPLAN Service
Ethernet transparent transmission board
EGT1
EPL
-
Ethernet switching board
EFS8
EPL
EVPLAN (IEEE 802.1q bridge), EPLAN (IEEE 802.1d bridge), and EVPLAN (IEEE 802.1ad bridge)
EVPL
6.2 Requirements for Binding Paths with VCTRUNKs on Ethernet Boards One VCTRUNK on an Ethernet board can only be bound with timeslots of the same level. Table 6-2 Requirements for binding paths with VCTRUNKs on Ethernet boards Board
Requirement for Binding Paths with a VCTRUNK
EGT1
l The VCTRUNKs can be bound with the VC-12 VC-3 and VC-4 paths. l Only one VCTRUNK with a maximum bandwidth of 1.25 Gbit/s is supported. l VCTRUNK1 can only be bound with the fourth VC-4, namely, VC4-4, if the path binding is at VC-12 level. l VCTRUNK1 can be bound with the first to eighth VC-4s, namely, VC4-1 to VC4-8, if the path binding is at VC-3 level.
EFS8
l The VCTRUNKs can be bound with the VC-12 paths and VC-3 paths. l Eight VCTRUNKs are supported. The maximum bandwidth of each VCTRUNK is 100 Mbit/s. l VCTRUNK1 to VCTRUNK8 can only be bound with the fourth VC-4, namely, VC4-4, if the path binding is at VC-12 level. l VCTRUNK1 to VCTRUNK8 can be bound with the first to fourth VC-4s, namely, VC4-1 to VC4-4, if the path binding is at VC-3 level.
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6.3 Ethernet Service Bandwidths Carried by VCTRUNKs of Ethernet Boards To determine the level of the bandwidths to be bound with a VCTRUNK and the number of paths that are required for an Ethernet service, you need to calculate the theoretical bandwidth of the Ethernet service that can be carried by a VCTRUNK. Bandwidth = Number of paths bound with the VCTRUNK x Payload rate of the binding granularity x Encapsulation efficiency of the encapsulation protocol The payload rate of the VC-12 is 2.176 Mbit/s; the payload rate of the VC-3 is 48.384 Mbit/s; the payload rate of the VC-3 is 149.760 Mbit/s. GFP encapsulation efficiency has different values in the following two scenarios: l
GFP encapsulation efficiency = Ethernet frame length/(Ethernet frame length + 12-byte overhead), when the GFP protocol uses FCS32 as the check field.
l
GFP encapsulation efficiency = Ethernet frame length/(Ethernet frame length + 8-byte overhead), when the GFP protocol does not add the check field. NOTE
When the Ethernet board uses the GFP protocol to encapsulate Ethernet services, you can determine whether a check field is used during the encapsulation by setting the Check Field Length parameter. By default, FCS32 is used as the check field. In this case, if the Ethernet board uses the default GFP parameter settings, the theoretical bandwidth of the VCTRUNK bound with five VC-12 paths is 10.938 Mbit/s when the Ethernet frame length is 1500 bytes and the theoretical bandwidth of the VCTRUNK bound with five VC-12 paths is 12.025 bit/s when the Ethernet frame length is 64 bytes.
In actual situations, you can estimate the level and quantity of the paths according to the following principle: One VC-12 path carries 2 Mbit/s services; one VC-3 path carries 48 Mbit/ s services; one VC-4 path carries 150 Mbit/s services. For example, in the case of a 10 Mbit/s Ethernet service, the VCTRUNKs can be bound with five VC-12 paths.
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7
List of Parameters
About This Chapter This section describes all the parameters that are used for configuring and querying the common boards and functions on the U2000. Each parameter is described in terms of the description, impact on the system, values, configuration guidelines, and relationship with other parameters. 7.1 Port Attributes (Ethernet Port) 7.2 Maximum Frame Length (Ethernet Port Attribute) 7.3 Non-Autonegotiation Flow Control Mode (Ethernet Port Attribute) 7.4 Autonegotiation Flow Control Mode (Ethernet Port Attribute) 7.5 MAC Loopback (Ethernet Port Attribute) 7.6 PHY Loopback (Ethernet Port Attribute) 7.7 QinQ Type Area 7.8 Loop Detection (Ethernet Port Attribute) 7.9 Loop Port Shutdown (Ethernet Port Attribute) 7.10 Traffic Threshold(Mbit/s)(External Ethernet Port Attribute) 7.11 Broadcast Packet Suppression Threshold (Ethernet Interface Attributes) 7.12 Broadcast Packet Suppression (Ethernet Interface Attributes) 7.13 Zero-Flow Monitor (Ethernet Interface Attributes) 7.14 Port Traffic Threshold Time Window(Min) 7.15 Jumbo Frame Type 7.16 Default VLAN ID (Ethernet Port Attribute) 7.17 VLAN Priority (Ethernet Port Attribute) 7.18 Entry Detection (Ethernet Port Attribute) 7.19 TAG Issue 02 (2011-06-30)
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7.20 Mapping Protocol 7.21 Scramble 7.22 Set Inverse Value for CRC 7.23 Check Field Length 7.24 FCS Calculated Bit Sequence 7.25 Operation Type (EPL Service) 7.26 Service Type (EPL Service) 7.27 Encapsulation Format of P Port (Network Attributes) 7.28 C-VLAN and S-VLAN 7.29 VLAN ID (For Creation of Ethernet Virtual Private Lines) 7.30 Bridge Learning Mode (Ethernet LAN Service) 7.31 MEP ID (Ethernet OAM) 7.32 Maintenance Point Type (Ethernet OAM) 7.33 CC Status (Ethernet OAM) 7.34 Test Result (LB and LT Test) 7.35 Responding MP Type (Ethernet LT Test) 7.36 Hop Count (Ethernet LT Test) 7.37 Packet Length (Ping Test) 7.38 Timeout (Ping Test) 7.39 Detect Attempts 7.40 Send Direction (Ethernet Test) 7.41 Error Frame Monitor Window (ms) 7.42 Error Frame Monitor Threshold(Entries) 7.43 Error Frame Period Window(Frames) 7.44 Error Frame Monitor Threshold(Frames) 7.45 Error Frame Second Window (s) 7.46 Error Frame Second Threshold(s) 7.47 Enable OAM Protocol 7.48 OAM Working Mode 7.49 Remote Alarm Support for Link Event 7.50 Unidirectional Operation 7.51 Loopback Status (OAM Parameter) 7.52 Flow Type (Flow Configuration) 7-2
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7.53 Bound CAR (Flow Configuration) 7.54 Bound CoS (Flow Configuration) 7.55 CAR ID (CAR Configuration) 7.56 Enabled/Disabled (CAR Configuration) 7.57 Committed Information Rate (kbit/s) (CAR Configuration) 7.58 Committed Burst Size (kbyte) (CAR Configuration) 7.59 Peak Information Rate (kbit/s) (CAR Configuration) 7.60 Maximum Burst Size (kbyte) (CAR Configuration) 7.61 CoS ID (CoS Configuration) 7.62 CoS Type (CoS Configuration) 7.63 CoS Priority (CoS Configuration) 7.64 Port Priority (Link Aggregation) 7.65 System Priority (Link Aggregation) 7.66 Status (Link Aggregation) 7.67 Load Sharing(Ethernet Link Aggregation) 7.68 Protocol Enabled (Spanning Tree) 7.69 Protocol Type (Spanning Tree Protocol) 7.70 Priority (Bridge Parameters) 7.71 Max Age(s) 7.72 Hello Time(s) (Spanning Tree) 7.73 Forward Delay(s) (Spanning Tree) 7.74 TxHoldCount(per second) (Spanning Tree) 7.75 Root Path Cost 7.76 Hold Count (Spanning Tree) 7.77 Port ID 7.78 Designated Path Cost 7.79 Designated Root Bridge Priority 7.80 Designated Bridge Priority(Spanning Tree) 7.81 Designated Bridge MAC Address (Spanning Tree) 7.82 Edge Port Status (Spanning Tree) 7.83 Point to Point Attributes(External Ethernet Port Attributes) 7.84 Enabling LCAS 7.85 LCAS Mode Issue 02 (2011-06-30)
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7.86 Hold-Off Time (ms) (LCAS) 7.87 WTR Time (s) (LCAS) 7.88 TSD (LCAS) 7.89 Min Members - Transmit Direction 7.90 LPT 7.91 Bearer Mode 7.92 Port-Type Port Hold-Off Time (ms) 7.93 VCTRUNK Port Hold-off Time (ms) 7.94 Protocol Enable (IGMP Snooping Protocol) 7.95 Multicast Aging Time(Min) 7.96 Frames to Send 7.97 Status 7.98 Set Frame Count 7.99 Received Response Test Frame Count 7.100 Test Frames to Receive 7.101 Send Mode (Ethernet Test) 7.102 Call Waiting Time(s) 7.103 Conference Call 7.104 Phone 7.105 Available Orderwire Port 7.106 No.(F1 Data Port) 7.107 Data Channel (F1 Data Port) 7.108 Overhead Byte (Broadcast Data Port) 7.109 Working Mode (Broadcast Data Port) 7.110 Broadcast Data Source (Broadcast Data Port) 7.111 Broadcast Data Sink (Broadcast Data Port) 7.112 External Clock Output Mode When 2M Output Synchronous Source Is Invalid 7.113 External Clock Output Mode 7.114 External Clock Output Timeslot 7.115 External Source Output Threshold 7.116 2M Phase-Locked Source Fail Condition 7.117 2M Phase-Locked Source Fail Action 7.118 Clock Source Threshold 7-4
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7.119 AIS Alarm Generated 7.120 B1 BER Threshold-Crossing Generated 7.121 B2-EXC Alarm Generated 7.122 Higher Priority Clock Source Reversion Mode 7.123 Clock Source WTR Time 7.124 Lock Status 7.125 Synchronous Source 7.126 S1 Byte Synchronization Quality Information 7.127 NE Clock Working Mode 7.128 Data Output Method in Holdover Mode 7.129 Retiming Mode 7.130 Switching Mode (MSP)
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7.1 Port Attributes (Ethernet Port) Description The Port Attributes (Ethernet Port) parameter specifies the position of a port in the network. Different port attributes support different packets.
Impact on the System The system operation is not affected.
Values Board Name
Valid Values
Default Value
EFS8
UNI, C-Aware, S-Aware
UNI
The following table lists the description of each value. Value
Description
UNI
Indicates the interface between CE and PE. This port processes the packets with TAG attributes specified in IEEE 802.1Q. Moreover, this port identifies and processes the VLAN IDs of the received packets according to the supported Tag Aware, Access or Hybrid.
C-Aware
A C-Aware (C-VLAN Aware) port in the network is located in the position as the UNI port at the client access side. This port identifies and processes the VLAN (C-VLAN) in the packets. If the value of QinQ TYPE is valid, this port treats the outer labels of the packets as C-VLAN.
S-Aware
A S-Aware (S-VLAN Aware) port in the network is located in the position as the interface on the network side. This port identifies and processes the VLAN (S-VLAN) in the packets. If the value of QinQ TYPE is valid, this port treats the outer labels of the packets as S-VLAN.
Configuration Guidelines The port attribute depends on the port position in the network and the service. For this reason, select a proper port attribute as required. Generally, select the default value.
7-6
l
For the MPLS service, select P for the port that transmits or receives packets with MPLS labels.
l
For the QinQ service, select C-Aware or S-Aware for the port. Connecting to the port of the client network, a C-Aware port identifies and processes the packets with C-VLAN Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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labels. Connecting to the port at the network side, an S-Aware port identifies and processes the packets with S-VLAN tags. The configuration examples are described as follows: – Add the S-VLAN tag to the service from Port A to Port B, and remove the S-VLAN tag from the service from Port B to Port A. Then select C-Aware for Port A, and SAware for Port B. – Configure a service from Port A to Port B to transparently transmit the C-VLAN tags at the client side. Then select C-Aware for Ports A and B. – Configure a service from Port A to Port B to transparently transmit the S-VALN tags at the network side. Then select S-Aware for Ports A and B. – Configure a service from Port A to Port B to switch the C-VLAN tags at the client side. Then select C-Aware for Ports A and B. – Configure a service from Port A to Port B to switch the S-VALN tags at the network side. Then select S-Aware for Ports A and B.
Relationship with Other Parameters None.
Related Information According to the position and role of the equipment in the networking, there are three types of equipment: CE, PE (U-PE & N-PE), and P. Client Edge (CE) indicates the equipment at the client side. Provider Edge (PE) indicates the edge equipment at the network side. Provider (P) indicates the intermediate node at the network side.
7.2 Maximum Frame Length (Ethernet Port Attribute) Description The Maximum Frame Length (Ethernet Port Attribute) parameter specifies the maximum frame length that is supported at an Ethernet port.
Impact on the System If the packet length exceeds the specified maximum frame length, the packets are discarded. Alternatively, the packet length is minimized to the specified frame length. This parameter takes effect only when the packet enters the port rather than when the packet that exits the port.
Values Valid Values
Default Value
Unit
1518-9600
1522
Byte
Configuration Guidelines Set the value as required. Generally, select the default value, unless otherwise specified. Issue 02 (2011-06-30)
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Relationship with Other Parameters None.
7.3 Non-Autonegotiation Flow Control Mode (Ethernet Port Attribute) Description The Non-Autonegotiation Flow Control Mode (Ethernet Port Attribute) specifies the flow control mode adopted when an Ethernet port works in non-auto-negotiation mode.
Impact on the System The system operation is not affected.
Values Board Name
Valid Values
Default Value
EFS8, EGT1
Disabled, Enable Symmetric Flow Control, Send Only, Receive Only
Disable
The following table lists the description of each value. Value
Description
Disable
Indicates that the port disables the flow control function.
Enable Symmetric Flow Control
Indicates that the port can transmit PAUSE frames and process the received PAUSE frames.
Send Only
Indicates that the port sends the PAUSE frame only.
Receive Only
Indicates that the port can only process the received PAUSE frames.
Configuration Guidelines This parameter is meaningful only when you configure the EPL service. You can select the value as required.
Relationship with Other Parameters None. 7-8
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7.4 Autonegotiation Flow Control Mode (Ethernet Port Attribute) Description The Autonegotiation Flow Control Mode (Ethernet Port Attribute) specifies the flow control mode adopted when an Ethernet port works in auto-negotiation mode.
Impact on the System If the negotiation result is to enable the flow control function, the PAUSE frame is transmitted to the upstream port.
Values Valid Values
Default Value
Disabled, Enable Dissymmetric Flow Control, Enable Symmetric Flow Control, Enable Symmetric/Dissymmetric Flow Control
Disabled
The following table lists the description of each value. Value
Description
Disabled
Indicates that the port disables the flow control function.
Enable Dissymmetric Flow Control
Indicates that the port only transmits flow control frames, but does not process the received flow control frames.
Enable Symmetric Flow Control
Indicates that the port can transmit PAUSE frames and process the received PAUSE frames.
Enable Symmetric/ Dissymmetric Flow Control
Indicates that the symmetric/dissymmetric flow control mode is decided by the auto-negotiation result.
Configuration Guidelines Generally, set this parameter to Enable Symmetric/Dissymmetric Flow Control, unless otherwise specified.
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7.5 MAC Loopback (Ethernet Port Attribute) Description The MAC Loopback (Ethernet Port Attribute) parameter specifies the MAC loopback state at an Ethernet port. Port loopback setting is applied to locating faults only.
Impact on the System MAC loopback is a function of diagnosing faults. It may affect the services configured at the port. If the loopback state is set to Inloop, the services at the port may be interrupted.
Values Value Range
Default Value
Non-Loopback, Inloop
Non-Loopback
The following table lists the description of each value. Value
Description
Non-Loopback
Indicates the normal state. If the equipment works normally, you do not need to set the MAC loopback.
Inloop
Loops back the services from the cross-connection side to the cross-connection side within the equipment at the local end.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.6 PHY Loopback (Ethernet Port Attribute) Description The PHY Loopback (Ethernet Port Attribute) parameter specifies the PHY loopback state at an Ethernet port. Port loopback setting is applied to locating faults only.
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Impact on the System PHY loopback is a function of diagnosing faults. It may affect the services configured at the port. If the loopback state is set to Inloop, the services at the port may be interrupted.
Values Value Range
Default Value
Non-Loopback, Inloop
Default Value
The following table lists the description of each value. Value
Description
Non-Loopback
Indicates the normal state. If the equipment works normally, you do not need to set the PHY loopback.
Inloop
Loops back the services from the cross-connection side to the cross-connection side within the equipment at the local end.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.7 QinQ Type Area Description The QinQ Type Area parameter indicates the VLAN protocol used by the packet that is transmitted by QinQ. The default value 0x8100 of this parameter is the protocol type that is specified by the related standard. The original equipment of other vendors may use 0x88A8 or 0x9100 to represent the VLAN protocol. To realize the interconnection with the original equipment, the user should set this parameter accordingly.
Impact on the System If the values of the QinQ Type Area parameter set for the equipment at the two ends of the interconnection are inconsistent, the service becomes unavailable.
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Values Value Range
Default Value
0x600-0xFFFF
0x8100
Configuration Guidelines Set this parameter according to the supported value of QinQ Type Area of the opposite equipment.
7.8 Loop Detection (Ethernet Port Attribute) Description The Loop Detection (Ethernet Port Attribute) parameter specifies the function of reporting the self-loop alarms after one of the following loopback cases is detected. l
For the external physical interface of the board, the transmit direction is connected to the receive direction by a fiber.
l
The two external physical ports on the board are cross-connected to each other through fibers.
l
The cross-connection is created on the same VCTRUNK of the board.
l
The cross-connection is created between different VCTRUNKs of the board.
Impact on the System After the self-loop check function is enabled for a port, the specified self-loop check packets are transmitted from the port. One packet is transmitted each second.
Values Board Name
Valid Values
Default Value
EFS8
Enabled, Disabled
Disabled
Configuration Guidelines To check the self-loop port, select Enabled.
Relationship with Other Parameters The loop port shut-down function takes effect only after the loop check function is enabled.
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7.9 Loop Port Shutdown (Ethernet Port Attribute) Description The Loop Port Shutdown (Ethernet Port Attribute) parameter is set to disable the self-loop port after a self-loop port is detected if the loop port shutdown function is enabled. After the self-loop port is shut down, the self-loop port only transmits or receives the self-loop detection packets rather than any other packets. If the port is not a self-loop port, it starts to work again.
Impact on the System If a port enables the loop port shut-down function, the IEEE 802.3ah protocol blocks the port once the port is detected to be a self-loop port. In this case, the services at the port are interrupted. All the packets based on the upper-level protocol are discarded.
Values Board Name
Valid Values
Default Value
EFS8
Enabled, Disabled
Enabled
Configuration Guidelines To block a self-loop port, select Enabled. Otherwise, select Disabled.
Relationship with Other Parameters The loop port shutdown function takes effect only after the IEEE 802.3ah protocol and the loop detection function are enabled.
7.10 Traffic Threshold(Mbit/s)(External Ethernet Port Attribute) Description The Traffic Threshold(Mbit/s) (External Ethernet Port Attribute) parameter specifies the data flow threshold at external physical ports.
Impact on the System If the data flow at external physical ports is greater than the specified threshold, the FLOW_OVER alarm is generated.
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Values Board Name
Valid Values
Default Value
Unit
EFS8
0-100 (FE), 0-1000 (GE), in step length of 1
100 (FE), 1000 (GE)
Mbit/s
Configuration Guidelines Generally, select the value according to the bandwidth.
Relationship with Other Parameters None.
7.11 Broadcast Packet Suppression Threshold (Ethernet Interface Attributes) Description The Broadcast Packet Suppression Threshold(Ethernet Interface Attributes) parameter allocates the specified bandwidth to the broadcast packets. The bandwidth is allocated on the basis of the traffic proportion at the port. If the bandwidth allocated to the broadcast packets reaches the specified threshold, the port discards the broadcast data packets that are received.
Impact on the System l
If less bandwidth is allocated to the broadcast packets, some necessary broadcast services are affected.
l
If excessive bandwidth is allocated to the broadcast packets, excessive broadcast packets may enter the network. Consequently, the network running is affected.
Values Board Name
Value Range
Default Value
EFS8
10%-100%
30%
You can set this parameter according to the percentage of the traffic at the port. The value 10 means that the whole bandwidth is allocated to the port.
Configuration Guidelines Generally, adopt the default value. 7-14
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Relationship with Other Parameters None.
7.12 Broadcast Packet Suppression (Ethernet Interface Attributes) Description The Broadcast Packet Suppression (Ethernet Interface Attributes) parameter specifies whether to enable the function for a port to suppress the broadcast packets and to control the traffic of the broadcast data packets that enter the port. If the broadcast packet suppression function is enabled, and if the broadcast traffic exceeds the specified threshold value, the broadcast packets that enter the port are discarded.
Impact on the System If Broadcast Packet Suppression is set to Enabled, the port can effectively suppress the traffic of the broadcast packets by using the statistic function of the network processor on the board.
Values Board Name
Value Range
Default Value
EFS8
Enabled, Disabled
Disabled
Configuration Guidelines You can set this parameter according to whether to control the traffic of the broadcast packets.
Relationship with Other Parameters None.
7.13 Zero-Flow Monitor (Ethernet Interface Attributes) Description The Zero-Flow Monitor parameter specifies whether the traffic on a port is monitored.
Impact on the System After the zero traffic monitoring function is enabled, the port can report the zero traffic alarm after the state of zero traffic lasts for a certain period. Hence, the user can check whether the service is interrupted due to the fault on the equipment side. Issue 02 (2011-06-30)
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Values Value Range
Default Value
Enabled, Disabled
Disabled
The following table provides the description of each value. Value
Description
Enabled
The zero traffic monitoring function is enabled on the port.
Disabled
The zero traffic monitoring function is disabled on the port.
Configuration Guidelines Set this parameter according to the actual requirement of the user. Set this parameter to Enabled if the traffic on a port needs to be monitored.
7.14 Port Traffic Threshold Time Window(Min) Description The Port Traffic Threshold Time Window(Min) parameter specifies the duration for a VCTRUNK or a IP port to monitor the traffic after the zero traffic monitoring function of the port is enabled.
Impact on the System If the value of this parameter is too large, the port may fail to report the zero traffic alarm. If the value of this parameter is too small, the jitter due to the zero traffic alarm may occur on the port.
Values Board Name
Value Range
Default Value
Unit
EFS8
0-30
0
min
Configuration Guidelines The user can set this parameter according to the actual service requirement.
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7.15 Jumbo Frame Type Description Jumbo Frame Type specifies the value of the jumbo frame type on an Ethernet port. The jumbo frame indicates the oversized Ethernet frame, whose maximum length is 65535 bytes. The Ethernet service board determines whether the Ethernet frame is a jumbo frame according to the value of the jumbo frame type.
Impact on the System The system operation is not affected.
Values Value Range
Default Value
0 to 65535
34928
Configuration Guidelines The value of this parameter must be the same as the value of the accessed jumbo frame type. Otherwise, the Ethernet board does not consider the frame as a jumbo frame.
Relationship with Other Parameters The maximum transmission unit (MTU) parameter is used for the Ethernet port. If the length of Ethernet frames is greater than the length of the jumbo frame, the Ethernet port discards these Ethernet frames. If the length of Ethernet frames is smaller than the length of the jumbo frame but is greater than the MTU, the Ethernet port discards the Ethernet frames whose length is greater than the MTU. If the length of Ethernet frames is smaller than the MTU, the Ethernet port does not discard the received Ethernet frames.
7.16 Default VLAN ID (Ethernet Port Attribute) Description The Default VLAN ID (Ethernet Port Attribute) parameter specifies the default VLAN ID of a port.
Impact on the System The system operation is not affected.
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Values Board Name
Valid Values
Default Value
EFS8
1-4095
1
Configuration Guidelines Allocate the default VLAN ID according to the networking plan of the service carrier.
Relationship with Other Parameters l
If Tag is set to Access for a port, packets without VLAN IDs are added with the default VLAN IDs when they enter the port. After these packets are transmitted from the port, their VLAN IDs are peeled off.
l
If Tag is set to Hybrid for a port, packets without VLAN IDs are added with the default VLAN IDs when they enter the port. After these packets are transmitted from the port, the VLAN IDs are peeled off if they are the same as the default VLAN IDs. Otherwise, these packets are directly transmitted.
l
If Tag is set to Tag Aware for a port, packets without VLAN IDs are discarded before they enter the port. Otherwise, these packets are directly transmitted.
7.17 VLAN Priority (Ethernet Port Attribute) Description The VLAN Priority (Ethernet Port Attribute) parameter specifies the priority of the default VLAN ID of a port. It indicates the priority of the service quality.
Impact on the System The system operation is not affected.
Values Board Name
Valid Values
Default Value
EFS8
0-7
0
Configuration Guidelines Set the VLAN priority according to the service requirements and the allocation of the service carrier.
Relationship with Other Parameters None. 7-18
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7.18 Entry Detection (Ethernet Port Attribute) Description The Entry Detection (Ethernet Port Attribute) parameter specifies whether to identify the tag labels in the data packets.
Impact on the System The entry detection function can be disabled in the port-based services only. If the entry detection function is disabled, you may fail to configure other VLAN-based services.
Values Board Name
Valid Values
Default Value
EFS8
Enabled, Disabled
Enabled
The following table lists the description of each value. Value
Description
Enabled
The port checks the Tag label. In this case, the Tag attribute of the port is valid.
Disabled
The port does not check the tag label. In this case, the Tag attribute of the port is invalid.
Configuration Guidelines l
To transmit the data packet transparently, the user can disable the entry detection function.
l
To forward the data packet according to the contents of the data packet, the user can enable the entry detection function.
Relationship with Other Parameters None.
7.19 TAG Description TAG indicates that the Ethernet port supports IEEE 802.1Q Ethernet packets that contain VLAN tags. You can set three attributes to differentiate the packets from each other so that these packets can be transmitted efficiently. Issue 02 (2011-06-30)
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Impact on the System The system operation is not affected.
Values Value Range
Default Value
Access, Tag Aware, Hybrid
Tag Aware
The following table lists the description of each value. Value
Description
Access
A port receives only the packets that do not contain VLAN tags. After receiving the packets, the port adds the default VLAN tag (PVID) to these packets. When the packets are transmitted from the port, the VLAN tags are stripped off the packets.
Tag Aware
A port receives only the packets that contain VLAN tags and discards the packets that do not contain VLAN tags. When the packets are transmitted from the port, they are directly forwarded to the next port.
Hybrid
A port can receive all the packets regardless of VLAN tags. After receiving the packets that do not contain VLAN tags, the port adds the default VLAN tag (PVID) to these packets. When the packets are transmitted from the hybrid port, the egress port determines whether the VLAN tags contained in the packets are the same as the PVID. If yes, the egress port strips the VLAN tags off the packets and then forwards these packets. Otherwise, the egress port directly forwards these packets.
Configuration Guidelines The tag attributes are configured for MAC ports and VCTRUNK ports. Hence, the VCTRUNK ports at both ends of the trunk link can be configured with the tag attributes. In the case of a link, the services are available only when the parameters of the tag attributes are the same for the VCTRUNK ports on the source and sink ports. No requirements are proposed for the tag attributes of MAC ports.
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Relationship with Other Parameters l
If TAG is set to Access for a port, packets without VLAN IDs are added with the default VLAN IDs when they enter the port. After these packets are transmitted from the port, their VLAN IDs are peeled off.
l
If TAG is set to Hybrid for a port, packets without VLAN IDs are added with the default VLAN IDs when they enter the port. After these packets are transmitted from the port, the VLAN IDs are peeled off if they are the same as the default VLAN IDs. Otherwise, these packets are directly transmitted.
l
If TAG is set to Tag Aware for a port, packets without VLAN IDs are discarded before they enter the port. Otherwise, these packets are directly transmitted.
l
For C-Aware and S-Aware ports, the tag attribute cannot be set.
Related Information Mapping relationship between the packets handled by the port and the tag identifiers Packet Type
Attribute of the Ingress Port
Handling Method
Ethernet packets that contain tags
Tag aware
The port transmits these packets.
Access
The port discards these packets.
Hybrid
The port transmits these packets.
Tag aware
The port discards these packets.
Access
The port transmits these packets after adding the default VLAN ID to these packets.
Hybrid
The port transmits these packets after adding the default VLAN ID to these packets.
Ethernet packets that do not contain tags
7.20 Mapping Protocol Description The Mapping Protocol parameter specifies the mapping protocol of the VCTRUNK port.
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Impact on the System The Mapping Protocol parameter of the VCTRUNK is the basic setting of the VCTRUNK port. If the parameter value is different from that of Mapping Protocol for the VCTRUNK of the interconnected equipment, the service is interrupted.
Values Table 7-1 shows the value range of each type of board. Table 7-1 The mapping protocol supported by each type of board Value Range
Default Value
GFP, LAPS, HDLC
GFP
The following table lists the description of each value. Value
Description
GFP
Uses the GFP protocol to encapsulate the data of the VCTRUNK port.
LAPS
Uses the LAPS protocol to encapsulate the data of the VCTRUNK port.
HDLC
Uses the HDLC protocol to encapsulate the data of the VCTRUNK port.
Configuration Guidelines The value of Mapping Protocol for VCTRUNK of the local equipment must be the same as that of Mapping Protocol for the VCTRUNK of the interconnected equipment.
Relationship with Other Parameters None.
7.21 Scramble Description The Scramble parameter specifies whether to scramble the payload area of the encapsulation protocol and the scramble mode.
Impact on the System If the value of Scramble for the VCTRUNK of the local equipment is different from that of Scramble for the VCTRUNK of the interconnected equipment, the service is interrupted. 7-22
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Values Table 7-2 shows the value range of each type of board. Table 7-2 Scramble supported by each type of board Value Range
Default Value
Unscrambled, Scrambling mode[X43+1], Scrambling mode [X48+1]
Scrambling mode[X43+1]
The following table lists the description of each value. Value
Description
Unscrambled
Does not scramble the payload area.
Scrambling mode[X43+1]
Scrambles the payload area in [X43+1] mode.
Scrambling mode[X48+1]
Scrambles the payload area in [X481] mode.
Configuration Guidelines The value of Scramble for VCTRUNK must be the same as that of Scramble for the VCTRUNK of the interconnected equipment.
Relationship with Other Parameters None.
7.22 Set Inverse Value for CRC Description The Set Inverse Value for CRC parameter specifies whether to set an inverse value for the CRC field of the HDLC or LAPS protocol.
Impact on the System If the value of Set Inverse Value for CRC for the VCTRUNK of the local equipment is different from that of Set Inverse Value for CRC for the VCTRUNK of the interconnected equipment, the service is interrupted.
Values
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Board Name
Value Range
Default Value
EFS8, EGT1
Yes, No
Yes
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The following table lists the description of each value. Value
Description
Yes
Sets an inverse value for the CRC field.
No
Does not set an inverse value for the CRC field.
Configuration Guidelines The value of Set Inverse Value for CRC for VCTRUNK of the local equipment must be the same as that of Set Inverse Value for CRC for the VCTRUNK of the interconnected equipment.
Relationship with Other Parameters This parameter takes effect only when Mapping Protocol is set to LAPS or HDLC.
7.23 Check Field Length Description The Check Field Length parameter specifies the length of the CRC field of the mapping protocol.
Impact on the System If Mapping Protocol is set to HDLCor LAPS, and if the value of Check Field Length is different from that for the interconnected VCTRUNKs at the two ends, the service is interrupted.
Values Table 7-3 shows the value range of each type of board. Table 7-3 The length of the CRC field supported by each type of board Board Name
Mapping Protocol
Value Range
Default Value
EFS8, EGT1
GFP
l FCS32
FCS32
l No LAPS
l FCS32
HDLC
l FCS32
The following table lists the description of each value. 7-24
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Value
Description
No
The protocol frame does not contain the CRC field. Only the GFP protocol supports this option.
FCS32
The CRC field of the protocol frame contains 32 bits.
Configuration Guidelines If Mapping Protocol is set to HDLC or LAPS, the value of Check Field Length must be consistent for the interconnected VCTRUNKs at the two ends.
Relationship with Other Parameters If Mapping Protocol is set to HDLC or LAPS, select FCS32 only.
7.24 FCS Calculated Bit Sequence Description The FCS Calculated Bit Sequence parameter specifies the sequence of storing the bits in the CRC field of the mapping protocol.
Impact on the System If the value of FCS Calculated Bit Sequence for the VCTRUNK of the local equipment is different from that of FCS Calculated Bit Sequence for the VCTRUNK of the interconnected equipment, the service is interrupted.
Values Table 7-4 shows the value range of each type of board. Table 7-4 FCS calculated bit sequence supported by each type of boards Board Name
Mapping Protocol
Value Range
Default Value
EFS8
l GFP
Big endian
l LAPS
Little endian
l Mapping Protocol: GFP l FCS Calculated Bit Sequence: Big endian
l HDLC EGT1
l GFP
Big endian
l LAPS l HDLC
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l Mapping Protocol: GFP l FCS Calculated Bit Sequence: Big endian
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The following table lists the description of each value. Value
Description
Big endian
Stores the FCS field based on Big endian.
Little endian
Stores the FCS field based on Little endian.
Configuration Guidelines The value of FCS Calculated Bit Sequence for the VCTRUNK of the local equipment must the same as that of FCS Calculated Bit Sequence for the VCTRUNK of the interconnected equipment.
Relationship with Other Parameters None.
7.25 Operation Type (EPL Service) Description The Operation Type (EPL Service) parameter specifies whether to add, strip, translate or transparently transmit VLAN labels for service packets at a port when Service Type is set to EVPL(QinQ).
Impact on the System After you select an operation type, the system performs the relevant operation.
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Values Board Name
Valid Values
Default Value
EFS8
l For bidirectional services, the options are as follows:
Add S-VLAN
– Add S-VLAN – Transparently Transmit C-VLAN – Transparently Transmit S-VLAN – Transparently Transmit S-VLAN and CVLAN – Translate S-VLAN l For unidirectional services, the options are as follows: – Add S-VLAN – Transparently Transmit C-VLAN – Transparently Transmit S-VLAN – Transparently Transmit S-VLAN and CVLAN – Translate S-VLAN – Strip S-VLAN
The following table lists the description of each value.
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Value
Description
Add S-VLAN
Indicates that the one layer of S-VLAN label is added to the processed packets in the service.
Translate S-VLAN
If the source S-VLAN labels of the packets processed in the service are translated into the sink S-VLAN labels, the source S-VLAN label must be different from the sink S-VLAN label.
Transparently transmit SVLAN
Forwards the service packets according to the port or S-VLAN. After the packets are processed in the service, the S-VLAN labels in the packets are not changed.
Transparently transmit CVLAN
Forwards the service packets according to the port or C-VLAN. After the packets are processed in the service, the C-VLAN labels in the packet are not changed.
Transparently Transmit SVLAN and C-VLAN
Indicates that the Transparently transmit C-VLAN and Transparently transmit S-VLAN labels are added to the packets processed in the service.
Strip S-VLAN
Strips the S-VLAN label.
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Configuration Guidelines Select a proper item according to network planning and service model.
Relationship with Other Parameters None.
7.26 Service Type (EPL Service) Description The Service Type (EPL Service) parameter specifies the Ethernet private line service type.
Impact on the System The system operation is not affected.
Values Board Name
Valid Values
Default Value
EFS8
EPL, EVPL(QinQ)
EPL
EGT1
EPL
EPL
The following table lists the description of each value. Value
Description
EPL
Indicates the transparent transmission service or the VLAN private line service.
EVPL(QinQ)
Indicates the Ethernet QinQ virtual private line service.
Configuration Guidelines Select a service type as required.
Relationship with Other Parameters None.
7.27 Encapsulation Format of P Port (Network Attributes) Description Encapsulation Format of P Port (Network Attributes) indicates that the board supports receiving of data packets in the MPLS encapsulation format and normal Ethernet data packets. 7-28
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The port needs to process different types of packets in different ways, so you need to set the port to a PE port or a P port. The PE port is not configured with the encapsulation format, while the P port is configured with the encapsulation format. The P port indicates a port for connecting the equipment of the network provider, so the P port receives data packets in the MPLS encapsulation format. You can set the packet encapsulation format of the P port by running the configuration command.
Impact on the System If the encapsulation format of the data packet that enters the port is inconsistent with the configured encapsulation format of the port, the data packet is discarded.
Values Value Range
Default Value
MartinioE, stack VLAN
MartinioE
The following table lists the description of each value. Value
Description
MartinioE
Figure 7-1 shows the encapsulation format of MartinioE.
Stack VLAN
Figure 7-2 shows the encapsulation format of Stack VLAN.
Configuration Guidelines The user can choose an encapsulation format according to the requirements of the service. Different encapsulation formats support different types of data packets. When the encapsulation format is inconsistent with the type of the receive data packet, the data packet is discarded. When configuring services, the user needs to make sure that the encapsulation format of the port is consistent with the type of the data packet that is transmitted by the interconnected equipment.
Relationship with Other Parameters None.
Related Information Figure 7-1 Encapsulation format of MartinioE
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DA SA
0x8847
Tunnel
VC
6
2
4
4
6
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Figure 7-2 Encapsulation format of Stack VLAN
DA SA
0x8100
VLAN
VLAN TAG L3Data
7.28 C-VLAN and S-VLAN Description The C-VLAN and S-VLAN parameter specifies the two types of VLAN tags defined in the QinQ service and IEEE 802.1ad. C-VLAN is taken as the client VLAN tag. S-VLAN is taken as the service VLAN tag. C-VLAN Tag (C-TAG) indicates the VLAN tag on the client side, and S-VLAN Tag (S-TAG) indicates the VLAN tag at the service layer of the carrier. DMAC
SMAC
S-VLAN
C-VLAN
Data
FCS
6 bytes
6 bytes
4 bytes
4 bytes
-
4 bytes
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Empty, 1-4095
Empty
The following table lists the description of each value.
7-30
Value
Description
Empty
Indicates that the port does not check the C-VLAN/S-VLAN. The services are forwarded according to the port.
1-4095
Indicates that the port checks the C-VLAN/S-VLAN. The services are forwarded according to the port and C-VLAN/SVLAN.
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Configuration Guidelines Select the value according to the network. Generally, select C-VLAN and S-VLAN allocated by the carrier.
Relationship with Other Parameters None.
7.29 VLAN ID (For Creation of Ethernet Virtual Private Lines) Description VLAN ID-- stands for virtual local area network identifier. If port+VLAN is selected in the policy of using a port, you can select different VLAN IDs (1-4095) to represent different Ethernet services.
Impact on the System The system operation is not affected.
Values Value Range
Default Value
1 to 4095
-
Configuration Guidelines l
The value range is relevant to the encapsulation format of the P port (Per-NE configuration). In the case of Martinioe, the value ranges from 16 to 1023. In the case of stack VLAN, the value ranges from 1 to 4095.
l
The VLAN IDs at both ends of a link must be the same. In the case of different Ethernet services, you can set the VLAN ID to different values.
Relationship with Other Parameters This parameter is valid only when you set "Flow Type" to "Port+VLAN".
7.30 Bridge Learning Mode (Ethernet LAN Service) Description Bridge Learning Mode (Ethernet LAN Service) indicates how the bridge learns the MAC address. Bridge Learning Mode is classified into the shared VLAN learning and independent VLAN learning modes. The shared VLAN learning mode indicates learning and forwarding Issue 02 (2011-06-30)
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based on the MAC address. The independent VLAN learning mode indicates learning and forwarding based on the VLAN and MAC address.
Impact on the System The independent VLAN learning mode realizes the functions of broadcast packet constraint and virtual workgroup and ensures that the data are transmitted safely on the network. The shared VLAN learning mode indicates the MAC address that is learnt by this VLAN interface is shared by all the other VLAN interfaces, which reduces the safety of data packets.
Values Value Range
Default Value
IVL, SVL
IVL (The bridge type is compliant with IEEE 802.1q or IEEE 802.1ad), SVL (The bridge type is compliant with IEEE802.1d or IEEE 802.1ad)
The following table lists the description of each value. Value
Description
SVL
Indicates that in the shared VLAN learning mode, the bridge learns all the data messages based on the MAC address.
IVL
Indicates that in the independent VLAN learning mode, data packets of different VLAN interfaces are not associated.
Configuration Guidelines The user can set the parameter according to the networking requirements.
Relationship with Other Parameters None.
7.31 MEP ID (Ethernet OAM) Description The MEP ID (Ethernet OAM) specifies the flag that uniquely identifies a maintenance point. The bytes from higher bits to lower bits are respectively described here. The first byte indicates the network number. The second byte indicates the number of the node in the local network. 7-32
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The third and forth bytes indicate the ID of the maintenance point on the network node. The maintenance point ID must be unique in the entire network.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
00-00-0001 to FF-FF-FF00
00-00-0001
Configuration Guidelines The maintenance point ID must be unique in the entire network. Moreover, the U2000 can check whether the maintenance point ID is duplicate.
Relationship with Other Parameters None.
7.32 Maintenance Point Type (Ethernet OAM) Description The Maintenance Point Type (Ethernet OAM) specifies the maintenance point type defined in IEEE 802.1ag. MEP stands for Maintenance association End Point, and MIP stands for Maintenance association Intermediate Point.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
MEP, MIP
MEP
Configuration Guidelines None.
Relationship with Other Parameters None. Issue 02 (2011-06-30)
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7.33 CC Status (Ethernet OAM) Description The CC Status (Ethernet OAM) parameter specifies whether to activate the connectivity check (CC) function at a maintenance point.
Impact on the System After the CC function is activated, the maintenance point starts the CC. If the check is initially successful, the EX_ETHOAM_CC_LOS alarm is reported if a CC failure occurs later.
Values Valid Values
Default Value
Activate, Inactivate
Inactivate
Configuration Guidelines To start the connectivity check, activate the CC function at a maintenance endpoint. To stop the connectivity check, deactivate the CC function.
Relationship with Other Parameters The CC function can be activated at a maintenance endpoint only.
7.34 Test Result (LB and LT Test) Description The Test Result (LB and LT Test) parameter specifies the result derived from the LB or LT test each time.
Impact on the System The system operation is not affected.
Values
7-34
Valid Values
Default Value
Succeeded, Failed
-
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Configuration Guidelines None.
Relationship with Other Parameters None.
7.35 Responding MP Type (Ethernet LT Test) Description The Responding MP Type (Ethernet LT Test) parameter specifies the type of the responding maintenance point in each LT test.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
MEP, MIP, Unknown
Unknown
Configuration Guidelines None.
Relationship with Other Parameters The responding maintenance point must return the type, which is specified when this maintenance point is created.
7.36 Hop Count (Ethernet LT Test) Description The Hop Count (Ethernet LT Test) parameter specifies the number of hops from the maintenance source endpoint to an maintenance intermediate point, namely, the number of responding intermediate points from the maintenance source point to a certain responding point. As shown in Figure 7-3, MEP1 and MEP2 are the maintenance endpoints. MIP1, MIP2, MIP3 and MIP4 are the maintenance intermediate points. In this case, the number of hops from MEP1 to MEP2 is 5, and that from MEP1 to MIP3 is 3.
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Figure 7-3 An example of number of hops
Impact on the System The system operation is not affected.
Values If the value of Hop Count is 2, there are two hops.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.37 Packet Length (Ping Test) Description The Packet Length (Ping Test) parameter specifies the maximum length of the Ping packets if the Ping operation is initiated at a maintenance endpoint.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Unit
64-1522, in step length of 1
64
Byte
Configuration Guidelines Set the value according to the expected frame length. 7-36
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Relationship with Other Parameters None.
7.38 Timeout (Ping Test) Description The Timeout (Ping Test) parameter specifies the waiting period in which no response message is received from the opposite end after a maintenance point initiates the Ping test. In this case, the maintenance point regards that the Ping test fails. This waiting period is called the Ping timeout time.
Impact on the System After initiating the Ping test, the maintenance point returns a Ping timeout message if it fails to receive the response message from the opposite end when the Ping timeout time is reached.
Values Valid Values
Default Value
Unit
3-60, in step length of 1
5
Second
Configuration Guidelines Set this parameter to a lower value if the requirement is high for the response time. Set this parameter to a higher value if the requirement is low for the response time.
Relationship with Other Parameters The values of Timeout and Ping Attempts decides the longest duration required to perform the Ping test.
7.39 Detect Attempts Description The Detect Attempts parameter specifies the detection attempts for performing performance detection defined in IEEE 802.1ag.
Impact on the System If the value of Detection Count is larger, the test result is more accurate in each performance detection test. In this case, more system resources are used, and longer time is consumed. Issue 02 (2011-06-30)
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Values Valid Values
Default Value
Unit
1-1000, in step length of 1
1
Attempt
Configuration Guidelines Set this parameter to a proper value according to the test accuracy and the system resource used in the test.
Relationship with Other Parameters None.
7.40 Send Direction (Ethernet Test) Description Send Direction (Ethernet Test) indicates the transmit direction of the test packet.
Impact on the System The system operation is not affected.
Values Value Range
Default Value
SDH Direction, /
/
The following table lists the description of each value. Value
Description
SDH Direction, /
Indicates that the test packet is transmitted from the VC trunk port to the SDH side.
/
Indicates that the parameter is invalid.
Relationship with Other Parameters This parameter is valid and displayed as SDH Direction only when Send Mode is set to Burst Mode or Continue Mode. This parameter is displayed as / when Send Mode is set to Disabled. 7-38
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7.41 Error Frame Monitor Window (ms) Description The Error Frame Monitor Window (ms) parameter specifies the period during which the number of error frames received at the port exceeds the specified upper threshold. In this case, a link event alarm is reported.
Impact on the System After you set the Error Frame Monitor Threshold (Entries) and Error Frame Monitor Window (ms) parameters, a link event alarm is reported if the actual number of error frames in the link exceeds the specified threshold.
Values Valid Values
Default Value
Unit
1000-60000, in step length of 100
1000
ms
Configuration Guidelines Set the value according to the actual port rate and the monitoring period. Make sure that the value of Error Frame Monitor Threshold (Entries) is not greater than the maximum number of frames received at the port within the time specified in Error Frame Monitor Window (ms).
Relationship with Other Parameters To set Error Frame Monitor Window (ms), set Error Frame Monitor Threshold (Entries). Moreover, set Port Rate. For details, refer to the description of the Error Frame Period Window(Frames) parameter.
7.42 Error Frame Monitor Threshold(Entries) Description The Error Frame Monitor Threshold(Entries) parameter specifies the upper threshold of error frames received at the port. In this case, a link event alarm is reported.
Impact on the System After you set the Error Frame Monitor Threshold(Entries) and Error Frame Monitor Window (ms) parameters, a link event alarm is reported if the actual number of error frames in the link exceeds the specified threshold. Issue 02 (2011-06-30)
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Values Valid Values
Default Value
Unit
1-4294967295 (in step length of 1)
2
Frame
Configuration Guidelines If higher link performance is required, set the threshold to a lower value. Otherwise, set the threshold to a higher value. Make sure that the value of Error Frame Monitor Threshold(Entries) is not greater than the maximum number of frames received at the port within the time specified in Error Frame Monitor Window (ms).
Relationship with Other Parameters To set Error Frame Monitor Threshold(Entries), set Error Frame Monitor Window (ms). Moreover, set Port Rate. For details, refer to the description of the Error Frame Period Window(Frames)parameter.
7.43 Error Frame Period Window(Frames) Description The Error Frame Period Window(Frames) parameter specifies the received N frames in which the number of error frames reach the specified upper threshold. In this case, a link event alarm is reported.
Impact on the System After you set the Error Frame Period Window(Frames) and Error Frame Period Threshold (Frames) parameters, a link event alarm is reported if the number of error frames received within a certain period reaches the specified upper threshold.
Values Valid Values
Default Value
Unit
Maxpps/10-Maxpps*60, in step length of 1
Maxpps
Frame
Configuration Guidelines Set the value according to the actual data frame transmission rate and the frames. If the data transmission rate is high, set this parameter to a higher value. Otherwise, set this parameter to a lower value. 7-40
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Relationship with Other Parameters The value range depends on the port rate.
Related Information Maxpps: indicates the maximum number of frames per second. Specifically, l
If the port rate is 10 Mbit/s, the Maxpps value is 14880.
l
If the port rate is 100 Mbit/s, the Maxpps value is 148800.
l
If the port rate is 1000 Mbit/s, the Maxpps value is 1488000.
l
If the port rate is 10 Gbit/s, the Maxpps value is 14880000.
According to the rule of Maxpps/10 < Error Frame Period Window(Frames) < Maxpps*60, you know the value range of the Error Frame Period Window(Frames) parameter for a certain port rate.
7.44 Error Frame Monitor Threshold(Frames) Description The Error Frame Monitor Threshold(Frames) parameter specifies the received N frames in which the number of error frames reach the specified upper threshold. In this case, a link event alarm is reported.
Impact on the System After you set the Error Frame Period Window(Frames) and Error Frame Period Threshold (Frames) parameters, a link event alarm is reported if the number of error frames received within a certain period reaches the specified upper threshold.
Values Valid Values
Default Value
Unit
1-892800000, in step length of 1
1
Frame
Configuration Guidelines None.
Relationship with Other Parameters None.
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7.45 Error Frame Second Window (s) Description The Error Frame Second Window (s) parameter specifies the error frame second when any error frames are received at the port within one second. If the error frame seconds within a certain time period reach the specified upper threshold, link event alarms are reported. The time period in which error frames are received is called the error frame second window.
Impact on the System After you set the Error Frame Second Window (s) and Error Frame Second Threshold (s) parameters, link event alarms are reported if the actual error frame seconds in the link reach the specified upper threshold.
Values Valid Values
Default Value
Unit
10-900, in step length of 1
60
Second
Configuration Guidelines Set the value according to the monitoring time period. Make sure that the value of Error Frame Second Window (s) is not less than that of Error Frame Second Threshold (s).
Relationship with Other Parameters Set the Error Frame Second Window (s) parameter together with the Error Frame Second Threshold (s) parameter.
7.46 Error Frame Second Threshold(s) Description The Error Frame Second Threshold(s) parameter specifies the second during which error frames are received at the port. If the error frame seconds within a certain time period reach the specified upper threshold, a link event alarm is reported. The upper threshold is called the error frame second threshold.
Impact on the System After you set the Error Frame Second Threshold (s) parameter, link event alarms are reported if the actual error frame seconds in the link reach the specified upper threshold. 7-42
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Values Valid Values
Default Value
Unit
1-900, in step length of 1
2
Second
Configuration Guidelines None.
Relationship with Other Parameters None.
7.47 Enable OAM Protocol Description The Enable OAM Protocol parameter specified whether the end-to-end OAM protocol (namely, the IEEE 802.3ah protocol) is enabled at a port.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Enabled, Disabled
Disabled
Configuration Guidelines None.
Relationship with Other Parameters None.
7.48 OAM Working Mode Description The OAM Working Mode parameter specifies a negotiation mode defined in IEEE 802.3ah. It involves two modes: Passive and Active. Issue 02 (2011-06-30)
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Impact on the System Before IEEE 802.3ah is enabled, the local and opposite ends fail to negotiate with each other if OMA Working Mode is set to Passive.
Values Valid Values
Default Value
Active, Passive
Active
Value
Description
Active
Indicates that a port actively transmits the IEEE 802.3 ah packets.
Passive
Indicates a port transmits the IEEE 802.3 ah packets to the opposite end only after receiving IEEE 802.3 ah packets from the opposite end.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.49 Remote Alarm Support for Link Event Description The Remote Alarm Support for Link Event parameter specifies whether to report the detected link events (for example, Error Frame Period Threshold, Error Frame Monitor Threshold, and Error Frame Second Threshold) to the opposite end.
Impact on the System After the Remote Alarm Support for Link Event parameter is set to Enabled, link event alarms are displayed in the opposite equipment if any link events occur.
Values
7-44
Valid Values
Default Value
Enabled, Disabled
Enabled
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Configuration Guidelines None.
Relationship with Other Parameters None.
7.50 Unidirectional Operation Description The Unidirectional Operation parameter specifies the hardware capability. If a port fails at the receive end, but can transmit data frames at the transmit end, it has the capability of performing unidirectional operations. Otherwise, it does not have the capability of performing unidirectional operations. The unidirectional operation function specified in IEEE 802.3ah refers to whether the hardware performs unidirectional operations if it has the capability of performing unidirectional operations. If the hardware does not have the capability of performing unidirectional operations, the unidirectional operation function specified in IEEE 802.3ah is unavailable.
Impact on the System After the Unidirectional Operation parameter is set to Enabled, IEEE 802.3ah packets are still transmitted to the opposite end if the receive end is faulty.
Values Valid Values
Default Value
Enabled, Disabled
Disabled
Configuration Guidelines If the hardware has the capability of performing unidirectional operations and supports unidirectional software operations, generally, set Unidirectional Operation to Enabled.
Relationship with Other Parameters This parameter depends on whether the port hardware has the capability of performing unidirectional operations.
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7.51 Loopback Status (OAM Parameter) Description The Loopback Status (OAM Parameter) parameter specifies whether a port on the board is in the loopback state. If yes, the port is in the Initiate Loopback at Local or Respond Loopback of Remote state.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Initiate Loopback at Local, Respond Loopback of Remote, Non-Loopback
Non-Loopback
The following table lists the description of each value. Value
Description
Non-Loopback
Indicates that the port is not in the loopback state defined in IEEE 802.3ah.
Initiate Loopback at Local
Indicates that the local end can transmit the loopback packets to the remote end.
Respond Loopback of Remote
Indicates that the local end can respond to the loopback packets from the remote end.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.52 Flow Type (Flow Configuration) Description The Flow Type(Flow Configuration) parameter specifies Flow Type of the flow in the Ethernet data board. This parameter decides the method of binding the service with the flow. 7-46
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Impact on the System If the Flow Type parameter is set incorrectly, that is, the flow classification method is incorrect, the (Bound CAR or Bound CoS) parameter may fail to meet the expected result. For the effects of CAR and CoS, refer to the relevant description.
Values Value Range
Default Value
Port Flow, Port+VLAN Flow, Port+SVLAN Flow, Port +CVLAN+SVLAN Flow
Port Flow
The following table lists the description of each value. Value
Description
Port Flow
All the packets entering the specified port are regarded as one flow.
Port+VLAN Flow
All the packets that enter the specified port, and whose Tag VID is consistent with the specified VID, are regarded as one flow.
Port+SVLAN Flow
All the packets that enter from the specified port, and whose SVLAN VID is consistent with the specified VID, are regarded as one flow.
Port+CVLAN+SVLAN Flow
All the packets that enter from the specified port, and whose SVLAN VID and CVLAN VID are consistent with the specified VID, are regarded as one flow.
Configuration Guidelines Based on the required QoS and service type, set a proper value for Flow Type.
Relationship with Other Parameters None.
7.53 Bound CAR (Flow Configuration) Description The Bound CAR (Flow Configuration) parameter specifies the method of binding a flow with a CAR ID and querying the CAR ID bound with the flow. One flow can be bound with one CAR ID only. The CAR takes effect only after the flow is bound with the CAR. Issue 02 (2011-06-30)
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Impact on the System The CAR-based flow rate can take effect only after the flow is bound with the enabled CAR policy.
Values Value Range
Default Value
Created CAR ID
-
Configuration Guidelines The created flow can be bound with the created CAR policy only. For this reason, you can select the value from the created CAR ID.
Relationship with Other Parameters A flow can be bound with the CAR only after the flow and CAR are created.
7.54 Bound CoS (Flow Configuration) Description The Bound CoS (Flow Configuration) parameter specifies the method of binding a flow with a CoS ID and querying the CoS ID bound with the flow. A flow can be bound with one CoS ID only. The CoS policy can be used to divide the packet priority after the flow is bound with the CoS.
Impact on the System The flow packets can be divided into different priorities based on the CoS rules only after the flow is bound with the CoS.
Values Value Range
Default Value
Created CoS ID
-
Configuration Guidelines The created flow can be bound with the created CoS policy only. For this reason, you can select the value from the created CoS ID.
Relationship with Other Parameters A flow can be bound with the CoS only after the flow and CoS are created. 7-48
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7.55 CAR ID (CAR Configuration) Description The CAR ID (CAR Configuration) parameter specifies the ID of a committed access rate (CAR). When a CAR is created, it needs to be specified with a CAR ID.
Impact on the System The system running is not affected.
Values Value Range
Default Value
1-65535
1
Configuration Guidelines You can set this parameter to any value in the value range as required. A CAR maps a CAR ID.
Relationship with Other Parameters None.
7.56 Enabled/Disabled (CAR Configuration) Description The CAR Enabled/Disabled (CAR Configuration) parameter specifies whether a CAR can limit the traffic volume.
Impact on the System After the CAR is enabled and bound with a flow, the traffic volume of the flow is limited according to the value of the CAR parameter. If the transmitted traffic is greater than the specified value, the excessive traffic is discarded.
Values Value Range
Default Value
Enabled, Disabled
Disabled
The following table lists the description of each value. Issue 02 (2011-06-30)
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Value
Description
Disabled
A CAR is created, but does not take effect.
Enabled
A CAR is created, and takes effect.
Configuration Guidelines You can set this parameter to Enabled or Disabled, depending on whether to enable the CAR to limit the traffic volume.
Relationship with Other Parameters A CAR can limit the traffic of the flow only when it is set to Enabled and bound with a flow.
7.57 Committed Information Rate (kbit/s) (CAR Configuration) Description The Committed Information Rate (kbit/s) (CAR Configuration) parameter specifies the committed information rate (CIR) of the committed access rate (CAR). It specifies the minimum guarantee bandwidth of a flow.
Impact on the System After the CAR is enabled and bound with a flow, the committed bandwidth of the flow is guaranteed. If the traffic volume is greater than the guarantee bandwidth, the transmission of excessive traffic cannot be guaranteed.
Values Value Range
Default Value
Unit
An integer of 0-1048576, in step length of 64
0
kbit/s
Configuration Guidelines Based on the actual requirement of QoS, you can set a proper value for Committed Information Rate. Generally, the value of Committed Information Rate is not less than the expected average rate of transmitting the flow.
Relationship with Other Parameters You can set Committed Information Rate of a CAR only after creating the CAR. 7-50
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7.58 Committed Burst Size (kbyte) (CAR Configuration) Description The Committed Burst Size (kbyte) (CAR Configuration) parameter specifies the maximum guaranteed data volume of a flow, which can be transmitted within a certain period.
Impact on the System After the CAR is enabled and bound with a flow, if the volume of burst data in the flow is less than the value of Committed Burst Size (kbyte), the burst data can be guaranteed for transmission. Otherwise, they cannot be guaranteed for transmission.
Values Value Range
Default Value
Unit
0-32
0
Kbyte
Configuration Guidelines Based on the actual requirements of QoS, you can set a proper value for Committed Burst Size (kbyte). Generally, the value of Committed Burst Size (kbyte) is not less than the possible size of expected burst data flow to be transmitted.
Relationship with Other Parameters You can set Committed Burst Size (kbyte) of a CAR only after creating the CAR.
7.59 Peak Information Rate (kbit/s) (CAR Configuration) Description The Peak Information Rate (kbit/s) (CAR Configuration) parameter specifies the peak information rate (PIR) of the committed access rate (CAR). It specifies the allowed maximum rate of a flow.
Impact on the System After the CAR is enabled and bound with a flow, the flow rate is limited according to the peak bandwidth of the CAR parameter. If the traffic volume is greater than the value of Peak Information Rate (kbit/s), the excessive traffic is discarded. Issue 02 (2011-06-30)
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Values Value Range
Default Value
Unit
An integer of 0-1048576, in step length of 64
0
kbit/s
Configuration Guidelines Based on the actual requirement of QoS, you can set a proper value for Peak Information Rate (kbit/s). The value of Peak Information Rate (kbit/s) should not be less than the guarantee bandwidth. Generally, the value of Peak Information Rate (kbit/s) is not greater than the expected maximum rate of transmitting the flow.
Relationship with Other Parameters You can set Peak Information Rate (kbit/s) of a CAR only after creating the CAR.
7.60 Maximum Burst Size (kbyte) (CAR Configuration) Description The Maximum Burst Size (kbyte) (CAR Configuration) parameter specifies the maximum excessive data volume of a flow, which can be transmitted within a certain period.
Impact on the System After the CAR is enabled and bound with a flow, if the burst data volume of the flow is greater than the value of Maximum Burst Size (kbyte), the excessive data is discarded.
Values Value Range
Default Value
Unit
0-32
0
kbyte
Configuration Guidelines Based on the actual requirement of QoS, you can set a proper value for Maximum Burst Size (kbyte). Generally, the value of Maximum Burst Size (kbyte) is not greater than the size of burst data flow to be transmitted.
Relationship with Other Parameters You can set Maximum Burst Size (kbyte) of a CAR only after creating the CAR. 7-52
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7.61 CoS ID (CoS Configuration) Description The CoS ID (CAR Configuration) parameter specifies the ID of a class of service (CoS). When a CoS is created, it needs to be specified with a unique CoS ID.
Impact on the System The system running is not affected.
Values The value ranges for each type of board is as follows: Value Range
Default Value
1-65535
1
Configuration Guidelines You can set this parameter to any value in the value range as required. A CoS maps a CoS ID.
Relationship with Other Parameters None.
7.62 CoS Type (CoS Configuration) Description The CoS Type (CoS Configuration) parameter specifies the type of CoS of the flow in the Ethernet data board. This parameter decides the method adopted to classify the flow in the Ethernet data board.
Impact on the System If CoS Type is set incorrectly, packets cannot be correctly dispatched to a proper queue.
Values Value Range
Default Value
Simple, VLAN priority, DSCP, IPTOS
Simple
The following table lists the description of each value. Issue 02 (2011-06-30)
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Value
Description
Simple
Assigns the CoS Priority based on the flow.
VLAN priority
Assigns the CoS Priority based on the VLAN priority.
DSCP
Assigns the CoS Priority based on the DSCP field in the IP packet header.
IPTOS
Assigns the CoS Priority based on the TOS field in the IP packet header.
Configuration Guidelines Based on the requirements of QoS, set a proper value for CoS Type.
Relationship with Other Parameters None.
7.63 CoS Priority (CoS Configuration) Description The CoS Priority (CoS Configuration) parameter classifies packets into different levels based on the CoS type, and maps these packets into different CoS priorities. The packets of higher priorities are first processed.
Impact on the System The packets of higher priorities are transmitted before those of lower priorities. Moreover, better service quality is available.
Values For the CoS of the Simple type, follow Table 7-5 to set a simple CoS Priority. Table 7-5 CoS priority of the simple type CoS Parameter
Value Range of CoS Parameter
Value Range of CoS Priority
Default Value of CoS Priority
Invalid
Invalid
0-7
0
For the CoS of the VLAN Priority type, follow Table 7-6 to set the mapping from VLAN Priority to CoS Priority. 7-54
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Table 7-6 CoS priority of the VLAN Priority type CoS Parameter
Value Range of CoS Parameter
Value Range of CoS Priority
Default Value of CoS Priority
User priority in VLAN
0-7
0-7
The same as that of CoS priority
For the CoS of the DSCP type, follow Table 7-7 to set the mapping from DSCP Priority to CoS Priority. Table 7-7 CoS priority of the DSCP type CoS Parameter
Value Range of CoS Parameter
Value Range of CoS Priority
Default Value of CoS Priority
DSCP
000000-111111 (in binary)
0-7
0
For the CoS of the IPTOS type, follow Table 7-8 to set the mapping from IPTOS Priority to CoS Priority. Table 7-8 CoS priority of the IPTOS type CoS Parameter
Value Range of CoS Parameter
Value Range of CoS Priority
Default Value of CoS Priority
IPTOS
0000-1111 (in binary)
0-7
0
Configuration Guidelines Based on the requirements, you can map the packets into different queues by setting CoS Priority. If CoS Type is set to VLAN Priority, IPTOS or DSCP, generally, you can map the packets into the proper CoS Priority according to the priority information contained in the packets. At the application layer, if a service (for example, VOIP, video conference, video conferencing call, and video on demand) has higher requirements for QoS, set a higher priority for the service to get better bandwidth and service guarantee. To ensure good bandwidth multiplexing, be sure to avoid a larger ratio of real-time services in the network. For a service (for example, Internet access, E-Mail, and FTP) that has lower requirements for QoS, set a lower priority for the service to provide better bandwidth sharing and contention mechanism.
Relationship with Other Parameters None. Issue 02 (2011-06-30)
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7.64 Port Priority (Link Aggregation) Description The Port Priority (Link Aggregation) parameter specifies the priority of the ports in the link aggregation group of the LACP protocol. The port priority can be set. It indicates the priority level of a port to be aggregated. If a port is of higher priority, this port is preferred to carry the services. If a link aggregation group (for example, manual aggregation group) does not run the LACP protocol, it does not take effect after the port priority is set.
Impact on the System If other conditions (for example, port rate, and port working mode) are the same, a port of higher priority is preferred to carry the services.
Values Valid Values
Default Value
0-65535, in step length of 1
32768
Configuration Guidelines If the value of Port Priority is smaller, the priority is higher. When using a port to carry the services, set Port Priority to a smaller value. Otherwise, set Port Priority to a greater value.
Relationship with Other Parameters The member port state in the link aggregation group is decided according to these parameters, such as port working mode, port working rate, whether the port receives LACP packets, port priority, and LAG priority.
7.65 System Priority (Link Aggregation) Description The System Priority (Link Aggregation) parameter specifies the priority level of a link aggregation group. It may affect the working state of the member ports in the link aggregation group.
Impact on the System When the link aggregation groups at the local and opposite ends negotiate with each other by sending LACP packets, they can get the system priority of the link aggregation groups from each other. The result selected at the end of higher priority is taken as the result for the two ends. If 7-56
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the system priority of the link aggregation group is the same at the two ends, the system MAC addresses are compared. A MAC address is used if it is of lower value. If the value of System Priority is smaller, the system priority of the link aggregation group is higher.
Values Valid Values
Default Value
0-65535, in step length of 1
32768
Configuration Guidelines To take the result selected by the static link aggregation group as the actual value, set System Priority to a smaller value.
Relationship with Other Parameters The member port state in the link aggregation group is decided according to these parameters, such as port working mode, port working rate, whether the port receives LACP packets, port priority, and system priority.
7.66 Status (Link Aggregation) Description The Status (Link Aggregation) parameter specifies the state, which is derived from logical computation, of each member ports in a link aggregation group.
Impact on the System When a port is not configured with services, this port can be added to a link aggregation group. If this port is in service in this link aggregation group, this port can share the service. If this port is out of service in this link aggregation group, this port cannot share the service. When a port is already configured with services, this port cannot be added to a link aggregation group and cannot share the service.
Values
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Valid Values
Default Value
Unknown, In Service, Out of Service
Unknown
Value
Description
Unknown
Indicates that the link aggregation group is not queried. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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Value
Description
In Service
Indicates that the port can carry the service.
Out of Service
Indicates that the port cannot carry the service.
Configuration Guidelines This parameter is used for query only. No rules are provided for selecting a value.
Relationship with Other Parameters l
For static link aggregation, the LACP protocol is used. The member port state in the link aggregation group is decided by these parameters, such as port working mode, port working rate, port priority, and link aggregation group priority.
l
For manual link aggregation, the LCAP protocol is not used. The member port state in the link aggregation group is not related to these parameters, such as port working mode and port working rate.
7.67 Load Sharing(Ethernet Link Aggregation) Description The Load Sharing parameter specifies the load sharing mode of an aggregation group.
Impact on the System Different load sharing modes have different effects. In load sharing mode, the ports in the aggregation group can share the service. In load non-sharing mode, only one port in the aggregation group can carry the service and the other port provides protection.
Values Value Range
Default Value
Sharing, Non-Sharing
Sharing
The following table provides the description of each value.
7-58
Value
Description
Sharing
Indicates that the ports in the aggregation group share the service.
Non-Sharing
Indicates that the ports in the aggregation group do not share the service. Only one port in the aggregation group carries the service.
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Configuration Guidelines If the bandwidth needs to be increased and several ports need to be enabled to share the service, select the load sharing mode. If only one port needs to carry the service and protection is required for this port, select the load non-sharing mode.
7.68 Protocol Enabled (Spanning Tree) Description Protocol Enabled (Spanning Tree) indicates whether the spanning tree protocol is enabled on the VB.
Impact on the System After the protocol is enabled, and when the computation of the spanning tree is performed according to the protocol type (STP/RSTP), the network topology changes and services are interrupted temporarily.
Values Value Range
Default Value
Enabled, Disabled
Disabled
Configuration Guidelines The user can set this parameter according to the actual service requirement.
Relationship with Other Parameters This parameter can be set only when the VB is created and Protocol Type is selected.
Related Information The rapid spanning tree protocol (RSTP) can realize all the functions of the spanning tree. Similar to the STP, the RSTP avoids temporary loops. Different from the STP, the RSTP shortens the time delay at the ports from blocking to forwarding, restores the network connectivity more rapidly, and provides better services.
7.69 Protocol Type (Spanning Tree Protocol) Description Protocol Type (Spanning Tree) indicates that the Ethernet data board of the OptiX OSN equipment supports two spanning tree protocols, that is, the spanning tree protocol (STP) and the rapid spanning tree Protocol (RSTP). Issue 02 (2011-06-30)
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l
The STP is a Layer 2 management protocol that avoids Layer 2 loops by selectively blocking redundant network links and supports the link backup.
l
The RSTP develops from the STP and shortens the convergence time.
Impact on the System If this parameter is changed incorrectly, a network topology oscillation may occur and services are severely affected.
Values Value Range
Default Value
STP, RSTP
RSTP
Configuration Guidelines The RSTP and STP can be configured at the same time. The RSTP is compatible with the STP. It is recommended that you use the default value RSTP.
Relationship with Other Parameters None.
7.70 Priority (Bridge Parameters) Description VB Priority (Bridge Parameters) indicates the fixed parameters of the bridge, used for selecting the role of the bridge and computing the topology of the spanning tree. As the value of the parameter decreases, the VB priority increases and the bridge is more likely to be selected as a root bridge.
Impact on the System Changing the value of Priority may affect the selection of a root bridge, which may finally affect the entire network topology.
Values Value Range
Default Value
0-65535, in step length of 4096
32768
Configuration Guidelines Set this parameter according to what role the user expects the bridge to play in the spanning tree topology. 7-60
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Relationship with Other Parameters None.
7.71 Max Age(s) Description The Max Age(s) parameter specifies the maximum life cycle of the configuration message. A configuration message contains the message aging time and maximum aging time of the message. The maximum life cycle of the configuration message is equivalent to the maximum aging time of the message.
Impact on the System If the message aging time exceeds the maximum aging time of the message, the received message is discarded and the port that receives the message becomes a designated port.
Values Value Range
Default Value
Unit
6-40
20
s
Configuration Guidelines When you set the value of this parameter, ensure that the following requirement is met: 2 x (Hello Time + 1) ≤ Max Age ≤ 2 x (Forward Delay - 1)
Relationship with Other Parameters This parameter is related to the Hello Time and Forward Delay parameters. For details, refer to the principles for setting these parameters.
7.72 Hello Time(s) (Spanning Tree) Description The Hello Time(s) parameter specifies the transmission period of the message. The bridge time consists of the following parts: forward delay of the bridge, handshake time of the bridge, maximum bridge aging time, and message aging time (0). The Hello Time parameter is equivalent to the bridge handshake time.
Impact on the System This parameter ensures the stable operation of the STP. Issue 02 (2011-06-30)
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Values Value Range
Default Value
Unit
1-10
2
s
Configuration Guidelines When you set the value of this parameter, ensure that the following requirement is met: 2 x (Hello Time + 1) ≤ Max Age ≤ 2 x (Forward Delay - 1)
Relationship with Other Parameters This parameter is related to the Max Age and Forward Delay parameters. For details, refer to the principles for setting these parameters.
7.73 Forward Delay(s) (Spanning Tree) Description The Forward Delay(s) parameter specifies the delay of the port state migration. This parameter is actually a timer that is used by the ports in the listening state and in the learning state to control the migration from the listening state to the learning state and the migration from the learning state to the forwarding state. The timer is started when the port enters the listening state. When the timer expires, the port automatically migrates to the learning state and the timer is started again. When the timer expires the second time, the port automatically migrates to the forwarding state and the timer is stopped.
Impact on the System The restoration time of the service from the learning state to the forwarding state is affected.
Values Value Range
Default Value
Unit
4-30
15
s
Configuration Guidelines When you set the value of this parameter, ensure that the following requirement is met: 2 x (Hello Time + 1) ≤ Max Age ≤ 2 x (Forward Delay - 1).
Relationship with Other Parameters This parameter is related to the Hello Time and Max Age parameters. For details, refer to the principles for setting these parameters. 7-62
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7.74 TxHoldCount(per second) (Spanning Tree) Description The TxHoldCount(per second) parameter enables the transmission state machine of the port to specify the maximum transmission rate of the BPDU packet.
Impact on the System This parameter ensures that the number of the BPDU packets transmitted within a period of hello time does not exceed the preset value.
Values Value Range
Default Value
1-10 times/s
6
Configuration Guidelines Set this parameter according to the actual requirement of the user. It is recommended that you use the default value.
7.75 Root Path Cost Description Each bridge has the root path cost. The root path cost of the root bridge is equal to 0. In the case of non-root bridges, the root path cost of each bridge is equal to the sum of path cost values of each port on the other bridges that a non-root bridge passes when the bridge receives the frame from the root bridge along the minimum cost path. The path cost of each port can be managed. The network segment in each LAN has the root path cost. The root path cost of the network segment is equal to the root path cost of the bridge whose cost is the smallest among all the bridges that are connected to the network segment through the bridge ports. In this case, the bridge whose cost is the smallest is selected as the designated bridge. If the root path cost values of two or more bridges are the same and the smallest, the bridge with a higher priority is selected as the root bridge. In the case of non-root bridges, the root path cost of each bridge is equal to the sum of path cost values of each port on the other bridges that a non-root bridge passes when the bridge receives the frame from the root bridge along the minimum cost path. That is, the value of the root path cost is the sum of the path cost values of all bridges.
Impact on the System The root path cost can determine the designated bridge and the service flow in the STP. Issue 02 (2011-06-30)
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Values Based on the protocol, the value of this parameter is calculated according to the network topology. This parameter is used for querying.
Configuration Guidelines There are no principles for setting the value of this parameter because this parameter is used for querying.
7.76 Hold Count (Spanning Tree) Description The Hold Count parameter indicates the maximum number of BPDUs that are actually transmitted within a period of hello time.
Impact on the System The system is not affected because this parameter is used to check the counter of the BPDU packet.
Values This parameter is used for querying.
Configuration Guidelines There are no principles for setting the value of this parameter because this parameter is used for querying.
7.77 Port ID Description The Port ID parameter contains 16 bits, which show the port priority and the unique port number in the bridge. The first eight bits indicate the port priority, and the later eight bits indicate the port number. The port ID represents the priority in the spanning tree. If the value of the port ID is smaller, the port priority in the bridge is higher. To enable the RSTP to be compatible with the STP, the port priority is represented by eight bits, of which the later four bits are 0 for easy management.
Impact on the System This parameter is for query only. The system is not affected.
Values The parameter value is in decimal system. For example, Port ID = 32769. 7-64
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Relationship with Other Parameters You can change the parameter value by setting the port priority. In this case, however, the topology of the spanning tree may be rearranged. If the port priority is smaller, the port ID is smaller. When the port priorities are the same, the port ID is smaller if the port number is smaller.
7.78 Designated Path Cost Description The Designated Path Cost parameter is applicable to the port and is used for the state machine calculation of the spanning tree. Based on the port path cost, you can calculate the root path cost of the port of the switch. The root path cost is equal to 0 in the case of a root bridge. In the case of other bridges, the root path cost of the bridge refers to the path cost from the root bridge to this bridge. The root path cost is the sum of the minimum root path cost of the port on this bridge and the path cost of this port. The path cost of each port can be set through the management module. Table 7-9 shows the recommended values of the port path cost. The values are generally related to the MAC type and transmission rate. Table 7-9 Recommended values of the port path cost Parameter
Link Speed
Recommende d value
Recommende d range
Range
Path Cost
<=100 Kb/s
200000000
20000000-2000 00000
1-200000000
1 Mb/s
20000000
2000000-20000 0000
1-200000000
10 Mb/s
2000000
200000-200000 00
1-200000000
100 Mb/s
200000
20000-2000000
1-200000000
1 Gb/s
20000
2000-200000
1-200000000
10 Gb/s
2000
200-20000
1-200000000
100 Gb/s
200
20-2000
1-200000000
1 Tb/s
20
2-200
1-200000000
10 Tb/s
2
1-20
1-200000000
Impact on the System This parameter affects the calculation of the root path cost based on the STP and hence affects the service flow in the spanning tree.
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Values Value Range
Default Value
1-65535
0
The following table provides the description of each value. Value
Description
1-65535
Indicates the cost required by the transmission of the bridge port.
Configuration Guidelines If the port rate is greater, the designed path cost is smaller. It is recommended that you use the default value.
7.79 Designated Root Bridge Priority Description The Designated Root Bridge Priority parameter indicates the priority of the root bridge that is selected based on the STP. The selection is based on the bridge IDs in a network. A bridge ID consists of the priority and MAC address of the bridge. The bridge whose ID is the smallest is selected as the root bridge in this network.
Impact on the System This parameter is used for querying. It indicates the priority of the current root bridge and may change in the case of a spanning tree topology change.
Values Value Range
Default Value
0-65535
32768
Configuration Guidelines There are no specific principles for setting the value of this parameter because this parameter is used for querying.
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7.80 Designated Bridge Priority(Spanning Tree) Description The Designated Bridge Priority parameter indicates the priority of each bridge during the selection of the root bridge based on the STP. The bridge priority is a part of the bridge ID. A bridge ID consists of the bridge priority and MAC address of the bridge. The bridge whose ID is the smallest is selected as the root bridge in the network.
Impact on the System If the priority of a bridge is higher, the probability is higher that the bridge is selected as the root bridge.
Values Value Range
Default Value
0-61440
32768
Configuration Guidelines If the value of the parameter is smaller, the priority of the bridge is higher. Set this parameter according to the actual network condition.
7.81 Designated Bridge MAC Address (Spanning Tree) Description The Designated Bridge MAC Address parameter indicates the MAC address of a bridge. To ensure that the bridge protocols operate normally, the following requirements should be met: l
The multicast MAC address must be unique and be identified by all the bridges in the LAN. The multicast MAC address identifies the protocol entities of a bridge that is connected to different and individual physical network segments.
l
Each bridge has a unique ID in the entire LAN.
l
Ports on a bridge have port IDs, which are different from each other. Ports IDs of different bridges are different. The values of these IDs can be assigned independently. The values can also be used by other bridges.
l
Each bridge must provide the values of the parameters that are described previously or provide the mechanism for assigning values for these parameters.
Impact on the System The MAC address of a bridge affects the priority of the bridge. Issue 02 (2011-06-30)
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Values Value Range
Default Value
unicast mac address
00-00-00-00-00-00
Configuration Guidelines It is recommended that you use the default value.
7.82 Edge Port Status (Spanning Tree) Description The Edge Port Status parameter specifies whether a bridge port is an edge port. Edge ports are directly connected to the terminal equipment and are no longer connected to any bridges. This parameter is important in the RSTP. The status of these ports does not affect the connectivity of the entire network, and does not cause any loops. Hence, these ports can enter the forwarding state without any delay after the bridge starts.
Impact on the System After this parameter is enabled, convergence time of the RSTP is reduced and thus the reliability of the system is improved.
Values Value Range
Default Value
Enabled, Disabled
Disabled
The following table provides the description of each value. Value
Description
Enabled
Indicates that the edge port function is enabled. In this case, the port can enter the forwarding state directly without any delay during the calculation process of the state machine.
Disabled
Indicates that the edge port function is disabled.
Configuration Guidelines The user can set this parameter according to the network topology to reduce the delay in the case of a state migration of the network edge port. 7-68
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7.83 Point to Point Attributes(External Ethernet Port Attributes) Description The Point to Point Attributes (External Ethernet Port Attributes) parameter specifies the mode of connecting Ethernet ports to the external equipment. According to this parameter, the spanning tree protocol (STP) decides whether to rapidly transit the port state from discarding to forwarding.
Impact on the System If the connection is in shared media mode and if the port is not defined as an edge port, the STP cannot rapidly transit the port state. After the STP updates the network topology, the service restoration time becomes longer.
Values Valid Values
Default Value
Adaptive connection, Shared media, Link connection
Adaptive connection
The following table lists the description of each value. Value
Description
Adaptive connection
If the port is a full-duplex port or a VCTRUNK port, and if the port has the point-to-point attribute, the port state can be transited rapidly.
Shared media
If the port has the non-point-to-point attribute, the port state cannot be transited rapidly.
Link connection
If the port has the point-to-point attribute, the port state can be transited rapidly.
Configuration Guidelines If the port connection mode is known, select Shared media or Link connection. Otherwise, select Adaptive connection.
Relationship with Other Parameters None. Issue 02 (2011-06-30)
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7.84 Enabling LCAS Description The Enabling LCAS parameter can increase or decrease the SDH network capacity without affecting the service. The capacity is automatically decreased if a member fails, and is automatically increased if the member recovers.
Impact on the System As a bidirectional protocol, the LCAS can work normally only when some bandwidth is available in the bidirectional physical paths. If the bandwidth is available in the unidirectional physical paths only, the LCAS may fail to correctly adjust the bandwidth.
Values Value Range
Default Value
Enabled, Disabled
Disabled
The following table lists the description of each value. Value
Description
Disabled
Disables the LCAS protocol.
Enabled
Enables the LCAS protocol.
Configuration Guidelines You can set Enabling LCAS as required.
Relationship with Other Parameters None.
7.85 LCAS Mode Description The LCAS Mode parameter specifies the sequence for the sink end to respond to the MST and Rs_Ack messages received from the source end.
Impact on the System The system operation is not affected. 7-70
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Values Value Range
Default Value
Huawei Mode, Standard Mode
Huawei Mode
The following table lists the description of each value. Value
Description
Huawei Mode
Inverts the RS_Ack message, and then transmits the MST message.
Standard Mode
Transmits the MST message, and then Inverts the RS_Ack message.
Configuration Guidelines To set the LCAS mode, follow the principles: l
If the interconnected equipment at the two ends are Huawei equipment, select Huawei Mode.
l
If Huawei equipment is interconnected to a third-party equipment, set the interconnected equipment to the same mode according to the mode supported by the third-party equipment.
Relationship with Other Parameters None.
7.86 Hold-Off Time (ms) (LCAS) Description The Hold-Off Time (ms)(LCAS) parameter is also called HO Procedure Timer Duration. It specifies HO Procedure Timer Duration of the LCAS protocol. If the LCAS coexists with another network-level protection scheme (for example, MSP or SNCP), you can set this parameter to postpone the LCAS switching.
Impact on the System The LCAS switching tiime is affected. For example, if both the MSP and the LCAS are available in a network, set the LCAS hold off time to 2000 ms. If the network fails, only the MSP switching occurs, but the LCAS switching does not occur.
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Values Value Range
Default Value
Unit
0 to 10000 (in step length of 100)
2000
ms
Configuration Guidelines The User can set this parameter according to the expected hold off time of LCAS switching.
Relationship with Other Parameters This parameter is valid only when Enabling LCAS is set to Enabled.
7.87 WTR Time (s) (LCAS) Description The WTR Time (s) parameter is also called WTR Procedure Timer Duration. It specifies WTR Procedure Timer Duration of the LCAS protocol. Set this parameter to avoid impact caused by the alarm jitter on the link status.
Impact on the System The fault recovery time of the LCAS protocol is affected. After the network recovers from a fault, the LCAS protocol can recover only after a WTR duration.
Values Value Range
Default Value
Unit
0 to 720
300
Second
Configuration Guidelines The User can set this parameter according to the expected WTR duration of LCAS recovery.
Relationship with Other Parameters This parameter is valid only when Enabling LCAS is set to Enabled.
7.88 TSD (LCAS) Description The TSD (LCAS) parameter specifies the B3 or BIP error status of a VCTRUNK member. TSD stands for trail signal degrade. When this parameter is set to Enabled, and if a VCTRUNK 7-72
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member has excessive B3 or BIP bit errors, the LCAS protocol regards that this member fails and deletes it from the available members. If this parameter is set to Disabled, the LCAS protocol does not monitor the status of the B3 or BIP bit errors of a VCTRUNK member.
Impact on the System The system running is not affected.
Values Value Range
Default Value
Enabled, Disabled
Disabled
Configuration Guidelines You can set whether to enable the TSD as required.
Relationship with Other Parameters This parameter is valid only when Enabling LCAS is set to Enabled.
7.89 Min Members - Transmit Direction Description When the LCAS is enabled, the LCAS_PLCT alarm is reported if certain members in the transmit direction fail and the number of valid members is smaller than a certain value. The Min Members - Transmit Direction parameter specifies the certain number of the valid members in the transmit direction.
Impact on the System When the LCAS is enabled, failure of certain paths does not affect the service in the case of sufficient bandwidths. The user can set this parameter to enable the reporting of the LCAS_PLCT alarm only when the number of the valid members in the transmit direction is smaller than a certain value.
Values Value Range
Default Value
2-256
256
Configuration Guidelines Set this parameter according to the actual requirement of the user. Issue 02 (2011-06-30)
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7.90 LPT Description The LPT parameter specifies whether the link state pass through (LPT) function is enabled. The LPT is a technology developed by Huawei to increase the speed of the link state response. Through the LPT protocol, the faults on the service access point and in the intermediate network can be detected and reported.
Impact on the System When the LPT function is enabled, the faults on the service access point and in the intermediate network can be detected and reported. For example, the service access point can be informed of the fault in the intermediate network and thus can handle the fault accordingly (switch the service to the backup link). When the LPT function is disabled, the link fault in the intermediate network is not reported to the service access point.
Values Value Range
Default Value
Yes, No
No
The following table provides the description of each value. Value
Description
Yes
Indicates that the LPT function is enabled.
No
Indicates that the LPT function is disabled.
Configuration Guidelines Set this parameter according to the actual requirement of the user. Set this parameter to Yes if the LPT function is required.
7.91 Bearer Mode Description The Bearer Mode parameter specifies the frame format of the LPT protocol packet for transmission. Three bearer modes are available, namely, GFP (HUAWEI), Ethernet, and GFP (CSF).
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Impact on the System All the equipment on the service access point and in the intermediate network should use the same LPT bearer mode. Otherwise, the LPT function cannot work normally.
Values Value Range
Default Value
GFP(HUAWEI), Ethernet, GFP(CSF)
GFP(HUAWEI)
The following table provides the description of each value. Value
Description
GFP(HUAWEI)
Indicates the frame format specially used by Huawei.
Ethernet
Indicates the Ethernet frame format.
GFP(CSF)
Indicates the standard CSF frame format.
Configuration Guidelines Set this parameter according to the actual requirement of the user. Ensure that the configurations of the two interconnected ports are consistent.
7.92 Port-Type Port Hold-Off Time (ms) Description The Port-Type Port Hold-Off Time (ms) parameter specifies the interval for the PORT to transmit the LPT fault information after it receives the information.
Impact on the System The greater the hold-off time of the PORT, the slower is the transmission of fault information between networks.
Values Value Range
Default Value
Unit
0-10000 (in step length of 100)
0
ms
Configuration Guidelines Set this parameter according to the actual requirement of the user. Issue 02 (2011-06-30)
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7.93 VCTRUNK Port Hold-off Time (ms) Description The VCTRUNK-Type Port Hold-off Time (ms) parameter specifies the interval for the VCTRUNK port to transmit the LPT fault information after it receives the information.
Impact on the System The greater the hold-off time of the VCTRUNK port, the slower is the transmission of fault information between networks.
Values Value Range
Default Value
Unit
0-100000
0
ms
Configuration Guidelines Set this parameter according to the actual requirement of the user.
7.94 Protocol Enable (IGMP Snooping Protocol) Description IGMP Snooping is a Layer-2 multicast protocol. If the IGMP Snooping is supported, an Ethernet board can detect the IGMP packets that are transmitted between IP multicast routers or switches and IP multicast hosts, and then check the detected IGMP packets. After being successfully checked, these packets are transmitted transparently. An Ethernet board retrieves the registration information of the multicast group from the checked IGMP packets. Moreover, it configures the relevant functions to generate route ports and multicast groups. The multicast service packets are forwarded according to the multicast group information. This parameter specifies whether to enable the IGMP Snooping protocol within the specified virtual bridge (VB).
Impact on the System
7-76
l
If the IGMP Snooping protocol is enabled, the Ethernet physical port captures and analyzes the received IGMP packets. Then the Ethernet physical port registers the multicast information to generate the router port and the multicast group. Finally the Ethernet physical port transparently transports the packets.
l
If the IGMP Snooping protocol is disabled, the Ethernet physical port does not analyze the received IGMP packets. Instead, the Ethernet physical port broadcasts the IGMP packets as ordinary multicast packets. Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
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Values Valid Values
Default Value
Enabled, Disabled
Disabled
The following table lists the description of each value. Value
Description
Enabled
If the IGMP Snooping protocol is enabled, multicast groups and router ports can be generated.
Disabled
If the IGMP Snooping protocol is disabled, multicast groups and router ports cannot be generated.
Configuration Guidelines l
To create and maintain a multicast service, select Enabled.
l
Otherwise, select Disabled.
7.95 Multicast Aging Time(Min) Description The Multicast Aging Time(Min) parameter specifies the aging time of the router port in the multicast group. The time is learnt by the board port. This parameter decides the valid time of the router port in the multicast group. Within the aging time period, if the router port is learnt again, its aging time is reset. Otherwise, when the aging time expires, the relevant router port in the multicast group is aged. After the router port is aged, the whole multicast group is deleted if no other router ports exist in the multicast group.
Impact on the System The parameter value may affect the forwarding efficiency of the EVPLAN service. l
If the aging time is extremely long, and if the multicast MAC address table in the board fails to be updated in time, the board forwards the service packets incorrectly. Consequently, the forwarding efficiency is decreased.
l
If the aging time is extremely short, the multicast MAC address table may be updated rapidly. Moreover, a great number of received multicast service packets fail to be found in the MAC address table. Consequently, the board broadcasts these data packets to all the ports. As a result, the forwarding efficiency is also decreased.
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Values Valid Values
Default Value
Unit
1-120, in step length of 1
8
Min
Configuration Guidelines Generally, select the default value, unless otherwise specified. Otherwise, set the value according to the requirements. Do not set the value beyond the range allowed by the board.
Relationship with Other Parameters None.
7.96 Frames to Send Description Frames to Send indicates the number of test packets to be transmitted. With this parameter enabled, the system transmits a test packet at the intervals of certain period of time until the number of transmitted test packets reaches the specified value.
Impact on the System The system operation is not affected.
Values Value Range
Default Value
Unit
0-255
0
Unit
Configuration Guidelines The user can set the number of test packets to be transmitted as required.
Relationship with Other Parameters This parameter is valid only when Send Mode is set to Burst Mode.
7.97 Status Description Status indicates the transmit status of the current test frames at the port. This parameter is displayed as the current test status after you configure Send Mode and Frames to Send and then click Apply. 7-78
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Impact on the System The system operation is not affected.
Values Value Range
Default Value
Sending, Finished Sending
-
The following table lists the description of each value. Value
Description
Sending
Indicates that the port is currently transmitting the test frames.
Finished Sending
Indicates that the port finishes transmitting the test frames.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.98 Set Frame Count Description Set Frame Count indicates the number of test frames that are transmitted by the VC trunk port in the Ethernet test. This parameter value is accumulative. The value indicates the total number of test frames that are transmitted from last time when the parameter value is cleared to this time when the value is queried.
Impact on the System This parameter is for query only and does not affect the system operation.
Values For example, the parameter value 5indicates that the port transmits five test frames.
Configuration Guidelines None. Issue 02 (2011-06-30)
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Relationship with Other Parameters None.
7.99 Received Response Test Frame Count Description Received Response Test Frame Count indicates the number of response test frames that are received by the VC trunk port in the Ethernet test. This parameter value is accumulative. The value indicates the total number of response test frames that are received from last time when the parameter value is cleared to this time when the value is queried.
Impact on the System This parameter is for query only and does not affect the system operation.
Values For example, the parameter value 5indicates that this port receives five response test frames.
Configuration Guidelines None.
Relationship with Other Parameters None.
7.100 Test Frames to Receive Description Test Frames to Receive indicates the number of test frames that are received by the VC trunk port in the Ethernet test. This parameter value is accumulative. The value indicates the total number of test frames that are transmitted from last time when the parameter value is cleared to this time when the value is queried.
Impact on the System This parameter is for query only and does not affect the system operation.
Values For example, the parameter value 5indicates that the port receives five test frames.
Configuration Guidelines None. 7-80
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Relationship with Other Parameters None.
7.101 Send Mode (Ethernet Test) Description Send Mode(Ethernet Test) is used to set the test frame and the transmit mode of the test frame. The test frame is used for simulating packet transmission to check whether the link is normal.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Disabled, Burst Mode, Continue Mode
Disabled
The following table lists the description of each value. Value
Description
Disabled
Indicates the test is not performed.
Burst Mode
Indicates that the system transmits a test frame every one second. The test ends after a specified number of test frames are transmitted.
Continue Mode
Indicates that the system continuously transmits test frames with a frequency of 1 frame per second.
Configuration Guidelines Set this parameter according to the requirements of the test. l
To perform the test continuously, set the parameter to Continue Mode.
l
To stop the test, set the parameter to Disabled.
Relationship with Other Parameters None..
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7.102 Call Waiting Time(s) Description The Call Waiting Time(s) parameter specifies the timeout period of searching an orderwire route. If the period of searching an orderwire route exceeds the specified value, the orderwire phone changes to the busy tone status.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Unit
1-9
9
s
Configuration Guidelines For all the network elements (NEs) that communicate with each other over the orderwire phone, this parameter must be set to the same value. l
If the number of NEs is less than 30, usually, set the value to 5 seconds.
l
If the number of NEs is not less than 30, usually, set the value to 9 seconds.
Generally, set it to the default value (namely, 9 seconds).
7.103 Conference Call Description The Conference Call parameter specifies the phone numbers of networkwide orderwire calls.
Impact on the System The system operation is not affected.
Values
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Valid Values
Default Value
100-99999999
999
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Configuration Guidelines l
For orderwire conference calls on each node of the same subnet, the phone number must be the same.
l
The length of an orderwire conference call number can be set as required. The value range is 3-8.
l
The length of an orderwire conference call number must be consistent with that of the addressing call number.
OptiX OSN 550 equipment does not support this parameter.
Relationship with Other Parameters None.
7.104 Phone Description The Phone parameter specifies the phone numbers of orderwire addressing calls. An addressing call refers to a point-to-point call.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
100-99999999
101
Configuration Guidelines l
The phone numbers of orderwire addressing calls cannot be duplicate within the same subnet.
l
The length of an orderwire call number can be set as required. The value range is 3-8. Within the same orderwire network, the length of orderwire call numbers must be consistent for each node.
l
The length of phone numbers used to make orderwire addressing calls must be consistent with that of conference call numbers. NOTE
OptiX OSN 550 equipment only supports Phone 1.
Relationship with Other Parameters If the length of an orderwire phone number is set to another value, the orderwire addressing call number is changed to the default phone number that maps the length. Issue 02 (2011-06-30)
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For example, if the length of a phone number is set to contain three digits, the addressing call number is changed to the default number 101. If the length of the phone number is set to contain four digits, the addressing call number is changed to the default number 1001, and the rest may be deduced by analogy.
7.105 Available Orderwire Port Description The Available Orderwire Port parameter specifies whether the optical interface is used to make orderwire calls.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
Available Orderwire Port
Bid-BidType-PortID
The following table lists the description of each value. Value
Description
Bid-BidType-PortID
Indicates the available optical interface of a board in a slot, which is used to set orderwire calls. l Bid indicates the slot number of the board used to set orderwire calls. l BidType indicates the name of the board used to set orderwire calls. l PortID indicates the number of the optical interface on the board used to set orderwire calls.
Configuration Guidelines None.
Relationship with Other Parameters None.
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7.106 No.(F1 Data Port) Description The No. (F1 Data Port) parameter specifies the numbers of the F1 data ports that have the same direction.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
1-88
-
Configuration Guidelines None.
Relationship with Other Parameters None.
7.107 Data Channel (F1 Data Port) Description The Data Channel (F1 Data Port) parameter specifies the uplink and downlink ports that pass through the F1 data.
Impact on the System After the data channel is cancelled, the services that pass through the F1 data port are interrupted.
Values Valid Values
Default Value
F1, Bid-BidType-PortID
-
The following table lists the description of each value. Issue 02 (2011-06-30)
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Value
Description
F1
Indicates the F1 data port of the NE.
Bid-BidType-PortID
Indicates a port that can be used to set a slot of the F1 data port.
Configuration Guidelines When using the F1 data port, you need to configure its route. That is, set the 64 Kbit/s data being added to or dropped from the NE, or passing through the NE.
Relationship with Other Parameters You can correctly set the F1 data ports that have the same direction only when the F1 port is not set to Transparent ECC Overhead Transmission.
7.108 Overhead Byte (Broadcast Data Port) Description The Overhead Byte (Broadcast Data Port) parameter specifies the number of the overhead bytes, which are used to transmit orderwire broadcast data services, in the SDH frame header.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
SERIAL1, SERIAL2, SERIAL3, SERIAL4
SERIAL1
The following table lists the description of each value.
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Value
Description
SERIAL1
Indicates the S1 byte in the SDH frame header.
SERIAL2
Indicates the S2 byte in the SDH frame header.
SERIAL3
Indicates the S3 byte in the SDH frame header.
SERIAL4
Indicates the S4 byte in the SDH frame header.
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Configuration Guidelines Select the value according to the configuration.
Relationship with Other Parameters If the S1 byte, the S2 byte, the S3 byte, the S4 byte, or an optical interface is set to transparently transmit DCC overhead, the broadcast data port may fail to be set.
7.109 Working Mode (Broadcast Data Port) Description The Working Mode (Broadcast Data Port) parameter specifies the working mode of the local interface at which broadcast data services are added or dropped.
Impact on the System The system operation is not affected.
Values Value
Valid Values
RS232
RS232
The following table lists the description of each value. Value
Description
RS232
Indicates an asynchronous transmission mode, in which no handshake signal is available. An NE operating in RS232 mode can communicate with an NE operating in RS232 or RS422 mode directly; in this case, data transmission is transparent and the maximum rate is 19.2 kbit/s.
Configuration Guidelines None.
Relationship with Other Parameters None.
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7.110 Broadcast Data Source (Broadcast Data Port) Description The Broadcast Data Source (Broadcast Data Port) parameter specifies the source of the orderwire broadcast data service.
Impact on the System The system operation is not affected.
Values Valid Values
Default Value
No Data, SERIALx, BidBidType-PortID
-
The following table lists the description of each value. Value
Description
No Data
Clears all the broadcast data services.
SERIALx
Indicates the local broadcast data port. For example, SERIAL1.
Bid-BidType-PortID
Indicates a port that is used to set a slot of the F1 data port.
Configuration Guidelines Select the value according to the configuration.
Relationship with Other Parameters If the S1 byte, the S4 byte, or an optical interface is set to transparently transmit DCC overhead, the broadcast data service may fail to be set.
7.111 Broadcast Data Sink (Broadcast Data Port) Description The Broadcast Data Sink (Broadcast Data Port) parameter specifies the sink of the orderwire broadcast data service. 7-88
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Impact on the System The system operation is not affected.
Values Valid Values
Default Value
SERIALx, Bid-BidTypePortID
-
The following table lists the description of each value. Value
Description
SERIALx
Indicates the local broadcast data port, for example, SERIAL1.
Bid-BidType-PortID
Indicates a port that is used to set a slot of the F1 data port.
Configuration Guidelines Select the value according to the configuration.
Relationship with Other Parameters If the S1 byte, the S4 byte, or an optical interface is set to transparently transmit DCC overhead, the broadcast data service may fail to be set.
7.112 External Clock Output Mode When 2M Output Synchronous Source Is Invalid Description The External Clock Output Mode When 2M Output Synchronous Source Is Invalidparameter is used to specify an action to control the output mode of external clock source when all the clock sources in the 2M phase-locked source priority table become invalid or when the clock quality of the selected source is inferior to the output quality threshold of external clock source.
Impact on the System The system running is not affected.
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Values Value Range
Default Value
Synchronization Quality Unavailable, Output AIS, Shut off
Shut off
The following table lists the description of each value. Parameter
Description
Synchronization Quality Unavailable
Indicates that the synchronous source is unavailable when the S1 byte contains 0x0f.
Output AIS
Indicates that all "1"s signal is sent.
Shut off
Indicates that the output is shut down.
Configuration Guidelines In actual application, this parameter can be set according to the requirements of the opposite NE that connects to the specific external clock. By default, this parameter is set to Shut off.
Relationship with Other Parameters None.
Related Information None.
7.113 External Clock Output Mode Description The External Clock Output Mode parameter is used to set the output mode of the external clock source to 2 Mbit/s or 2 MHz.
Impact on the System Modifying the output mode of the external clock source may result in the switching of the clock sources, which may bring bit errors to the service.
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Values Value Range
Default Value
2 MHz, 2 Mbit/s
2 Mbit/s
The following table lists the description of each value. Value
Description
2 MHz
Indicates that the output mode of the external clock source is set to 2 MHz. That is, the external clock source outputs 2 MHz clock signals.
2 Mbit/s
Indicates that the output mode of the external clock source is set to 2 Mbit/s.
Configuration Guidelines The input mode of the two channels of external clock signals can be set to 2 MHz or 2 Mbit/s. The default input mode is 2 Mbit/s. In actual application, make sure that the output mode matches the input mode on the receive end.
Relationship with Other Parameters None.
Related Information None.
7.114 External Clock Output Timeslot Description The External Clock Output Timeslot parameter is used to set the output timeslot for the S1 byte of the external clock source. The external clock source transmits the S1 overhead byte through certain timeslots. After starting the SSM protocol, make sure that the timeslot for receiving the S1 byte is consistent with the timeslot for transmitting the S1 byte so that the S1 byte can be received correctly.
Impact on the System When the SSM protocol is enabled on the NEs, setting the S1 byte may result in the switching of the clock sources. This may bring bit errors to the service when clock jitters occur.
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Values Value Range
Default Value
SA4, SA5, SA6, SA7, SA8, All versions
All versions
The following table lists the description of each value. Value
Description
SA4
Indicates that the S1 byte is transmitted through the SA4 timeslot of the external clock port.
SA5
Indicates that the S1 byte is transmitted through the SA5 timeslot of the external clock interface.
SA6
Indicates that the S1 byte is transmitted through the SA6 timeslot of the external clock interface.
SA7
Indicates that the S1 byte is transmitted through the SA7 timeslot of the external clock interface.
SA8
Indicates that the S1 byte is transmitted through the SA8 timeslot of the external clock interface.
All versions
Indicates that the S1 byte is transmitted through all timeslots of the external clock interface.
Configuration Guidelines None.
Relationship with Other Parameters This parameter can be set only when the External Clock Output Mode parameter is set to 2 Mbit/s.
Related Information None.
7.115 External Source Output Threshold Description The External Source Output Threshold parameter is used to set the output quality threshold of the external clock source. When the output quality of the external clock source is inferior to the threshold, the action specified for 2M phase-locked source failure is invoked to control the external clock source output. 7-92
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Impact on the System The system running is not affected.
Values Value Range
Default Value
Threshold Disabled, Not Inferior to G. 813 SETS Signal, Not Inferior to G.812 Local Clock Signal, Not Inferior to G. 812 Transit Clock Signal, Not Inferior to G.811 Clock Signal
Threshold Disabled
The following table lists the description of each value. Value
Description
Threshold Disabled
Indicates that the external source quality threshold is disabled.
Not Inferior to G.813 SETS Signal
Indicates that the external clock source becomes invalid when its output quality is inferior to the G.813 signal.
Not Inferior to G.812 Local Clock Signal
Indicates that the external clock source becomes invalid when its output quality is inferior to the G.812 local clock signal.
Not Inferior to G.812 Transit Clock Signal
Indicates that the external clock source becomes invalid when its output quality is inferior to the G.812 transit office clock signal.
Not Inferior to G.811 Clock Signal
Indicates that the external clock source becomes invalid when its output quality is inferior to the G.811 signal.
Configuration Guidelines The output quality of the external clock source should not be inferior to the specified quality threshold. Therefore, the quality threshold should be set to a value that is inferior to or equal to the output clock quality level.
Relationship with Other Parameters This parameter is valid only when the Protection Status parameter is set to Start Standard SSM Protocol.
Related Information None. Issue 02 (2011-06-30)
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7.116 2M Phase-Locked Source Fail Condition Description The 2M Phase-Locked Source Fail Condition parameter is used to set the failure condition of the 2M phase-locked source.
Impact on the System The system running is not affected.
Values Value Range
Default Value
No Failure Condition, AIS, LOF, AIS OR LOF
No Failure Condition
The following table lists the description of each value. Value
Description
No Failure Condition
Indicates that no failure condition is set. The 2M phase-lock source remains valid when an AIS or LOF alarm of the external clock signal occurs.
AIS
Indicates that the failure condition is set to AIS. The 2M phase-lock source becomes invalid when an AIS alarm of external clock signal occurs.
LOF
Indicates that the failure condition is set to an LOF alarm. The 2M phase-lock source becomes invalid when an LOF alarm of external clock signal occurs.
AIS OR LOF
Indicates that the failure condition is set to an AIS alarm or LOF alarm. The 2M phase-lock source becomes invalid when an AIS or LOF alarm of external clock signal occurs.
Configuration Guidelines Failure condition can be set as required.
Relationship with Other Parameters None.
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Related Information None.
7.117 2M Phase-Locked Source Fail Action Description The 2M Phase-Locked Source Fail Action parameter is used to specify the action to be invoked in the case of 2M phase-locked source failure. When the reference clock signal for locking external clock output is invalid or inferior to the threshold, the specific action is invoked to control the external clock output by either shutting down the output or inserting an AIS alarm.
Impact on the System The system running is not affected.
Values Value Range
Default Value
Shut Down Output, Send AIS, 2M Output S1 Byte Unavailable
Shut Down Output
The following table lists the description of each value. Value
Description
Shut Down Output
Indicates that the output of external clock signal is shut down.
Send AIS
Indicates that the external clock sends all "1"s signals.
2M Output S1 Byte Unavailable
Indicated that the S1 byte sent by the external clock is unavailable. That is, the external clock sends 0x0f.
Configuration Guidelines When the 2M phase-locked source is invalid, output action can be set as required. When the External Clock Output Mode parameter is set to 2 MHz, the output of external clock signal is shut down no matter what action is set.
Relationship with Other Parameters None.
Related Information None. Issue 02 (2011-06-30)
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7.118 Clock Source Threshold Description The Clock Source Threshold parameter indicates the lower quality threshold of 2M external clock source. When the clock quality level of the external clock source that is selected from the 2M phase-locked source priority table is inferior to the threshold, the 2M phase-locked source becomes invalid, and the action specified for 2M phase-locked source failure is invoked to control the external clock source output.
Impact on the System The system running is not affected.
Values Value Range
Default Value
No Threshold Value, G.813 SETS Signal, G.812 Lock Clock Signal, G.812 Transit Clock Signal, G.811 Clock Signal
No Threshold Value
The following table lists the description of each value. Value
Description
No Threshold Value
Threshold disabled
G.813 SETS Signal
Indicates that the lower threshold is not inferior to the G.813 SETS signal.
G.812 Lock Clock Signal
Indicates that the lower threshold is not inferior to the G.812 lock clock signal.
G.812 Transit Clock Signal
Indicates that the lower threshold is not inferior to the G.812 transit clock signal.
G.811 Clock Signal
Indicates that the lower threshold is not inferior to the G.811 clock signal.
Configuration Guidelines In actual application, the output quality threshold of external clock source should be determined according to the quality information about the NE clock and the opposite NE.
Relationship with Other Parameters None. 7-96
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Related Information None.
7.119 AIS Alarm Generated Description The AIS Alarm Generated parameter is used to specify whether an AIS alarm is a condition for triggering the switching of clock sources.
Impact on the System The system running is not affected.
Values Value Range
Default Value
Yes, No
No
The following table lists the description of each value. Value
Description
Yes
Indicates that an AIS alarm is the sufficient condition to trigger clock source switching.
No
Indicates that an AIS alarm is not a condition for triggering clock source switching.
Configuration Guidelines It is recommended to set the AIS alarm as the condition for triggering clock source switching in actual application to ensure system performance.
Relationship with Other Parameters None.
Related Information None.
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7.120 B1 BER Threshold-Crossing Generated Description The B1 BER Threshold-Crossing Generated parameter is used to specify whether a B1 BER threshold-crossing alarm is a condition for triggering clock source switching. B1 BER Threshold-Crossing alarm is an index for measuring the performance of clock source signals.
Impact on the System The system running is not affected.
Values Value Range
Default Value
Yes, No
No
The following table lists the description of each value. Value
Description
Yes
Indicates that a B1 BER threshold-crossing alarm is the sufficient condition for triggering clock source switching.
No
Indicates that a B1 BER threshold-crossing alarm is not the condition for triggering clock source switching.
Configuration Guidelines A B1 BER threshold-crossing alarm indicates that the transmitted signal and the clock in the signal are being interfered. Therefore, this parameter can be set as a condition for triggering clock source switching in actual application to ensure system performance.
Relationship with Other Parameters None.
Related Information None.
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7.121 B2-EXC Alarm Generated Description The B2-EXC Alarm Generated parameter is used to specify whether a B2-EXC alarm is a condition for triggering clock source switching. B2-EXC alarm is an index for measuring the performance of clock source signals.
Impact on the System The system running is not affected.
Values Value Range
Default Value
Yes, No
No
The following table lists the description of each value. Value
Description
Yes
Indicates that a B2-EXC alarm is the sufficient condition for triggering clock source switching.
No
Indicates that a B2-EXC alarm is not the condition for triggering clock source switching.
Configuration Guidelines A B2-EXC alarm indicates that the transmitted signal and the clock in the signal are being interfered. Therefore, this parameter can be set as a condition for triggering clock source switching in actual application to ensure system performance.
Relationship with Other Parameters None.
Related Information None.
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7.122 Higher Priority Clock Source Reversion Mode Description The Higher Priority Clock Source Reversion Mode parameter specifies whether to switch from the lower-priority clock source back to the higher-priority clock source after the higherpriority clock source is restored to normal.
Impact on the System If the conditions for clock source switching are excessively strict, jitters may occur in the monitoring results of the clock status. If the auto-revertive mode is selected, the frequent switching of clock sources may affect the service.
Values Value Range
Default Value
Non-Revertive, AutoRevertive
Auto-Revertive
The following table lists the description of each value. Value
Description
Non-Revertive
Indicates that the higher-priority clock source cannot be selected automatically after it is restored to normal.
Auto-Revertive
Indicates that the higher-priority clock source is selected automatically after it is restored to normal.
Configuration Guidelines If the conditions for clock source switching are properly set and the switching of clock sources can be guaranteed, the Auto-Revertive mode can be selected to improve clock quality. Otherwise, the Non-Revertive mode is recommended to avoid clock jitters.
Relationship with Other Parameters None.
Related Information None.
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7.123 Clock Source WTR Time Description The Clock Source WTR Time parameter is used to specify the wait-to-restore (WTR) time when the Higher Priority Clock Source Reversion Mode parameter is set to AutoRevertive. When a clock source is restored to its valid status, the system does not regard it as a valid source immediately but verifies the validity of the clock source in a specific period of time. The system regards the clock source as a valid source only if the clock source remains valid during the specific period of time. This specific period of time is called the WTR time of the clock source.
Impact on the System Insufficient WTR time may result in wrong judgments on clock source restoration and clock status jitters, which may interrupt the service.
Values Value Range
Default Value
0-12
5
Configuration Guidelines The WRT time is counted in minutes. The shorter the WTR time is, the faster the clock is recovered, and the higher the average clock quality is. On the other hand, the shorter the WTR time is, the more likely the clock jitters are caused due to unstable clock signals. Therefore, do not set the WTR time to 0 in actual application.
Relationship with Other Parameters The setting of the WTR time is valid only when the Higher Priority Clock Source Reversion Mode parameter is set to Auto-Revertive.
Related Information None.
7.124 Lock Status Description The Lock Status parameter indicates the lock status of a clock source in the priority table.
Impact on the System The system running is not affected. Issue 02 (2011-06-30)
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Values Value Range
Default Value
Lock, Unlock
Unlock
The following table lists the description of each value. Value
Description
Lock
Indicates that a certain channel of clock source in the priority table is in the lock status where the switching of clock sources is not allowed.
Unlock
Indicates that a certain channel of clock source in the priority table is in the unlock status where the switching of clock sources is allowed.
Configuration Guidelines None.
Relationship with Other Parameters None.
Related Information None.
7.125 Synchronous Source Description The Synchronous Source parameter indicates the synchronous clock source that is being traced. The synchronous clock source here refers to a certain clock source contained in the system clock priority table.
Impact on the System The system running is not affected.
Values
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Value Range
Default Value
Clock Source in System Clock Priority Table
None
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The following table lists the description of each value. Value
Description
Clock Source in System Clock Priority Table
Indicates that the system clock priority table contains the tributary clock sources, line clock sources, external clock sources, and internal clock sources.
Configuration Guidelines The OptiX OSN 550 does not support External Clock Source.
Relationship with Other Parameters None.
Related Information None.
7.126 S1 Byte Synchronization Quality Information Description The S1 Byte Synchronization Quality Information parameter indicates the synchronization quality information in the S1 byte that is output by the current traced synchronous source. The S1 byte defined by the ITUT is used to transmit the quality information about the clock sources. It indicates the quality information of 16 types of synchronous sources with bits 5-8 of the S1 byte in the section overhead. With this quality information and certain switching protocols, the automatic protection switching of the synchronization clock can be realized in the synchronous network.
Impact on the System The system running is not affected.
Values
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Value Range
Default Value
Synchronous Source Unavailable, Quality Unknown, G.811 Reference Clock, G.812 Transit Clock, G.812 Local Clock, SDH equipment timing source (SETS) signal
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The following table lists the description of each value. Value
Description
Synchronous Source Unavailable
Indicates that the SSM protocol is disabled and the S1 byte synchronization quality information output by the synchronous source is not available.
Quality Unknown
Indicates that the SSM protocol is started but the S1 byte synchronization quality information output by the synchronous source is unknown.
G.811 Reference Clock
Indicates that the SSM protocol is started and the S1 byte synchronization quality information output by the synchronous source is the G.811 reference clock.
G.812 Transit Clock
Indicates that the SSM protocol is started and the S1 byte synchronization quality information output by the synchronous source is the G.812 transit clock.
G.812 Local Clock
Indicates that the SSM protocol is started and the S1 byte synchronization quality information output by the synchronous source is the G.812 local clock.
SDH equipment timing source (SETS) signal
Indicates that the SSM protocol is enabled and the S1 byte synchronization quality information output by the synchronous source is the synchronous equipment timing source (SETS) clock.
Configuration Guidelines None.
Relationship with Other Parameters None.
Related Information None.
7.127 NE Clock Working Mode Description The NE Clock Working Mode parameter is used to set the current working mode of the system clock to the normal, holdover or free-run mode.
Impact on the System The system running is not affected. 7-104
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Values Value Range
Default Value
Normal Mode, Holdover Mode, FreeRun Mode
-
The following table lists the description of each value. Value
Description
Normal Mode
Indicates that the NE clock works in the tracing mode. That is, the NE clock traces and locks the working mode of its upper-level clock.
Holdover Mode
Indicates that the NE clock works in the holdover mode. That is, in this mode, the NE clock uses the frequency information that is stored before all timing reference signals are lost as its timing reference.
Free-Run Mode
Indicates that the NE clock works in the free-run mode. That is, the internal oscillator works in this mode when all external timing reference signals are lost.
Configuration Guidelines None.
Relationship with Other Parameters None.
Related Information None.
7.128 Data Output Method in Holdover Mode Description The Data Output Method in Holdover Mode parameter is used to specify whether the data is output normally or the latest data is kept when the NE clock is in the holdover mode.
Impact on the System The system running is not affected. Issue 02 (2011-06-30)
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Values Value Range
Default Value
Normal Data Output Mode, Keep the Latest Data
Normal Data Output Mode
The following table lists the description of each value. Value
Description
Normal Data Output Mode
Indicates the normal data output mode. The duration of this output mode is determined by the phase lock. This data output mode can continue for a maximum of 24 hours.
Keep the Latest Data
Indicates that the latest phase-locked data is kept. This data output mode is a forced holdover mode.
Configuration Guidelines The Keep the Latest Data mode is a forced holdover mode. Therefore, the clock accuracy is not high. In actual application, the Normal Data Output mode is recommended.
Relationship with Other Parameters The NE clock can work in three modes: the trace, holdover, and free-run modes. This parameter is valid only when the NE clock is working in the holdover mode.
Related Information None.
7.129 Retiming Mode Description The Retiming Mode parameter specifies whether the retiming clock, tributary clock, or crossconnect (external) clock is used.
Impact on the System If the downstream board that corresponds to this board provides the clock source for the downstream NE, the selection of the user affects the precision of the downstream NE.
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Values Value Range
Default Value
Normal, Retiming Mode of Tributary Clock, Retiming Mode of Cross-Connect Clock
Normal
The following table provides the description of each value. Value
Description
Normal
Indicates that the retiming clock is not used.
Retiming Mode of Tributary Clock
Indicates that the tributary clock is used as the retiming clock.
Retiming Mode of CrossConnect Clock
Indicates that the cross-connect (external) clock is used as the retiming clock.
Configuration Guidelines Select the proper clock according to the actual networking planning of the user. The OptiX OSN equipment supports only Retiming Mode of Tributary Clock. This parameter is applicable to only SP3D boards.
7.130 Switching Mode (MSP) Description The Switching Mode parameter specifies the switching mode of the linear MSP.
Impact on the System The system operation is not affected.
Values Value Range
Default Value
Single-Ended Switching, DualEnded Switching
Single-Ended Switching
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Value
Description
Single-Ended Switching
Indicates that the transmit end continues to transmit signals to the broken fiber after the switching occurs at the faulty end.
Dual-Ended Switching
Indicates that the transmit end does not transmit signals to the broken fiber after the switching occurs at the transmit end and at the receive end.
Configuration Guidelines In the case of the 1+1 MSP, you can set this parameter to Single-Ended Switching or DualEnded Switching. In the case of the 1:N MSP, you can set this parameter to Dual-Ended Switching only.
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A Glossary and Acronyms
Glossary and Acronyms
Terms and abbreviations are listed in an alphabetical order. A.1 Numerics A.2 A A.3 B A.4 C A.5 D A.6 E A.7 F A.8 G A.9 H A.10 I A.11 J A.12 L A.13 M A.14 N A.15 O A.16 P A.17 Q A.18 R A.19 S A.20 T A.21 U A.22 V Issue 02 (2011-06-30)
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A.23 W
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A.1 Numerics 1+1 protection
An architecture that has one normal traffic signal, one working SNC/trail, one protection SNC/trail and a permanent bridge. At the source end, the normal traffic signal is permanently bridged to both the working and protection SNC/trail. At the sink end, the normal traffic signal is selected from the better of the two SNCs/trails. Due to the permanent bridging, the 1+1 architecture does not allow an extra unprotected traffic signal to be provided.
100BASE-T
IEEE 802.3 Physical Layer specification for a 100 Mb/s CSMA/CD local area network.
100BASE-TX
IEEE 802.3 Physical Layer specification for a 100 Mb/s CSMA/CD local area network over two pairs of Category 5 unshielded twisted-pair (UTP) or shielded twisted-pair (STP) wire.
10BASE-T
An Ethernet specification that uses the twisted pair cable with the transmission speed as 10 Mbit/s and the transmission distance as 100 meters.
1:N protection
An architecture that has N normal service signals, N working SNCs/trails, and one protection SNC/trail. It may have one extra service signal.
1PPS
Pulse per second, which, strictly speaking, is not a time synchronization signal. This is because 1PPS provides only the "gauge" corresponding to the UTC second, but does not provide the information about the day, month, or year. Therefore, 1PPS is used as the reference for frequency synchronization. On certain occasions, 1PPS can also be used on other interfaces for high precision timing.
3R
Reshaping, Retiming, Regenerating.
A.2 A ABR
Available Bit Rate
AC
Alternating Current
ACAP
A channel configuration method, which uses two adjacent channels (a horizontal polarization wave and a vertical polarization wave) to transmit two signals.
Active/Standby switching of crossconnect board
The process in which the standby cross-connect board automatically takes the place of the active one. If there are two cross-connect boards on the SDH equipment, which are in hot back-up relation of each other, the operation reliability is improved. When both the cross-connect boards are in position, the one inserted first is in the working status. Unplug the active board, the standby one will run in the working status automatically. When the active cross-connect board fails in self-test, the board is pulled out, the board power supply fails or the board hardware operation fails, the standby cross-connect board can automatically take the place of the active one.
add/drop multiplexer
Network elements that provide access to all or some subset of the constituent signals contained within an STM-N signal. The constituent signals are added to (inserted), and/ or dropped from (extracted) the STM-N signal as it passed through the ADM.
ADM
See add/drop multiplexer
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Administrative Unit
The information structure which provides adaptation between the higher order path layer and the multiplex section layer. It consists of an information payload (the higher order VC) and a AU pointer which indicates the offset of the payload frame start relative to the multiplex section frame start.
Administrative Unit Group
One or more administrative units occupying fixed, defined positions in an STM payload. An AUG consists of AU-4s.
Administrator
A user who has authority to access all the Management Domains of the product. He or she has access to the whole network and to all the management functionalities.
Aging time
The time to live before an object becomes invalid.
AIS
Alarm Indication Signal
Alarm
A message reported when a fault is detected by a device or by the network management system during the process of polling devices. Each alarm corresponds to a recovery alarm. After a recovery alarm is received, the status of the corresponding alarm changes to cleared.
Alarm automatic report
A function wherein an alarm generated on the device side is immediately and automatically reported to the NMS. After an alarm is reported, an alarm panel prompts, and the user can view the details of the alarm.
alarm cable
The cable for generation of visual or audio alarms.
alarm filtering
An alarm management method. Alarms are detected and reported to the NMS system, and whether the alarm information is displayed and saved is decided by the alarm filtering status. An alarm with the filtering status set to "Filter" is not displayed and saved on the NMS, but is monitored on the NE.
alarm indication
A function that indicates the alarm status of an NE. On the cabinet of an NE, there are four indicators in different colors indicating the current alarm status of the NE. When the green indicator is on, the NE is powered on. When the red indicator is on, a critical alarm is generated. When the orange indicator is on, a major alarm is generated. When the yellow indicator is on, a minor alarm is generated. The ALM alarm indicator on the front panel of a board indicates the current status of the board.
Alarm indication signal A code sent downstream in a digital network as an indication that an upstream failure has been detected and alarmed. It is associated with multiple transport layers. Alarm inversion
For the port that has already been configured but has no service, this function can be used to avoid generating relevant alarm information, thus preventing alarm interference. The alarm report condition of the NE port is related to the alarm inverse mode (not inverse, automatic recovery and manual recovery) setting of the NE and the alarm inversion status (Enable and Disable) setting of the port. When the alarm inversion mode of NE is set to no inversion, alarms of the port will be reported as usual no matter whatever the inversion status of the port is. When the alarm inversion mode of the NE is set to automatic recovery, and the alarm inversion state of the port is set to Enabled, then the alarm of the port will be suppressed. The alarm inversion status of the port will automatically recover to "not inverse" after the alarm ends. For the port that has already been configured but not actually loaded with services, this function can be used to avoid generating relevant alarm information, thus preventing alarm interference. When the alarm inverse mode of the NE is set as "not automatic recovery", if the alarm inversion status of the port is set as Enable, the alarm of the port will be reported.
Alarm Masking
An alarm management method. Alarms that are set to be masked are not displayed on the NMS or the NMS does not monitor unimportant alarms.
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Alarm Severity
The significance of a change in system performance or events. According to ITU-T recommendations, an alarm can have one of the following severities: Critical, Major, Minor, Warning.
Alarm suppression
An alarm management method. Alarms that are set to be suppressed are not reported from NEs any more.
ALS
See Automatic laser shutdown
APS
See Automatic Protection Switching
asynchronous
Pertaining to, being, or characteristic of something that is not dependent on timing.
Asynchronous Transfer Mode
A protocol for the transmission of a variety of digital signals using uniform 53 byte cells. A transfer mode in which the information is organized into cells; it is asynchronous in the sense that the recurrence of cells depends on the required or instantaneous bit rate. Statistical and deterministic values may also be used to qualify the transfer mode.
ATM
See Asynchronous Transfer Mode
ATPC
See Automatic Transmit Power Control
attenuation
Reduction of signal magnitude or signal loss, usually expressed in decibels.
AU
See Administrative Unit
AUG
See Administrative Unit Group
auto-negotiation
An optional function of the IEEE 802.3u Fast Ethernet standard that enables devices to automatically exchange information over a link about speed and duplex abilities..
Automatic laser shutdown
A technique (procedure) to automatically shutdown the output power of laser transmitters and optical amplifiers to avoid exposure to hazardous levels.
Automatic Protection Switching
Capability of a transmission system to detect a failure on a working facility and to switch to a standby facility to recover the traffic.
Automatic Transmit Power Control
A method of adjusting the transmit power based on fading of the transmit signal detected at the receiver.
A.3 B backplane
An electronic circuit board containing circuits and sockets into which additional electronic devices on other circuit boards or cards can be plugged.
backup
A periodic operation performed on the data stored in the database for the purposes of database recovery in case that the database is faulty. The backup also refers to data synchronization between active and standby boards.
bandwidth
A range of transmission frequencies that a transmission line or channel can carry in a network. In fact, it is the difference between the highest and lowest frequencies the transmission line or channel. The greater the bandwidth, the faster the data transfer rate.
BDI
Backward Defect Indicator
BER
See Bit Error Rate
BER tester
Used to measure the bit error rate (BER) of signals during transmission.
Binding strap
The binding strap is 12.7 mm wide, with one hook side (made of transparent polypropylene material) and one mat side (made of black nylon material).
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BIP
A method of error monitoring. With even parity an X-bit code is generated by equipment at the transmit end over a specified portion of the signal in such a manner that the first bit of the code provides even parity over the first bit of all X-bit sequences in the covered portion of the signal, the second bit provides even parity over the second bit of all X-bit sequences within the specified portion, and so on. Even parity is generated by setting the BIP-X bits so that there is an even number of 1s in each monitored partition of the signal. A monitored partition comprises all bits which are in the same bit position within the Xbit sequences in the covered portion of the signal. The covered portion includes the BIPX.
Bit error
An incompatibility between a bit in a transmitted digital signal and the corresponding bit in the received digital signal.
Bit Error Rate
Ratio of received bits that contain errors. BER is an important index used to measure the communications quality of a network.
BITS
See Building Integrated Timing Supply
bound path
A parallel path with several serial paths bundled together. It improves the data throughput capacity.
BPDU
See Bridge Protocol Data Unit
BPS
Board Protection Switching
bridge
A device that connects two or more networks and forwards packets among them. Bridges operate at the physical network level. Bridges differs from repeaters because bridges store and forward complete packets, while repeaters forward all electrical signals. Bridges differ from routers because bridges use physical addresses, while routers use IP addresses.
Bridge Protocol Data Unit
The data messages that are exchanged across the switches within an extended LAN that uses a spanning tree protocol (STP) topology. BPDU packets contain information on ports, addresses, priorities and costs and ensure that the data ends up where it was intended to go. BPDU messages are exchanged across bridges to detect loops in a network topology. The loops are then removed by shutting down selected bridges interfaces and placing redundant switch ports in a backup, or blocked, state.
broadcast
The process of sending packets from a source to multiple destinations. All the ports of the nodes in the network can receive packets.
Broadcast
A means of delivering information to all members in a network. The broadcast range is determined by the broadcast address.
BSC
Base Station Controller
BSS
Base Station Subsystem
Build-in WDM
A function which integrates some simple WDM systems into products that belong to the OSN series. That is, the OSN products can add or drop several wavelengths directly.
Building Integrated Timing Supply
In the situation of multiple synchronous nodes or communication devices, one can use a device to set up a clock system on the hinge of telecom network to connect the synchronous network as a whole, and provide satisfactory synchronous base signals to the building integrated device. This device is called BITS.
BWS
Backbone WDM System
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A.4 C cabling
The method by which a group of insulated conductors is mechanically assembled or twisted together.
cable trough
The trough which is used for cable routing in the cabinet.
captive nut
See Floating nut
CAR
See committed access rate
CAS
Channel Associated Signaling
CBR
See Constant Bit Rate
CBS
Committed Burst Size
CCDP
Co-Channel Dual Polarization
CCM
Continuity Check Message
CDR
Clock and Data Recovery
CDVT
See Cell Delay Variation Tolerance
Cell Delay Variation Tolerance
This parameter measures the tolerance level a network interface has to aggressive sending (back-to-back or very closely spaced cells) by a connected device, and does not apply to end-systems.
Centralized alarm system
The system that gathers all the information about alarms into a certain terminal console.
CES
See circuit emulation service
CFM
Connectivity Fault Management
Chain network
One type of network that all network nodes are connected one after one to be in series.
channel
A telecommunication path of a specific capacity and/or at a specific speed between two or more locations in a network. Channels can be established through wire, radio (microwave), fiber or a combination of the three. The amount of information transmitted per second in a channel is the information transmission speed, expressed in bits per second. For example, b/s, kb/s, Mb/s, Gb/s, and Tb/s.
CIR
Committed Information Rate
Circuit
A combination of two transmission channels permitting transmission in both directions between two points.
circuit emulation service
A function with which the E1/T1 data can be transmitted through ATM networks. At the transmission end, the interface module packs timeslot data into ATM cells. These ATM cells are sent to the reception end through the ATM network. At the reception end, the interface module re-assigns the data in these ATM cells to E1/T1 timeslots. The CES technology guarantees that the data in E1/T1 timeslots can be recovered to the original sequence at the reception end.
CIST
Common and Internal Spanning Tree
Class of Service
CoS is a rule for queuing. It classifies the packets according to the service type field or the tag in packets, and specifies different priorities for them. All the nodes in DiffServ domain forwards the packets according to their priorities.
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client
A device that sends requests, receives responses, and obtains services from the server.
Clock Synchronization Also called frequency synchronization. The signal frequency traces the reference frequency, but the start point does not need to be consistent. Clock tracing
The method to keep the time on each node being synchronized with a clock source in a network.
CLP
Cell Loss Priority
CM
See Configuration Management
committed access rate
A traffic control method that uses a set of rate limits to be applied to a router interface. CAR is a configurable method by which incoming and outgoing packets can be classified into Quality of Service (QoS) groups, and by which the input or output transmission rate can be defined.
Concatenation
A process that combines multiple virtual containers. The combined capacities can be used a single capacity. The concatenation also keeps the integrity of bit sequence.
Configuration Data
A command file defining hardware configurations of an NE. With this file, an NE can collaborate with other NEs in an entire network. Configuration data is the key factor for normal running of an entire network.
Configuration Management
A network management function defined by the International Standards Organization (ISO). It involves installing, reinitializing & modifying hardware & software.
Configure
To set the basic parameters of an operation object.
congestion
An extra intra-network or inter-network traffic resulting in decreasing network service efficiency.
Connection point
A reference point where the output of a trail termination source or a connection is bound to the input of another connection, or where the output of a connection is bound to the input of a trail termination sink or another connection. The connection point is characterized by the information which passes across it. A bidirectional connection point is formed by the association of a contradirectional pair.
Constant Bit Rate
A kind of service categories defined by the ATM forum. CBR transfers cells based on the constant bandwidth. It is applicable to service connections that depend on precise clocking to ensure undistorted transmission.
Convergence
A process in which multiple channels of low-rate signals are multiplexed into one or several channels of required signals. It refers to the speed and capability for a group of networking devices to run a specific routing protocol. It functions to keep the network topology consistent.
Convergence service
A service that provides enhancements to an underlying service in order to meet the specific requirements of users.
corrugated tube
Used to protect optical fibers.
CoS
See Class of Service
CPU
Central Processing Unit
CRC
See Cyclic Redundancy Check
current alarm
An alarm not handled or not acknowledged after being handled.
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Current Performance Data
Performance data stored currently in a register. An NE provides two types of registers, namely, 15-minute register and 24-hour register, to store performance parameters of a performance monitoring entity. The two types of registers stores performance data only in the specified monitoring period.
Cyclic Redundancy Check
A procedure used in checking for errors in data transmission. CRC error checking uses a complex calculation to generate a number based on the data transmitted. The sending device performs the calculation before transmission and includes it in the packet that it sends to the receiving device. The receiving device repeats the same calculation after transmission. If both devices obtain the same result, it is assumed that the transmission was error free. The procedure is known as a redundancy check because each transmission includes not only data but extra (redundant) error-checking values.
A.5 D Data Communication Network
A communication network used in a TMN or between TMNs to support the data communication function.
Digital Data Network
A high-quality data transport tunnel that combines the digital channel (such as fiber channel, digital microwave channel, or satellite channel) and the cross multiplex technology.
DC
Direct Current
DCC
Data Communication Channel
DCD
Data Carrier Detect
DCE
Data Circuit-terminal Equipment
DCN
See Data Communication Network
DDF
See Digital Distribution Frame
DDN
See Digital Data Network
Defect
A limited interruption in the ability of an item to perform a required function.
Delay Measurement
The time elapsed since the start of transmission of the first bit of the frame by a source node until the reception of the last bit of the loopbacked frame by the same source node, when the loopback is performed at the frame's destination node.
Demultiplexing
A process applied to a composite signal formed by multiplexing, for recovering the original independent signals, or groups of these signals.
Device set
A collection of multiple managed devices. By dividing managed devices into different device sets, users can manage the devices by using the U2000 in an easier way. If an operation authority over one device set is assigned to a user (user group), the authority over all the devices in the device set is assigned to the user (user group), thus making it unnecessary to set the operation authority over all the devices in a device set separately. It is recommended to configure device set by geographical region, network level, device type, or another criterion.
Differentiated Services A marker in the header of each IP packet that prompts network routers to apply differentiated grades of service to various packet streams. It is specified by the DiffServ Code Point policy proposed by the IETF (Internet Engineering Task Force). This allows Internet and other IP-based network service providers to offer different levels of service to customers.
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DiffServ
A service architecture that provides the end-to-end QoS function. It consists of a series of functional units implemented at the network nodes, including a small group of perhop forwarding behaviors, packet classification functions, and traffic conditioning functions such as metering, marking, shaping and policing.
Digital Distribution Frame
A type of equipment used between the transmission equipment and the exchange with transmission rate of 2 to 155 Mbit/s to provide the functions such as cables connection, cable patching, and test of loops that transmitting digital signals.
digital signal
A signal in which information is represented by a limited number of discrete states number of discrete states (for example, high and low voltages) rather than by fluctuating levels in a continuous stream, as in an analog signal. In the pulse code modulation (PCM) technology, the 8 kHz sampling frequency is used and a byte contains 8 bits in length. Therefore, a digital signal is also referred to as a byte-based code stream. Digital signals, with simple structures and broad bandwidth, are easy to shape or regenerate, and are not easily affected by external interference.
Distributed Link Aggregation Group
A board-level port protection technology used to detect unidirectional fiber cuts and to negotiate with the opposite end. Once a link down failure occurs on a port or a hardware failure occurs on a board, the services can automatically be switched to the slave board, achieving 1+1 protection for the inter-board ports.
DLAG
See Distributed Link Aggregation Group
DM
See Delay Measurement
DNI
See Dual Node Interconnection
domain
A logical subscriber group based on which the subscriber rights are controlled.
DSCP
See Differentiated Services Code Point
DSL
Digital Subscriber Line
DSLAM
Digital Subscriber Line Access Multiplexer
DSR
Data Set Ready
DTE
Data Terminal Equipments
DTR
Data Terminal Ready
Dual Node Interconnection
DNI provides an alternative physical interconnection point, between the rings, in case of an interconnection failure scenario.
DVB-ASI
Digital Video Broadcast- Asynchronous Serial Interface
DVMRP
Distance Vector Multicast Routing Protocol
DWDM
Dense Wavelength Division Multiplexing
A.6 E E-AGGR
See Ethernet aggregation
Ear bracket
A piece of angle plate with holes in it on a rack. It is used to fix network elements or components.
ECC
See Embedded Control Channel
EFM
Ethernet in the First Mile
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A Glossary and Acronyms
A type of Ethernet service that is based on a multipoint-to-multipoint EVC (Ethernet virtual connection).
ElectroStatic Discharge The sudden and momentary electric current that flows between two objects at different electrical potentials caused by direct contact or induced by an electrostatic field. E-Line
A type of Ethernet service that is based on a point-to-point EVC (Ethernet virtual connection).
Embedded Control Channel
A logical channel that uses a data communications channel (DCC) as its physical layer, to enable transmission of operation, administration, and maintenance (OAM) information between NEs.
EMS
Element Management System
encapsulation
A technology for layered protocols, in which a lower-level protocol accepts a message from a higher-level protocol and places it in the data portion of the lower-level frame. Protocol A's packets have complete header information, and are carried by protocol B as data. Packets that encapsulate protocol A have a B header, an A header, followed by the information that protocol A is carrying. Note that A could equal to B, as in IP inside IP.
Enterprise System Connection
A path protocol which connects the host with various control units in a storage system. It is a serial bit stream transmission protocol. The transmission rate is 200 Mbit/s.
Entity
A part, device, subsystem, functional unit, equipment, or system that can be considered individually.
EoD
See Ethernet over Dual Domains
EPL
See Ethernet Private Line
EPLAN
See Ethernet virtual private LAN service
Equipment Serial Number
A string of characters that identify a piece of equipment and ensures correct allocation of a license file to the specified equipment. It is also called "equipment fingerprint".
ESCON
See Enterprise System Connection
ESD
See ElectroStatic Discharge
ESD jack
Electrostatic discharge jack. A hole in the cabinet or shelf, which connect the shelf or cabinet to the insertion of ESD wrist strap.
ESN
See Equipment Serial Number
Ethernet
A LAN technology that uses Carrier Sense Multiple Access/Collision Detection. The speed of an Ethernet interface can be 10 Mbit/s, 100 Mbit/s, 1000 Mbit/s or 10000 Mbit/ s. An Ethernet network features high reliability and is easy to maintain.
Ethernet aggregation
A type of Ethernet service that is based on a multipoint-to-point EVC (Ethernet virtual connection).
Ethernet Alarm Group The Ethernet alarm group periodically obtain the statistics value to compare with the configured threshold. If the value exceeds the threshold, an event is reported. Ethernet over Dual Domains
A type of boards. EoD boards bridge the PSN and TDM networks, enabling Ethernet service transmission across PSN and TDM networks.
Ethernet Private LAN service
A type of Ethernet service provided by SDH, PDH, ATM, or MPLS networks. This service is carried over a dedicated bridge and point-to-multipoint connections.
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Ethernet Private Line
A type of Ethernet service that is provided with dedicated bandwidth and point-to-point connections on an SDH, PDH, ATM, or MPLS server layer network.
Ethernet virtual private LAN service
A type of Ethernet service provided by SDH, PDH, ATM, or MPLS networks. This service is carried over a shared bridge and point-to-multipoint connections.
Ethernet virtual private line
A type of Ethernet service provided by SDH, PDH, ATM, or MPLS networks. This service is carried over a shared bridge and point-to-point connections.
ETSI
European Telecommunications Standards Institute
EVPL
See Ethernet virtual private line
EVPLAN
See Ethernet virtual private LAN service
Exercise Switching
An operation to check whether the protection switching protocol functions properly. The protection switching is not really performed.
Exerciser - Ring
This command exercises ring protection switching of the requested channel without completing the actual bridge and switch. The command is issued and the responses are checked, but no working traffic is affected.
Extended ID
The number of the subnet that an NE belongs to, for identifying different network segments in a WAN. The physical ID of an NE is comprised of the NE ID and extended ID.
extra traffic
The traffic that is carried over the protection channels when that capacity is not used for the protection of working traffic. Extra traffic is not protected.
A.7 F Failure
If the fault persists long enough to consider the ability of an item with a required function to be terminated. The item may be considered as having failed; a fault has now been detected.
Fairness
A feature in which for any link specified in a ring network, the source node is provided with certain bandwidth capacities if the data packets transmitted by the source node are constrained by the fairness algorithm.
fairness algorithm
An algorithm designed to ensure the fair sharing of bandwidth among stations in the case of congestion or overloading.
fault
A failure to implement the function while the specified operations are performed. A fault does not involve the failure caused by preventive maintenance, insufficiency of external resources or intentional settings.
FC
See Fiber Channel
FD
See frequency diversity
FDDI
See fiber distributed data interface
FDI
Forward Defect Indicator
FE
Fast Ethernet
feature code
Code used to select/activate a service feature (for example, forwarding, using two or three digit codes preceded by * or 11 or #, and which may precede subsequent digit selection).
FEC
See forwarding equivalence class
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FEC
See Forward Error Correction
fiber patch cord
A kind of fiber used for connections between the subrack and the ODF, and for connections between subracks or inside a subrack.
Fiber Channel
A high-speed transport technology used to build storage area networks (SANs). Fiber channel can be on the networks carrying ATM and IP traffic. It is primarily used for transporting SCSI traffic from servers to disk arrays. Fiber channel supports single-mode and multi-mode fiber connections. Fiber channel signaling can run on both twisted pair copper wires and coaxial cables. Fiber channel provides both connection-oriented and connectionless services.
Fiber Connect
A new generation connection protocol which connects the host to various control units. It carries single byte command protocol through the physical path of fiber channel, and provides higher rate and better performance than ESCON.
Fiber Connector
A device installed at the end of a fiber, optical source or receive unit. It is used to couple the optical wave to the fiber when connected to another device of the same type. A connector can either connect two fiber ends or connect a fiber end and a optical source (or a detector).
fiber distributed data interface
A standard developed by the American National Standards Institute (ANSI) for highspeed fiber-optic local area networks (LANs). FDDI provides specifications for transmission rates of 100 megabits (100 million bits) per second on networks based on the token ring network.
fiber/cable
General name of optical fiber and cable. It refers to the physical entities that connect the transmission equipment, carry transmission objects (user information and network management information) and perform the transmission function in the transmission network. The optical fiber transmits optical signal, while the cable transmits electrical signal. The fiber/cable between NEs represents the optical fiber connection or cable connection between NEs. The fiber/cable between SDH NEs represents the connection relationship between NEs. At this time, the fiber/cable is of optical fiber type.
FICON
See Fiber Connect
FIFO
First In First Out
Floating nut
Floating nuts (or as they are more correctly named, 'tee nuts') have a range of uses but are more commonly used in the hobby for engine fixing (securing engine mounts to the firewall), wing fixings, and undercarriage fixing.
Flow
An aggregation of packets that have the same characteristics. On the network management system or NE software, flow is a group of classification rules. On boards, it is a group of packets that have the same quality of service (QoS) operation.
FLR
See Frame loss ratio
Forced switch
For normal traffic signals, switches normal traffic signal to the protection section, unless an equal or higher priority switch command is in effect or SF condition exists on the protection section, by issuing a forced switch request for that traffic signal.
Forward Error Correction
A bit error correction technology that adds the correction information to the payload at the transmit end. Based on the correction information, the bit errors generated during transmission are corrected at the receive end.
forwarding equivalence A class-based forwarding technology that classifies the packets with the same forwarding class mode. Packets with the same FEC are processed similarly on an MPLS network. The division of FECs is flexible, and can be a combination of the source address, destination address, source port, destination port, protocol type, and VPN. Issue 02 (2011-06-30)
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FPGA
Field Programmable Gate Array
frame
A frame, starting with a header, is a string of bytes with a specified length. Frame length is represented by the sampling circle or the total number of bytes sampled during a circle. A header comprises one or a number of bytes with pre-specified values. In other words, a header is a code segment that reflects the distribution (diagram) of the elements prespecified by the sending and receiving parties.
Frame loss ratio
A ratio, is expressed as a percentage, of the number of service frames not delivered divided by the total number of service frames during time interval T, where the number of service frames not delivered is the difference between the number of service frames arriving at the ingress ETH flow point and the number of service frames delivered at the egress ETH flow point in a point-to-point ETH connection.
Free-run mode
An operating condition of a clock, the output signal of which is strongly influenced by the oscillating element and not controlled by servo phase-locking techniques. In this mode the clock has never had a network reference input, or the clock has lost external reference and has no access to stored data, that could be acquired from a previously connected external reference. Free-run begins when the clock output no longer reflects the influence of a connected external reference, or transition from it. Free-run terminates when the clock output has achieved lock to an external reference.
frequency diversity
A diversity scheme in which two or more microwave frequencies with a certain frequency interval are used to transmit/receive the same signal and selection is then performed between the two signals to ease the impact of fading.
FTP
File Transfer Protocol
full-duplex
A full-duplex, or sometimes double-duplex system, allows communication in both directions, and, unlike half-duplex, allows this to happen simultaneously. Land-line telephone networks are full-duplex, since they allow both callers to speak and be heard at the same time. A good analogy for a full-duplex system would be a two-lane road with one lane for each direction.
A.8 G Gain
The difference between the optical power from the input optical interface of the optical amplifier and the optical power from the output optical interface of the jumper fiber, which expressed in dB.
Gateway IP
When an NE accesses a remote network management system or NE, a router can be used to enable the TCP/IP communication. In this case, the IP address of the router is the gateway IP. Only the gateway NE requires the IP address. The IP address itself cannot identify the uniqueness of an NE. The same IP addresses may exist in different TCP/IP networks. An NE may have multiple IP addresses, for example, one IP address of the network and one IP address of the Ethernet port.
Gateway Network Element
A network element that is used for communication between the NE application layer and the NM application layer.
GE
Gigabit Ethernet
Generic Framing Procedure
A framing and encapsulation method which can be applied to any data type. It has been standardized by ITU-T SG15.
GFP
See Generic Framing Procedure
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GNE
See Gateway Network Element
GPS
Global Positioning System
GSM
Global System for Mobile Communications
GTS
Generic Traffic Shaping
GUI
Graphic User Interface
A Glossary and Acronyms
A.9 H half-duplex
A transmitting mode in which a half-duplex system provides for communication in both directions, but only one direction at a time (not simultaneously). Typically, once a party begins receiving a signal, it must wait for the transmitter to stop transmitting, before replying.
Hardware loopback
A connection mode in which a fiber jumper is used to connect the input optical interface to the output optical interface of a board to achieve signal loopback.
HDLC
High level Data Link Control
HD-SDI
See High Definition-Serial Digital Interface signal
HEC
Header Error Control
Hierarchical Quality of A type of QoS that controls the traffic of users and performs the scheduling according Service to the priority of user services. HQoS has an advanced traffic statistics function, and the administrator can monitor the usage of bandwidth of each service. Hence, the bandwidth can be allocated reasonably through traffic analysis. High Definition-Serial High definition video signal transported by serial digital interface. Digital Interface signal History alarm
The confirmed alarm that has been saved in the memory and other external memories.
Historical performance The performance data that is stored in the history register or that is automatically reported data and stored on the NMS. HP
Higher Order Path
HPT
Higher Order Path Termination
HQoS
See Hierarchical Quality of Service
A.10 I IC
Integrated Circuit
IDU
Indoor Unit
IEEE
Institute of Electrical and Electronics Engineers
IETF
Internet Engineering Task Force
IF
Intermediate Frequency
IGMP
See Internet Group Management Protocol
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IGMP Snooping
A multicast constraint mechanism running on a layer 2 device. This protocol manages and controls the multicast group by listening to and analyzing Internet Group Management Protocol (IGMP) packets between hosts and Layer 3 devices. In this manner, the spread of the multicast data on layer 2 network can be prevented efficiently.
IMA
See Inverse Multiplexing over ATM
IMA frame
A control unit in the IMA protocol. It is a logical frame defined as M consecutive cells, numbered 0 to M-l, transmitted on each of the N links in an IMA group.
Input jitter tolerance
The maximum amplitude of sinusoidal jitter at a given jitter frequency, which, when modulating the signal at an equipment input port, results in no more than two errored seconds cumulative, where these errored seconds are integrated over successive 30second measurement intervals.
Intelligent power adjusting
A mechanism used to reduce the optical power of all the amplifiers in an adjacent regeneration section in the upstream to a safety level if the system detects the loss of optical signals on the link. If the fiber is broken, the device performance degrades, or the connector is not plugged well, the loss of optical signals may occur. With IPA, maintenance engineers will not be hurt by the laser sent out from the slice of broken fiber.
Interface board area
The area for the interface boards on the subrack.
Internal cable
The cables and optical fibers which are used for interconnecting electrical interfaces and optical interfaces within the cabinet.
Internet Group Management Protocol
One of the TCP/IP protocols for managing the membership of Internet Protocol multicast groups. It is used by IP hosts and adjacent multicast routers to establish and maintain multicast group memberships.
Inverse Multiplexing over ATM
A technique that involves inverse multiplexing and de-multiplexing of ATM cells in a cyclical fashion among links grouped to form a higher bandwidth logical link whose rate is approximately the sum of the link rates.
IP
Internet Protocol
IP address
A 32-bit (4-byte) binary digit that uniquely identifies a host (computer) connected to the Internet for communication with other hosts in the Internet by transferring packets. An IP address is expressed in dotted decimal notation, consisting of decimal values of its 4 bytes, separated by periods (,), for example, 127.0.0.1. The first three bytes of an IP address identify the network to which the host is connected, and the last byte identifies the host itself.
IP over DCC
A technology that enables a DCC channel to carry TCP/IP protocol packets. The IP over DCC technology provides the TCP/IP protocol without using any extra overheads or service resources to ensure interconnection of management channels.
IPA
See Intelligent power adjusting
IS-IS
Intermedia System-Intermedia System
ISDN
Integrated Services Digital Network
ISO
International Standard Organization
ISP
Internet Service Provider
IST
Internal Spanning Tree
ITU-T
International Telecommunication Union Telecommunication Standardization
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A.11 J Jitter
Short waveform variations caused by vibration, voltage fluctuations, and control system instability.
jitter tolerance
Jitter tolerance is defined as the peak-to-peak amplitude of sinusoidal jitter applied on the input ATM-PON signal that causes a 1 dB optical power penalty at the optical equipment.
A.12 L Label
A short identifier that is of fixed length and local significance. It is used to uniquely identify the FEC to which a packet belongs. It does not contain topology information. It is carried in the header of a packet and does not contain topology information.
LACP
See Link Aggregation Control Protocol
LAG
See link aggregation group
LAN
Local Area Network
LAPS
Link Access Procedure-SDH
Laser
A component that generates directional optical waves of narrow wavelengths. The laser light has better coherence than ordinary light. The fiber system takes the semi-conductor laser as the light source.
Layer
A concept used to allow the transport network functionality to be described hierarchically as successive levels; each layer being solely concerned with the generation and transfer of its characteristic information.
layer 2 switch
A data forwarding method. In a LAN, a network bridge or 802.3 Ethernet switch transmits and distributes packet data based on the MAC address. Since the MAC address is at the second layer of the OSI model, this data forwarding method is called Layer 2 switch.
LB
See Loopback
LBM
Loopback Message
LBR
Loopback Reply
LC
Lucent Connector
LCAS
See Link Capacity Adjustment Scheme
LCD
Liquid Crystal Display
LCT
Local Craft Terminal
License
A permission that the vendor provides for the user with a specific function, capacity, and duration of a product. A license can be a file or a serial number. Usually the license consists of encrypted codes. The operation authority granted varies with the level of the license.
Link
In the topology view, a link is used to identify the physical or logical connection between two topological nodes. A link is used to connect signaling points (SPs) and signaling transfer points (STPs) and transmit signaling messages.
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Link Aggregation Control Protocol
A method of bundling a group of physical interfaces together as a logical interface to increase bandwidth and reliability. For related protocols and standards, refer to IEEE 802.3ad.
link aggregation group An aggregation that allows one or more links to be aggregated together to form a link aggregation group so that a MAC client can treat the link aggregation group as if it were a single link. Link Capacity Adjustment Scheme
LCAS in the virtual concatenation source and sink adaptation functions provides a control mechanism to hitless increase or decrease the capacity of a link to meet the bandwidth needs of the application. It also provides a means of removing member links that have experienced failure. The LCAS assumes that in cases of capacity initiation, increases or decreases, the construction or destruction of the end-to-end path is the responsibility of the network and element management systems.
LLC
Logical Link Control
LM
See Loss Measurement
Locked switching
When the switching condition is satisfied, this function disables the service from being switched from the working channel to the protection channel. When the service has been switched, the function enables the service to be restored from the protection channel to the working channel.
LOF
Loss of Frame
LOM
Loss of Multiframe
Loopback
A troubleshooting technique that returns a transmitted signal to its source so that the signal or message can be analyzed for errors. The loopback can be a inloop or outloop.
LOS
Loss of Signal
Loss Measurement
Loss measurement, a method used to collect counter values applicable for ingress and egress service frames where the counters maintain a count of transmitted and received data frames between a pair of MEPs.
Lower Threshold
A lower performance limit which when exceeded by a performance event counter will trigger a threshold-crossing event.
LP
Lower Order Path
LPT
Link State Pass Through
LSP
Label Switched Path
LSR
Label Switching Router
LT
Link Trace
A.13 M MA
See Maintenance Association
MAC
Medium Access Control
Maintenance Association
TThat portion of a Service Instance, preferably all of it or as much as possible, the connectivity of which is maintained by CFM. It is also a full mesh of Maintenance Entities.
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Maintenance Domain
The network or the part of the network for which connectivity is managed by connectivity fault management (CFM). The devices in a maintenance domain are managed by a single Internet service provider (ISP).
MAN
See Metropolitan Area Network
Manual switch
Switches normal traffic signal to the protection section, unless a failure condition exists on other sections (including the protection section) or an equal or higher priority switch command is in effect, by issuing a manual switch request for that normal traffic signal.
Mapping
A procedure by which tributaries are adapted into virtual containers at the boundary of an SDH network.
Marking-off template
A quadrate cardboard with four holes. It is used to mark the positions of the installation holes for the cabinet.
MBS
Maximum Burst Size
MCF
Message Communication Function
MCR
Minimum Cell Rate
MD
See Maintenance Domain
Mean launched power
The average power of a pseudo-random data sequence coupled into the fiber by the transmitter.
MEP
Maintenance End Point
Metropolitan Area Network
A network that interconnects users with computer resources in a geographic area or region larger than that covered by even a large LAN but smaller than the area covered by an WAN. The term is applied to the interconnection of networks in a city into a single larger network (which may then also offer efficient connection to a wide area network). It is also used to mean the interconnection of several local area networks by bridging them with backbone lines. The latter usage is also sometimes referred to as a campus network.
MIB
Management Information Base
MIP
Maintenance Intermediate Point
MODEM
MOdulator-DEModulator
MP
Maintenance Point
MPID
Maintenance Point Identification
MPLS
See Multiprotocol Label Switching
MS
Multiplex Section
MSA
Multiplex Section Adaptation
MSOH
See Multiplex Section Overhead
MSP
See Multiplex Section Protection
MST
Multiplex Section Termination
MSTI
Multiple Spanning Tree Instance
MSTP
See Multi-service transmission platform
MSTP
See Multiple Spanning Tree Protocol
MTIE
Maximum Time Interval Error
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MTU
Maximum Transmission Unit
Multiprotocol Label Switching
A technology that uses short tags of fixed length to encapsulate packets in different link layers, and provides connection-oriented switching for the network layer on the basis of IP routing and control protocols. It improves the cost performance and expandability of networks, and is beneficial to routing.
Multi-service transmission platform
A platform based on the SDH platform, capable of accessing, processing and transmitting TDM services, ATM services, and Ethernet services, and providing unified management of these services.
Multicast
A process of transmitting data packets from one source to many destinations. The destination address of the multicast packet uses Class D address, that is, the IP address ranges from 224.0.0.0 to 239.255.255.255. Each multicast address represents a multicast group rather than a host.
Multiple Spanning Tree Protocol
A protocol that can be used in a loop network. Using an algorithm, the MSTP blocks redundant paths so that the loop network can be trimmed as a tree network. In this case, the proliferation and endless cycling of packets is avoided in the loop network. The protocol that introduces the mapping between VLANs and multiple spanning trees. This solves the problem that data cannot be normally forwarded in a VLAN because in STP/ RSTP, only one spanning tree corresponds to all the VLANs.
Multiplex Section Overhead
The overhead that comprises rows 5 to 9 of the SOH of the STM-N signal. See SOH definition.
Multiplex Section Protection
A function, which is performed to provide capability for switching a signal between and including two multiplex section termination (MST) functions, from a "working" to a "protection" channel.
Multiplexing
A procedure by which multiple lower order path layer signals are adapted into a higher order path or the multiple higher order path layer signals are adapted into a multiplex section.
A.14 N NE
See network element
NE Explorer
The main operation interface, of the network management system, which is used to manage the telecommunication equipment. In the NE Explorer, the user can query, manage and maintain the NE, boards, and ports on a per-NE basis.
network element
An NE contains both the hardware and the software running on it. One NE is at least equipped with one system control and communication(SCC) board which manages and monitors the entire network element. The NE software runs on the SCC board.
network node interface The interface at a network node which is used to interconnect with another network node. network segment
A part of an Ethernet or other network, on which all message traffic is common to all nodes, that is, it is broadcast from one node on the segment and received by all others.
NLP
Normal Link Pulse
NMS
Network Management System
NNI
See network node interface
NPC
Network Parameter Control
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nrt-VBR
Non Real-Time Variable Bit Rate
NRZ
Non Return to Zero code
NSAP
Network Service Access Point
NTP
Network Time Protocol
A Glossary and Acronyms
A.15 O OA
See Optical Amplifier
OADM
See Optical Add/Drop Multiplexer
OAM
Operations, Administration and Maintenance
OAM auto-discovery
In the case of OAM auto-discovery, two interconnected ports, enabled with the Ethernet in the First Mile OAM (EFM OAM) function, negotiate to determine whether the mutual EFM OAM configuration match with each other by sending and responding to the OAM protocol data unit (OAMPDU). If the mutual EFM OAM configuration match, the two ports enter the EFM OAM handshake phase. In the handshake phase, the two ports regularly send the OAMPDU to maintain the neighborhood relation.
OCP
See Optical Channel Protection
ODF
See Optical Distribution Frame
ODU
Outdoor Unit
OFS
Out-of-frame Second
OHA
Overhead Access Function
OLT
Optical Line Terminal
Online Help
The capability of many programs and operating systems to display advice or instructions for using their features when so requested by the user.
ONU
Optical Network Unit
OOF
Out of Frame
Optical Add/Drop Multiplexer
A device that can be used to add the optical signals of various wavelengths to one channel and drop the optical signals of various wavelengths from one channel.
Optical Amplifier
Devices or subsystems in which optical signals can be amplified by means of the stimulated emission taking place in a suitable active medium.
Optical attenuator
A passive device that increases the attenuation in a fiber link. It is used to ensure that the optical power of the signals received at the receive end is not extremely high. It is available in two types: fixed attenuator and variable attenuator.
Optical Channel Protection
In an optical transmission link that contains multiple wavelengths, when a certain wavelength goes faulty, the services at the wavelength can be protected if the optical channel protection is configured.
Optical Connector
A component normally attached to an optical cable or a piece of apparatus to provide frequent optical interconnection/disconnection of optical fibers or cables.
Optical Distribution Frame
A frame which is used to transfer and spool fibers.
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A Glossary and Acronyms
Optical Interface
A component that connects several transmit or receive units.
Optical Time Domain Reflectometer
A device that sends a very short pulse of light down a fiber optic communication system and measures the time history of the pulse reflection to measure the fiber length, the light loss and locate the fiber fault.
orderwire
A channel that provides voice communication between operation engineers or maintenance engineers of different stations.
OSI
Open Systems Interconnection
OSN
Optical Switch Node
OSPF
Open Shortest Path First
OTDR
See Optical Time Domain Reflectometer
OTU
See Optical transponder unit
Optical transponder unit
A device or subsystem that converts the accessed client signals into the G.694.1/G.694.2compliant WDM wavelength.
Output optical power
The ranger of optical energy level of output signals.
Overhead
Extra bits in a digital stream used to carry information besides traffic signals. Orderwire, for example, would be considered overhead information.
A.16 P Paired slots
Two slots of which the overheads can be passed through by using the bus on the backplane.
pass-through
The action of transmitting the same information that is being received for any given direction of transmission.
Path
A performance resource object defined in the network management system. The left end of a path is a device node whose port needs to be specified and the right end of a path is a certain IP address which can be configured by the user. By defining a path in the network management system, a user can test the performance of a network path between a device port and an IP address. The tested performance may be the path delay, packet loss ratio or other aspects.
PBS
Peak Burst Size
PC
Personal Computer
PCM
Pulse Code Modulation
PCR
Peak Cell Rate
PDH
See Plesiochronous Digital Hierarchy
PDU
See Power distribution unit
PE
See provider edge
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Performance register
A Glossary and Acronyms
The memory space for performance event counts, including 15-min current performance register, 24-hour current performance register, 15-min historical performance register, 24-hour historical performance register, UAT register and CSES register. The object of performance event monitoring is the board functional module, so every board functional module has a performance register. A performance register is used to count the performance events taking place within a period of operation time, so as to evaluate the quality of operation from the angle of statistics.
performance threshold A limit for generating an alarm for a selected entity. When the measurement result reaches or exceeds the preset alarm threshold, the performance management system generates a performance alarm. Permanent Virtual Connection
A connection between two ATM end hosts. The connection consists of PVPs between the ATM end hosts and their respective switches, and SVPs between the switches.
PGND
Protection Ground
PGND cable
A cable which connects the equipment and the protection grounding bar. Usually, one half of the cable is yellow, whereas the other half is green.
PIM-SM
Protocol Independent Multicast-Sparse Mode
PIR
Peak Information Rate
plesiochronous
Qualifying two time-varying phenomena, time-scales, or signals in which corresponding significant instants occur at the same rate, any variations in rate being constrained within specified limits. Note: Corresponding significant instants are separated by time intervals having durations which may vary without limit.
Plesiochronous Digital A multiplexing scheme of bit stuffing and byte interleaving. It multiplexes the minimum Hierarchy rate 64 kit/s into the 2 Mbit/s, 34 Mbit/s, 140 Mbit/s, and 565 Mbit/s rates. PLL
Phase-Locked Loop
Pointer
An indicator whose value defines the frame offset of a virtual container with respect to the frame reference of the transport entity on which this pointer is supported.
POS
Packet Over SDH
Power box
A direct current power distribution box at the upper part of a cabinet, which supplies power for the subracks in the cabinet.
Power distribution unit A unit that performs AC or DC power distribution. PPP
Point-to-Point Protocol
PRBS
See Pseudo Random Binary Sequence
PRC
Primary Reference Clock
Primitive
In the hierarchy of signaling system No.7, when the upper layer applies for services from the lower layer or the lower layer transmits services to the upper layer, the data is exchanged between the user and the service provider. The data transmitted between adjacent layers is called primitive.
Private Line
A line, such as a subscriber cable and trunk cable, which are leased by the telecommunication carrier and are used to meet the special user requirements.
Protection path
A specific path that is part of a protection group and is labeled protection.
Protection service
A specific service that is part of a protection group and is labeled protection.
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A Glossary and Acronyms
Protection subnet
In the NMS, the protection subnet becomes a concept of network level other than multiplex section rings or path protection rings. The protection sub-network involves NEs and fiber cable connections.
Protection View
The user interface, of the NMS, which is used to manage protection in the network.
provider edge
A device that is located in the backbone network of the MPLS VPN structure. A PE is responsible for managing VPN users, establishing LSPs between PEs, and exchanging routing information between sites of the same VPN. A PE performs the mapping and forwarding of packets between the private network and the public channel. A PE can be a UPE, an SPE, or an NPE.
PS
Packet Switched
PSD
Power Spectral Density
Pseudo Random Binary A sequence that is random in a sense that the value of an element is independent of the Sequence values of any of the other elements, similar to real random sequences. Pseudo Wire
An emulated connection between two PEs for transmitting frames. The PW is established and maintained by PEs through signaling protocols. The status information of a PW is maintained by the two end PEs of a PW.
Pseudo Sire Emulation An end-to-end Layer 2 transmission technology. It emulates the essential attributes of a edge-to-edge telecommunication service such as ATM, FR or Ethernet in a packet switched network (PSN). PWE3 also emulates the essential attributes of low speed time division multiplexing (TDM) circuit and SONET/SDH. The simulation approximates to the real situation. PVC
See Permanent Virtual Connection
PW
See Pseudo Wire
PWE3
See Pseudo Sire Emulation edge-to-edge
A.17 Q QinQ
A layer 2 tunnel protocol based on IEEE 802.1Q encapsulation. It add a public VLAN tag to a frame with a private VLAN tag to allow the frame with double VLAN tags to be transmitted over the service provider’s backbone network based on the public VLAN tag. This provides a layer 2 VPN tunnel for customers and enables transparent transmission of packets over private VLANs.
QoS
See Quality of Service
Quality of Service
A commonly-used performance indicator of a telecommunication system or channel. Depending on the specific system and service, it may relate to jitter, delay, packet loss ratio, bit error ratio, and signal-to-noise ratio. It functions to measure the quality of the transmission system and the effectiveness of the services, as well as the capability of a service provider to meet the demands of users.
A.18 R Rapid Spanning Tree Protocol
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A Glossary and Acronyms
RDI
Remote Defect Indication
Receiver Sensitivity
The minimum acceptable value of average received power at point R to achieve a 1 x 10-12 BER (The FEC is open).
Reference clock
A kind of stable and high-precision autonous clock providing frequencies for other clocks for reference.
REG
A piece of equipment or device that regenerates electrical signals.
Regeneration
The process of receiving and reconstructing a digital signal so that the amplitudes, waveforms and timing of its signal elements are constrained within specified limits.
Regenerator section overhead
The regenerator section overhead comprises rows 1 to 3 of the SOH of the STM-N signal.
Remote optical pumping amplifier
A remote optical amplifier subsystem designed for applications where power supply and monitoring systems are unavailable. The ROPA subsystem is a power compensation solution to the ultra-long distance long hop (LHP) transmission.
Resilient Packet Ring
A network topology being developed as a new standard for fiber optic rings.
RF
Radio Frequency
RFA
Request For Announcement
RFI
Request for Information
ring network
A type of network topology in which each node connects to exactly two other nodes, forming a circular pathway for signals.
RNC
Radio Network Controller
ROPA
See Remote optical pumping amplifier
route
The path that network traffic takes from its source to its destination. In a TCP/IP network, each IP packet is routed independently. Routes can change dynamically.
router
A device on the network layer that selects routes in the network. The router selects the optimal route according to the destination address of the received packet through a network and forwards the packet to the next router. The last router is responsible for sending the packet to the destination host. Can be used to connect a LAN to a LAN, a WAN to a WAN, or a LAN to the Internet.
RP
Rendezvous Point
RPR
See Resilient Packet Ring
RS232
A asynchronous transfer mode that does not involve hand-shaking signal. It can communicate with RS232 and RS422 of other stations in point-to-point mode and the transmission is transparent. Its highest speed is 19.2kbit/s.
RS422
The specification that defines the electrical characteristics of balanced voltage digital interface circuits. The interface can change to RS232 via the hardware jumper and others are the same as RS232.
RSTP
See Rapid Spanning Tree Protocol
RTN
Radio Transmission Node
RX
Receiver
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A Glossary and Acronyms
A.19 S S1 byte
A byte to transmit network synchronization status information. On an SDH network, each NE traces hop by hop to the same clock reference source through a specific clock synchronization path, realizing synchronization on the entire network. If a clock reference source traced by an NE is missing, this NE will trace another clock reference source of a lower level. To implement protection switching of clocks in the whole network, the NE must learn about clock quality information of the clock reference source it traces. Therefore, ITU-T defines S1 byte to transmit network synchronization status information. It uses the lower four bits of the multiplex section overhead S1 byte to indicate 16 types of synchronization quality grades. Auto protection switching of clocks in a synchronous network can be implemented using S1 byte and a proper switching protocol.
SAN
Storage Area Network
SC
Square Connector
SCR
Sustainable Cell Rate
SD
See space diversity
SD
See Signal Degrade
SD
See Standard definition
SDH
See Synchronous Digital Hierarchy
SDP
Serious Disturbance Period
SD-SDI
See Standard definition-Serial Digital Interface signal
SEC
SDH Equipment Clock
Section
The portion of a SONET transmission facility, including terminating points, between (i) a terminal network element and a regenerator or (ii) two regenerators. A terminating point is the point after signal regeneration at which performance monitoring is (or may be) done.
Self-healing
A function of establishing a replacement connection by network without the network management connection function. When a connection failure occurs, the replacement connection is found by the network elements and rerouted depending on network resources available at that time.
Serial port extended ECC
The ECC channel realized by means of serial port.
server
A network device that provides services to network users by managing shared resources, often used in the context of a client-server architecture for a LAN.
Service protection
A measure that ensures that the services can be received at the receive end.
SES
Severely Errored Second
SETS
Synchronous Equipment Timing Source
settings
Parameters of a system or operation that can be selected by the user.
SF
See Signal Fail
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A Glossary and Acronyms
Signal Fail
A signal indicating that associated data has failed in the sense that a near-end defect condition (non-degrade defect) is active.
SFP
See Small Form-Factor Pluggable
SHDSL
Single-line High speed Digital Subscriber Line
Side Mode Suppression The Side Mode Suppression Ratio (SMSR) is the ratio of the largest peak of the total Ratio source spectrum to the second largest peak. signal cable
Common signal cables cover the E1 cable, network cable, and other non-subscriber signal cable.
Signal Degrade
SD is a signal indicating the associated data has degraded in the sense that a degraded defect (e.g., dDEG) condition is active.
Signal Fail
SF is a signal indicating the associated data has failed in the sense that a near-end defect condition (not being the degraded defect) is active.
Simple Network Management Protocol
A network management protocol of TCP/IP. It enables remote users to view and modify the management information of a network element. This protocol ensures the transmission of management information between any two points. The polling mechanism is adopted to provide basic function sets. According to SNMP, agents, which can be hardware as well as software, can monitor the activities of various devices on the network and report these activities to the network console workstation. Control information about each device is maintained by a management information block.
slide rail
Angle-bars on which shelves and chassis may slide and be supported within a cabinet or shelf.
Small Form-Factor Pluggable
A specification for a new generation of optical modular transceivers.
SMSR
See Side Mode Suppression Ratio
SNC
SubNetwork Connection
SNCMP
See Subnetwork connection multipath protection
SNCP
See SubNetwork Connection Protection
SNCP node
Set the SNC node on the protection sub-network to support sub-network connection protection that spans protection sub-networks. The SNCP node of the ring sub-network can support electric circuit dually feed and selectively receive a timeslot out of the ring, thus implementing sub-network connection protection. The SNCP node is generally set on the node on the line board with the path protection type of the dual fed and selectively received.
SNCTP
See Subnetwork Connection Tunnel Protection
SNMP
See Simple Network Management Protocol
SNR
Signal Noise Ratio
space diversity
A diversity scheme that enables two or more antennas separated by a specific distance to transmit/receive the same signal and selection is then performed between the two signals to ease the impact of fading. Currently, only receive SD is used.
Spanning Tree Protocol STP is a protocol that is used in the LAN to remove the loop. STP applies to the redundant network to block some undesirable redundant paths through certain algorithms and prune a loop network into a loop-free tree network. SPI Issue 02 (2011-06-30)
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A Glossary and Acronyms
SSM
See Synchronization Status Message
SSU
Synchronization Supply Unit
Standard definition
Standard definition defines a video format with the resolution below 720P.
Standard definitionStandard definition video signal transported by serial digital interface. Serial Digital Interface signal Statistical multiplexing A multiplexing technique whereby information from multiple logical channels can be transmitted across a single physical channel. It dynamically allocates bandwidth only to active input channels, to make better use of available bandwidth and allow more devices to be connected than with other multiplexing techniques. STM-4
SDH standard for transmission over optical fiber at 622.08 Mbit/s.
STP
See Spanning Tree Protocol
Sub-network number
A number used to differentiate network sections in a sub-network conference. A subnetwork ID consists of the first several digits (one or two) of a user phone number. An order wire phone number consists of the sub-network ID and the user number.
subnet
A type of smaller networks that form a larger network according to a rule, for example, according to different districts. This facilitates the management of the large network.
subnet mask
The technique used by the IP protocol to determine which network segment packets are destined for. The subnet mask is a binary pattern that is stored in the client machine, server or router matches with the IP address.
Subnetwork connection The only difference is that SNCP is of 1+1 protection and SNCMP is of N+1 protection. multipath protection That is, several backup channels protect one active channel in SNCMP. SubNetwork A function, which allows a working subnetwork connection to be replaced by a protection Connection Protection subnetwork connection if the working subnetwork connection fails, or if its performance falls below a required level. Subnetwork Connection Tunnel Protection
SNCTP provides a VC-4 level channel protection. When the working channel is faulty, the services of the entire VC-4 path can be switched over to the protection channel.
Support
A part used to support and fix a cabinet on the antistatic floor. It is made of welded steel plates and is used to block up the cabinets to facilitate floor layout and cabling. Before the whole set of equipment is grounded, insulation plates must be installed under the supports, and insulating coverings must be added to the expansion bolts to achieve good insulation performance.
Suppression state
An attribute set to determine whether an NE monitors the alarm. Under suppression status, NE will not monitor the corresponding alarm conditions and the alarm will not occur even when the alarm conditions are met.
SVC
Switching Virtual Connection
Switching priority
A priority of a board that is defined for protection switching. When several protected boards need to be switched, a switching priority should be set for each board. If the switching priorities of the boards are the same, services on the board that fails later cannot be switched. Services on the board with higher priority can preempt the switching resources of that with lower priority.
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Switching restoration time
A Glossary and Acronyms
It refers to the period of time between the start of detecting and the moment when the line is switched back to the original status after protection switching occurs in the MSP sub-network.
Synchronization Status A message that carries quality levels of timing signals on a synchronous timing link. Message Nodes on an SDH network and a synchronization network acquire upstream clock information through this message. Then the nodes can perform proper operations on their clocks, such as tracing, switching, or converting to holdoff, and forward the synchronization information to downstream nodes. Synchronous Digital Hierarchy
A transmission scheme that follows ITU-T G.707, G.708, and G.709. It defines the transmission features of digital signals such as frame structure, multiplexing mode, transmission rate level, and interface code. SDH is an important part of ISDN and BISDN. It interleaves the bytes of low-speed signals to multiplex the signals to high-speed counterparts, and the line coding of scrambling is used only for signals. SDH is suitable for the fiber communication system with high speed and a large capacity since it uses synchronous multiplexing and flexible mapping structure.
Synchronous source
A clock providing timing services to connected network elements. This would include clocks conforming to Recommendations G.811, G.812 and G.813.
A.20 T Tandem Connection Monitor
In the SDH transport hierarchy, the TCM is located between the AU/TU management layer and HP/LP layer. It uses the N1/N2 byte of POH overhead to monitor the quality of the transport channels on a transmission section (TCM section).
TCM
See Tandem Connection Monitor
TCP/IP
See Transmission Control Protocol/Internet Protocol
TDM
Time Division Multiplexing
TIM
Trace Identifier Mismatch
Timeslot
Continuously repeating interval of time or a time period in which two devices are able to interconnect.
Time Synchronization
Also called the moment synchronization, time synchronization means that the synchronization of the absolute time, which requires that the starting time of the signals keeps consistent with the UTC time.
TM
Terminal Multiplexer
TMN
Telecommunications Management Network
ToS
See Type of Service
TPS
See Tributary Protection Switch
Trail management function
A network level management function of the network management system. This function enables you to configure end-to-end services, view graphic interface and visual routes of a trail, query detailed information of a trail, filter, search and locate a trail quickly, manage and maintain trails in a centralized manner, manage alarms and performance data by trail, and print a trail report.
Transceiver
A transmitter and receiver housed together in a single unit and having some circuits in common, often for portable or mobile use.
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A Glossary and Acronyms
Transmission Control Protocol/Internet Protocol
Common name for the suite of protocols developed to support the construction of worldwide internetworks.
transparent transmission
A process during which the signaling protocol or data is not processed in the content but encapsulated in the format for the processing of the next phase.
Tray
A component that can be installed in the cabinet for holding chassis or other devices.
Tributary loopback
A fault can be located for each service path by performing loopback to each path of the tributary board. There are three kinds of loopback modes: no loopback, outloop, and inloop.
Tributary Protection Switch
A function that uses a standby tributary processing board to protect N tributary processing boards.
Tributary unit
An information structure which provides adaptation between the lower order path layer and the higher order path layer. It consists of an information payload (the lower order VC) and a TU pointer which indicates the offset of the payload frame start relative to the higher order VC frame start.
Tributary Unit Group
One or more Tributary Units, occupying fixed, defined positions in a higher order VCn payload is termed a Tributary Unit Group (TUG). TUGs are defined in such a way that mixed capacity payloads made up of different size Tributary Units can be constructed to increase flexibility of the transport network.
TTL
Time To Live
TU
Tributary Unit
TUG
See Tributary Unit Group
Tunnel
A channel on the packet switching network that transmits service traffic between PEs. In VPN, a tunnel is an information transmission channel between two entities. The tunnel ensures secure and transparent transmission of VPN information. In most cases, a tunnel is an MPLS tunnel.
Type of Service
A field in an IP packet (IP datagram) used for quality of service (QoS). The TOS field has 8 bits in length, which is divided into five subfields.
A.21 U UART
Universal Asynchronous Receiver/Transmitter
UAS
Unavailable Second
UBR
Unspecified Bit Rate
underfloor cabling
The cables connected cabinets and other devices are routed underfloor.
UNI
See User-to-Network Interface
Unprotected
Pertaining to the transmission of the services that are not protected. The services cannot be switched to the protection channel if the working channel is faulty or the service is interrupted, because protection mechanism is not configured.
Unprotected subnetwork
A sub-network without any protection mechanism. The purpose of such configuration is to provide the basic data of trail protection for subsequent trail management.
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A Glossary and Acronyms
Upload
An operation to report some or all configuration data of an NE to the NMS. The configuration data then covers the configuration data stored at the NMS side.
UPM
Uninterruptible Power Module
Upper threshold
TThe critical value that can induce unexpected events if exceeded.
UPS
Uninterruptible Power Supply
Upward cabling
Cables or fibers connect the cabinet with other equipment from the top of the cabinet.
User
Any entity external to the network which utilizes connections through the network for communication. A person or other entity authorized by a subscriber to use some or all of the services subscribed to by that subscriber.
User-to-Network Interface
The interface between user equipment and private or public network equipment (for example, ATM switches).
UTC
Universal Time Coordinated
A.22 V VB
Virtual Bridge
VBR
Variable Bit Rate
VC
Virtual Concatenation
VC
See Virtual Container
VCG
Virtual Concatenation Group
VCI
Virtual Channel Identifier
Virtual Container
The information structure used to support path layer connections in the SDH. It consists of information payload and path overhead (POH) information fields organized in a block frame structure which repeats every 125 or 500 μs.
Virtual local area network
A logical grouping of two or more nodes which are not necessarily on the same physical network segment but which share the same IP network number. This is often associated with switched Ethernet.
Virtual Private Network
A system configuration, where the subscriber is able to build a private network via connections to different network switches that may include private network capabilities.
VLAN
See Virtual local area network
VP
Virtual Path
VPI
Virtual Path Identifier
VPN
See Virtual Private Network
A.23 W Wait to Restore
The number of minutes to wait before services are switched back to the working line.
WAN
Wide Area Network
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Wander
The long-term variations of the significant instants of a digital signal from their ideal position in time (where long-term implies that these variations are of frequency less than 10 Hz).
washer
A washer is a thin flat ring of metal or rubber which is placed over a bolt before the nut is screwed on.
Wavelength Division Multiplexing
A technology that utilizes the characteristics of broad bandwidth and low attenuation of single mode optical fiber, uses multiple wavelengths as carriers, and allows multiple channels to transmit simultaneously in a single fiber.
Wavelength protection Data for describing the wavelength protection structure. Its function is similar to that of group the protection subnet for SDH NEs. The wavelength path protection can work only with the correct configuration of the wavelength protection group. WDM
See Wavelength Division Multiplexing
WFQ
Weighted Fair Queuing
Winding pipe
A tool for fiber routing, which acts as the corrugated pipe.
Working path
A path allocated to transport the normal traffic.
WRED
Weighted Random Early Detection
WTR
See Wait to Restore
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