eRAN
AAS Feature Parameter Description Issue
03
Date
2015-08-31
HUAWEI TECHNOLOGIES CO., LTD.
Copyright © Huawei Technologies Co., Ltd. 2015. 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.
Trademarks and Permissions and other Huawei trademarks are trademarks of Huawei Technologies Co., Ltd. All other trademarks trademarks and trade names mentioned mentioned in this this document are are the property of of their respective holders.
Notice The purchased products, services and features are stipulated by the contract made between Huawei and the customer. customer. All or part of the products, services and features described in this document may not be within the purchase scope or the usage scope. Unless otherwise specified in the contract, all statements, information, information, and recommendations in this document are provided "AS IS" without warranties, guarantees or representations representations of any kind, either express or implied. The information in this document is subject to change without notice. Every effort has been made in the preparation of this document to ensure accuracy of the contents, but all statements, information, and recommendations recommendations in this document do not constitute a warranty of any kind, express or implied.
Huawei Technologies Co., Ltd. Address:
Huawei Industrial Industrial Base Bantian, Longgang Shenzhen 518129 People's Republic of China
Website:
http://www.huawei.com
Email:
[email protected]
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i
Copyright © Huawei Technologies Co., Ltd. 2015. 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.
Trademarks and Permissions and other Huawei trademarks are trademarks of Huawei Technologies Co., Ltd. All other trademarks trademarks and trade names mentioned mentioned in this this document are are the property of of their respective holders.
Notice The purchased products, services and features are stipulated by the contract made between Huawei and the customer. customer. All or part of the products, services and features described in this document may not be within the purchase scope or the usage scope. Unless otherwise specified in the contract, all statements, information, information, and recommendations in this document are provided "AS IS" without warranties, guarantees or representations representations of any kind, either express or implied. The information in this document is subject to change without notice. Every effort has been made in the preparation of this document to ensure accuracy of the contents, but all statements, information, and recommendations recommendations in this document do not constitute a warranty of any kind, express or implied.
Huawei Technologies Co., Ltd. Address:
Huawei Industrial Industrial Base Bantian, Longgang Shenzhen 518129 People's Republic of China
Website:
http://www.huawei.com
Email:
[email protected]
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eRAN AAS Feature Parameter Description
Contents
Contents 1 About This This Document........... Document................................. ............................................ ............................................. ............................................. .................................... .............. 1 1.1 Scope........................................................................................................... Scope....... ....................................................................................................................................................................... ................................................................... 1 1.2 Intended Audience..........................................................................................................................................................1 1.3 Change History................................................................................................... H istory............................................................................................................................................................... ............................................................ 2
2 Overview........... Overview................................. ............................................ ............................................ ............................................. ............................................. ..................................... ............... 5 2.1 Introduction................................................................................ Introduction.................................................................................................................................................................... .................................................................................... 5 2.2 Benefits........................................................................................................................................................................... Benefits........................................................................................................................................................................... 5 2.3 Architecture.................................................................................................. Architecture.................................................................................................................................................................... .................................................................. 5 2.3.1 AAS Hardware........................................................................................ Ha rdware............................................................................................................................................................ .................................................................... 5 2.3.2 RET..............................................................................................................................................................................7 RET..............................................................................................................................................................................7 2.3.3 AAS Configuration......................................................................................................................................................9 2.4 AAS Features................................................................................................................................................................11 Feat ures................................................................................................................................................................11
3 AAS Virtual Virtual Four Uplink Channels for LTE.............. LTE.................................... ............................................ ......................................12 ................12 4 AAS User User Specific Tilting for LTE......................................................... LTE............................................................................... ..................................14 ............14 5 AAS Vertical Vertical Multiple Sectors for LTE........................................................ LTE.............................................................................. ........................... .....15 15 6 AAS Dividual Dividual Tilts by Carrier for LTE.......................................................... LTE................................................................................ ......................... ... 17 7 AAS RAT RAT Specific Tilting (LTE)....................................................... (LTE)............................................................................. ....................................... ................. 19 8 Related Features........ Features.............................. ............................................ ............................................. ............................................. ............................................ .......................... ....20 20 9 Network Impact........... Impact.................................. ............................................. ............................................ ............................................ ............................................ ........................ 21 9.1 AAS Virtual Four Uplink Channels for LTE.......................................................................................................... TE................................................................................................................ ...... 21 9.1.1 System Capacity............................................................................................................................ Capacity........................................................................................................................................................ ............................ 21 9.1.2 Network Performance................................................................................................................................................ Performance................................................................................................................................................21 21 9.1.3 NEs............................................................................................ NEs............................................................................................................................................................................ ................................................................................ 21 9.1.4 Hardwar e................................................................................................................................................................... e................................................................................................................................................................... 21 9.1.5 Inter-NE Interfaces......................................................................................... Interfaces.................................................................................................................................................... ........................................................... 21 9.1.6 Operation Operatio n and Maintenance.......................................................................................................................................22 9.2 AAS User Specific Tilting for LTE.............................................................................................................................. LTE.............................................................................................................................. 23 9.2.1 System Capacity............................................................................................................................ Capacity........................................................................................................................................................ ............................ 23 9.2.2 Network Performance................................................................................................................................................23 9.2.3 NEs............................................................................................................. NEs............................................................................................................................................................................ ............................................................... 23 Issue 03 (2015-08-31)
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9.2.4 Hardware................................................................................................................................................................... 23 9.2.5 Inter-NE Interfaces.................................................................................................................................................... 23 9.2.6 Operation and Maintenance.......................................................................................................................................24 9.3 AAS Vertical Multiple Sectors for LTE........................................................................................................................24 9.3.1 System Capacity........................................................................................................................................................ 24 9.3.2 Network Performance................................................................................................................................................24 9.3.3 NEs............................................................................................................................................................................ 25 9.3.4 Hardwar e................................................................................................................................................................... 25 9.3.5 Inter-NE Interfaces.................................................................................................................................................... 25 9.3.6 Operation and Maintenance.......................................................................................................................................25 9.4 AAS Dividual Tilts by Carrier for LTE........................................................................................................................ 25 9.4.1 System Capacity........................................................................................................................................................ 25 9.4.2 Network Performance................................................................................................................................................25 9.4.3 NEs............................................................................................................................................................................ 26 9.4.4 Hardwar e................................................................................................................................................................... 26 9.4.5 Inter-NE Interfaces.................................................................................................................................................... 26 9.4.6 Operation and Maintenance.......................................................................................................................................26 9.5 AAS RAT Specific Tilting (LTE)................................................................................................................................. 26 9.5.1 System Capacity........................................................................................................................................................ 26 9.5.2 Network Performance................................................................................................................................................27 9.5.3 NEs............................................................................................................................................................................ 27 9.5.4 Hardwar e................................................................................................................................................................... 27 9.5.5 Inter-NE Interfaces.................................................................................................................................................... 27 9.5.6 Operation and Maintenance.......................................................................................................................................27
10 Engineering Guidelines........................................................................................................... 28 10.1 Deployment of Passive Antennas............................................................................................................................... 29 10.1.1 Requir ements........................................................................................................................................................... 29 10.1.2 Data Preparation...................................................................................................................................................... 29 10.1.3 Precautions...............................................................................................................................................................31 10.1.4 Hardware Adjustment..............................................................................................................................................31 10.1.5 Initial Configuration................................................................................................................................................ 31 10.1.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs................................................31 10.1.5.2 Using the CME to Perform Batch Configuration for Existing NodeBs............................................................... 33 10.1.5.3 Using the CME to Perform Single Configuration................................................................................................ 33 10.1.5.4 Using MML Commands.......................................................................................................................................33 10.1.5.5 MML Command Examples.................................................................................................................................. 34 10.1.6 Activation Observation............................................................................................................................................34 10.2 Deployment of Active Antennas................................................................................................................................ 34 10.2.1 Requir ements........................................................................................................................................................... 35 10.2.2 Data Preparation...................................................................................................................................................... 35 10.2.3 Precautions...............................................................................................................................................................36 10.2.4 Hardware Adjustment..............................................................................................................................................36 Issue 03 (2015-08-31)
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10.2.5 Initial Configuration................................................................................................................................................ 36 10.2.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs................................................36 10.2.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs............................................................. 37 10.2.5.3 Using the CME to Perform Single Configuration................................................................................................ 38 10.2.5.4 Using MML Commands.......................................................................................................................................38 10.2.5.5 MML Command Examples.................................................................................................................................. 38 10.2.6 Activation Observation............................................................................................................................................39 10.3 Deployment of AAS Virtual Four Uplink Channels for LTE.....................................................................................39 10.3.1 Application Suggestions.......................................................................................................................................... 40 10.3.2 Requir ed Information.............................................................................................................................................. 40 10.3.3 Planning................................................................................................................................................................... 40 10.3.4 Deployment............................................................................................................................................................. 40 10.3.4.1 Requirements........................................................................................................................................................ 40 10.3.4.2 Data Preparation................................................................................................................................................... 40 10.3.4.3 Precautions............................................................................................................................................................40 10.3.4.4 Hardware Adjustment...........................................................................................................................................41 10.3.4.5 Initial Configuration............................................................................................................................................. 41 10.3.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs.............................................41 10.3.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs.......................................................... 43 10.3.4.5.3 Using the CME to Perform Single Configuration............................................................................................. 43 10.3.4.5.4 Using MML Commands....................................................................................................................................43 10.3.4.5.5 MML Command Examples............................................................................................................................... 44 10.3.4.6 Activation Observation.........................................................................................................................................45 10.3.5 Perfor mance Monitoring..........................................................................................................................................46 10.3.6 Parameter Optimization........................................................................................................................................... 47 10.3.7 Troubleshooting.......................................................................................................................................................47 10.4 Deployment of AAS User Specific Tilting for LTE................................................................................................... 47 10.4.1 Application Suggestions.......................................................................................................................................... 47 10.4.2 Requir ed Information.............................................................................................................................................. 48 10.4.3 Planning................................................................................................................................................................... 48 10.4.4 Deployment............................................................................................................................................................. 49 10.4.4.1 Requirements........................................................................................................................................................ 49 10.4.4.2 Data Preparation................................................................................................................................................... 49 10.4.4.3 Precautions............................................................................................................................................................49 10.4.4.4 Hardware Adjustment...........................................................................................................................................49 10.4.4.5 Initial Configuration............................................................................................................................................. 49 10.4.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs.............................................49 10.4.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs.......................................................... 50 10.4.4.5.3 Using the CME to Perform Single Configuration............................................................................................. 50 10.4.4.5.4 Using MML Commands....................................................................................................................................50 10.4.4.5.5 MML Command Examples............................................................................................................................... 51 10.4.4.6 Activation Observation.........................................................................................................................................52
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10.4.5 Performance Monitoring..........................................................................................................................................52 10.4.6 Parameter Optimization........................................................................................................................................... 53 10.4.7 Troubleshooting....................................................................................................................................................... 54 10.5 Deployment of AAS Vertical Multiple Sectors for LTE.............................................................................................54 10.5.1 Application Suggestions.......................................................................................................................................... 54 10.5.2 Requir ed Information.............................................................................................................................................. 54 10.5.3 Planning................................................................................................................................................................... 54 10.5.4 Deployment............................................................................................................................................................. 56 10.5.4.1 Requirements........................................................................................................................................................ 56 10.5.4.2 Data Preparation................................................................................................................................................... 56 10.5.4.3 Precautions............................................................................................................................................................56 10.5.4.4 Hardware Adjustment...........................................................................................................................................56 10.5.4.5 Initial Configuration............................................................................................................................................. 56 10.5.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs.............................................56 10.5.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs.......................................................... 57 10.5.4.5.3 Using the CME to Perform Single Configuration............................................................................................. 57 10.5.4.5.4 Using MML Commands....................................................................................................................................57 10.5.4.5.5 MML Command Examples............................................................................................................................... 58 10.5.4.6 Activation Observation.........................................................................................................................................59 10.5.5 Perfor mance Monitoring..........................................................................................................................................59 10.5.6 Parameter Optimization........................................................................................................................................... 61 10.5.7 Troubleshooting.......................................................................................................................................................61 10.6 Deployment of AAS Dividual Tilts by Carrier for LTE............................................................................................. 61 10.6.1 Application Suggestions.......................................................................................................................................... 61 10.6.2 Requir ed Information.............................................................................................................................................. 62 10.6.3 Planning................................................................................................................................................................... 62 10.6.4 Deployment............................................................................................................................................................. 62 10.6.4.1 Requirements........................................................................................................................................................ 62 10.6.4.2 Data Preparation................................................................................................................................................... 62 10.6.4.3 Precautions............................................................................................................................................................62 10.6.4.4 Hardware Adjustment...........................................................................................................................................62 10.6.4.5 Initial Configuration............................................................................................................................................. 62 10.6.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs.............................................62 10.6.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs.......................................................... 63 10.6.4.5.3 Using the CME to Perform Single Configuration............................................................................................. 63 10.6.4.5.4 Using MML Commands....................................................................................................................................63 10.6.4.5.5 MML Command Examples............................................................................................................................... 64 10.6.4.6 Activation Observation.........................................................................................................................................65 10.6.5 Perfor mance Monitoring..........................................................................................................................................66 10.6.6 Parameter Optimization........................................................................................................................................... 66 10.6.7 Troubleshooting.......................................................................................................................................................66 10.7 Deployment of AAS RAT Specific Tilting (LTE)...................................................................................................... 66
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10.7.1 Application Suggestions.......................................................................................................................................... 67 10.7.2 Required Information.............................................................................................................................................. 67 10.7.3 Planning................................................................................................................................................................... 67 10.7.4 Deployment............................................................................................................................................................. 67 10.7.4.1 Requirements........................................................................................................................................................ 67 10.7.4.2 Data Preparation................................................................................................................................................... 67 10.7.4.3 Precautions............................................................................................................................................................67 10.7.4.4 Hardware Adjustment...........................................................................................................................................68 10.7.4.5 Initial Configuration............................................................................................................................................. 68 10.7.4.6 Activation Observation.........................................................................................................................................68 10.7.5 Performance Monitoring..........................................................................................................................................68 10.7.6 Parameter Optimization........................................................................................................................................... 68 10.7.7 Troubleshooting....................................................................................................................................................... 68
11 Reference Documents............................................................................................................... 70
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1 About This Document
1
About This Document
1.1 Scope This document describes the LTE AAS, including its working principles, related features, network impact, and engineering guidelines. The AAS in this document indicates the AAU3902. This document covers the following features: l
LOFD-261101 AAS Virtual Four Uplink Channels for LTE
l
LOFD-261102 AAS User Specific Tilting for LTE
l
LOFD-261103 AAS Vertical Multiple Sectors for LTE
l
LOFD-261105 AAS Dividual Tilts by Carrier for LTE
l
MRFD-261105 AAS RAT Specific Tilting (LTE)
Any managed objects (MOs), parameters, alarms, or counters described herein correspond to the software release delivered with this document. Any future updates will be described in the product documentation delivered with future software releases. This document applies to the following types of eNodeBs.
eNodeB Type
Model
Macro
3900 series eNodeB
This document applies only to LTE FDD. Any "LTE" in this document refers to LTE FDD, and "eNodeB" refers to LTE FDD eNodeB. "AAU3902" in this document refers to the Huawei product of AAS.
1.2 Intended Audience This document is intended for personnel who: l
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Need to understand the features described herein Huawei Proprietary and Confidential Copyright © Huawei Technologies Co., Ltd.
1
eRAN AAS Feature Parameter Description l
1 About This Document
Work with Huawei products
1.3 Change History This section provides information about the changes in different document versions. There are two types of changes, which are defined as follows: l
Feature change Changes in features of a specific product version.
l
Editorial change Changes in wording or addition of information that was not described in the earlier version.
eRAN8.1 03 (2015-08-31) This issue includes the following changes.
Change Type
Change Description
Parameter Change
Feature change
None
None
Editorial change
Added relationships between the logical channel and logical port. For details, see 2.3.3 AAS Configuration.
None
eRAN8.1 02 (2015-05-08) This issue includes the following changes.
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Change Type
Change Description
Parameter Change
Feature change
None
None
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1 About This Document
Change Type
Change Description
Editorial change
l
l
Added descriptions on configurations when multiple AARUs are configured on the AAS. For details, see 10.1.5 Initial Configuration,10.2.5 Initial Configuration,10.3.4.5 Initial Configuration,10.4.4.5 Initial Configuration,10.5.4.5 Initial Configuration and 10.6.4.5 Initial Configuration.
Parameter Change None
Modified the description on angle difference between α1 and α2 of beams 1 and 2. For details, see 5 AAS Vertical Multiple Sectors for LTE.
eRAN8.1 01 (2015-03-23) This issue includes the following changes.
Change Type
Change Description
Parameter Change
Feature change
Changed the hardware specification description to keep consistency with that in the MIMO Feature Parameter Description. For details, see 10.3.3 Planning,10.4.3 Planning and 10.5.3 Planning.
None
Editorial change
None
None
eRAN8.1 Draft A (2015-01-15) Compared with Issue 04 (2014-11-15) of eRAN7.0, this issue includes the following changes.
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1 About This Document
Change Type
Change Description
Feature change
Modified MML command None. examples and added cell operator configuration commands. For details, see 10.3.4.5.5 MML Command Examples,10.4.4.5.5 MML Command Examples, 10.5.4.5.5 MML Command Examples and 10.6.4.5.5 MML Command Examples.
Editorial change
None.
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Parameter Change
None.
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eRAN AAS Feature Parameter Description
2 Overview
2
Overview
2.1 Introduction The AAS is a new type of radio frequency (RF) module that uses common public radio interface (CPRI) ports to connect to baseband signal processing boards in the same way as the remote radio unit (RRU) and radio frequency unit (RFU). The AAS can incorporate the functions of RF modules and antennas. Each AAS has multiple transmit and receive channels. Beams from an AAS can be adjusted on both vertical and horizontal planes. Beam adjustments help improve radio coverage and increase network capacity.
2.2 Benefits The AAS provides the following benefits: l
Saves antenna space The AAS occupies less antenna space than an RRU and traditional antenna, thereby helping operators free up more antenna space for other devices.
l
Supports the beamforming function The AAS can be used to increase network capacity in heavy traffic areas.
2.3 Architecture 2.3.1 AAS Hardware The AAS has a modular design. Figure 2-1 shows its logical structure.
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Figure 2-1 AAS logical structure
NOTE
The AASs of different models have different structures. For more information, see associated AAS hardware descriptions.
The AAS consists of the following units: l
Active Antenna-Antenna Unit (AAAU): includes active and passive antennas. Passive antennas can work for both the base station to which the AAS is connected and other base stations.
l
Active Antenna-Management Unit (AAMU): controls the AAS. The AAMU connects to the BBU using common public radio interface (CPRI) ports and to the AAS's other units using cables.
l
Active Antenna Passive Unit (AAPU): serves as the RF signal interface of the AAS, used to provide an interface for external RRUs/RFUs and transfer RF signals.
l
Active Antenna-Radio Unit (AARU): serves as the RF subsystem of the AAS, used to implement the transceiver function and provide the phase calibration function.
l
Active Antenna-Cover Unit (AACU): protects the AAAU from rainwater and dust. If no AARUs are configured, one AACU must be configured.
Table 2-1 lists AAU3902 slot configuration.
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Table 2-1 AAU3902 slot configuration
Slot No.
Unit
Supported Frequency Bands
Supported Mode
0
AAMU
N/A
UMTS, LTE FDD, and GL
1
AARU or AACU
AARU: 2.1 GHz
UMTS
2
AAPU
1.8 GHz, 2.1 GHz, and 2.6 GHz (An AAPU supports the three frequency bands.)
N/A
3
AARU or AACU
AARU: 1.8 GHz
LTE FDD and GL
2.3.2 RET The logical objects of the remote electrical tilt (RET) function for passive antennas are RET subunits, and the logical objects of the RET function for active antennas are virtual RET subunits.
RET for Passive Antennas The RET function for passive antennas implements external or internal control, depending on which device the AAS is connected to. The RET function implements external control when the AAAU is connected to RRUs using RF feeders and the ALD control line to control the RET. (Note that these RRUs can belong to either the same base station as the AAS or to a different base station.) External control complies with the Antenna Interface Standards Group (AISG) protocol and requires RET signal processing of the remote control units (RCUs) in the AAAU. The RET function implements internal control when the AAMU connects to the BBU using a CPRI cable. This connection method is used because the AAAU does not have AISG ports. Internal control requires the AAMU to use one CPRI port to forward RET signals to the RCUs for signal processing.
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Figure 2-2 External and internal control
For details about the RET function for passive antennas, see ALD Management Feature Parameter Description.
RET for Active Antennas The RET function for active antennas adjusts the downlink downtilt angles of beams from AASs by modifying the downtilt angle attribute of the related virtual RET subunits. Features related to the RET function for active antennas are described later in this document. The RET function for active antennas requires that the BBU connect to the AAMU, as shown in Figure 2-3. Connection method required by RET for active antennas
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Figure 2-3 Connection method required by RET for active antennas
2.3.3 AAS Configuration The AAS configuration is different from the RRU configuration. Figure 2-4 shows the different configuration objects of an AAS compared to an RRU. Figure 2-4 Configuration objects of AAS and RRU
NOTE
In Figure 2-4, "1:x" indicates the ratio of the number of left configuration objects to the number of right configuration objects. The value of a ranges from 1 to 8. The values of b and c range from 1 to 8.
As shown in Figure 2-4, one AAS has the following configuration objects: Issue 03 (2015-08-31)
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l
AAS: used to set physical attributes of the module, such as the subrack number.
l
AARU: corresponds to the physical AARU and used to set its physical attributes, such as the slot number, working mode, and number of transmit or receive channels in the AARU hardware.
l
VRET: automatically created with the AARU configuration object and used to control the number of virtual RET subunits. VRET is the parent object of VRETSUBUNIT .
l
VRETSUBUNIT : automatically created with the AARU configuration object. VRET has eight configuration objects VRETSUBUNIT by default. Each VRETSUBUNIT corresponds to a virtual RET subunit. Each VRETSUBUNIT can be configured with 1, 2, or 4 connection ports. Connection ports are numbered in an R XY format. The meaning of x and y is as follows:
–
Y indicates the number of a logical channel on the horizontal plane and can be set to A or B. A indicates +45° polarization; B indicates -45° polarization.
– X indicates the number of a logical port on the vertical plane and is an integer ranging from 0 to 7. Each logical channel can have multiple logical ports. Beam haracteristics can be defined for each port separately. Downtilt angles on the vertical plane can be defined for AAU3902. Figure 2-5 shows the diagram of logical channels and logical ports. Figure 2-5 Diagram of logical channels and logical ports
Take AAU3902 as an example. The relationships between the logical channel, logical port, and antenna polarization are as follows.
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Antenna Polarizatio n
Logical Channel
Logical Port
+45°
A
R0A
R1A
R2A
R3A
R4A
R5A
R6A
R7A
-45°
B
R0B
R1B
R2B
R3B
R4B
R5B
R6B
R7B
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NOTE
1. Either logical channel A or B of the AAU3902 can transmit and receive signals simultaneously. 2. The AAU3902 does not support the modification of the TX logical port switch at the channel level by running the MOD TXBRANCH command but supports the modification of the TX logical port switch at the module level. 3. The AAU3902 does not support the modification of the RX logical port switch at both the channel level and the module level by running the MOD RXBRANCH command.
2.4 AAS Features Table 2-2 lists the AAS features and their version information. Table 2-2 AAS features and version information
Feature Name
AAU3902 (1.8Ghz, LTE)
AAS Virtual Four Uplink Channels for LTE
SRAN8.0 and later versions
AAS User Specific Tilting for LTE
SRAN8.0 and later versions
AAS Vertical Multiple Sectors for LTE
SRAN8.0 and later versions
AAS Dividual Tilts by Carrier for LTE
SRAN8.0 and later versions
AAS RAT Specific Tilting (LTE)
SRAN9.0 and later versions
NOTE
The downtilt angle difference between AAS beams is restricted by the maximum capability of the digital tilt (DT). All such differences among features or within any feature comply with this restriction. For more information, see "Technical Specifications of AAUs" in 3900 Series Base Station Technical Description.
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3 AAS Virtual Four Uplink Channels for LTE
3
AAS Virtual Four Uplink Channels for LTE
This chapter describes LOFD-261101 AAS Virtual Four Uplink Channels for LTE. To implement 4-antenna receive diversity, a traditional RRU/RFU uses two dual-polarized antennas, whereas an AAS with this feature uses only one active antenna polarized at +45° and -45°. Specifically, the AAS assigns different weights to received signals, forms two uplink beams on the vertical plane in each polarization direction, and obtains a total of four channels of signals. In this way, the AAS provides receive diversity gain, beamforming gain, and interference mitigation gain. The AAS increases uplink throughput and network performance. PN1 to To support this feature, the AAS requires that the four virtual antenna ports (CONN CONNPN4) of each virtual RET subunit be bound to the same sector. In addition, the AAS requires that the number of receive antennas in this sector ( ANTNUM ) be set to 4 so that the sector has a 4-antenna reception (4R) capability. Under this configuration, the AAS generates a total of four beams, corresponding to four receive ports. Together with LOFD-001005 UL 4Antenna Receive Diversity, the AAS generates four uplink virtual channels for different UEs.
Assume that four antenna ports are named R0A, R0B, R1A, and R1B, where R0A and R1A are configured in one polarization direction and R0B and R1B in the other polarization direction. The generated four uplink channels are shown in Figure 3-1.
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eRAN AAS Feature Parameter Description
3 AAS Virtual Four Uplink Channels for LTE
Figure 3-1 Working principle of AAS Virtual Four Uplink Channels for LTE (side view)
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eRAN AAS Feature Parameter Description
4 AAS User Specific Tilting for LTE
4
AAS User Specific Tilting for LTE
This chapter describes LOFD-261102 AAS User Specific Tilting for LTE. The AAS can use an active antenna to form two transmit beams in each polarization direction for a total of four transmit beams in the two polarization directions. Together with LOFD-001003 DL 4x2 MIMO or LOFD-001060 DL 4x4 MIMO in closed-loop mode, the AAS generates four downlink channels on the vertical plane in a cell. As shown in Figure 4-1, the red beam is a wide beam generated for control channels and the other three beams are narrow beams generated for traffic channels. These narrow beams are formed for different UEs based on the precoding matrix indicators (PMIs) reported by these UEs and the associated codebooks. This feature increases the signal power of UEs close to the AAS and reduces the interference with other cells, thereby increasing system capacity. Figure 4-1 Working principle of AAS User Specific Tilting for LTE(side view)
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5 AAS Vertical Multiple Sectors for LTE
5
AAS Vertical Multiple Sectors for LTE
This chapter describes LOFD-261103 AAS Vertical Multiple Sectors for LTE This feature splits a sector served by AASs into an inner sector and an outer sector. The inner and outer sectors correspond to an inner cell and an outer cell, respectively. These cells use the same frequency but have overlapping areas. This feature is mainly used to expand downlink capacity in hot spots (possibly due to cell resource insufficiency) when no extra frequencies are available. NOTE
To expand uplink capacity (possibly due to heavy uplink load), use the AAS Virtual Four Uplink Channels for LTE feature described in 3 AAS Virtual Four Uplink Channels for LTE.
In hot spots (such as urban areas), base stations are close together and strong interference easily occurs. After the AAS Vertical Multiple Sectors for LTE feature is applied, the outer and inner cells overlap and these two cells cause strong interference for each other in overlapping areas. When using this feature in urban areas, adjust the downtilt angles of beams in these cells to minimize the interference. The area covered by an inner cell is small because of the large downtilt angles of the beams i n the inner cell and interference from the outer cell. The lower the AAS is placed, the smaller the area covered by the inner cell. With this feature, the throughput in inner cells accounts for a large proportion of the throughput of the entire site. This feature is implemented by setting the ULTILT and DLTILT parameters in VRETSUBUNIT MOs. One beam is split into two (beams 1 and 2) on the vertical plane, corresponding to cells 1 and 2 respectively, as shown in Figure 5-1. The two cells have the same frequency. For detail of angle difference between α1 and α2 of beams 1 and 2 on the vertical plane, please refer to the 'AAU3902 Technical Specifications' chapter in the 3900 Series Base Station Technical Description.
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5 AAS Vertical Multiple Sectors for LTE
Figure 5-1 Working principle of AAS Vertical Multiple Sectors for LTE (side view)
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6 AAS Dividual Tilts by Carrier for LTE
6
AAS Dividual Tilts by Carrier for LTE
This chapter describes LOFD-261105 AAS Dividual Tilts by Carrier for LTE, which is also referred to as carrier specific tilting in this document. The AAS Dividual Tilts by Carrier for LTE feature enables multiple carriers operating at different frequencies on the same frequency band to use different downtilt angles. Carriers that use smaller downtilt angles deliver contiguous coverage, and carriers that use larger downtilt angles ensure capacity expansion for hotspots. Figure 6-1 shows the working principle of AAS Dividual Tilts by Carrier for LTE. Figure 6-1 Working principle of AAS Dividual Tilts by Carrier for LTE (side view)
In Figure 6-1, each carrier has an individual beam, which has a unique downtilt angle. These two carriers correspond to cells 1 and 2, respectively. The two cells use different frequencies F1 and F2 on the same frequency band. The downtilt angle of beam 1 is smaller than that of beam 2, which reduces the interference among F2 cells and increases network capacity. Issue 03 (2015-08-31)
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6 AAS Dividual Tilts by Carrier for LTE
With the AAS Dividual Tilts by Carrier for LTE feature, operators who have two or more frequencies can add carriers to cells to expand network capacity. In SRAN8.0 and later, a maximum of eight carriers can be added to a cell. This feature can be used in sector-level network planning or network optimization to obtain optimal downtilt angles for carriers. Operators determine the downtilt angle of the carrier that covers hot spots based on traffic distribution.
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7 AAS RAT Specific Tilting (LTE)
7
AAS RAT Specific Tilting (LTE)
This chapter describes MRFD-261105 AAS RAT Specific Tilting (LTE). In addition to intra-RAT carrier specific tilting, an AAU3902 of SRAN9.0 supports RAT specific tilting. To meet different RAT requirements on coverage and capacity, the AAS generally applies different downtilt angles to these RATs. An AAU3902 of SRAN9.0 can use one AARU to support both GSM and LTE on the 1.8 GHz frequency and performs separate tilting for them. Similar to carrier specific tilting, RAT specific tilting uses the ULTILT and DLTILT parameters in the VRETSUBUNIT MO to control the downtilt angles of two beams on the vertical plane. Beams 1 and 2 correspond to cells 1 and 2 respectively, and the two cells use different RATs and frequencies. Figure 7-1 illustrates RAT specific tilting. Figure 7-1 Working principle of AAS RAT Specific Tilting (LTE) (side view)
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8 Related Features
8
Related Features
Table 8-1 lists the prerequisite features and mutually exclusive features related to AAS. Table 8-1 Prerequisite features and mutually exclusive features AAS Feature
LTE Prerequisite Feature
Mutually Exclusive Feature
AAS Virtual Four Uplink Channels for LTE (Vertical)
l
LOFD-001005 UL 4-Antenna Receive Diversity
l
AAS Vertical Multiple Sectors for LTE
AAS User Specific Tilting for LTE
l
LOFD-001003 DL 4x2 MIMO
l
l
LOFD-001060 DL 4x4 MIMO
AAS Vertical Multiple Sectors for LTE
l
AAS Virtual Four Uplink Channels for LTE (Vertical)
l
AAS User Specific Tilting for LTE
AAS Vertical None Multiple Sectors for LTE
AAS Dividual Tilts by Carrier for LTE
None
None
AAS RAT Specific Tilting (LTE)
None
None
NOTE
Mutually exclusive features cannot be activated in the same sector or cell.
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9 Network Impact
9
Network Impact
9.1 AAS Virtual Four Uplink Channels for LTE 9.1.1 System Capacity This feature increases the uplink cell capacity by 10% to 45% i n densely populated, and common urban areas, and others.
9.1.2 Network Performance The network performance gain can be evaluated as follows: l
In ideal scenarios: If the inter-site distance is short, this feature lowers the transmit power by 3 dB to 6 dB for UEs not far from the AAS and therefore conserves UE battery power. In addition, this feature reduces uplink interference and increases uplink network performance.
l
In non-ideal scenarios: If the inter-site distance is long, this feature provides higher gain for UEs not far from the AAS but lower gain for UEs far from the AAS.
9.1.3 NEs This feature is implemented on the eNodeB.
9.1.4 Hardware This feature requires the baseband processing unit be the BBU3900 or BBU3910. This feature requires that the baseband processing unit support 4R.
9.1.5 Inter-NE Interfaces None.
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9 Network Impact
9.1.6 Operation and Maintenance License Feature ID
Feature Name
License Control Item
NE
Sales Unit
LOFD-261101
AAS Virtual Four Uplink Channels for LTE
AAS Virtual Four Uplink Channels for LTE
eNodeB
per RU
Configuration Management The following MML commands and parameters have been introduced on the eNodeB side to accommodate this feature. Table 9-1 New MML commands
Change Type
MML Command
Description
New
ADD AAS
Used to add an AAS to an RRU chain or ring.
New
ADD AARU
Used to add an AARU.
New
MOD VRET
Used to modify parameter settings for a managed object (MO) VRET.
New
MOD VRETSUBUNIT
Used to modify configurations of a virtual RET subunit.
Table 9-2 New parameters
Change Type
MO
Parameter ID
MML Command
Description
New
VRETS UBUNI T
ULTILT
MOD VRETSUBUNIT
Indicates the uplink downtilt angle of the virtual RET subunit.
New
VRETS DLTILT UBUNI T
MOD VRETSUBUNIT
Indicates the downlink downtilt angle of the virtual RET subunit.
Performance Management None.
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9 Network Impact
Fault Management Table 9-3 lists the alarms with online help information that was updated after this feature was introduced. Table 9-3 New alarms
Change Type
Alarm ID
Alarm Name
Alarm Severity
Applicable Product
New
26560
AAS Board Not In Position
Major
AAU3902
New
26561
AAS Hardware Fault
Major
AAU3902
9.2 AAS User Specific Tilting for LTE 9.2.1 System Capacity This feature provides beamforming gain and inter-cell interference mitigation gain in continuous coverage areas. In addition, this feature reduces downlink interference with neighboring cells and increases downlink throughput. In the full buffer traffic model, this feature increases the average cell throughput by 15 to 30% in continuous coverage areas if all UEs support downlink 4x2 MIMO.
9.2.2 Network Performance This feature provides positive gain in scenarios with high interference but negative gain for CEUs in scenarios with weak coverage. Compared with traditional 2-antenna transmission (2T), this feature decreases the beamforming gain by approximately 3 dB for the wide reference signal (RS) beam and reduces the RS level on the cell edge by approximately 3-5 dB.
9.2.3 NEs This feature is implemented on the eNodeB.
9.2.4 Hardware This feature requires that the baseband processing unit be the BBU3900 or BBU3910. This feature requires that the baseband processing unit support 4T.
9.2.5 Inter-NE Interfaces None.
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9 Network Impact
9.2.6 Operation and Maintenance License Feature ID
Feature Name
License Control Item
NE
Sales Unit
LOFD-261102
AAS User Specific Tilting for LTE
AAS User Specific Tilting for LTE
eNodeB
per RU
Configuration Management For a list of MML commands and parameters that have been introduced on the eNodeB side to accommodate this feature, see Table 9-1 and Table 9-2.
Performance Management None.
Fault Management For a list of alarms with updated online help information, see Table 9-3.
9.3 AAS Vertical Multiple Sectors for LTE 9.3.1 System Capacity This feature increases uplink and downlink system capacity. The capacity gain depends on the site height, coverage, and user distribution. In the downlink, the average throughput increases 20% to 40%. If users are evenly distributed, this feature provides positive gain mainly in inner cells but negative gain in outer cells. If the percentage of users in inner cells is 40% to 80%, this feature provides positive gain in both inner and outer cells but may provide negative gain for CEUs. When there are many small packets on the network, the perceptible throughput may decrease. In the uplink, the average throughput increases by 30% to 60%. This feature provides positive gain mainly in inner cells but slight positive gain or even negative gain i n outer cells. Together with LOFD-001066 Intra-eNodeB UL CoMP, this f eature provides positive gain for CEUs. With interference between beams of inner and outer cells, the signal quality deteriorates and KPIs may also decrease in the overlapping areas between these cells.
9.3.2 Network Performance This feature improves uplink and downlink service-related KPIs. However, this feature has adverse impacts on the call completion rate, service drop rate, and handover-related KPIs. Issue 03 (2015-08-31)
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9 Network Impact
This feature requires the addition of a new intra-frequency cell, which leads to additional interference. In the overlapping areas between these cells, the interference is higher than that in other areas, the SINRs of UEs greatly decrease, and KPIs may also deteriorate.
9.3.3 NEs This feature is implemented on the eNodeB.
9.3.4 Hardware This feature requires that the baseband processing unit be the BBU3900 or BBU3910.
9.3.5 Inter-NE Interfaces None.
9.3.6 Operation and Maintenance License Feature ID
Feature Name
License Control Item
NE
Sales Unit
LOFD-261103
AAS Vertical Multiple Sectors for LTE
AAS Vertical Multiple Sectors for LTE
eNodeB
per RU
Configuration Management For a list of MML commands and parameters that have been introduced on the eNodeB side to accommodate this feature, see Table 9-1 and Table 9-2.
Performance Management None.
Fault Management For a list of alarms with updated online help information, see Table 9-3.
9.4 AAS Dividual Tilts by Carrier for LTE 9.4.1 System Capacity This feature increases downlink capacity by applying appropriate downtilt angles for different carriers.
9.4.2 Network Performance By applying different downtilt angles to different carriers, this feature can optimize the coverage and capacity of different areas and improve service-related KPIs of these areas. For Issue 03 (2015-08-31)
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9 Network Impact
example, this feature uses one carrier for continuous coverage and another carrier for hop-spot traffic absorption. In addition, this feature improves both network KPIs and service-related KPIs by adjusting the coverage areas of different carriers, which cannot be achieved in scenarios where multiple carriers share the same antenna system.
9.4.3 NEs This feature is implemented on the eNodeB.
9.4.4 Hardware None.
9.4.5 Inter-NE Interfaces None.
9.4.6 Operation and Maintenance License Feature ID
Feature Name
License Control Item
NE
Sales Unit
LOFD-261105
AAS Dividual Tilts by Carrier for LTE
AAS Dividual Tilts by Carrier for LTE
eNodeB
per RU
Configuration Management For a list of MML commands and parameters that have been introduced on the eNodeB side to accommodate this feature, see Table 9-1 and Table 9-2.
Performance Management None.
Fault Management For a list of alarms with updated online help information, see Table 9-3.
9.5 AAS RAT Specific Tilting (LTE) 9.5.1 System Capacity This feature optimizes the coverage and capacity of different RATs by separately adjusting the downtilt angles for these RATs. Issue 03 (2015-08-31)
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9 Network Impact
9.5.2 Network Performance As this feature optimizes the coverage of each RAT, it improves KPIs such as the access success rate, service drop rate, and handover success rate.
9.5.3 NEs This feature is implemented on the eNodeB.
9.5.4 Hardware This feature requires that the baseband processing unit be the BBU3900 or BBU3910.
9.5.5 Inter-NE Interfaces None.
9.5.6 Operation and Maintenance License Feature ID
Feature Name
License Control Item
NE
Sales Unit
MRFD-261105
AAS RAT Specific Tilting (LTE)
AAS RAT Specific Tilting (LTE)
eNodeB
per RU
Configuration Management For a list of MML commands and parameters that have been introduced on the eNodeB side to accommodate this feature, see Table 9-1 and Table 9-2.
Performance Management None.
Fault Management For a list of alarms with updated online help information, see Table 9-3.
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10 Engineering Guidelines
10
Engineering Guidelines
About This Chapter This chapter provides engineering guidelines for the AAU3902. For details about engineering guidelines for other AASs (such as the AAS3910), see 3900 Series Base Station Initial Configuration Guide. A downtilt angle is equal to the sum of mechanical downtilt angle and configured downtilt angle: l
A mechanical downtilt angle is fixed and cannot be changed after installation.
l
A configured downtilt angle may be one of the following:
–
Electrical downtilt angle of a passive antenna, which can be set using the TILT parameter.
–
Electrical downtilt angle of an active antenna, which can be set using the DLTILT or ULTILT parameters.
Table 10-1 lists the ranges of mechanical downtilt angles and electrical downtilt angles. Table 10-1 Downtilt angle ranges
Unit Involved
Mechanical Downtilt Angle
Electrical Downtilt Angle of a Passive Antenna
Electrical Downtilt Angle of an Active Antenna
MO
AAS
RETSUBUNIT
VRETSUBUNIT
AAU3902
-3°, -1.5°, 0°, 1.5°, 3°
Low-frequency passive antennas operating in the 790-960 MHz frequency band: [0, 10]
[0, 12]
High-frequency passive antennas operating in the 1710-2690 MHz frequency band: [2, 10]
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If the AARU operating in the 1800 MHz frequency band is used, the maximum difference between beam downtilt angles is 6°.
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10 Engineering Guidelines
10.1 Deployment of Passive Antennas 10.1.1 Requirements Passive antennas are not license-controlled.
10.1.2 Data Preparation Table 10-2 describes the parameters that must be set in an RET MO. Table 10-2 Key parameters in an RET MO
Parameter Name Device No.
Device name
Parameter ID
Setting Notes
Data Source
DEVICENO
All antenna line devices (ALDs) (including RET antennas and the TMA) in a base station must have a unique device number.
Equipment plan
DEVICENAME
This parameter identifies an RET antenna. All RET antennas must have a unique device name. If an entered device name already exists, the system returns an error message. The format of the parameter value is: sector+port+device type_network type.
Engineering design
This parameter is optional. Control port cabinet No.
CTRLCN
Control Plane Subrack No.
CTRLSRN
Control Plane Slot No.
CTRLSN
RET type
RETTYPE
RET subunit number
Polar type
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These parameters specify the numbers of the cabinet, subrack, and slot, respectively, where an AAS is located.
Equipment plan Equipment plan Equipment plan
For passive antennas, set this parameter to MULTI_RET .
Equipment plan
SUBUNITNUM
When the RETTYPE parameter is set Equipment to MULTI_RET, the plan SUBUNITNUM parameter must be set. Set this parameter to the number of the highest number RET subunit to be used.
POLARTYPE
Set this parameter based on the AAS specifications.
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Equipment plan
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10 Engineering Guidelines
Parameter Name
Parameter ID
Antenna scenario
SCENARIO
Vendor code
VENDORCODE
Serial Number SERIALNO
Setting Notes
Data Source
Set this parameter to REGULAR for Equipment passive antennas. plan This parameter is mandatory in cascading scenarios. Set this parameter based on the manufacturer information, for example: l
KA: Kathrein RET antenna
l
AN: Andrew RET antenna
l
HW: Huawei Agisson RET antenna
This parameter is mandatory in cascading scenarios. Set this parameter according to the device serial number of the target antenna.
Equipment plan
Equipment plan
Table 10-3 describes the parameters that must be set in an RETSUBUNIT MO. Table 10-3 Key parameters in an RETSUBUNIT MO
Parameter Name
Parameter ID
Setting Notes
Data Source
Subunit No.
SUBUNITNO
This parameter specifies the RET subunit number, which starts from 1.
Equipment plan
Connect Port 1 Cabinet No.
CONNCN1
Connect Port 1 Subrack No.
CONNSRN1
Set each of these parameters based Equipment on the connection between the plan target AAS and the peer RRU or Equipment RFU. plan
Connect Port 1 Slot No.
CONNSN1
Equipment plan
Connect Port 1 Port No.
CONNPN1
Equipment plan
Connect Port 2 Cabinet No.
CONNCN2
Equipment plan
Connect Port 2 Subrack No.
CONNSRN2
Equipment plan
Connect Port 2 Slot No.
CONNSN2
Equipment plan
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Parameter Name
Parameter ID
Connect Port 2 Port No.
CONNPN2
Tilt
TILT
Setting Notes
Data Source Equipment plan
Set this parameter based on the engineering design.
Engineering design
10.1.3 Precautions None.
10.1.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.1.5 Initial Configuration 10.1.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-4 in a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
l
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The managed objects (MOs) in Table 10-4 are contained in a scenario-specific summary data file. In this situation, set the parameters in the MOs, and then verify and save the file. Some MOs in Table 10-4 are not contained in a scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters.
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Table 10-4 MOs related to passive antennas
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MO
Sheet in the Summary Data File
Parameter Group
Remarks
RRUCH AIN
Userdefined sheet
Chain No., Topo Type, Backup Mode, Access Type, Head Cabinet No., Head Subrack No., Head Slot No., Head Port No., Tail Cabinet No., Tail Subrack No., Tail Slot No., Tail Port No., BreakPoint Position1, BreakPoint Position2, CPRI Line Rate(Gbit/s), Local Slot No., Protocol Type
-
AAS
Userdefined sheet
Cabinet No., Subrack No., AAS Name, AAU Specification
-
AARU
Userdefined sheet
Cabinet No., Subrack No., Slot No., Administrative State, AARU Work Standard, AARU Name, Number of RX channels, Number of TX channels, Intermediate Frequency Offset(100KHz), Logical Switch of TX Channel, Frequency Min Bandwidth, VRET No.
When multiple AARUs are configured in the AAS, information about all AARUs is required.
AAMU
Userdefined sheet
Cabinet No., Subrack No., Slot No., RRU Topo Position, RRU Chain No., AAS Position
-
RET
Userdefined sheet
Device No., RET Type, Polar Type, Antenna Scenario, RET Subunit Number, Device Name, Control Port Cabinet No., Control Port Subrack No., Control Port Slot No., Vendor Code, Serial No.
-
RETSUB UNIT
Userdefined sheet
Device No., Subunit No., Connect Port 1 Cabinet No., Connect Port 1 Subrack No., Connect Port 1 Slot No., Connect Port 1 Port No., Connect Port 2 Cabinet No., Connect Port 2 Subrack No., Connect Port 2 Slot No., Connect Port 2 Port No., Tilt(0.1degree), Tilt Alarm Error Range(0.1degree), Subunit Name
-
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10 Engineering Guidelines
10.1.5.2 Using the CME to Perform Batch Configuration for Existing NodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-4 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End
10.1.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters listed in 10.1.2 Data Preparation for a single eNodeB. For configuration steps, see CME Single Configuration Operation Guide.
10.1.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS to the RRU chain or ring. Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eGBTS to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot No. to 1.
Step 4 Run the SCN ALD command to scan an antenna device connected to RRUs or RFUs. Step 5 Run the ADD RET command with SCENARIO set to REGULAR to add an RET antenna. Step 6 Run the CLB RET command to calibrate the RET antenna to ensure that downtilt angles supported by the RET antenna can be correctly configured and that the actual downtilt angles of the RET antenna match the configured downtilt angles. Issue 03 (2015-08-31)
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Step 7 Run the MOD RETSUBUNIT command and set parameters under an RETSUBUNIT MO. In this step, set CONNPN1 to R0A, CONNCN2 to R0B, and Tilt to to a planned value such as 5.6°. R ETTILT T command to configure the downtilt angle of t he Step 8 (Optional) Run the MOD RETTIL
previously added RET antenna. antenna. In this step, set RETCLASS to to RET(RET) and Tilt to to a planned value such as as 6.0°. ----End
10.1.5.5 MML Command Examples //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HSN=0, HPN=0;
//Adding an AAS to the RRU chain or ring ADD AAS:
CN=0, SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=2, TXNUM=2, VRETNO=60;
//Adding other AARU boards if an AAS is configured with more than one. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//Scanning an antenna device SCN ALD: CTRLCN=0, CTRLSRN=60, CTRLSN=0;
//Adding an RET antenna ADD RET: DEVICENO=0, DEVICENAME="RET", CTRLCN=0, CTRLSRN=60, CTRLSN=0, RETTYPE=MULTI_RET, SUBUNITNUM=1, SCENARIO=REGULAR;
//Calibrating the RET antenna CLB RET: OPMODE=SITE;
//Setting parameters under an RETSUBUNIT MO MOD RETSUBUNIT: DEVICENO=0, SUBUNITNO=1, SUBNAME="RET", CONNCN1=0, CONNSRN1=60, CONNSN1=0, CONNPN1=R0A, CONNCN2=1, CONNSRN2=60, CONNSN2=0, CONNPN2=R0B, TILT=40;
//(Optional) Configuring the downtilt angle of the previously added RET antenna MOD RETTILT: RETCLASS=RET, OPMODE=DEVICENO, DEVICENO=0, TILT=40;
10.1.6 Activation Observation Perform the following operations after passive antennas were deployed: l
Check whether any alarms were falsely generated.
l
Run the DSP RET command to query the dynamic information about an RET or RETSUBUNIT MO.
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10.2.1 Requirements Active antennas are not license-controlled.
10.2.2 Data Preparation Table 10-5 1 0-5 describes the parameters that must be set in a VRET MO. Table 10-5 1 0-5 Key parameters in a VRET MO
Parameter Name Device No.
Parameter ID
Setting Notes
Data Source
DEVICENO
This parameter specifies the number of the virtual antenna device to which a virtual RET subunit belongs. The parameter value must be consistent with the subrack number of the target AAS. The value range is 60 to 255.
User-defined
Table 10-6 1 0-6 describes the parameters that must be set in a VRETSUBUNIT MO. Table 10-6 1 0-6 Key parameters in a VRETSUBUNIT MO
Parameter Name
Parameter ID
Subunit No.
SUBUNITNO
Setting Notes
Data Source
One AAS can be configured with a maximum of eight virtual RET subunits.
User-defined
Value range: 1 to 8 SubunitName SUBNAME
This parameter is user-defined. It contains 0 to 64 characters. All virtual RET subunits must have a unique name.
User-defined
PORTNUM PORTNUM
This parameter specifies the number of connection ports that can be configured for a virtual RET subunit. This parameter can can be set to 0, 1, 2, or 4.
User-defined
Connect Port n Port No.
This parameter specifies a connection port. The n value ranges from 1 to 4. A connection port is in R XY form, form, and each connection port belongs only to one virtual RET subunit.
User-defined
Polar type n
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CONNPNn
POLARTYPE Polarization is a property of a n connection port. This parameter specifies the polarization type of a connection port. The n value ranges from 1 to 4.
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Parameter Name
Parameter ID
Setting Notes
Data Source
ULTILT
Each virtual RET subunit can be configured with only one uplink downtilt angle.
User-defined
Downlink Tilt DLTILT
Each virtual RET subunit can be configured with only one downlink downtilt angle.
User-defined
BeamAzimuth BEAMAZIM UTH
Retain the default value.
User-defined
Beamwidth
Retain the default value.
User-defined
Uplink Tilt
BEAMWIDT H
10.2.3 Precautions None.
10.2.4 Hardware Adjustment For details, see AAU3902 see AAU3902 Installation Guide. Guide.
10.2.5 Initial Configuration 10.2.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-7 a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
The MOs in Table 10-7 are contained in a scenario-specific summary data file. In this situation, set the parameters in the MOs, and then verify and save the file.
l
1 0-7 are not contained in a scenario-specific Some MOs in Table 10-7 scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters.
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Table 10-7 MOs related to active antennas
MO
Sheet in the Summary Data File
Parameter Group
Remarks
VRET
User-defined sheet
Device No., Cabinet No., Subrack No., Slot No., Device Name, Subunit Quantity
-
VRETSUBU NIT
User-defined sheet
Device No., Subunit No., Subunit Name, Cabinet No., Subrack No., Slot No., PORTNUM, Connected Port 1, Polar Type1, Connected Port 2, Polar Type2, Connected Port 3, Polar Type3, Connected Port 4, Polar Type4, Uplink Tilt(0.1degree), Downlink Tilt(0.1degree), BeamAzimuth(0.1degree), BeamWidth(0.1degree)
-
SECTOR
User-defined sheet
Sector ID, Sector Name, Location Name, User Label, Antenna Azimuth(0.1degree), Sector Antenna
-
SECTOREQ M
User-defined sheet
Sector Equipment ID, Sector ID, Sector Equipment Antenna
-
10.2.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-7 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End Issue 03 (2015-08-31)
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10.2.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters listed in 10.2.2 Data Preparation for a single eNodeB. For configuration steps, see CME Single Configuration Operation Guide.
10.2.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS. Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eNodeB to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot No. to 1.
Step 4 (Optional) Run the MOD VRET command to modify parameter settings for a VRET MO. In this step, set the DEVICENAME and SUBUNITQUANTITY parameters to appropriate values. The default value of the SUBUNITQUANTITY parameter is 8. Note that the value of the DEVICENO parameter must be the same as the value of the SRN parameter for the previously added AAS.
Step 5 Run the MOD VRETSUBUNIT command. In this step, set DLTILT to the planned value for a virtual RET subunit and set ULTILT to the same value as DLTILT .
Step 6 Run the ADD SECTOR command to associate the virtual RET subunit with a sector. Step 7 Run the ADD SECTOREQM command to add sector equipment. Step 8 Run the ADD CELL command to add a local cell. Step 9 Run the ADD EUCELLSECTOREQM command to add a relationship between the cell and the sector equipment.
Step 10 Run the MOD PDSCHCFG and MOD CELLDLPCPDSCHPA commands to set the cell power parameters, including the ReferenceSignalPwr , PA, and PB.
Step 11 Run the ACT CELL command to activate the cell. ----End
10.2.5.5 MML Command Examples The following is a 2T2R configuration example: //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HSN=0, HPN=0;
//Adding an AAS ADD AAS: CN=0, SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU Issue 03 (2015-08-31)
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ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=2, TXNUM=2, VRETNO=60;
//Adding other AARU boards if an AAS is configured with more than one AARU. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//(Optional) Modifying parameter settings for a VRET MO MOD VRET: DEVICENO=60, DEVICENAME="VRET", SUBUNITQUANTITY=8;
//Modifying the configurations of a virtual RET subunit MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=1, SUBNAME=" VRETSUBUNIT_01",PORTNUM=2,CONNPN1=R0A, POLARTYPE1= POSITIVE_NEGATIVE_45, CONNPN2=R0B, POLARTYPE2= POSITIVE_NEGATIVE_45, ULTILT=50, DLTILT=50, BEAMAZIMUTH=0, BEAMWIDTH=650;
//Associating a virtual RET subunit with a sector ADD SECTOR: SECTORID=0, SECNAME="sector", LOCATIONNAME="huawei", ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, CREATESECTOREQM=FALSE;
//Adding sector equipment ADD SECTOREQM: SECTOREQMID=0, SECTORID=0, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANTTYPE2=RXTX_MODE;
//Adding a local cell ADD CELL: LocalCellId=0, CellName="0", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1800, UlBandWidth=CELL_BW_N50, DlBandWidth=CELL_BW_N50, CellId=0, PhyCellId=48, FddTddInd=CELL_FDD, RootSequenceIdx=48, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T2R;
//Adding a relationship between the cell and the sector equipment ADD EUCELLSECTOREQM: LocalCellId=0, SectorEqmId=10;
//Setting the cell power parameters MOD PDSCHCFG: LocalCellId=0, ReferenceSignalPwr=152, Pb=1; MOD CELLDLPCPDSCHPA: LocalCellId=0, PdschPaAdjSwitch=OFF, PaPcOff=DB_3_P_A;
//Activating the cell ACT CELL: LocalCellId=0;
10.2.6 Activation Observation Perform the following operations after active antennas were deployed: l
Check whether any alarms were falsely generated.
l
Run the DSP VRETSUBUNIT command to query the status of virtual RET subunits.
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10.3.1 Application Suggestions This feature is recommended if the following conditions are all met: l
There are no problems such as service drop or access failure due to coverage.
l
The uplink interference over thermal (IoT) in the cell is high.
10.3.2 Required Information l
Traffic statistics: used to identify hot spots.
l
Measurement report and drive test data: used to analyze traffic distribution and coverage distribution.
l
Site engineering parameters: used to obtain engineering information such as installation information, downtilt angle configuration, and inter-site distance.
10.3.3 Planning RF Planning The suggestions for RF planning are as follows: l
Set the uplink downtilt angles to the values used in 2T.
l
Obtain multiple-antenna reception information, and determine the link budget and capacity in the uplink.
l
Complete RF planning according to the general network planning procedure.
Network Planning None.
Hardware Planning The hardware planning for this feature is the same as that for LOFD-001005 UL 4-Antenna Receive Diversity, and the LBBPd and UBBPd are required.
10.3.4 Deployment 10.3.4.1 Requirements Purchase the license for LOFD-261101 AAS Virtual Four Uplink Channels for LTE and LOFD-001005 UL 4-Antenna Receive Diversity.
10.3.4.2 Data Preparation For the parameters that must be set in a VRET MO, see Table 10-5. For the parameters that must be set in a VRETSUBUNIT MO, see Table 10-6.
10.3.4.3 Precautions None. Issue 03 (2015-08-31)
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10.3.4.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.3.4.5 Initial Configuration 10.3.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-8 in a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
The MOs in Table 10-8 are contained in a scenario-specific summary data file. In this situation, set the parameters in the MOs, and then verify and save the file.
l
Some MOs in Table 10-8 are not contained in a scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters. Table 10-8 MOs related to AAS Virtual Four Uplink Channels for LTE
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MO
Sheet in the Summary Data File
Parameter Group
Remarks
RRUCHAIN
EQUIPMENT
Chain No., Topo Type, Backup Mode, Access Type, Head Cabinet No., Head Subrack No., Head Slot No., Head Port No., Tail Cabinet No., Tail Subrack No., Tail Slot No., Tail Port No., BreakPoint Position1, BreakPoint Position2, CPRI Line Rate(Gbit/s), Local Slot No., Protocol Type
-
AAS
EQUIPMENT
Cabinet No., Subrack No., AAS Name, AAU Specification
-
AARU
AAS
Cabinet No., Subrack No., Slot No., Administrative State, AARU Work Standard, AARU Name, Number of RX channels, Number of TX channels, Intermediate Frequency Offset(100KHz), Logical Switch of TX Channel, Frequency Min Bandwidth, VRET No.
When multiple AARUs are configure d in the AAS, informati on about all AARUs is required.
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MO
Sheet in the Summary Data File
Parameter Group
Remarks
AAMU
User-defined sheet
Cabinet No., Subrack No., Slot No., RRU Topo Position, RRU Chain No., AAS Position
-
VRET
AARU
Device No., Cabinet No., Subrack No., Slot No., Device Name, Subunit Quantity
-
VRETSUBU NIT
VRET
Device No., Subunit No., Subunit Name, Cabinet No., Subrack No., Slot No., PORTNUM, Connected Port 1, Polar Type1, Connected Port 2, Polar Type2, Connected Port 3, Polar Type3, Connected Port 4, Polar Type4, Uplink Tilt(0.1degree), Downlink Tilt(0.1degree), BeamAzimuth(0.1degree), BeamWidth(0.1degree)
-
SECTOR
CARRIERRES Sector ID, Sector Name, Location OURCE Name, User Label, Antenna Azimuth(0.1degree), Sector Antenna
-
SECTOREQ M
CARRIERRES OURCE
Sector Equipment ID, Sector ID, Sector Equipment Antenna
-
CELL
eNodeBFuncti on
LocalCellID, CellName, CellId, SectorEqmId, CsgInd, UlCyclicPrefix, DlCyclicPrefix, FrequencyBand, Uplink earfcn indicationUlEarfcn, DlEarfcn, DlBandwidth, UlBandwidth, PCI, AdditionalSpectrumEmission, CellActiveState, CellAdminState, CellMidBlkTimer, FddTddInd, SubframeAssignment, SpecialSubframePatterns, CellSpecificOffset, QoffsetFreq, RootSequenceIdx, HighSpeedFlag, PreambleFmt, CellRadius, Customized bandwidth configure indicator, Customized uplink bandwidth(0.1MHz), Customized downlink bandwidth(0.1MHz), EmergencyAreaIdCfgInd, EmergencyAreaId, UePowerMaxCfgInd, UePowerMax, MultiRruCellFlag, MultiRruCellMode/ Cell transmission and reception mode
-
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MO
Sheet in the Summary Data File
Parameter Group
Remarks
CnOperator
eNodeBFuncti on
Operator ID, Operator name, Operator type, Mcc, Mnc
-
CnOperator TA
eNodeBFuncti on
TrackingAreaId, TAC, CnOperatorId
-
CellOp
Cell
LocalCellID, TrackingAreaId
-
EUCELLSE CTOREQM
Cell
LocalCellID, Sector equipment ID, Baseband equipment ID
-
PDSCHCFG
Cell
Local cell ID, Reference signal power
-
10.3.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-7 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End
10.3.4.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters listed in 10.3.4.2 Data Preparation for a single eNodeB. For configuration steps, see CME Single Configuration Operation Guide.
10.3.4.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS to the RRU chain or ring. Issue 03 (2015-08-31)
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Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eNodeB to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot No. to 1.
Step 4 (Optional) Run the MOD VRET command to modify parameter settings for a VRET MO. In this step, set the DEVICENAME and SUBUNITQUANTITY parameters to appropriate values. The default value of the SUBUNITQUANTITY parameter is 8. Note that the value of the DEVICENO parameter must be the same as the value of the VRETNO parameter for the AARU.
Step 5 Run the MOD VRETSUBUNIT command to configure virtual RET subunit 1. In this step: l l
Set the PORTNUM parameter to 4. Set all of the POLARTYPE1, POLARTYPE2, POLARTYPE3, and POLARTYPE4 parameters to POSITIVE_NEGATIVE_45(POSITIVE_NEGATIVE_45) .
Step 6 Run the ADD SECTOR command to add sector 0. In this step: l
Set the ANTNUM parameter of sector 0 to 4, equal to the PORTNUM parameter value of virtual RET subunit 1.
l
Set the ANT1N parameter of antenna 1 to the CONNPN1 parameter value of the subunit.
l
Set the ANT2N parameter of antenna 2 to the CONNPN2 parameter value of the subunit.
l
Set the ANT3N parameter of antenna 3 to the CONNPN3 parameter value of the subunit.
l
Set the ANT4N parameter of antenna 4 to the CONNPN4 parameter value of the subunit.
Step 7 Run the ADD SECTOREQM command to add sector equipment. Step 8 Run the ADD CELL command to add a local cell. Step 9 Run the ADD EUCELLSECTOREQM command to add a relationship between the cell and the sector equipment.
Step 10 Run the MOD PDSCHCFG and MOD CELLDLPCPDSCHPA commands to set the cell power parameters, including the ReferenceSignalPwr , PA, and PB.
Step 11 Run the ACT CELL command to activate the cell. ----End
10.3.4.5.5 MML Command Examples The following is a 2T4R configuration example: //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HSN=0, HPN=0;
//Adding an AAS to the RRU chain or ring ADD AAS: CN=0,
SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=4, TXNUM=2, VRETNO=60;
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//Adding other AARU boards if an AAS is configured with more than one AARU. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//(Optional) Modifying parameter settings for a VRET MO MOD VRET: DEVICENO=60, DEVICENAME="VRET", SUBUNITQUANTITY=8;
//Configure a virtual RET antenna. MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=1, PORTNUM=4, CONNPN1=R0A, CONNPN2=R0B, CONNPN3=R1A, CONNPN4=R1B, ULTILT=40, DLTILT=40;
//Adding a sector ADD SECTOR: SECTORID=0, SECNAME="sector", LOCATIONNAME="huawei", ANTNUM=4, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANT3CN=0, ANT3SRN=60, ANT3SN=1, ANT3N=R1A, ANT4CN=0, ANT4SRN=60, ANT4SN=1, ANT4N=R1B, CREATESECTOREQM=FALSE;
//Adding sector equipment ADD SECTOREQM: SECTOREQMID=0, SECTORID=0, ANTNUM=4, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANTTYPE2=RXTx_MODE ANT3CN=0, ANT3SRN=60, ANT3SN=1, ANT3N=R1A, ANTTYPE3=RX_MODE, ANT4CN=0, ANT4SRN=60, ANT4SN=1, ANT4N=R1B, ANTTYPE4=RX_MODE;
//Adding operator information for a cell ADD CELLOP: LocalCellId=0, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0;
//Adding a local cell ADD CELL: LocalCellId=0, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1800, UlBandWidth=CELL_BW_N50, DlBandWidth=CELL_BW_N50, CellId=0, PhyCellId=48, FddTddInd=CELL_FDD, RootSequenceIdx=48, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T4R;
//Adding a relationship between the cell and the sector equipment ADD EUCELLSECTOREQM: LocalCellId=0, SectorEqmId=0;
//Setting the cell power parameters MOD PDSCHCFG: LocalCellId=0, ReferenceSignalPwr=152, Pb=1; MOD CELLDLPCPDSCHPA: LocalCellId=0, PdschPaAdjSwitch=OFF, PaPcOff=DB_3_P_A;
//Activating the cell ACT CELL: LocalCellId=0;
10.3.4.6 Activation Observation Perform the following operations after the Vertical Four Uplink Channels feature was activated: l
Check whether any alarms were falsely generated.
l
Run the DSP VRETSUBUNIT, DSP SECTOR , and DSP CELL commands to query the status of virtual RET subunits, sectors, and cells, respectively.
On the U2000 client, perform the following steps:
Step 1 Choose Monitor > Signaling Trace > Signaling Trace Management. Issue 03 (2015-08-31)
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Step 2 In the navigation tree of the Signaling Trace Management window, choose Cell Performance Monitoring > RSSI Statistic Monitoring.
Step 3 In the displayed dialog box, select an eNodeB and set the local ID of the cell to be traced. Then, click Finish to start a tracing task.
Step 4 Observe the real-time values of antenna 0 RSSI(dBm), antenna 1 RSSI(dBm), antenna 2 RSSI(dBm) , and antenna 3 RSSI(dBm). If none of the values is N/A, four receive antennas have been configured and this feature have been activated. ----End
10.3.5 Performance Monitoring After the feature is activated, monitor the following counters related to access, service, and handover. Table 10-9 Counters to query
Counter Name
Formula
RRC Setup Success Rate
Number of successful RRC connection setups in a cell/Number of RRC connection setup attempts in a cell = L.RRC ConnReq.Succ/L.RRC.ConnSetup x 100%
eRAB Setup Success Rate
Number of successful E-RAB setups in a cell/Number of ERAB setup attempts in a cell = L.E-RAB.SuccEst/L.ERAB.AttEst x 100%
Intra-Freq HO Success Rate
(Number of successful intra-eNodeB outgoing handovers in a cell + Number of successful inter-eNodeB outgoing handovers in a cell)/(Number of intra-eNodeB outgoing handovers executions in a cell + Number of inter-eNodeB outgoing handovers executions in a cell) = (L.HHO.IntraeNB.IntraFreq.ExecSuccOut + L.HHO.IntereNB.IntraFreq.ExecSuccOut)/ (L.HHO.IntraeNB.IntraFreq.ExecAttOut + L.HHO.IntereNB.IntraFreq.ExecAttOut) x 100%
Call Drop Rate
Number of abnormal E-RAB releases in a cell/(Number of abnormal E-RAB releases in a cell + Number of normal E-RAB releases in a cell) = L.E-RAB.AbnormRel/(L.ERAB.AbnormRel + L.E-RAB.NormRel) x 100%
Distribution of INs on the PUSCH
L.UL.Interference.PUSCH
Maximum uplink interference and noise received by each PRB in a cell
L.UL.Interference.Max
Number of Times an MCS Index Is Scheduled on the PUSCH
L.ChMeas.PUSCH.MCS
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Counter Name
Formula
Average number of used PRBs over the PUCCH
L.ChMeas.PRB.PUCCH.Avg
Uplink user-perceived rate
Uplink traffic volume for PDCP PDUs in a cell/Receive duration of uplink PDCP PDUs in a cell = L.Thrp.bits.UL/L.Thrp.Time.UL x 100%
10.3.6 Parameter Optimization If the cell radius is large, reducing the uplink downtilt angle can improve uplink coverage. However, if the inter-cell distance is short, reducing the uplink downtilt angle increases uplink interference and deteriorates the performance.
10.3.7 Troubleshooting l
Fault symptom The feature fails to be enabled or this feature is configured but is ineffective.
l
Solution
–
Check whether the same AAS is configured with any feature that is mutually exclusive with LOFD-261101 AAS Virtual Four Uplink Channels for LTE. For details, see 8 Related Features.
Check whether ALM-26532 RF Unit Hardware Fault is generated on the same AAS. If so, the AAS Virtual Four Uplink Channels for LTE feature fails to be enabled.
10.4 Deployment of AAS User Specific Tilting for LTE 10.4.1 Application Suggestions To expand the capacity on hot spots, this feature is recommended if the following conditions are all met: l
No extra frequencies are available to the operator.
l
Cells selected for user specific tilting provide continuous coverage.
l
There are no coverage problems, or there are coverage problems but the problems are not serious, for example, in densely populated urban areas. In densely populated urban areas, the site height is higher than 25 m, and the distance between two eNodeBs is equal to or less than 500 m. In common urban areas, the site height is higher than 30 m, and the distance between two eNodeBs is less than 1000 m.
l
The downtilt angle on the site is smaller than or equal to 10°.
l
There is traffic in cell centers.
l
UEs support 4x2 or 4x4 closed-loop MIMO.
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10.4.2 Required Information l
The required information for this feature is the same as that for LOFD-261101 AAS Virtual Four Uplink Channels for LTE. For details, see 10.3.2 Required Information.
10.4.3 Planning RF Planning The suggestions for RF planning are as follows: l
Set the downtilt angles to the values used in 2T. Compared with the RS beam in 2T, the RS beam generated after user specific tilting has a decrease of about 3 dB in the main lobe gain and an increase in the beamwidth. It is recommended that the initially configured downtilt angles be the same as those used in 2T; that is, the outer edges of these beams coincide with those of 2T beams.
l
Set the power as follows. Power planning is different from that of traditional 4T. The reference signal (RS) beam gain is less than the data beam gain, so it is good practice to set the RS power to be 3 dB greater than the rated power of 2T, set PA to -6, and set PB to 1 to provide optimal performance. However, the power of the symbol containing RS exceeds the threshold by about 1.25 dB. If the symbol power is not allowed to exceed the threshold, set the RS power to be the same as that of 2T, set PA to -6, and set PB to 3. Alternatively, set the RS power to be about 1.77 dB greater than the power configuration of 2T, set PA to -4.77, and PB to 2. In this case, the performance of UST deteriorates. For example, the normal configurations for 2T are as follows: Total Power = 40 W, RS Power = 15.2 dBm, PA = -3, PB = 1; The UST configurations are as follows: Total Power = 40 W, RS Power = 15.2 dBm, PA = -6, PB = 1. If the symbol power is not allowed to exceed the threshold, set the UST configurations as follows: Total Power = 40 W, RS Power = 15.2 dBm, PA = -6, PB = 3.
l
Obtain multiple-antenna reception information, and determine the link budget and capacity in the uplink.
l
Complete RF planning according to the general network planning procedure.
Network Planning None.
Hardware Planning The user specific tilting requires LBBPd or UBBPd. Table 10-10 lists the required CPRI bit rates and the maximum number of cells under different configurations of system bandwidths and antennas.
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Table 10-10 CPRI bit rates and maximum number of cells
CPRI Bit Rate
Maximum Number of Cells ≤ 10 MHz,
15 or 20 MHz,
≤ 10 MHz,
15 or 20 MHz,
2 Antennas
2 Antennas
4 Antennas
4 Antennas
1.25 Gbit/s
1
Not supported
Not supported
Not supported
2.5 Gbit/s
2
1
1
Not supported
4.9 Gbit/s
4
2
2
1
6.144 Gbit/s
4
2
2
1
9.8 Gbit/s
4
Not supported
4
Not supported
10.4.4 Deployment 10.4.4.1 Requirements Purchase the license for LOFD-261102 AAS User Specific Tilting for LTE , LOFD-001003 DL 4x2 MIMO, and LOFD-001060 DL 4x4 MIMO.
10.4.4.2 Data Preparation For the parameters that must be set in a VRET MO, see Table 10-5. For the parameters that must be set in a VRETSUBUNIT MO, see Table 10-6.
10.4.4.3 Precautions None.
10.4.4.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.4.4.5 Initial Configuration 10.4.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-8 in a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
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Some MOs in Table 10-8 are not contained in a scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters.
10.4.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-8 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End
10.4.4.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters for a single eNodeB, as listed in 10.4.4.2 Data Preparation. For configuration steps, see CME Single Configuration Operation Guide.
10.4.4.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS to the RRU chain or ring. Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eNodeB to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot No. to 1.
Step 4 (Optional) Run the MOD VRET command to modify parameter settings for a VRET MO. In this step, set the Device Name and Subunit Quantity parameters to appropriate values. The default value of the Subunit Quantity parameter is 8. Note that the value of the Device No. parameter must be the same as the value of the Subrack No. parameter for the previously added AAS. Issue 03 (2015-08-31)
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Step 5 Run the MOD VRETSUBUNIT command to configure virtual RET subunit 1. In this step: l l
Set the PORTNUM parameter to 4. Set all of the POLARTYPE1, POLARTYPE2, POLARTYPE3, and POLARTYPE4 parameters to POSITIVE_NEGATIVE_45(POSITIVE_NEGATIVE_45) .
Step 6 Run the ADD SECTOR command to add sector 0. In this step: l
Set the ANTNUM parameter of sector 0 to 4, equal to the PORTNUM parameter value of virtual RET subunit 1.
l
Set the ANT1N parameter of antenna 1 to the CONNPN1 parameter value of the subunit.
l
Set the ANT2N parameter of antenna 2 to the CONNPN2 parameter value of the subunit.
l
Set the ANT3N parameter of antenna 3 to the CONNPN3 parameter value of the subunit.
l
Set the ANT4N parameter of antenna 4 to the CONNPN4 parameter value of the subunit.
Step 7 Run the ADD SECTOREQM command to add sector equipment. Step 8 Run the ADD CELL command to add a cell. Step 9 Run the ADD EUCELLSECTOREQM command to add a relationship between the cell and the sector equipment.
Step 10 Run the MOD CELLMIMOPARACFG command to set the MIMO mode to TM4. Step 11 Run the MOD PDSCHCFG and MOD CELLDLPCPDSCHPA commands to set the cell power parameters, including the ReferenceSignalPwr , PA, and PB.
Step 12 Run the ACT CELL command to activate the cell. ----End
10.4.4.5.5 MML Command Examples The following is a 4T4R configuration example: //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HSN=0, HPN=0;
//Adding an AAS to the RRU chain or ring ADD AAS: CN=0,
SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=2, TXNUM=2, VRETNO=60;
//Adding other AARU boards if an AAS is configured with more than one AARU. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//(Optional) Modifying parameter settings for a VRET MO MOD VRET: DEVICENO=60, DEVICENAME="VRET", SUBUNITQUANTITY=8;
//Configuring a virtual RET subunit MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=1, PORTNUM=4, CONNPN1=R0A, CONNPN2=R0B, CONNPN3=R1A, CONNPN4=R1B, ULTILT=40, DLTILT=40;
//Adding a sector ADD SECTOR: SECTORID=0, SECNAME="sector", LOCATIONNAME="huawei", ANTNUM=4, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANT2CN=0, ANT2SRN=60, ANT2SN=1,
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ANT2N=R0B, ANT3CN=0, ANT3SRN=60, ANT3SN=1, ANT3N=R1A, ANT4CN=0, ANT4SRN=60, ANT4SN=1, ANT4N=R1B, CREATESECTOREQM=FALSE;
//Adding sector equipment ADD SECTOREQM: SECTOREQMID=0, SECTORID=0, ANTNUM=4, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANTTYPE2=RXTx_MODE ANT3CN=0, ANT3SRN=60, ANT3SN=1, ANT3N=R1A, ANTTYPE3=RXTx_MODE, ANT4CN=0, ANT4SRN=60, ANT4SN=1, ANT4N=R1B, ANTTYPE4=RXTx_MODE;
//Adding operator information for a cell ADD CELLOP: LocalCellId=0, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0;
//Adding a local cell ADD CELL: LocalCellId=0, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1800, UlBandWidth=CELL_BW_N50, DlBandWidth=CELL_BW_N50, CellId=0, PhyCellId=48, FddTddInd=CELL_FDD, RootSequenceIdx=48, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_4, TxRxMode=4T4R;
//Adding a relationship between the cell and the sector equipment ADD EUCELLSECTOREQM: LocalCellId=0, SectorEqmId=0;
//Setting the MIMO mode MOD CELLMIMOPARACFG: LocalCellId=0, MimoAdaptiveSwitch=NO_ADAPTIVE, FixedMimoMode=TM4, InitialMimoType=ADAPTIVE;
//Setting the cell power parameters MOD PDSCHCFG: LocalCellId=0, ReferenceSignalPwr=152, Pb=1; MOD CELLDLPCPDSCHPA: LocalCellId=0, PdschPaAdjSwitch=OFF, PaPcOff=DB_6_P_A;
//Activating the cell ACT CELL: LocalCellId=0;
10.4.4.6 Activation Observation Perform the following operators to check whether the feature has been activated: l
Check whether there are alarms.
l
Run the DSP VRETSUBUNIT, DSP SECTOR , and DSP CELL commands to query the status of virtual RET subunits, sectors, and cells, respectively.
10.4.5 Performance Monitoring After feature activation, check the values of the counters listed in Table 10-11 to determine performance gains provided by this feature. Table 10-11 Counters to query
Counter Name
Formula
Number of Used Downlink PRBs in MIMO Mode
L.ChMeas.MIMO.PRB
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Counter Name
Formula
RRC Setup Success Rate
Number of successful RRC connection setups in a cell/Number of RRC connection setup attempts in a cell = L.RRC ConnReq.Succ/L.RRC.ConnSetup x 100%
eRAB Setup Success Rate
Number of successful E-RAB setups in a cell/Number of ERAB setup attempts in a cell = L.E-RAB.SuccEst/L.ERAB.AttEst x 100%
Intra-Freq HO Success Rate
(Number of successful intra-eNodeB outgoing handovers in a cell + Number of successful inter-eNodeB outgoing handovers in a cell)/(Number of intra-eNodeB outgoing handovers executions in a cell + Number of inter-eNodeB outgoing handovers executions in a cell) = (L.HHO.IntraeNB.IntraFreq.ExecSuccOut + L.HHO.IntereNB.IntraFreq.ExecSuccOut)/ (L.HHO.IntraeNB.IntraFreq.ExecAttOut + L.HHO.IntereNB.IntraFreq.ExecAttOut) x 100%
Call Drop Rate
Number of abnormal E-RAB releases in a cell/(Number of abnormal E-RAB releases in a cell + Number of normal E-RAB releases in a cell) = L.E-RAB.AbnormRel/(L.ERAB.AbnormRel + L.E-RAB.NormRel) x 100%
Downlink PRB Usage
Average number of used PDSCH PRBs/Number of available downlink PRBs = L.ChMeas.PRB.DL.Used.Avg/ L.ChMeas.PRB.DL.Avail x 100%
Number of Times a Specific MCS Index Is Scheduled on the PDSCH
L.ChMeas.PDSCH.MCS
Number of OFDM Symbols Occupied by the PDCCH
L.ChMeas.PDCCH.SymNum
Downlink user perceived rate
Downlink traffic volume for PDCP SDUs in a cell/Total duration of downlink data transmission in a cell = L.Thrp.bits.DL/ L.Thrp.Time.Cell.DL x 100%
10.4.6 Parameter Optimization If the call completion rate, service drop rate, or handover success rate deteriorates, use traditional RF optimization methods to optimize network performance and KPIs. To achieve the optimal performance, you are advised to set the user specific downtilt angles and RS power to the values used in 2T, set PA to -6, and set PB to 1. In this situation, the RS power exceeds the threshold by 1.25 dB. If the symbol power is not allowed to exceed the threshold, set the RS power to be about 1.2 dB lower than the power configuration of 2T, set PA to -4.77, and PB to 2. Issue 03 (2015-08-31)
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Compared with the RS beam in 2T, the RS beam generated after user specific tilting has a decrease of about 3 dB in the main lobe gain, which leads to a reduction of about 3-5 dB in the edge coverage level. To improve the edge coverage, you can lift the cell transmit power to increase the RS power.
10.4.7 Troubleshooting l
Fault symptom The feature fails to be enabled or this feature is configured but is ineffective.
l
Solution
–
Check whether the same AAS is configured with any feature that is mutually exclusive with LOFD-261102 AAS User Specific Tilting for LTE. For details, see 8 Related Features.
–
Check whether ALM-26532 RF Unit Hardware Fault is generated on the same AAS. If so, LOFD-261102 AAS User Specific Tilting for LTE cannot be used.
10.5 Deployment of AAS Vertical Multiple Sectors for LTE 10.5.1 Application Suggestions Use this feature in hot spots when the following conditions are met: l
The operator does not have extra frequencies.
l
The downlink load of the target cell has reached or exceeded the downlink load threshold (70%) for capacity expansion.
l
In densely-populated urban areas, the site height is higher than 25 m, and the distance between two eNodeBs is about 500 m.
l
In common urban areas, the site height is higher than 30 m, and the distance between two eNodeBs is less than 1000 m.
l
The downtilt angle on the site is smaller than or equal to 10°.
l
Traffic is available near the site. Deploy this feature in scenarios where traffic in inner cells accounts for 40% to 80% of the total traffic.
If users are mainly on the overlapping areas between inner and outer cells, this feature is not recommended because it cannot provide any gain.
10.5.2 Required Information The required information is the same as that for LOFD-261101 AAS Virtual Four Uplink Channels for LTE. For details, see 10.3.2 Required Information.
10.5.3 Planning RF planning RF planning involves the following: l
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Power configurations: The maximum transmit power of the AAU3902 is 2x40 W.
–
If the total transmit power of the inner and outer cells does not reach the maximum transmit power of the target AAS after sector splitting, it is recommended that the transmit power of an inner cell and the corresponding outer cell be the same as the transmit power of the original cell. For example, if the transmit power of a cell using the AAU3902 is 30 W before sector splitting, the transmit power of the inner and outer cells can be 30 W after sector splitting.
–
If the total transmit power of the inner and outer cells exceeds the maximum transmit power of the target AAS after sector splitting, it is recommended that the transmit power of an inner cell and the corresponding outer cell be half of the transmit power of the original cell. For example, if the transmit power of a cell using the AAU3902 is 50 W before sector splitting, the transmit power of the inner and outer cells is still 50 W after sector splitting. In this case, the maximum transmit power of the AAU3902 is exceeded and your are advised to reduce the transmit power of the inner and outer cells to 25 W. You can also increase the transmit power of each cell, but the total transmit power of inner and outer cells cannot exceed the maximum transmit power of the AAS. For example, you can increase the transmit power of each cell to 30 W. As a result, the total transmit power is 60 W, which is a little higher than that before sector splitting.
l
Downtilt angle planning: Ensure that the downtilt angle of the outer cell is equal to that of the original cell, and downtilt angle of the inner cell is equal to the sum of the outer cell downtilt angle and the downtilt angle difference. In addition, avoid the sector border from deviation as possible as you can.
l
PRACH/PCI planning: After three sectors are split into six sectors, the number of PRACH/PCI reuse times becomes smaller, the reuse distance becomes shorter, and the possibility of PRACH/PCI conflicts will increase. To reduce this possibility, you can use the U-NET tool to for sector planning.
l
Neighboring cell planning: The original neighbor relationships require re-planning or optimization. You can use the ANR feature and perform drive tests to optimize neighbor relation tables (NRTs). If you manually configure an NRT, pay attention to the following:
–
For the outer cell, add the intra-frequency inner cells and inter-frequency inner cells at this site and neighboring sites to the intra-frequency NRT.
–
For the inner cell, copy the NRT of the corresponding outer cell and add the outer cell to this NRT.
–
After this feature is enabled, the network topology changes. Therefore, neighboring cell planning is also affected. For the neighboring cells of the original outer cell, add the intra-/inter-frequency inner cell in the intra-/inter-frequency neighboring cell list so that call drops will not occur.
Network Planning None.
Hardware Planning This feature requires the addition of new cells. If the existing baseband processing units cannot accommodate these new cells, additional baseband processing units must be installed. Issue 03 (2015-08-31)
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10.5.4 Deployment 10.5.4.1 Requirements Purchase the license for LOFD-261103 AAS Vertical Multiple Sectors for LTE.
10.5.4.2 Data Preparation For the parameters that must be set in a VRET MO, see Table 10-5. For the parameters that must be set in a VRETSUBUNIT MO, see Table 10-6. Table 10-12 lists the parameters that must be set in a Cell MO. Table 10-12 Key parameters in the Cell MO
Parameter Name
Paramete r ID
Setting Notes
Data Source
Uplink EARFCN
UlEarfcn
Set the uplink frequencies of the two cells to the same value.
User-defined
Downlink EARFCN
DlEarfcn
Set the downlink frequencies of the two cells to the same value.
User-defined
10.5.4.3 Precautions None.
10.5.4.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.5.4.5 Initial Configuration 10.5.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-8 in a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
The MOs in Table 10-8 are contained in a scenario-specific summary data file. In this situation, set the parameters in the MOs, and then verify and save the file.
l
Some MOs in Table 10-8 are not contained in a scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters.
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10.5.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-8 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End
10.5.4.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters for a single eNodeB, as listed in 10.5.4.2 Data Preparation. For configuration steps, see CME Single Configuration Operation Guide.
10.5.4.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS to the RRU chain or ring. Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eGBTS to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot N o. to 1.
Step 4 (Optional) Run the MOD VRET command to modify parameter settings for a VRET MO. In this step, set the DEVICENAME and SUBUNITQUANTITY parameters to appropriate values. The default value of the SUBUNITQUANTITY parameter is 8. Note that the value of the DEVICENO parameter must be the same as the value of the SRN parameter for the previously added AAS.
Step 5 Run the MOD VRETSUBUNIT command to set the ULTILT and DLTILT parameters of virtual RET subunits 1 and 2 to the planned values. Issue 03 (2015-08-31)
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Step 6 Run the ADD SECTOR command to associate virtual RET subunits with sectors. In this step: l
For sector 0: Set the ANTNUM parameter to the value of the PORTNUM parameter for virtual RET subunit 1. Set the ANT1N and ANT2N parameters to the values of the CONNPN1 and CONNPN2 parameters for virtual RET subunit 1, respectively.
l
For sector 1: Set the ANTNUM parameter to the value of the PORTNUM parameter for virtual RET subunit 2. Set the ANT1N and ANT2N parameters to the values of the CONNPN1 and CONNPN2 parameters for virtual RET subunit 2, respectively.
Step 7 Run the ADD SECTOREQM command to add sector equipment. Step 8 Run the ADD CELL command twice to add two local cells in total. Step 9 Run the ADD EUCELLSECTOREQM command to add relationships between the cells and the sector equipment.
Step 10 Run the MOD PDSCHCFG and MOD CELLDLPCPDSCHPA commands to set the cell power parameters, including the ReferenceSignalPwr , PA, and PB.
Step 11 Run the ACT CELL command to activate the cells. ----End
10.5.4.5.5 MML Command Examples //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HCN=0, HSN=3, HPN=0;
//Adding an AAS to the RRU chain or ring ADD AAS: CN=0,
SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=2, TXNUM=2, VRETNO=60;
//Adding other AARU boards if an AAS is configured with more than one AARU. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//Modifying the configurations of virtual RET subunit 1 MOD VRET: DEVICENO=60, DEVICENAME="VRET", SUBUNITQUANTITY=1;
//Modifying the configurations of virtual RET subunit 1 MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=1, PORTNUM=2, CONNPN1=R0A, CONNPN2=R0B, ULTILT=0, DLTILT=0;
//Modifying the configurations of virtual RET subunit 2 MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=2, PORTNUM=2, CONNPN1=R1A, CONNPN2=R1B, ULTILT=20, DLTILT=20;
//Adding two sectors ADD SECTOR: SECTORID=10, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, CREATESECTOREQM=FALSE;
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ADD SECTOR: SECTORID=11, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R1A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R1B, CREATESECTOREQM=FALSE;
//Adding two sets of sector equipment ADD SECTOREQM: SECTOREQMID=10, SECTORID=10, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANTTYPE2=RXTX_MODE; ADD SECTOREQM: SECTOREQMID=11, SECTORID=11, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R1A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R1B, ANTTYPE2=RXTX_MODE;
//Adding operator information for a cell ADD CELLOP: LocalCellId=0, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0; ADD CELLOP: LocalCellId=1, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0;
//Adding two cells ADD CELL: LocalCellId=0, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1550, UlBandWidth=CELL_BW_N25, DlBandWidth=CELL_BW_N25, CellId=0, PhyCellId=0, FddTddInd=CELL_FDD, RootSequenceIdx=0, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T2R; ADD CELL: LocalCellId=1, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1550, UlBandWidth=CELL_BW_N25, DlBandWidth=CELL_BW_N25, CellId=1, PhyCellId=1, FddTddInd=CELL_FDD, RootSequenceIdx=1, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T2R;
//Adding relationships between the cells and the sector equipment ADD EUCELLSECTOREQM: LocalCellId=0, SectorEqmId=10; ADD EUCELLSECTOREQM: LocalCellId=1, SectorEqmId=11;
//Setting the cell power parameters MOD MOD MOD MOD
PDSCHCFG: LocalCellId=0, ReferenceSignalPwr=122, Pb=1; CELLDLPCPDSCHPA: LocalCellId=0, PdschPaAdjSwitch=OFF, PaPcOff=DB3_P_A; PDSCHCFG: LocalCellId=1, ReferenceSignalPwr=122, Pb=1; CELLDLPCPDSCHPA: LocalCellId=1, PdschPaAdjSwitch=OFF, PaPcOff=DB3_P_A;
//Activating the cells ACT CELL: LocalCellId=0; ACT CELL: LocalCellId=1;
10.5.4.6 Activation Observation Perform the following operations after the Vertical Multiple Sectors feature was activated: l
Check whether any alarms were falsely generated.
l
Run the DSP VRETSUBUNIT and DSP SECTOR commands to query the status of virtual RET subunits and sectors, respectively.
l
Run the DSP CELL command to check whether each pair of inner and outer cells is successfully set up.
10.5.5 Performance Monitoring After feature activation, check the values of the counters listed in Table 10-13 to determine performance gains provided by this feature. Issue 03 (2015-08-31)
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Table 10-13 Counters to query
Counter Name
Formula
Number of Used Downlink PRBs in MIMO Mode
L.ChMeas.MIMO.PRB
RRC Setup Success Rate
Number of successful RRC connection setups in a cell/Number of RRC connection setup attempts in a cell = L.RRC ConnReq.Succ/L.RRC.ConnSetup x 100%
eRAB Setup Success Rate
Number of successful E-RAB setups in a cell/Number of ERAB setup attempts in a cell = L.E-RAB.SuccEst/L.ERAB.AttEst x 100%
Intra-Freq HO Success Rate
(Number of successful inter-eNodeB outgoing handovers in a cell + Number of successful intra-eNodeB outgoing handovers in a cell)/(Number of inter-eNodeB outgoing handovers executions in a cell + Number of intra-eNodeB outgoing handovers executions in a cell) = (L.HHO.IntraeNB.IntraFreq.ExecSuccOut + L.HHO.IntereNB.IntraFreq.ExecSuccOut)/ (L.HHO.IntraeNB.IntraFreq.ExecAttOut + L.HHO.IntereNB.IntraFreq.ExecAttOut) x 100%
Call Drop Rate
Number of abnormal E-RAB releases in a cell/(Number of abnormal E-RAB releases in a cell + Number of normal E-RAB releases in a cell) = L.E-RAB.AbnormRel/(L.ERAB.AbnormRel + L.E-RAB.NormRel) x 100%
Average Number of Users in a Cell
L.Traffic.User.Avg
Average number of used PRBs over the PUCCH
L.ChMeas.PRB.PUCCH.Avg
Number of OFDM Symbols Occupied by the PDCCH
L.ChMeas.PDCCH.SymNum
Uplink PRB Usage
Average number of used uplink PRBs/Number of available uplink PRB = L.ChMeas.PRB.UL.Used.Avg/ L.ChMeas.PRB.UL.Avail x 100%
Downlink PRB Usage
Average number of used downlink PRBs/Number of available downlink PRB = L.ChMeas.PRB.DL.Used.Avg/ L.ChMeas.PRB.DL.Avail x 100%
Uplink user-perceived rate
Uplink traffic volume for PDCP PDUs in a cell/Receive duration of uplink PDCP PDUs in a cell = L.Thrp.bits.UL/L.Thrp.Time.UL x 100%
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Counter Name
Formula
Downlink user perceived rate
Downlink traffic volume for PDCP SDUs in a cell/Total duration of downlink data transmission in a cell = L.Thrp.bits.DL/ L.Thrp.Time.Cell.DL x 100%L.Thrp.Time.Cell.DL
10.5.6 Parameter Optimization This feature impacts KPIs such as the call completion rate and service drop rate. Particularly, the service drop rate decreases by 10% to 20% each day in some scenarios. You can use the traditional methods for optimization. To avoid abnormal coverage or strong interference after the AAS Vertical Multiple Sectors for LTE feature is enabled, use the fixed outer cell downtilt angle and ensure that the absolute RS power of the outer cell remains the same so that outer cell coverage remains the same. Set the downtilt angle difference between the outer cell and inner cell to maximum DT value (6° for the AAU3902 1.8GHz). For details, see Technical Specifications of AAUs in 3900 Series Base Station Technical Description. Therefore, do not optimize the preceding parameters.
10.5.7 Troubleshooting l
Fault symptom The feature fails to be enabled or this feature is configured but is ineffective.
l
l
Solution
–
Check whether the same AAS is configured with any feature that is mutually exclusive with the AAS Vertical Multiple Sectors for LTE feature. For details, see 8 Related Features.
–
Check whether ALM-26532 RF Unit Hardware Fault is generated on the same AAS. If so, the AAS Vertical Multiple Sectors for LTE feature fails to be enabled.
Fault symptom KPIs deteriorate after this feature is enabled.
l
Solution Observe the KPIs after this feature is enabled. If KPIs deteriorate, take the same KPI optimization methodology as for common sites.
10.6 Deployment of AAS Dividual Tilts by Carrier for LTE 10.6.1 Application Suggestions Use the AAS Dividual Tilts by Carrier for LTE feature when the following conditions are met: l
The operator has two frequencies serving the same mode in the same frequency band.
l
Traffic near the cell center is dense.
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10.6.2 Required Information The required information for this feature is the same as that for LOFD-261101 AAS Virtual Four Uplink Channels for LTE. For details, see 10.3.2 Required Information.
10.6.3 Planning RF Planning Before deploying this feature, make a traffic map. Conduct a network planning simulation test based on the traffic map. Determine the optimal capacity by adjusting the downtilt angles.
Network Planning None.
Hardware Planning The AAU3902 must be configured.
10.6.4 Deployment 10.6.4.1 Requirements Purchase the license for AAS Dividual Tilts by Carrier for LTE
10.6.4.2 Data Preparation For the parameters that must be set in a VRET MO, see Table 10-5. For the parameters that must be set in a VRETSUBUNIT MO, see Table 10-6. For the parameters that must be set in a Cell MO, see Table 10-12.
10.6.4.3 Precautions None.
10.6.4.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.6.4.5 Initial Configuration 10.6.4.5.1 Using the CME to Perform Batch Configuration for Newly Deployed eNodeBs Enter the values of the parameters listed in Table 10-8 in a summary data file, which also contains other data for the new eNodeBs to be deployed. Then, import the summary data file into the CME for batch configuration. Issue 03 (2015-08-31)
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The summary data file may be a scenario-specific file provided by the CME or a customized file, depending on the following conditions: l
The MOs in Table 10-8 are contained in a scenario-specific summary data file. In this situation, set the parameters in the MOs, and then verify and save the file.
l
Some MOs in Table 10-8 are not contained in a scenario-specific summary data file. In this situation, customize a summary data file to include the MOs before you can set the parameters.
10.6.4.5.2 Using the CME to Perform Batch Configuration for Existing eNodeBs Batch reconfiguration using the CME is the recommended method to activate a feature on existing eNodeBs. This method reconfigures all data, except neighbor relationships, for multiple eNodeBs in a single procedure. The procedure is as follows:
Step 1 Choose CME > Customize Summary Data File from the main menu of an U2000 client, or choose Advanced > Customize Summary Data File from the main menu of a CME client, to customize a summary data file for batch reconfiguration. NOTE
For context-sensitive help on a current task in the client, press F1.
Step 2 Choose CME > Export Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Export Base Station Bulk Configuration Data from the main menu of the CME client, to export the eNodeB data stored on the CME into the customized summary data file.
Step 3 In the summary data file, set the parameters in the MOs listed in Table 10-8 and close the file. Step 4 Choose CME > Import Base Station Bulk Configuration Data from the main menu of the U2000 client, or choose Advanced > Import Base Station Bulk Configuration Data from the main menu of the CME client, to import the summary data file into the CME. ----End
10.6.4.5.3 Using the CME to Perform Single Configuration On the CME, set the parameters listed in 10.6.4.2 Data Preparation for a single eNodeB. For configuration steps, see CME Single Configuration Operation Guide.
10.6.4.5.4 Using MML Commands Perform the following steps on the eNodeB side:
Step 1 Run the ADD RRUCHAIN command to add an RRU chain or ring. Step 2 Run the ADD AAS command to add an AAS to the RRU chain or ring. Step 3 Run the ADD AARU command to add an AARU. In this step, set RS to LO, RXNUM to 2, and TXNUM to 2. When multiple AARUs are installed on the AAS, configure all the AARUs. To add an AARU in UMTS mode in slot 1, perform the following operation: Run the ADD AARU command on the eGBTS to add an AARU. In this step, set AARU Work Standard to UO, Number of RX channels to 2, Number of TX channels to 2, and Slot No. to 1. Issue 03 (2015-08-31)
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Step 4 (Optional) Run the MOD VRET command to modify parameter settings for a VRET MO. In this step, set the DEVICENAME and SUBUNITQUANTITY parameters to appropriate values. The default value of the SUBUNITQUANTITY parameter is 8. Note that the value of the DEVICENO parameter must be the same as the value of the SRN parameter for the previously added AAS.
Step 5 Run the MOD VRETSUBUNIT command to configure virtual RET subunit 1. In this step: l l
Set the PORTNUM parameter to 4. Set all of the POLARTYPE1, POLARTYPE2, POLARTYPE3, and POLARTYPE4 parameters to POSITIVE_NEGATIVE_45(POSITIVE_NEGATIVE_45) .
Step 6 Run the ADD SECTOR command to add sector 0. In this step: l
Set the ANTNUM parameter of sector 0 to 4, equal to the PORTNUM parameter value of virtual RET subunit 1.
l
Set the ANT1N parameter of antenna 1 to the CONNPN1 parameter value of the subunit.
l
Set the ANT2N parameter of antenna 2 to the CONNPN2 parameter value of the subunit.
l
Set the ANT3N parameter of antenna 3 to the CONNPN3 parameter value of the subunit.
l
Set the ANT4N parameter of antenna 4 to the CONNPN4 parameter value of the subunit.
Step 7 Run the ADD SECTOREQM command to add sector equipment. Step 8 Run the ADD CELL command to add a cell. Step 9 Run the ADD EUCELLSECTOREQM command to add a relationship between the cell and the sector equipment.
Step 10 Run the MOD PDSCHCFG and MOD CELLDLPCPDSCHPA commands to set the cell power parameters, including the ReferenceSignalPwr , PA, and PB.
Step 11 Run the ACT CELL command to activate the cell. ----End
10.6.4.5.5 MML Command Examples //Adding an RRU chain or ring ADD RRUCHAIN: RCN=0, TT=CHAIN, BM=COLD, HSN=3, HPN=0;
//Adding an AAS to the RRU chain or ring ADD AAS: CN=0, SRN=60, TP=TRUNK, RCN=0, PS=0, AN="AAS";
//Adding an AARU ADD AARU: CN=0, SRN=60, SN=3, RS=LO, AN="AARU_1", RXNUM=2, TXNUM=2, VRETNO=60;
//Adding other AARU boards if an AAS is configured with more than one AARU. ADD AARU: CN=0, SRN=60, SN=1, RS=UO, AN="AARU_2", RXNUM=2, TXNUM=2, VRETNO=61;
//(Optional) Modifying parameter settings for a VRET MO MOD VRET: DEVICENO=60, DEVICENAME="VRET", SUBUNITQUANTITY=8;
//Modifying the configurations of virtual RET subunit 1 MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=1, PORTNUM=2, CONNPN1=R0A, CONNPN2=R0B, ULTILT=40, DLTILT=40;
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//Modifying the configurations of virtual RET subunit 2 MOD VRETSUBUNIT: DEVICENO=60, SUBUNITNO=2, PORTNUM=2, CONNPN1=R1A, CONNPN2=R1B, ULTILT=90, DLTILT=90;
//Adding two sectors ADD SECTOR: SECTORID=10, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, CREATESECTOREQM=FALSE; ADD SECTOR: SECTORID=11, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R1A, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R1B, CREATESECTOREQM=FALSE;
//Adding two sets of sector equipment ADD SECTOREQM: SECTOREQMID=10, SECTORID=10, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R0A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R0B, ANTTYPE2=RXTX_MODE; ADD SECTOREQM: SECTOREQMID=11, SECTORID=11, ANTNUM=2, ANT1CN=0, ANT1SRN=60, ANT1SN=1, ANT1N=R1A, ANTTYPE1=RXTX_MODE, ANT2CN=0, ANT2SRN=60, ANT2SN=1, ANT2N=R1B, ANTTYPE2=RXTX_MODE;
//Adding operator information for a cell ADD CELLOP: LocalCellId=0, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0; ADD CELLOP: LocalCellId=1, TrackingAreaId=0, MMECfgNum=CELL_MME_CFG_NUM_0;
//Adding two cells ADD CELL: LocalCellId=0, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1550, UlBandWidth=CELL_BW_N50, DlBandWidth=CELL_BW_N50, CellId=0, PhyCellId=0, FddTddInd=CELL_FDD, RootSequenceIdx=0, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T2R; ADD CELL: LocalCellId=1, CellName="lte", FreqBand=3, UlEarfcnCfgInd=NOT_CFG, DlEarfcn=1800, UlBandWidth=CELL_BW_N50, DlBandWidth=CELL_BW_N50, CellId=1, PhyCellId=1, FddTddInd=CELL_FDD, RootSequenceIdx=1, CustomizedBandWidthCfgInd=NOT_CFG, EmergencyAreaIdCfgInd=NOT_CFG, UePowerMaxCfgInd=NOT_CFG, MultiRruCellFlag=BOOLEAN_FALSE, CrsPortNum=CRS_PORT_2, TxRxMode=2T2R;
//Adding relationships between the cells and the sector equipment ADD EUCELLSECTOREQM: LocalCellId=0, SectorEqmId=10; ADD EUCELLSECTOREQM: LocalCellId=1, SectorEqmId=11;
//Setting the cell power parameters MOD MOD MOD MOD
PDSCHCFG: LocalCellId=0, ReferenceSignalPwr=122, Pb=1; CELLDLPCPDSCHPA: LocalCellId=0, PdschPaAdjSwitch=OFF, PaPcOff=DB3_P_A; PDSCHCFG: LocalCellId=1, ReferenceSignalPwr=122, Pb=1; CELLDLPCPDSCHPA: LocalCellId=1, PdschPaAdjSwitch=OFF, PaPcOff=DB3_P_A;
//Activating the cells ACT CELL: LocalCellId=0; ACT CELL: LocalCellId=1;
10.6.4.6 Activation Observation Perform the following operations after the Dividual Tilts by Carrier feature was activated: l
Check whether any alarms were falsely generated.
l
Run the DSP VRETSUBUNIT, DSP SECTOR , and DSP CELL commands to query the status of virtual RET subunits, sectors, and cells, respectively.
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10.6.5 Performance Monitoring After feature activation, check the values of the counters listed in Table 10-14 to determine performance gains provided by this feature. Table 10-14 Counters to query
Counter Name
Formula
RRC Setup Success Rate
Number of successful RRC connection setups in a cell/ Number of RRC connection setup attempts in a cell = L.RRC ConnReq.Succ/L.RRC.ConnSetup x 100%
eRAB Setup Success Rate
Number of successful E-RAB setups in a cell/Number of ERAB setup attempts in a cell = L.E-RAB.SuccEst/L.ERAB.AttEst x 100%
Intra-Freq HO Success Rate
(Number of successful intra-eNodeB outgoing handovers in a cell + Number of successful inter-eNodeB outgoing handovers in a cell)/(Number of intra-eNodeB outgoing handovers executions in a cell + Number of i nter-eNodeB outgoing handovers executions in a cell) = (L.HHO.IntraeNB.IntraFreq.ExecSuccOut + L.HHO.IntereNB.IntraFreq.ExecSuccOut)/ (L.HHO.IntraeNB.IntraFreq.ExecAttOut + L.HHO.IntereNB.IntraFreq.ExecAttOut) x 100%
Call Drop Rate
Number of abnormal E-RAB releases in a cell/(Number of abnormal E-RAB releases in a cell + Number of normal ERAB releases in a cell) = L.E-RAB.AbnormRel/(L.ERAB.AbnormRel + L.E-RAB.NormRel) x 100%
10.6.6 Parameter Optimization Parameters are optimized in the same way as that for the common sites. After this feature is enabled, downtilt angles of carriers can be independently adjusted. If the call completion rate, call drop rate, or handover success rate deteriorates, adjust the downlink downtilt angles of carriers.
10.6.7 Troubleshooting l
Fault symptom
KPIs deteriorate after this feature is enabled. l
Solution Observe the KPIs after this feature is enabled. If KPIs deteriorate, take the same KPI optimization method as that in common si tes.
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10.7.1 Application Suggestions This feature is recommended if the following conditions are all met: l
Multiple RATs work concurrently on the AAU3902.
l
Cells using different RATs need to be configured with different downtilt angles.
10.7.2 Required Information l
Traffic statistics: used to identify hot spots.
l
Measurement report and drive test data: used to analyze traffic distribution and coverage distribution.
l
Site engineering parameters: used to obtain engineering information such as installation information, downtilt angle configuration, and inter-site distance.
10.7.3 Planning RF Planning Perform RF planning according to the principles for each RAT.
Network Planning Perform network planning according to the principles for each RAT.
Hardware Planning The AAU3902 must be configured.
10.7.4 Deployment 10.7.4.1 Requirements Purchase the license for AAS RAT Specific Tilting (LTE).
10.7.4.2 Data Preparation For the parameters that must be set in a VRET MO, see Table 10-5. For the parameters that must be set in a VRETSUBUNIT MO, see Table 10-6. For the parameters that must be set in a Cell MO, see Table 10-12.
10.7.4.3 Precautions The downtilt angle difference between AAS beams is restricted by the maximum capability of the digital tilt (DT). All such differences among features or within any features comply with this restriction. For more information, see "Technical Specifications of AAUs" in 3900 Series Base Station Technical Description. Issue 03 (2015-08-31)
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10.7.4.4 Hardware Adjustment For details, see AAU3902 Installation Guide.
10.7.4.5 Initial Configuration For details, see 10.6.4.5 Initial Configuration.
10.7.4.6 Activation Observation Perform the following operations after the Dividual Tilts by Carrier feature was activated: l
Check whether any alarms were falsely generated.
l
Run the DSP VRETSUBUNIT, DSP SECTOR , and DSP CELL commands to query the status of virtual RET subunits, sectors, and cells, respectively.
10.7.5 Performance Monitoring After feature activation, check the values of the counters listed in Table 10-15 to determine performance gains provided by this feature. Table 10-15 Counters to query
Counter Name
Formula
RRC Setup Success Rate
Number of successful RRC connection setups in a cell/ Number of RRC connection setup attempts in a cell = L.RRC ConnReq.Succ/L.RRC.ConnSetup x 100%
eRAB Setup Success Rate
Number of successful E-RAB setups in a cell/Number of ERAB setup attempts in a cell = L.E-RAB.SuccEst/L.ERAB.AttEst x 100%
Intra-Freq HO Success Rate
Intra-frequency handover success rate
Call Drop Rate
Number of abnormal E-RAB releases in a cell/(Number of abnormal E-RAB releases in a cell + Number of normal ERAB releases in a cell) = L.E-RAB.AbnormRel/(L.ERAB.AbnormRel + L.E-RAB.NormRel) x 100%
10.7.6 Parameter Optimization If the call completion rate, call drop rate, or handover success rate deteriorates, adjust the downlink downtilt angles of carriers.
10.7.7 Troubleshooting l
Fault symptom The feature fails to be enabled or this feature is configured but is ineffective.
l
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–
Check whether the same AAS is configured with any feature that is mutually exclusive with this feature. For details, see 8 Related Features.
–
Check whether ALM-26532 RF Unit Hardware Fault is generated on the same AAS. If so, the AAS RAT Specific Tilting (LTE) feature fails to be enabled.
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