Download Feature Description

eLTE 2.3 DBS3900
Optional Feature Description
Issue
03
Date
2013-11-28
HUAWEI TECHNOLOGIES CO., LTD.
Copyright © Huawei Technologies Co., Ltd. 2013. All rights reserved.
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Huawei Technologies Co., Ltd.
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Email:
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i
eLTE 2.2 DBS3900 Optional
Optional Feature Description
About This Document
About This Document
Change History
Draft B
Date
Author
Description
2013-08-28
Hua
wenjian(em
ployee ID:
00051326)
This issue is a draft.
2013-09-13
Hua
wenjian(em
ployee ID:
00051326)
删除 TDLOFD-003022，
PPoE 特性，
因为 eLTE2.2
中不配套 Micro，而此特性仅仅适用于 Micro。
因此删除。
2013-09-30
Hua
wenjian(em
ployee ID:
00051326)
删除 V-MIMO 特性对 Control Channel IRC 的依
赖关系
2013-10-12
Hua wenjian 经过与 eRAN MO 许楠确认，TDLOFD-001066
（employee
的限制说明中：“Once the parameter
ID:
CellUlschAlgo.UlHoppingType =
00051326） ‘Hopping_OFF’, UL CoMP will be disabled.”改
为“Once the parameter
CellUlschAlgo.UlHoppingType =
‘Hopping_OFF’, UL CoMP will be enabled.”
2013-11-28
Hua
wenjian(000
51326);Yan
g
Binhe(1235
26)
20131026 企业无线 CCB 决策：在
TDLOFD-001058 UL 2x4 MU-MIMO 特性中增
加约束关系：This feature is only applicable to
Non-GBR bears.
2014-02-10
Ouyangfan/
00149383
This draft is based on eLTE2.2
Optional Feature Description Draft
Add new features:
TDLOFD-070222 Scheduling Based on Max Bit
Rate
TDLOFD-001009 Extended Cell Access Radius
TDLOFD-00301402 Access Control List (ACL)
autogeneration
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eLTE 2.2 DBS3900 Optional
Optional Feature Description
About This Document
Date
Author
Description
TDLOFD-070215 Intra-LTE User Number Load
Balancing
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eLTE 2.2 DBS3900 Optional
Optional Feature Description
1 Radio & Performance
Contents
About This Document .................................................................................................................... ii
1 Radio & Performance ................................................................................................................... 6
1.1 LTE 2 Antenna ................................................................................................................................................. 6
1.1.1 TDLOFD-001001 DL 2x2 MIMO .......................................................................................................... 6
1.1.2 TDLOFD-001030 Support of UE Category 2/3/4 ................................................................................... 7
1.2 LTE 4 Antenna ................................................................................................................................................. 8
1.2.1 TDLOFD-001049 Single Streaming Beamforming ................................................................................ 8
1.2.2 TDLOFD-001005 UL 4-Antenna Receive Diversity .............................................................................. 9
1.2.3 TDLOFD-001058 UL 2x4 MU-MIMO................................................................................................. 10
1.5 Interference Handling ..................................................................................................................................... 11
1.5.1 TDLOFD-001012 UL Interference Rejection Combining .................................................................... 11
1.5.2 TDLOFD-001094 Control Channel IRC ............................................................................................... 12
1.6 QoS................................................................................................................................................................. 13
1.6.1 TDLOFD-001026 Optional uplink-downlink subframe configuration ................................................. 13
1.6.2 TDLOFD-001015 Enhanced Scheduling .............................................................................................. 14
1.6.3 TDLOFD-070222 Scheduling Based on Max Bit Rate ......................................................................... 19
1.6.4 TDLOFD-001028 TCP Proxy Enhancer (TPE) .................................................................................... 19
1.6.5 TDLOFD-001027 Active Queue Management (AQM) ........................................................................ 20
1.6.6 TDLOFD-001029 Enhanced Admission Control .................................................................................. 21
1.6.7 TDLOFD-001054 Flexible User Steering ............................................................................................. 22
1.6.8 TDLOFD-001059 UL Pre-allocation Based on SPID ........................................................................... 24
1.6.9 TDLOFD-001109 DL Non-GBR Packet Bundling ............................................................................... 24
1.6.10 TDLOFD-001076 CPRI Compression ................................................................................................ 25
1.7 High Speed Mobility ...................................................................................................................................... 26
1.7.1 TDLOFD-001007 High Speed Mobility ............................................................................................... 26
1.7.2 TDLOFD-001008 Ultra High Speed Mobility ...................................................................................... 27
2 Networking & Transmission & Security ................................................................................ 29
2.1 Transmission & Synchronization ................................................................................................................... 29
2.1.1 TDLOFD-003011 Enhanced Transmission QoS Management ............................................................. 29
2.1.2 TDLOFD-003018 IP Active Performance Measurement ...................................................................... 31
2.1.3 TDLOFD-001134 Virtual Routing & Forwarding ................................................................................ 34
2.2 Security .......................................................................................................................................................... 35
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eLTE 2.2 DBS3900 Optional
Optional Feature Description
1 Radio & Performance
2.2.1 TDLOFD-001010 Security Mechanism ................................................................................................ 35
2.2.2 TDLOFD-003009 IPsec ........................................................................................................................ 36
2.2.3 TDLOFD-003010 Public Key Infrastructure (PKI) .............................................................................. 38
2.2.4 TDLOFD-003014 Integrated Firewall .................................................................................................. 39
2.2.5 TDLOFD-003015 Access Control based on 802.1x.............................................................................. 41
2.3 Reliability ....................................................................................................................................................... 42
2.3.1 TDLOFD-001018 S1-flex ..................................................................................................................... 42
2.3.2 TDLOFD-003007 Bidirectional Forwarding Detection ........................................................................ 44
2.3.3 TDLOFD-003008 Ethernet Link Aggregation (IEEE 802.3ad) ............................................................ 45
3 O&M .............................................................................................................................................. 47
3.1 SON Self-Optimization .................................................................................................................................. 47
3.1.1 TDLOFD-001032 Intra-LTE Load Balancing ....................................................................................... 47
3.1.2 TDLOFD-001123 Enhanced Intra-LTE Load Balancing ...................................................................... 48
3.1.3 TDLOFD-070215 Intra-LTE User Number Load Balancing ................................................................ 49
3.1.4 TDLOFD-002005 Mobility Robust Optimization (MRO) .................................................................... 50
3.2 SON Self-Healing .......................................................................................................................................... 51
3.2.1 TDLOFD-002011 Antenna Fault Detection .......................................................................................... 51
3.3 Power Saving ................................................................................................................................................. 52
3.3.1 TDLOFD-001039 RF Channel Intelligent Shutdown ........................................................................... 52
3.3.2 TDLOFD-001040 Low Power Consumption Mode.............................................................................. 53
3.3.3 TDLOFD-001041 Power Consumption Monitoring ............................................................................. 53
3.3.4 TDLOFD-001042 Intelligent Power-Off of Carriers in the Same Coverage ........................................ 54
3.3.5 TDLOFD-001056 PSU Intelligent Sleep Mode .................................................................................... 55
3.3.6 TDLOFD-001070 Symbol Power Saving ............................................................................................. 56
3.3.7 TDLOFD-001071 Intelligent Battery Management .............................................................................. 57
3.4 Antenna Management ..................................................................................................................................... 59
3.4.1 TDLOFD-001024 Remote Electrical Tilt Control ................................................................................ 59
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
1
Radio & Performance
1.1 LTE 2 Antenna
1.1.1 TDLOFD-001001 DL 2x2 MIMO
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
Huawei LTE TDD eRAN1.0 supports DL 2x2 multiple-input multiple-output (MIMO),
2-antenna transmit diversity, and adaptive MIMO schemes between UEs and eNodeBs,
improving system downlink performance.
Benefits
This feature significantly improves downlink system throughput and coverage performance and
also provides good user experience by offering higher data rates.
Description
The downlink 2x2 MIMO is critical to the LTE outperforming the legacy system. Both space
diversity and spatial multiplexing are supported as defined in LTE specifications. Huawei
eNodeBs support two DL 2x2 MIMO modes:

Transmit diversity

Open-loop spatial multiplexing
If two transmit antennas are configured for the eNodeB, the eNodeB adaptively selects one of
the two modes based on the UE rate and downlink channel quality.
Transmit diversity is a solution to mitigate signal fading and interference. By providing several
signal branches that present independently varying signal levels, the robustness of the radio link
creates a low probability that all signal copies are simultaneously in deep fading.
Spatial multiplexing is a technique to transmit independent and separately encoded data signals,
known as streams, from each of the transmit antennas that results in the space dimension being
reused, or multiplexed. If the transmitter is equipped with Ntx antennas and the receiver has Nrx
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
antennas, the maximum spatial multiplexing order is Ns = min (Ntx, Nrx). If the spatial channels
are independent of each other (that is, Ns different data streams are transmitted over several
independent spatial channels), it leads to an Ns increase of the spectrum efficiency or capacity.
Enhancement
None
Dependencies
The eNodeB must be configured with two transmit channels and two antennas per sector, and
the UE must be configured with a minimum of two antennas for receiving.
1.1.2 TDLOFD-001030 Support of UE Category 2/3/4
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
An eNodeB must obtain the signaled UE radio access capability parameters when configuring
and scheduling the UE. There are five categories defined in the protocol. When this feature is
enabled, eNodeBs support UE categories 2, 3, and 4.
Benefits
eNodeBs support UE categories 2, 3, and 4.
Description
The following table lists the downlink physical layer parameter values in the ue-Category field.
UE
Category
Maximum Number
of DL-SCH
Transport Block Bits
Received Within a
TTI
Maximum Number of
Bits of a DL-SCH
Transport Block
Received Within a TTI
Total
Number of
Soft
Channel
Bits
Maximum Number
of Supported
Layers for DL
Spatial
Multiplexing
Category 1
10296
10296
250368
1
Category 2
51024
51024
1237248
2
Category 3
102048
75376
1237248
2
Category 4
150752
75376
1827072
2
The following table lists the uplink physical layer parameter values in the ue-Category field.
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
UE Category
Maximum Number of Bits of an UL-SCH
Transport Block Transmitted Within a TTI
Support for UL 64QAM
Category 1
5160
No
Category 2
25456
No
Category 3
51024
No
Category 4
51024
No
The following table lists the total layer-2 buffer sizes in the ue-Category field.
UE Category
Total Layer-2 Buffer Size (Kbytes)
Category 1
150
Category 2
700
Category 3
1400
Category 4
1900
Enhancement
None
Dependencies
UEs must support the same category as eNodeBs.
1.2 LTE 4 Antenna
1.2.1 TDLOFD-001049 Single Streaming Beamforming
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
This feature provides good user experience by offering higher data rates.
Benefits
This feature can significantly improve the system throughput (especially for CEUs) and
coverage performance in the uplink and downlink.
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
Description
The classical technique of using an antenna array for transmitting energy in the direction of the
intended receiver falls into the category of improving SINR. Beamforming achieves increased
SINR by adjusting the phase of signals transmitted on different antennas with the aim of
making the signals add-up constructively on the receiver. Huawei LTE TDD eRAN2.1 provides
support on DL 8x2 and DL 4x2 Beamforming.
Enhancement
None
Dependencies
The eNodeB must be configured with a minimum of four antennas for transmission.
This feature cannot be used in the LampSite solution.
This feature is not applicable to micro eNodeBs
UEs must support transmission mode 7 (TM7) for single streaming beamforming, which is
defined in 3GPP Release 8 specifications.
This feature cannot work when the eNodeB bandwidth is 5 MHz.
This feature cannot be used with the following features:

TDLOFD-001031 Extended CP

TDLOFD-001007 High Speed Mobility

TDLOFD-001008 Ultra High Speed Mobility
.
1.2.2 TDLOFD-001005 UL 4-Antenna Receive Diversity
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
Receive diversity is a common type of multiple-antenna technology to improve signal reception
and to mitigate signal fading and interference. It improves network capacity and data rates. In
addition to UL 2-antenna receive diversity, Huawei eNodeBs also support 4-antenna receive
diversity.
Benefits
This feature improves uplink coverage and throughput.
Description
Receive diversity is a technique to mitigate signal fading and interference. Multiple frequencies
may be monitored from the same signal source or the same frequency may be monitored from
multiple antennas.
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
Receive diversity is a way to enhance uplink channel reception, including the PUSCH, physical
uplink control channel (PUCCH), physical random access channel (PRACH), and sounding
reference signal (SRS).
Huawei eNodeBs can work with or without RX diversity. In RX diversity mode, Huawei
eNodeBs in LTE TDD eRAN2.1 can be configured with 4 antennas (4-way) by setting the
antenna magnitude in addition to UL 2-antenna receive diversity.
Enhancement
None
Dependencies
This feature requires eNodeBs to provide enough RF channels and demodulation resources to
match the number of diversity antennas.
This feature cannot be used in the LampSite solution.
This feature is not applicable to micro eNodeBs
This feature cannot work when the bandwidth of the eNodeB equipped with the LBBPc is 5
MHz.
1.2.3 TDLOFD-001058 UL 2x4 MU-MIMO
Availability
This feature was introduced in LTE TDD eRAN2.2.
Summary
Huawei LTE TDD eRAN2.2 supports UL 2x4 MU-MIMO between UEs and eNodeBs to
improve system uplink performance. A maximum of UEs can share the same time-frequency
resources to multiplex these resources.
Benefits
This feature improves the overall cell uplink throughput by allowing two users to transmit data
using the same time-frequency resources.
Description
If four receive antennas are configured for an eNodeB, the eNodeB adaptively selects between
UL 2x4 MU-MIMO and UL 4-antenna receive diversity.
The eNodeB measures the UE uplink channel SINR and channel orthogonality with another UE.
If the UE has adequate channel quality indicator (CQI) and channel orthogonality with the other
UE, 2x4 MU-MIMO is used. Otherwise, 4-antenna receive diversity is used.
UL 2x4 MU-MIMO is only used for the physical uplink shared channel (PUSCH).
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
Enhancement
In LTE TDD eRAN6.0, UL 2x4 MU-MIMO can be used with uplink-downlink subframe
configuration type 0.
Dependencies
This feature requires an eNodeB to provide four RX channels and four antennas per sector.
This feature cannot be used in the LampSite solution.
This feature is not applicable to micro eNodeBs
This feature is only applicable to Non-GBR bears.
This feature requires the following features:

TDLOFD-001015 Enhanced Scheduling

TDLOFD-001005 UL 4-Antenna Receive Diversity
When the LBBPc is configured, this feature cannot be used with the following features:

TDLOFD-001075 SFN

TDLOFD-002008 Adaptive SFN/SDMA

TDLOFD-001098 Inter-BBP SFN

TDLOFD-001080 Inter-BBU SFN

TDLOFD-001081 Inter-BBP Adaptive SFN/SDMA

TDLOFD-001082 Inter-BBU Adaptive SFN/SDMA
1.5 Interference Handling
1.5.1 TDLOFD-001012 UL Interference Rejection Combining
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
In addition to DL and UL inter-cell interference coordination (ICIC), Huawei LTE TDD
eRAN1.0 provides interference rejection combining (IRC) to effectively mitigate inter-cell
interference.
Benefits
This feature improves system performance in the presence of interference. Therefore, enhanced
network coverage and better service quality are provided for CEUs.
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
Description
IRC is a receive-antenna combining technique to effectively mitigate inter-cell interference.
IRC is often used together with receive diversity. In theory, IRC can be used for MIMO
decoding, and it is particularly effective for colored interference.
The main advantage of IRC is that it can outperform maximum ratio combining (MRC) in terms
of signal demodulation in the presence of interference or congestion.
Enhancement
None
Dependencies
eNodeBs must be configured with two or more receive antennas.
1.5.2 TDLOFD-001094 Control Channel IRC
Availability
This feature is introduced in LTE TDD eRAN6.0.
Summary
This feature prevents the PUCCH from being affected by inter-cell interference.
Benefits
This feature enhances interference resistance for uplink control channels and improves control
channel coverage.
Description
IRC combines signals on the PUCCH received by multiple antennas. Compared with MRC,
IRC performs better on colored interference mitigation.
eNodeBs support adaptive switching between IRC and MRC for PUCCHs. When there is
colored interference, eNodeBs select IRC. In other cases, eNodeBs select MRC.
Enhancement
None
Dependencies
This feature requires one of the following features:

TDLBFD-00202001 UL 2-Antenna Receive Diversity

TDLOFD-001005 UL 4-Antenna Receive Diversity
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description

1 Radio & Performance
TDLOFD-001062 UL 8-Antenna Receive Diversity
eNodeBs must be configured with two or more receive antennas and the LBBPd is required.
1.6 QoS
1.6.1 TDLOFD-001026 Optional uplink-downlink subframe
configuration
TDLOFD-00102601 uplink-downlink subframe configuration type 0
Availability
This feature was introduced in LTE TDD eRAN3.1.
Summary
eNodeBs support different uplink-downlink subframe configurations.
Benefits
This feature allows operators to flexibly configure the uplink-downlink subframe ratio based on
different service requirements.
Description
eNodeBs support different uplink-downlink subframe configurations specified in 3GPP TS
36.211.
Type 0: The ratio of uplink subframe to downlink subframe is 3:1. When this configuration is
used, the throughput of uplink traffic is larger than downlink traffic, such as in video
surveillance.
The following figure shows uplink-downlink subframe configuration type 0.
In the preceding figure, D denotes the subframe reserved for downlink transmissions, U denotes
the subframe reserved for uplink transmissions, and S denotes a special subframe that consists
of the downlink pilot timeslot (DwPTS), guard period (GP), and uplink pilot timeslot (UpPTS).
Enhancement
None
Dependencies
None
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
TDLOFD-00102602 uplink-downlink special subframe configuration type 4
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths).
Benefits
This feature allows operators to flexibly configure special subframe configurations according
to application scenarios, such as a different cell radius.
Description
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths)
specified in 3GPP TS 36.211.
Type 4: The length ratio of DwPTS to GP to UpPTS is 12:1:1 when eNodeBs use normal cyclic
prefix (CP). The length ratio of DwPTS to GP to UpPTS is 3:7:1 when eNodeBs use extended
CP.
The following two tables list special subframe configuration type 4.
Special Subframe
Configuration
Normal CP
DwPTS
GP
UpPTS
4
26336  Ts
2192  Ts
2192  Ts
Special Subframe
Configuration
Extended CP
DwPTS
GP
UpPTS
4
7680  Ts
17920  Ts
2560  Ts
Enhancement
None
Dependencies
None
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
TDLOFD-00102603 uplink-downlink special subframe configuration type 5
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths).
Benefits
This feature allows operators to flexibly configure special subframe configurations according
to application scenarios, such as a different cell radius.
Description
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths)
specified in 3GPP TS 36.211.
Type 5: The length ratio of DwPTS to GP to UpPTS is 3:9:2 when eNodeBs use normal CP. The
length ratio of DwPTS to GP to UpPTS is 8:2:2 when eNodeBs use extended CP.
The following two tables list special subframe configuration type 5.
Special Subframe
Configuration
Normal CP
DwPTS
GP
UpPTS
5
6592  Ts
19744  Ts
4384  Ts
Special Subframe
Configuration
Extended CP
DwPTS
GP
UpPTS
5
20480  Ts
5120  Ts
5120  Ts
Enhancement
None
Dependencies
None
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eLTE2.3 DBS3900 LTE TDD
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TDLOFD-00102604 uplink-downlink special subframe configuration type 6
Availability
This feature was introduced in LTE TDD eRAN6.0.
Summary
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths).
Benefits
This feature allows operators to flexibly configure special subframe configurations according
to application scenarios, such as a different cell radius.
Description
eNodeBs support different special subframe configurations (DwPTS, GP, and UpPTS lengths)
specified in 3GPP TS 36.211.
Type 6: The length ratio of DwPTS to GP to UpPTS is 9:3:2 when eNodeBs adopt normal CP.
The length ratio of DwPTS to GP to UpPTS is 9:1:2 when eNodeBs adopt extended CP.
The following two tables list special subframe configuration type 6.
Special Subframe
Configuration
Normal CP
DwPTS
GP
UpPTS
6
19760 Ts
6576 Ts
4384 Ts
Special Subframe
Configuration
Extended CP
DwPTS
GP
UpPTS
6
23040 Ts
2560 Ts
5120 Ts
Enhancement
None
Dependencies
The RRU3702, RRU3232, and RRU3233 do not support this feature.
This feature does not apply to micro eNodeBs.
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
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1.6.2 TDLOFD-001015 Enhanced Scheduling
TDLOFD-00101501 CQI Adjustment
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature enhances the conventional AMC scheme by introducing downlink CQI adjustment.
It provides additional performance gains.
Benefits
This feature brings the following benefits:

Effectively compensates for inaccurate CQI measurement and makes the modulation and
coding scheme (MCS) selection more accurate by using a closed-loop mechanism.

Improves system capacity by selecting an accurate MCS.

Allows an adaptive CQI measurement in different scenarios and therefore improves
system capacity.
Description
Under the conventional AMC scheme, the eNodeB chooses an MCS for a UE based on the
reported CQI. As a result, the MCS will mainly change according to the reported CQI. However,
the UE measurement error and channel fading affects the accuracy of the reported CQI to some
extent. MCS selection based on an inaccurate CQI will cause a failure to reach the block error
rate (BLER) target in DL transmission. The conventional AMC scheme does not have a
closed-loop feedback mechanism to guarantee that the actual BLER reaches the BLER target.
The CQI adjustment scheme introduces a closed-loop mechanism to compensate for CQI
measurement errors. When an eNodeB selects the MCS for DL transmission, in addition to the
CQI and transmit power, the eNodeB also considers the difference between the target BLER
and the actual BLER. Note that the actual BLER is calculated based on the closed-loop
ACK/NACK that the eNodeB received in DL transmission. In addition, the closed-loop
mechanism used in the CQI adjustment scheme allows the eNodeB to instruct a UE to change
the BLER target for CQI reporting, which can maximize system throughput.
Enhancement
None
Dependencies
None
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eLTE2.3 DBS3900 LTE TDD
Optional Feature Description
1 Radio & Performance
TDLOFD-00101502 Dynamic Scheduling
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature achieves efficient resource utilization. The fairness between different UEs is also
considered in the function. The dynamic scheduling algorithm is mainly used for guaranteed bit
rate (GBR) and non-GBR services.
Benefits
This feature provides the following benefits:

Achieves efficient resource utilization.

Achieves an optimal tradeoff among throughput, fairness, and QoS.
Description
This feature achieves efficient resource utilization on a shared channel. In an LTE system, the
scheduler allocates resources to the UEs every 1 ms or every one TTI. The scheduling
algorithm must achieve a balanced tradeoff between priority differentiation among different
services and fairness among users.
The UL scheduler uses the token bucket algorithm to control GBR and non-GBR service rates.
The proportional fair (PF) algorithm is the basic strategy to ensure scheduling priorities (based
on the QCI) among different services. High priorities are assigned to IMS signaling and GBR
services. When the congestion indicator from the load control algorithm is received, the
scheduler may reduce the guaranteed data rate for GBR services. The scheduler may also
consider the input from UL ICIC to reduce interference. QCI is short for QoS class identifier.
The DL scheduler uses an enhanced scheduling strategy. For GBR services, priorities are
calculated based on user channel quality and service packet delay. For non-GBR services, in
addition to user channel quality, the scheduled service throughput is also considered for
calculating the priority. The enhanced DL scheduler can guarantee an optimal tradeoff among
throughput, fairness, and QoS guarantee. Like the UL scheduler, the DL scheduler also
considers DL ICIC input to reduce inter-cell interference.
Enhancement
In LTE TDD eRAN6.0, when the Uu resources of a cell are congested, there is a possibility that
non-GBR services cannot be granted resources because non-GBR services have a lower priority
than GBR services. To address this issue, this feature allows a preset proportion of resources to
be reserved for non-GBR services, which ensures that there are always resources for downlink
non-GBR services.
Dependencies
None
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1.6.3 TDLOFD-070222 Scheduling Based on Max Bit Rate
Availability
This feature is introduced in eRAN7.0.
Summary
This feature enables eNodeBs to adjust scheduling weights based on aggregate maximum bit
rates (AMBRs) or maximum bit rates (MBRs) so that differentiated services can be provided
for subscribers.
Benefits
Operators can provide differentiated services for subscribers.
Description
For wireless broadband service packages, information about the AMBRs for non-GBR bearers
is stored in the policy and charging rules function (PCRF) or home subscriber server (HSS), and
information about the MBRs of GBR bearers is stored in the PCRF.
When a UE accesses the network, the PCRF or HSS notifies the eNodeB of the AMBR and
MBR configured for the UE. Then, the eNodeB adjusts uplink and downlink scheduling
weights for the UE based on the received AMBR and MBR information. This ensures that the
UEs configured with high AMBRs and MBRs are allocated high bandwidths.
Enhancement
None
Dependencies
None
1.6.4 TDLOFD-001028 TCP Proxy Enhancer (TPE)
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
A series of enhanced Transmission Control Protocol (TCP) functions adaptive to RAN link
characteristics are implemented in the eNodeB. This feature greatly improves the performance
of the TCP protocol (derived from the wired network) in the wireless network, therefore
enhancing user experience and system efficiency.
Benefits
This feature provides the following benefits:
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
Mitigates the negative impact of some factors (such as RAN packet loss) on TCP data
transmission performance.

Accelerates slow startup and fast retransmission of the server during data transmission.

Greatly improves TCP transmission performance.
Description
The Transmission Control Protocol/Internet Protocol (TCP/IP) protocol is used worldwide. It
was initially developed for wired transmission and later used in wireless networks. However,
wireless networks exhibit some characteristics quite different from the wired network. To
mitigate this effect, a number of enhancements have been implemented in the eNodeB.
The TPE functionality, implemented in the eNodeB, improves data transmission performance
in the wireless network. The TPE processes the TCP/IP packets by adopting the following TCP
performance optimization technologies:

ACK splitting
The congestion window is updated according to the number of received ACK messages
and is expanded by increasing the number of ACK messages. When slow startup occurs,
ACK splitting can quickly recover the congestion window. When the sender is in
congestion avoidance mode, ACK splitting can accelerate expansion of the congestion
window.
Enhancement
In LTE TDD eRAN6.0, this feature is enhanced by introducing the uplink ACK control
function to prevent bursts of ACKs.
In an LTE system, fluctuations over the air interface are inevitable. To ensure correct uplink
data transmission, HARQ or automatic repeat request (ARQ) is performed in the uplink to
ensure correct data transmission. According to 3GPP specifications for LTE, packets at the
Radio Link Control (RLC) layer must be transmitted in sequence. However, the HARQ/ARQ
transmission takes at least 8 ms, which may delay the in-sequence transmission of packets. If
the transmission is delayed, the packets to be transmitted are buffered, and then burst. For
downlink TCP services, ACK packets may also burst. As a result, downlink TCP services burst
as well, causing packet loss if the buffer of the transmission equipment is limited.
The ACK control function manages the uplink ACK traffic to prevent bursts of ACKs. If the
number of ACKs exceeds a threshold, the remaining ACKs are buffered for transmission in the
next transmission period. As a result, the ACK control function prevents bursts of downlink
data, reduces the packet loss rate, and increases average throughput.
Dependencies
None
1.6.5 TDLOFD-001027 Active Queue Management (AQM)
Availability
This feature was introduced in LTE TDD eRAN2.0.
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Summary
This feature provides an optimized buffer handling method to positively interact with the TCP
protocol and shorten the buffering delay.
Benefits
This feature decreases the delay of interactive services and improves user experience.
Description
In an interactive connection, the packet data to be transmitted is typically characterized by large
variations. To address this issue, the buffer is introduced. However, if the buffer is filled or an
overflow occurs, data packet loss will result.
Currently, TCP is the main transport layer protocol used on the Internet. Packet loss is regarded
as link congestion by TCP, and TCP will correspondingly reduce the data transmission rate. The
TCP protocol is also sensitive to round trip delay and will act differently if just one packet is lost
or if a burst of packets is lost. If a large number of packets are discarded, it may take
considerable time for the data rate to increase again, leading to low radio link utilization and
causing long delays for users.
In addition, if a user is performing concurrent services (such as FTP download and web
browsing), the file download as a dominant stream fills the buffers, leading to a long delay for
web browsing.
This feature can be disabled or enabled.
Enhancement
None
Dependencies
None
1.6.6 TDLOFD-001029 Enhanced Admission Control
TDLOFD-00102901 Radio/transport Resource Pre-emption
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
This feature enables service differentiation when the network is congested to provide better
services for high-priority users.
Benefits
This feature provides operators with a method to differentiate users according to priorities.
High-priority users can still obtain system resources in cases of resource limitation. In this way,
operators can provide better service to those high-priority users.
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Description
Pre-emption is a function related to admission control and is the method for differentiating
services. It enables operators to provide different services by setting different priorities, which
affect the service setup success rate during the service setup procedure. If there are not enough
resources and a new service is not admitted to access the network, high-priority users have
more chances to access the network than low-priority users, and the resources of low-priority
users are pre-empted.
Priority information is obtained from the E-RAB-specific QoS parameters, including the
allocation/retention priority (ARP), in the ERAB SETUP REQUEST message. The eNodeB
assigns user priority based on ARP values. E-RAB is short for E-UTRAN radio access bearer.
Pre-emption is performed if service admission fails due to lack of resources, including S1
transmission resources and radio resources (for example, admission based on the QoS
satisfaction rate fails). The attributes of Pre-emption Capability and Pre-emption Vulnerability
indicate the capability of pre-empting resources of other services and vulnerability to
pre-emption by other services, respectively.
Pre-emption is not triggered for a signaling radio bearer (SRB) if resource allocation for SRB
fails. Emergency call (for example, E911) service has top priority, and therefore always has
pre-emption capability. In general, common services cannot pre-empt the resources for SRBs,
emergency calls, or IMS signaling.
Enhancement
In LTE TDD eRAN6.0, this feature allows resource pre-emption when the number of UEs that
have accessed cells reaches the maximum number of UEs supported by an eNodeB. With this
enhancement, high-priority services and services that must be guaranteed according to local
laws and regulations can pre-empt the resources of common services.
An eNodeB allows RRC connections to be established for all UEs that initially access the
network. During E-RAB setup, the eNodeB enables high-priority services and emergency calls
to pre-empt the resources of common services. The eNodeB selects high-priority services and
emergency calls based on ARP values, and selects common services, whose resources are to be
pre-empted, in the following sequence: non-GBR services on unsynchronized UEs, non-GBR
services on synchronized UEs, and low-priority GBR services.
Dependencies
This feature requires the core network to bring the ARP IE to eNodeB during E-RAB
assignment procedure so that the eNodeB can obtain service priorities with those E-RAB
parameters.
1.6.7 TDLOFD-001054 Flexible User Steering
TDLOFD-00105401 Camp & Handover Based on SPID
Availability
This feature was introduced in LTE TDD eRAN3.0.
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Summary
This feature helps operators control UE mobility to enable it camp in, be redirected to, or be
handed over to a suitable cell. The priorities for cell selection are predefined and configured on
the eNodeB by using the subscriber profile ID for RAT/frequency priority (SPID).
Benefits
Operators can enable users to camp in, be redirected to, or be handed over to a suitable LTE,
UMTS, or GSM cell or frequency based on service characteristics. For a data centric subscriber,
an LTE cell is more suitable than a UMTS cell or a GSM cell; for a voice centric subscriber, a
GSM cell or a UMTS cell is more suitable than an LTE cell.
Description
The SPID is an index of user information (such as the mobility profile and service usage
profile). The information is UE-specific and applies to all its radio bearers.
The eNodeB maps this index to locally defined configuration to apply specific radio resource
management (RRM) policies (such as defining priorities in RRC_IDLE mode and controlling
inter-RAT or inter-frequency redirection or handover in RRC_CONNECTED mode).
In RRC_IDLE mode, a UE can camp in a cell with a suitable RAT or frequency.
In RRC_CONNECTED mode, when load balance or overload control triggers an
inter-frequency or inter-RAT handover or redirection, the eNodeB selects a suitable target cell
based on the priorities indexed by its SPID. In addition, when the UE completes a service, the
eNodeB can release it to a suitable cell according to its SPID priority. In case of overload, UEs
without SPIDs can also be redirected to a suitable cell based on common priority and overload
information.
Therefore, an operator can enable a user to camp in, be redirected to, or be handed over to a
suitable cell according to its subscription. For example, a dongle user usually stays in an LTE
high frequency band for a high service rate; a VoIP user preferentially stays in an LTE low
frequency band to guarantee continuous coverage.
Enhancement
None
Dependencies
The cell reselection policy for UEs requires TDLBFD-00201803 Cell Selection and
Re-selection.
The load-based handover policy for UEs requires the following features:

TDLOFD-001032 Intra-LTE Load Balancing

TDLOFD-001044 Inter-RAT Load Sharing to UTRAN

TDLOFD-001045 Inter-RAT Load Sharing to GERAN

UE HPLMN switch policy depends on either of the following features:

TDLBFD-00201802 Coverage Based Inter-frequency

TDLOFD-001019 PS Inter-RAT Mobility between E-UTRAN and UTRAN
The SAE must support the SPID configuration.
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The GSM/UMTS network must support this function to prevent ping-pong handovers.
1.6.8 TDLOFD-001059 UL Pre-allocation Based on SPID
Availability
This feature was introduced in LTE TDD eRAN3.0.
Summary
Operators can configure a suitable SPID on the core network for each UE. When a UE accesses
the network, its SPID is transmitted to the eNodeB. Based on the SPID, the eNodeB enables or
disables the UL pre-allocation for the UE.
Benefits
Operators can assign different UL pre-allocation capabilities for different UEs. UL
pre-allocation is used for light-loaded cells to decrease the latency for a certain UE.
Description
The SPID is an index of user information (such as the mobility profile and service usage
profile). The information is UE-specific and applies to all its radio bearers.
The eNodeB maps this index to locally defined configuration to apply specific RRM policies.
The UL pre-allocation functionality allocates PUSCH RBs to a UE in a light-loaded cell even if
the sending buffer of the UE is empty. This feature allows the UE to quickly obtain the
transmission chance and accelerates the ACK of a DL RRC signaling message.
UL pre-allocation decreases UE transmission delay but increases UE power consumption.
Operators can modify related parameters to achieve an optimal tradeoff between transmission
delay and power consumption.
Enhancement
None
Dependencies
The SAE must support the SPID configuration.
1.6.9 TDLOFD-001109 DL Non-GBR Packet Bundling
Availability
This feature is introduced in LTE TDD eRAN6.0.
Summary
This feature introduces delay control and bundles downlink packets before transmission.
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Benefits
This feature provides the following benefits:

Reduces PDCCH overhead and increases PDCCH capacity.

Meets the delay requirements of best effort (BE) services and increases the eNodeB
throughput when both GBR and non-GBR services are in use.
Description
This feature primarily introduces delay control for BE services.
When the network load is light and resources for control and traffic channels are sufficient, the
eNodeB does not perform delay-based downlink packet bundling. If the packet delay increases
with the network load, the eNodeB bundles downlink packets to reduce PDCCH overhead to
improve BE service quality. The eNodeB also increases throughput when users are performing
both GBR and non-GBR services.
Enhancement
None
Dependencies
None
1.6.10 TDLOFD-001076 CPRI Compression
Availability
This feature is introduced in LTE TDD eRAN6.0.
Summary
This feature reduces the common public radio interface (CPRI) bandwidth required by a cell.
Benefits
This feature provides the following benefits:

Increases the number of RRUs that can be cascaded on a CPRI port.

Decreases the number of optical fibers.

Reduces eNodeB installation and reconstruction costs.
Description
This feature decreases CPRI bandwidth resources required by a cell. More RRUs can be
cascaded on a CPRI port without changing the CPRI line rate, cell bandwidth, or number of
antennas for the cell. This reduces eNodeB installation and reconstruction costs.
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When this feature is enabled, the CPRI data on the LBBPd and LBBPc decreases to about 50%
and 60% of the original CPRI data, respectively. The extent of reduction is determined by the
processing capabilities of the two boards.
Enhancement
None
Dependencies
RRU323x and RRU3702 cannot support this feature.
The LBBPc cannot support this feature.
This feature is not applicable to micro eNodeBs
This feature cannot be used with TDLOFD-001031 Extended CP.
This feature cannot work when the eNodeB bandwidth is 5 or 10MHz.
1.7 High Speed Mobility
1.7.1 TDLOFD-001007 High Speed Mobility
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature allows eNodeBs to provide services for UEs moving at up to 208 km/h (Band
38/39/40/41) and 79 km/h (Band 42/43) with good performance. High-speed access is one of
the key features in Huawei SingleRAN LTE solutions to provide high-speed coverage.
Benefits
This feature provides the following benefits:

Allows Huawei LTE systems to provide good coverage for UEs moving at up to 120 km/h.

Provides seamless coverage in a high-speed scenario.
Description
This feature enables Huawei LTE systems to operate and perform well in high-speed scenarios.
When a UE moves at high speeds, the fast fading effect on the LTE system becomes severe. It is
more difficult to achieve the same performance at high-speeds as compared to normal speeds.
Huawei LTE TDD eRAN1.0 supports UE velocity up to 208 km/h (Band 38/39/40/41) and 79
km/h (Band 42/43), which covers most mobility scenarios in urban areas. The eNodeB must
measure the UE mobility speed and refine the channel estimation scheme accordingly. In
addition, the MIMO scheme and resource allocation mechanism are adaptively adjusted by the
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radio resource management (RRM) function to meet high-speed performance requirements.
For example, frequency diversity mode is more suitable than frequency-selective scheduling, as
is transmit diversity rather than spatial multiplexing for a UE at high speeds.
Enhancement
In LTE TDD eRAN6.0, eNodeBs can work in 4T4R mode.
Dependencies
eNodeBs must work in 4T4R or 2T2R mode.
This feature is not applicable to micro eNodeBs
This feature cannot be used with the following features:

TDLOFD-001016 VoIP Semi-persistent Scheduling

TDLOFD-001049 Single Streaming Beamforming

TDLOFD-001061 Dual Streaming Beamforming

TDLOFD-001077 MU-Beamforming
1.7.2 TDLOFD-001008 Ultra High Speed Mobility
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature allows eNodeBs to provide services for UEs moving at up to 450 km/h (Band
38/39/40/41) and 332 km/h (Band 42/43) with good performance. High-speed access is one of
the key features in Huawei SingleRAN LTE solutions to provide high-speed coverage.
Benefits
This feature provides the following benefits:

Allows Huawei LTE systems to operate in any high-speed scenario and provide good
coverage for UEs moving at up to 450 km/h.

Provides seamless coverage in a high-speed scenario.
Description
This feature enables Huawei LTE systems to support UEs with almost any mobility profile at up
to 450 km/h (Band 38/39/40/41) and 332 km/h (Band 42/43) in any scenario and deliver good
performance.
When a UE moves at high speeds, the fast fading effect on the LTE system becomes severe. In
this case, the MIMO scheme and resource allocation mechanism are adaptively adjusted to
meet ultra-high-speed performance requirements.
Enhancement
In LTE TDD eRAN6.0, eNodeBs can work in 4T4R mode.
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Dependencies
eNodeBs must work in 4T4R or 2T2R mode.
This feature is not applicable to micro eNodeBs
This feature cannot be used with the following features:

TDLOFD-001016 VoIP Semi-persistent Scheduling

TDLOFD-001049 Single Streaming Beamforming

TDLOFD-001061 Dual Streaming Beamforming

TDLOFD-001077 MU-Beamforming
This feature cannot work when the eNodeB bandwidth is 5 MHz.
The LBBPc cannot support this feature.
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2
2 Networking & Transmission & Security
Networking & Transmission & Security
2.1 Transmission & Synchronization
2.1.1 TDLOFD-003011 Enhanced Transmission QoS Management
TDLOFD-00301101 Transport Overbooking
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature allows the admission of more users while guaranteeing QoS by using the following
mechanisms:

Enhanced admission control mechanism: Transport Admission Control (TAC).

QoS mechanisms: traffic shaping and congestion control.
Benefits
This feature increases the number of admitted users.
Description
The implementation of this feature requires the following mechanisms:

TAC: Allows the bandwidth for user admission control to be larger than the bandwidth of
the physical port. By using this mechanism, operators can set the admission threshold to
allow the admission of more users.

Traffic shaping: Guarantees that the total available traffic bandwidth is not larger than the
total configured bandwidth. The minimum transmission bandwidth of each resource group
supported by eNodeB is 64 kbit/s for dual rate and 32 kbit/s for single rate. The bandwidth
granularity is 1 kbit/s.

Congestion control: Detects congestion. If congestion is detected, a signal is sent to the
data source indicating congestion and then selected low-priority packets are discarded.
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Enhancement
None
Dependencies
The core network must support this feature because SAE uses the TAC over the S1 interface.
TDLOFD-00301102 Transport Differentiated Flow Control
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature enhances the following mechanisms:

Admission control: TAC.

Queue scheduling: priority queue (PQ) scheduling and WRR scheduling.

Back-pressure flow control.
Benefits
This feature provides users with differentiated services while guaranteeing equitable
distribution of bandwidth.
Description
Transmission differentiated flow control provides users with differentiated services while
guaranteeing equitable distribution of bandwidth.

Equitable distribution of bandwidth: Each admitted user can be allocated some bandwidth.

Differentiation: High-priority users take precedence over low-priority users.
The implementation of this feature requires the following mechanisms:

TAC: In case of GBR services, the bandwidth allocated to services is computed based on
the GBR. Otherwise, it is computed based on the default reserved bandwidth (for example,
non-GBR services).

Queue scheduling: Services enter PQ and WRR queues based on service priorities.
Services that enter the PQ queues have the highest scheduling priority, and services that
enter the WRR queues are scheduled according to the weight, which is computed based on
the service bandwidth. Each service has a weight and then an opportunity to be scheduled.

Back-pressure flow control: Detects congestion on the S1 interface. If congestion is
detected, a signal is sent to the data source indicating congestion and then selected
low-priority packets are discarded.
Enhancement
None
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Dependencies
None
TDLOFD-00301103 Transport Resource Overload Control
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature rapidly enhances transmission stability when transmission resources are
unexpectedly overloaded.
Benefits
This feature provides protection for the system when transmission resources are unexpectedly
overloaded.
Description
There are two scenarios of unexpected overload:

The transport bearer bandwidth (the bandwidth available in the system) is greatly
increased or decreased. For example, the transmission bandwidth decreases from 20
Mbit/s to 10 Mbit/s because of network failure.

The traffic bandwidth (the bandwidth used in the system) is greatly increased or decreased.
For example, the traffic bandwidth rapidly increases from 5 Mb/s to 10 Mb/s.
In either of the preceding scenarios, actions such as releasing low-priority users must be taken
to guarantee QoS for high-priority users.
The actions to be taken depend on the ARP, which defines whether a user can be released when
transmission resources are overloaded.
Enhancement
None
Dependencies
None
2.1.2 TDLOFD-003018 IP Active Performance Measurement
Availability
This feature is introduced in LTE TDD eRAN6.1.
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Summary
The IP active performance measurement feature complies with the IETF IP PM standards,
RFC2678, RFC2680, RFC2681, RFC3393, and the Two-Way Active Measurement Protocol
(TWAMP) in RFC5357.
IP transmission performance can be detected between an eNodeB and a device that complies
with RFC5357 (TWAMP), for example, between an eNodeB and a CN, between an eNodeB
and a transmission device (for example, a router), and between an eNodeB and a test device.
This feature implements the following functions:

Network performance monitoring
When the transmission rate is unstable and the transmission bandwidth dynamically
changes, this function can detect the transport network's quality of service (QoS) so
operators can quickly locate network problems and take corrective measures, such as
capacity expansion and network optimization.

Transmission fault diagnosis
−
Quickly locates and isolates transmission faults, such as a high packet loss rate or a
long delay, using TWAMP.
−
Troubleshoots a transport network on a per segment basis by measuring round-trip
network performance between an eNodeB and a transmission device (such as an
intermediate router that supports TWAMP), therefore facilitating network
maintainability and reducing maintenance costs.
TWAMP testing uses User Datagram Protocol (UDP) packet injection, which
generates traffic on the transport network and therefore occupies some bandwidth. For
example, if 80-byte packets are continuously sent at a rate of 10 packets per second in a
test stream, the bandwidth consumption is 6.4 kbit/s.
Benefits
This feature offers the following benefits:

Helps operators quickly locate and rectify faults on networks.

Facilitates network maintainability and reduces maintenance costs.
Description
Based on the TWAMP protocol, this feature monitors the QoS of the transport network, such as
the packet loss rate, round-trip delay, and jitter.
The TWAMP architecture is composed of four logical parts: Session-Sender, Session-Reflector,
Control-Client, and Server.
TWAMP measurement includes testing and negotiation.

Testing is conducted between the Session-Sender and Session-Reflector based on the UDP
protocol. The Session-Sender and Session-Reflector function as TWAMP test hosts and
exchange UDP packets for testing. The Session-Sender sends test packets to the
Session-Reflector and the Session-Reflector responds to the test packets.

Negotiation is conducted between the Control-Client and Server using Transmission
Control Protocol (TCP) packets on port 862. The Control-Client and Server exchange TCP
packets to manage measurement tasks, for example, to initialize, start, and stop the tasks.
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The Session-Sender actively inserts test packets for the Session-Reflector's response. The
inserted test packets contain the same Session-Sender IP address, Session-Reflector IP address,
UDP port number, and Type-P, and are transmitted in a fixed stream. The Type-P descriptor can
be the protocol type, port number, packet length, or DSCP value.
TWAMP actively inserts test packets on test links and calculates the packet loss rate, delay, and
delay variation, and round-trip delay based on fields contained in the test packets. The
Session-Sender and Session-Reflector exchange test packets as follows:
1.
The Session-Sender includes sequence numbers and timestamp T1 in the test packets and
sends them to the Session-Reflector.
2.
The Session-Reflector records timestamp T2 upon receiving the test packets from the
Session-Sender. The Session-Reflector copies the packet sequence numbers and
timestamp T1 extracted from the received packets into the corresponding reflected packets,
which are then sent to the Session-Sender. The corresponding reflected packets also
include the Session-Reflector's transmit sequence numbers and timestamp T3.
3.
The Session-Sender records timestamp T4 upon receiving the response packets from the
Session-Reflector and then calculates the number of received packets
This feature supports unauthenticated mode, authenticated mode, or encrypted mode.
T1
Sender
Test Packets
T2
Reflector
Test Packets
T4
T3
This feature uses the following formulas to calculate the packet loss rate and the round-trip
delay:

Packet loss rate in a measurement period = Number of lost packets/Number of transmitted
packets
The number of lost packets is calculated based on the numbers of packets transmitted and
received by the Session-Sender and those transmitted by the Session-Reflector.

Round-trip delay = (T2 - T1) + (T4 - T3) = (T4 - T1) - (T3 - T2)
This feature calculates the packet delay variation based on the delays of two adjacent packets.
Enhancement
None
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Dependencies
This feature does not apply to micro eNodeBs.
This feature requires the UMPT.
The peer devices and CN must support the TWAMP protocol.
2.1.3 TDLOFD-001134 Virtual Routing & Forwarding
Availability
This feature is introduced in LTE TDD eRAN6.0.
Summary
This feature allows eNodeBs to connect to different operator networks that may be configured
with the same internal IP addresses.
Benefits
This feature greatly reduces the capital expenditure (CAPEX) and OPEX of operators.
Description
In a wholesale scenario, an eNodeB connects to each retailer's network, for which the retailer
operator has deployed the NEs and independently planned internal IP addresses.
When different operator networks are configured with the same internal IP address, this feature
allows an eNodeB to connect to the networks. The eNodeB prevents the destination IP address
of each route from conflicting with others and independently forwards packets in each routing
area. In this way, this feature prevents IP address conflicts between networks without changing
the internal IP addresses.
Enhancement
None
Dependencies
This feature is not applicable to micro eNodeBs
The EPC and transmission network must support virtual local area networks (VLANs).
This feature cannot support the UTRPc.
This feature cannot be used with the following features:

TDLOFD-003004 Ethernet OAM

TDLOFD-003005 OM Channel Backup

TDLOFD-003006 IP Route Backup

TDLOFD-003009 IPsec

TDLOFD-003010 Public Key Infrastructure (PKI)
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
TDLOFD-003012 IP Performance Monitoring

TDLOFD-00301302 IEEE1588 V2 Clock Synchronization

TDLOFD-003017 S1 and X2 over IPv6

TDLOFD-003019 IPsec Tunnel Backup

TDLOFD-003024 IPsec for IPv6
2.2 Security
2.2.1 TDLOFD-001010 Security Mechanism
TDLOFD-00101001 Encryption: AES
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature provides confidentiality protection for both signaling and user data between
eNodeBs and UEs.
Benefits
This feature prevents signaling data and user data from being illegally intercepted and
modified.
Description
The eNodeB provides encryption for RRC signaling and user data. The encryption function
consists of ciphering and deciphering and is performed at the Packet Data Convergence
Protocol (PDCP) layer. After receiving the UE context from the EPC, the eNodeB initiates the
initial security activation procedure. During RRC connection setup, an encryption algorithm is
selected and an encryption key is generated based on the RRC protocol. All radio bearers use
the encryption algorithm and key. For example, the configuration is used for the radio bearers
carrying signaling data as well as for those carrying user data.
The encryption algorithm can be changed by a handover. The encryption key can be changed by
a handover or RRC connection setup. The encryption keys for a UE in RRC_CONNECTED
mode may be changed by a handover procedure.
LTE TDD eRAN1.0 supports the AES encryption algorithm.
Enhancement
None
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Dependencies
UEs must support the same encryption algorithm as the eNodeB.
TDLOFD-00101002 Encryption: SNOW 3G
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature provides confidentiality protection for both signaling and user data between
eNodeBs and UEs.
Benefits
This feature prevents signaling data and user data from being illegally intercepted and
modified.
Description
The eNodeB provides encryption for RRC signaling and user data. The encryption function
consists of ciphering and deciphering and is performed at the PDCP layer. After receiving the
UE context from the EPC, the eNodeB initiates the initial security activation procedure. During
RRC connection setup, an encryption algorithm is selected and an encryption key is generated
based on the RRC protocol. All radio bearers use the encryption algorithm and key. For
example, the configuration is used for the radio bearers carrying signaling data as well as for
those carrying user data.
The encryption algorithm can be changed by a handover. The encryption key can be changed by
a handover or RRC connection setup. The encryption keys for a UE in RRC_CONNECTED
mode may be changed by a handover procedure.
LTE TDD eRAN1.1 supports the encryption algorithm SNOW3G with 128 bit keys.
Enhancement
None
Dependencies
UEs must support the same encryption algorithm as the eNodeB.
2.2.2 TDLOFD-003009 IPsec
Availability
This feature was introduced in LTE TDD eRAN1.0.
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Summary
IPsec is used to protect, authenticate, and encrypt data flow for necessary security between two
NEs at the IP layer.
Benefits
This feature provides the security mechanism, confidentiality, integrity, and authentication
between two NEs at the IP layer.
Description
Figure 2-1 illustrates IPsec.
Figure 2-1 IPsec
IPsec provides a framework of open standards dealing with data confidentiality, integrity, and
authentication between two NEs. IPsec provides these security services at the IP layer. It uses
IKEV1 and IKEV2 for negotiation of protocols and algorithms based on the local policy and to
generate the encryption and authentication keys used by IPsec. IKE stands for Internet Key
Exchange.
IPsec protects one or more data flows between two eNodeBs, between the eNodeB and S-GW
or MME, or between the SeGW and eNodeB.
The key characteristics of IPsec are as follows:

Two encapsulation modes: transport mode and channel mode

Two security protocols: AH and ESP

Main encryption methods: NULL, DES, 3DES, and AES

Main integrity protection methods: HMAC_SHA-1 and HMAC_MD5
Enhancement
None
Dependencies
The SeGW must be deployed.
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2.2.3 TDLOFD-003010 Public Key Infrastructure (PKI)
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
PKI provides digital certificate authentication, which is applied to IPsec tunnels between the
eNodeB and SeGW, and SSL channels between the eNodeB and OMC.
Benefits
This feature improves network security.
Description
PKI is a framework to manage digital certificates, which are used to provide authentication
between two NEs.
Digital certificate management involves creating, storing, distributing, and revoking
certificates, and distributing the certificate revocation list (CRL).
In general, a PKI system includes the Certificate Authority (CA), Certificate Repository (CR),
CRL server, and users to be authenticated. The eNodeB and SeGW are users of the PKI system.
The eNodeB interacts with the CA, CR and CRL server with assistance from the M2000.
The eNodeB supports the certificate reserved prior to delivery. The certificate format complies
with X.509 V3. After the eNodeB is working properly, it supports certificate replacement.
Figure 2-2 shows an illustration of the eRAN certificate application scenario.
Figure 2-2 eRAN certificate application scenario
In LTE TDD eRAN2.0, the eNodeB can update digital certificates automatically on the M2000.
In LTE TDD eRAN2.1, this feature is enhanced to support automatic certificate distribution
using CMPv2. When CMPv2 is introduced to establish a direct tunnel from the eNodeB to the
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CA, certificate enrollment and update can be automatically performed, and eNodeB certificate
issuing and update are more efficient if a large number of eNodeBs have been deployed.
The Certificate Management Protocol (CMP) is an Internet protocol used for X.509 digital
certificate creation and management in PKI.
An eNodeB can utilize CMP to obtain certificates from the CA. This procedure involves the
following CMP message:
1.
initial registration/certification
2.
key pair update
3.
certificate update
The CMP message cross-certification request helps a CA to obtain a certificate signed by
another CA.
CMP messages are encapsulated in HTTP/HTTPs messages for transmission.
Enhancement
None
Dependencies
Peer devices must support this feature.
2.2.4 TDLOFD-003014 Integrated Firewall
TDLOFD-00301401 Access Control List (ACL)
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
ACL is comprised of a series of access control rules. eNodeBs perform packet filtering based on
the ACL.
Benefits
This feature provides the following benefits:

Helps protect eNodeBs from some attacks.

Helps eNodeBs identify specific types of packets, which must be encrypted and
authenticated by IPsec.
Description
The system operates based on the rules in ACL.
By using the ACL, an eNodeB performs packet filtering according to packet attributes such as
source IP addresses, destination IP addresses, source port numbers and destination port
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numbers. Packet filtering can also be performed based on the type of service (TOS), DSCP, and
address wildcard.
By using the ACL, operators can select data flows that must be encrypted and authenticated by
IPsec, which is applied to guarantee data flow security.
In eRAN3.0, the layer-2 filter implements ACL. At layer 2, ACL rules will filter packages by
VLAN IDs. The eNodeB can identify the VLAN IDs of the packages, and only packages with
the correct VLAN ID will be allowed.
In eRAN3.0, eNodeBs support IPsec for IPv6 on the data flows selected based on the ACL.
Enhancement
None
Dependencies
None
TDLOFD-00301402 Access Control List (ACL) Auto Configuration
Availability
This feature is introduced in LTE TDD eRAN7.0.
Summary
This feature automatically creates access control list (ACL) rules for operation and
maintenance (O&M) data, service data, signaling data, data from the Certificate Authority (CA),
data from the security gateway (SeGW), and clock data. The automatic ACL rule creation
simplifies whitelist configuration for the packet filtering function.
Benefits
This feature reduces the complexity of configuring the packet filtering function.
Description
This feature works as follows:
Enables the eNodeB to obtain the IP address and port number of the peer NE from the O&M
link, service link, signaling link, CA, SeGW, and clock objects. Using the IP address and port
number, this feature automatically creates ACL rules for the data of these objects. These
automatically created ACL rules can ensure that the eNodeB provides basic services.
Updates related ACL rules when information about these objects changes.
When an O&M function is enabled at the peer end, not at the local end, the eNodeB cannot
obtain the IP address of a maintenance packet. To ensure information security, ACL rules for
maintenance data must be manually created, even if an O&M function is enabled at both ends.
Enhancement
None
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Dependencies
Dependency on the hardware of a base station controller
None
Dependency on eNodeB hardware
None
Dependency on the UE
None
Dependency on other NEs
None
Dependency on the CN
None
Dependency on other eRAN features
None
2.2.5 TDLOFD-003015 Access Control based on 802.1x
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
eNodeBs support authentication on the transmission network using IEEE 802.1x (Port-Based
Network Access Control). Authentication is performed based on the device certificate.
Benefits
This feature provides digital certificate authentication between the eNodeB and LAN switch,
improving network security.
Description
IEEE 802.1x (Port-Based Network Access Control) uses the physical access characteristics of
IEEE 802 LAN infrastructures to provide a method of authenticating and authorizing devices
attached to a LAN port that has point-to-point connection characteristics. IEEE 802.1x also
prevents access to that port if the authentication and authorization process fails.
IEEE802.1x authentication and authorization use the framework of Extensible Authentication
Protocol (EAP), and are performed for the eNodeB, LAN switch, and AAA server (RADIUS
server).
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Figure 2-3 eRAN 802.1x application scenario
Before the authentication and authorization process is complete, only Extensible
Authentication Protocol over LAN (EAPoL) packets can cross the LAN switch. All other
packets will be discarded by the LAN switch.
Enhancement
None
Dependencies
Peer devices must support IEEE 802.1x.
This feature requires TDLOFD-003010 Public Key Infrastructure (PKI).
2.3 Reliability
2.3.1 TDLOFD-001018 S1-flex
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
This feature is part of the MME pool solution, which must be supported by both the eNodeB
and the MME. It allows an eNodeB to connect to multiple MMEs simultaneously.
In LTE TDD eRAN2.0, Huawei eNodeBs support a maximum of 16 S1 interfaces. One S1
interface can be connected to one or more MMEs.
Benefits
This feature provides the following benefits:

Increased S1 interface flexibility.

Increases overall usage of the MME pool capacity.

Improves the performance of load sharing across MMEs in a pool.

Prevents unnecessary EPC signaling when the UE moves within the MME pool area. The
served MME of the UE does not change.
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Description
Figure 2-4 illustrates the topology between MME pools and eNodeBs.
Figure 2-4 Topology between MME pools and eNodeBs
POOL1
MME 1
eNB 1
MME 2
eNB 2
POOL2
MME 3
eNB 3
MME 4
eNB 4
POOL Area 1
MME 5
eNB 5
eNB 6
POOL Area 2
When an eNodeB connects to an MME pool, the eNodeB must determine which MME in the
pool will receive UE signaling:

If the UE sends the MME information in an RRC signaling message, the eNodeB will
select the MME based on this information.

If the UE does not send the MME information or the registered MME is not connected to
the eNodeB, the eNodeB will select an MME in one of the following ways:
−
Topology-based MME pool selection
The MME is selected based on the network topology to reduce the possibility of MME
switching during mobility.
−
Load-based MME selection
The MME is selected based on its capacity and load. The eNodeB can be informed of
MME capacity during S1 setup. When an MME is overloaded, the eNodeB will limit
new UE assignments to the MME according to overload action information, which the
MME sends to the eNodeB when overload starts.
Enhancement
In LTE TDD eRAN6.0, the priority-based MME selection method is added. When MMEs or the
S1 interfaces to MMEs are assigned different priorities, the MME with the highest priority is
preferentially selected. If multiple MMEs have the highest priority, the MME with the lowest
load among them is preferentially selected. An MME with a low priority is selected only when
all high-priority MMEs are faulty or overloaded.
Dependencies
The MME must support the MME pool function.
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2.3.2 TDLOFD-003007 Bidirectional Forwarding Detection
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
BFD (BFD) is a bidirectional-detecting mechanism used to detect faults on IP routes.
Benefits
This feature provides the following benefits:

Detects network faults.

Achieves reliability and high availability of Ethernet services and helps the service
provider to provide economical and efficient advanced Ethernet services.
Description
BFD is a method for IP connectivity failure detection that periodically transmits BFD packets
between two nodes. When no BFD packets are received during the detection interval, failure is
declared and related recovery actions will be triggered, such as IP routes, to prevent service
drops. BFD can quickly detect the failure, making it useful for telecom services on IP networks.
eNodeBs support two BFD types:

One-hop BFD
There is only one router on the IP path between two NEs.
One-hop BFD is used to detect gateway availability when a router is used.

Multi-hop BFD
There is at least one router on the IP path between two NEs.
Multi-hop BFD is used to detect the connectivity between two NEs, for example, between
two eNodeBs, between the eNodeB and S-GW or MME, and between the eNodeB and
transport equipment.
Figure 2-5 illustrates one-hop and multi-hop BFD application scenarios.
Figure 2-5 One-hop and multi-hop BFD application scenarios
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Enhancement
None
Dependencies
Peer devices must support BFD when BFD is used to detect faults on IP routes.
Ethernet interfaces are used.
2.3.3 TDLOFD-003008 Ethernet Link Aggregation (IEEE 802.3ad)
Availability
This feature was introduced in LTE TDD eRAN2.0.
Summary
This feature binds several Ethernet links to one logical link.
Benefits
This feature provides the following benefits:

Enhances the reliability of Ethernet links between eNodeBs and transport equipment.

Balances load on Ethernet links between the eNodeB and transport equipment and
increases the link bandwidth.
Description
Ethernet link aggregation is a protocol defined in IEEE 802.3ad.
IEEE 802.3ad defines the link aggregation control protocol (LACP) used to detect link status in
a link group.
The eNodeB supports static LACP, with parameters of a link group configured manually. Fault
detecting also uses the LACP.
Figure 2-6 illustrates Ethernet link aggregation.
Figure 2-6 Ethernet link aggregation
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Enhancement
None
Dependencies
This feature is not applicable to micro eNodeBs
The transport equipment directly connected to eNodeBs must support this feature.
Ethernet interfaces are used.
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3 O&M
3
O&M
3.1 SON Self-Optimization
3.1.1 TDLOFD-001032 Intra-LTE Load Balancing
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
This feature balances load between the serving cell and the inter-frequency neighboring cells.
Benefits
This feature provides the following benefits:

Utilizes the network resource efficiently.

Improves system capacity.

Reduces the possibility of system overload.

Improves the access success rate.
Description
In a commercial LTE network, some serving cells have high load but the load of neighboring
cells is low because of service differentiation. To resolve this problem, the eNodeB uses the
load balancing algorithm.
The serving cell measures the cell load and receives the neighboring cell load at the same time.
The serving cell evaluates the load and determines whether to perform a handover to a
neighboring cell.
If the serving cell load is very high and exceeds a specific threshold but the neighboring cell
load is low, some UEs are handed over to neighboring cells in advance.
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The cell load is defined as the PRB utilization rate. For details, see 3GPP TS 36.314.
There is only one type of inter-frequency load balancing: active load balancing. The active load
balancing procedure includes the following steps: load measurement and evaluation, load
information exchanges, and load balance decision.
In an LTE system, load balancing applies when coverage is overlapped by multiple
inter-frequency LTE cells.
Enhancement
In LTE TDD eRAN6.0, eNodeBs dynamically balance load between sectors based on the load
difference between these sectors. The load difference can be configured.
Dependencies
None.
3.1.2 TDLOFD-001123 Enhanced Intra-LTE Load Balancing
Availability
This feature was introduced in LTE TDD eRAN6.1.
Summary
It can resolve the unbalance between the service cell and the inter-frequency neighbor cells in
the same eNodeB.
Benefits
It can utilize the network resource fully and improve the UE throughput by balancing the load
between the neighbor cells.
Description
In some situation of commercial LTE network, UEs in some serving cells have poor throughput
but other UEs in neighbor cells have high throughput because of the differentiation of UE
Number in cell. Under this condition, it can trigger enhanced load balancing algorithm.
The serving cell measures the cell Ue Number and receives the neighboring cell's Ue number at
the same time. The serving cell evaluates the Ue number difference and decides whether to
perform a handover to neighboring cell. If the serving cell Ue number is higher than the
neighboring cell's Ue number, some UEs begin to be handed over to neighboring cell in
advance.
Selecting proper UE to handover, the overlap range difference of serving cell and neighboring
cell is considering, it is prior to selecting central UE to handover to small range neighbor cell,
and it is prior to selecting marginal UE to handover to big range neighbor cell.
The load balancing procedure includes the following steps: load measurement and evaluation,
load information exchanges, load balance decision, exection of measurement and handover.
Enhanced Intra-LTE load balancing is used in the scenario of coverage overlapped between
multiple multiple inter-frequency LTE cells.
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Enhancement
None.
Dependencies
The serving cell and inter-frequency cell must deployed in the same eNodeB for enhanced load
balancing.
3.1.3 TDLOFD-070215 Intra-LTE User Number Load Balancing
Availability
This feature is introduced in LTE TDD eRAN7.0
Summary
This feature resolves user number load imbalances between cells and frequencies.
Benefits
This feature achieves better utilization of network resources and balance user number to reduce
the probability of burst traffic.
Description
Intra-LTE User Number Load Balancing contains connected mode and idle mode .It is
recommended in commercial LTE networks with multiple LTE frequencies where one
frequency has a higher user number but other frequencies have lower user number.
For connected mode, serving cell measures its own cell user number, if the number exceeds a
preset threshold, the serving cell will send handover request to the neighboring cells which shall
acknowledge or reject handover judged by their own user number load.
For idle mode, users in normal RRC release procedure can be released to different frequency on
configured proportion, by using Dedicated Priority within RRC Connection Release message.
This function can precisely distribute idle users to different frequency as operators wish.
Especially, if we set the proportion of micro frequency to 100% highest priority, idle users in
micro coverage will only camp on micro’s frequency, which is called Fast Discovery of Micro,
it is quite meaningful to the scenario of absorbing users and traffic volume by micro site.
Intra-LTE User Number Load Balancing is used in scenarios where inter-frequency LTE cells
have highly overlapping coverage.
Enhancement
None
Dependency
An X2 interface is required to support for connected mode in this feature.
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3.1.4 TDLOFD-002005 Mobility Robust Optimization (MRO)
Availability
This feature was introduced in LTE TDD eRAN3.0.
Summary
MRO optimizes typical mobility control parameter settings to prevent ping-pong handovers,
premature handovers, and delayed handovers.
Benefits
This feature simplifies network maintenance and reduces labor cost in typical and common
mobility optimization scenarios.
Description
During MRO, the cell individual offset (CIO) mainly needs to be adjusted.
The CIO explicitly declares the handover threshold between signal quality measurement results
from the source and target cells. Therefore, adjusting the CIO will significantly speed up or
delay handovers.
Both premature and delayed handovers are captured at the source eNodeB because the source
eNodeB is informed of delayed handovers that have been prepared by the UE context release
mechanism. Only outgoing handover failures are captured. There is no need to capture
incoming handovers.
During handover preparation, the source eNodeB sends UE history information to the target
eNodeB, which helps to reduce ping-pong handovers. When the UE History Information is
received, the target eNodeB identifies the ping-pong handover if the GCI of the second newest
cell is equal to that of the target cell and the duration that the UE camps in the source cell is
shorter than a ping-pong time threshold. To prevent ping-pong handover, decrease the CIO
value.
Huawei LTE TDD eNodeBs support intra-frequency Mobility Robust Optimization.
The following administration functions are also supported:

Switch: Provided to enable or disable the MRO feature.

Log: records the key event during the SON process. Operators can use log information to
perform queries, collect statistics, and analyze the feature running process and key event.
Enhancement
In LTE TDD eRAN6.0, UE-level MRO against ping-pong handovers is introduced. The
eNodeB identifies ping-pong UEs and sends corresponding UE-level MRO parameters to these
UEs. This type of MRO reduces the number of ping-pong handovers, reduces UE resource
usage, and improves UE quality of experience (QoE).
The UE-level MRO algorithm is independent of the cell-level MRO algorithm. They are
controlled by different switches.
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Dependencies
None
3.2 SON Self-Healing
3.2.1 TDLOFD-002011 Antenna Fault Detection
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
Antenna system and radio frequency (RF) channel faults are caused by the following:

Incorrect project installation during creation, relocation, or optimization.

Natural or external changes.
This feature detects faults on LTE antennas and allows users to detect and locate antenna faults.
In addition, this feature does not require additional instruments for measuring eNodeBs at the
site.
Benefits
This feature improves the efficiency and accuracy of fault diagnosis and reduces project cost.
Description
The antenna system plays an important role in mobile communications. The performance of the
entire network is affected by the following problems:

Inappropriate type or location of the antenna system

Incorrectly configured parameters of the antenna system

Faulty antenna system
This feature allows eNodeBs to detect the following faults and report related alarms:

Weak received signal

Imbalance of received signals between the main and the diversity

Abnormal voltage standing wave ratio (VSWR)
Enhancement
None
Dependencies
None
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3.3 Power Saving
3.3.1 TDLOFD-001039 RF Channel Intelligent Shutdown
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
In MIMO mode, the carrier for a cell is transferred through different transmission channels.
When no data is transmitted in the cell, the carrier can be switched off on part of the
transmission channels. In this way, the power consumption of the eNodeB without data
transmission is decreased. When data is to be transmitted in the cell, the carrier can be switched
on automatically to have the cell work normally again.
Benefits
This feature reduces eNodeB power consumption.
Description
In the LTE system, an eNodeB is usually configured with two or four antennas. The traffic in
the cell varies by time and operators can customize periods accordingly. In certain periods, for
example, from midnight to the early morning hours, no data is transmitted. When the eNodeB
detects an idle state, it switches off the carrier on one transmission channel (if there are two
transmission channels) or on two transmission channels (if there are four transmission channels)
to decrease power consumption. When a UE accesses the cell or the period ends, the eNodeB
can automatically switch on the carrier that has been switched off. The cell then recovers and
continues with services.
Enhancement
None
Dependencies
This feature requires the following features:

TDLOFD-001001 DL 2x2 MIMO

OSS feature WOFD-200200 Base Station Power-Saving Management -LTE
This feature cannot work when the eNodeB bandwidth is 5 MHz.
This feature cannot be used with the following features:

TDLOFD-001075 SFN

TDLOFD-002008 Adaptive SFN/SDMA

TDLOFD-001098 Inter-BBP SFN

TDLOFD-001080 Inter-BBU SFN

TDLOFD-001081 Inter-BBP Adaptive SFN/SDMA

TDLOFD-001082 Inter-BBU Adaptive SFN/SDMA
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3.3.2 TDLOFD-001040 Low Power Consumption Mode
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
In some scenarios, such as a power outage, an eNodeB can be instructed to work in low power
consumption mode. This mode can help prolong the in-service time of an eNodeB powered by
battery.
Benefits
When an eNodeB is derated, its power consumption is reduced and its in-service time powered
by battery is prolonged. Therefore, the possibility of the eNodeB being out of service is reduced
even during periods of extended power outages.
Description
Low power consumption mode is implemented in four levels. If the power supply has not
recovered to its normal state and the power consumption of a level reaches the time threshold
preset by the operator, the eNodeB enters the low power consumption mode of the next level
until the cell is out of service.
Low power consumption mode of the eNodeB is triggered by one of the following conditions:

Power system alarms
If the power insufficiency or power failure lasts for the period preset by the operator, an
alarm is reported to trigger low power consumption mode of the eNodeB.

Command delivered by the EMS
The operator can deliver a command through the EMS to instruct the eNodeB to enter or
exit low power consumption mode.
Enhancement
None
Dependencies
This feature is not applicable to micro eNodeBs
This feature requires the OSS feature WOFD-200200 Base Station Power-Saving Management
-LTE.
3.3.3 TDLOFD-001041 Power Consumption Monitoring
Availability
This feature was introduced in LTE TDD eRAN2.1.
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Summary
eNodeBs report the power consumption status to the EMS. On the EMS, operators can monitor
the change in eNodeB power consumption and generate a power consumption report.
Benefits
This feature allows operators to determine the exact benefits brought by the decrease in power
consumption.
Description
The eNodeB periodically checks the power of each monitoring point and reports the power
consumption within a period. The EMS receives and collects all power consumption data. On
the EMS, the operator can monitor the change in power consumption and analyze power
consumption according to a statistics report generated by the EMS.
Enhancement
None
Dependencies
This feature requires the OSS feature WOFD-200200 Base Station Power-Saving Management
-LTE.
RRU3702 cannot support this feature.
This feature is not applicable to micro eNodeBs
3.3.4 TDLOFD-001042 Intelligent Power-Off of Carriers in the
Same Coverage
Availability
This feature was introduced in LTE TDD eRAN2.1.
Summary
When traffic is light in an area covered by multiple carriers, some of the carriers can be blocked,
and all services can be automatically taken over by the carriers that remain in service. When the
traffic increases to a certain degree, the carriers that have been blocked can be automatically
unblocked to again provide services.
Benefits
This feature helps reduce eNodeB power consumption without any impact on service quality.
Description
When multiple carriers provide coverage for the same area, the traffic in the area varies by time
and operators can customize periods accordingly. In certain periods, for example, from
midnight to the early morning hours, the traffic is light. When the eNodeB detects light traffic,
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it shifts UEs to some of the carriers and then blocks the carriers without any load. In this way,
the power consumption is reduced. When the traffic increases or the preset period ends, the
eNodeB can automatically switch on the carriers that have been blocked to recover
functionality. In this way, the system capacity is increased without any impact on the service
quality.
Enhancement
In eRAN3.1, RRU can adjust the power amplifier voltage according to the remaining carriers
after the carrier shutdown. If two carriers are configured and a carrier is shut down, the RRU
reduces the voltage of the power amplifier according to the remaining carrier to reduce power
consumption.
Dependencies
This feature is not applicable to micro eNodeBs
This feature requires either of the following features:

TDLBFD-00201802 Coverage Based Inter-frequency Handover

OSS feature WOFD-200200 Base Station Power-Saving Management -LTE
3.3.5 TDLOFD-001056 PSU Intelligent Sleep Mode
Availability
This feature was introduced in LTE TDD eRAN2.2.
Summary
With this feature, certain power supply units (PSUs) can be powered on or off according to the
power consumption of the eNodeB to reduce the power consumption. For example, three PSUs
are configured for a light-traffic eNodeB. After this feature is enabled, the eNodeB power
consumption can decrease by 4% to 5%.
Benefits
When traffic is light, the eNodeB can power off certain PSUs to reduce power consumption.
Description
When an eNodeB with AC input is configured with Huawei PSUs (that are used to convert AC
power into DC power) and Huawei PMU, this feature can be enabled. The number of
configured PSUs depends on the maximum power consumption of the eNodeB and ensures that
the eNodeB operates properly even at the maximum load. In most cases, the eNodeB does not
operate with a full load, and therefore the PSUs do not operate with full power. Generally, the
PSU conversion efficiency is proportional to its output power. Therefore, the decrease in the
conversion efficiency increases the overall power consumption of the eNodeB.
When the eNodeB is powered by multiple PSUs, the PSU intelligent shutdown function allows
the eNodeB to shut down one or several PSUs according to the actual load and power supply
demand. In this way, the remaining PSUs work in full load mode, ensuring efficiency.
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Enhancement
None
Dependencies
This feature is not applicable to micro eNodeBs
eNodeBs with AC input must be configured with Huawei PSUs and Huawei PMU.
3.3.6 TDLOFD-001070 Symbol Power Saving
Availability
This feature was introduced in LTE TDD eRAN3.0
Summary
This feature allows eNodeBs to shut down the PAs in the time of empty symbols. Multimedia
broadcast multicast service single frequency network (MBSFN) subframes can be used to
reduce the reference signal further, and therefore more empty symbols are available for PAs to
shut down.
Benefits
This feature reduces the static power consumption of PAs, and therefore reduces eNodeB power
consumption.
Description
PAs consume the most power in eNodeBs. A PA consumes static power even if no signal is
transmitted. If the PA supports fast power-on and power-off, the eNodeB can use symbol power
saving.
The eNodeB can shut down the PAs in the time of empty symbols to save the static power
consumption of the PA. To guarantee data integrity, the system must control the time when the
PA is switched on and off.
For example, when there are no active users in the cell and only RSs must be transmitted in
some subframes, the PA can be shut down in the OFDM symbols without RSs.
If the cell is not configured with the Multimedia Broadcast Multicast Service (MBMS), the
eNodeB must add some of the empty subframes to MBSFN subframes for further power saving.
When one subframe is configured as an MBSFN subframe, only the first RS must be
transmitted over the air interface. No data is transmitted in the remaining symbols so that the PA
can be shut down for those symbols to reduce power consumption.
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Figure 3-1 Symbol power saving
Enhancement
None
Dependencies
This feature only applies to macro eNodeBs.
This feature is not applicable to micro eNodeBs
MBSFN subframe configuration requires that UEs can identify and apply the MBSFN
subframe configuration related to the serving and neighbor cells.
This feature is only supported by the RRU3232 and RRU3235.
3.3.7 TDLOFD-001071 Intelligent Battery Management
Availability
This feature was introduced in LTE TDD eRAN3.0.
Summary
With this feature, the battery management mode automatically changes depending on the
selected grid type, which prolongs the battery lifespan.
The battery self-protection function is triggered under high temperature to prevent battery
overuse and subsequent damage.
The battery runtime is displayed after the mains supply is cut off. By considering the runtime,
operators can take proactive measures to prevent service interruption due to power supply
cutoff.
Benefits
This feature provides the following benefits:
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
Prolongs battery lifespan

Reduces energy consumption

Reduces OPEX

Improves system stability

Automatic change of the battery management mode:
Description
The PMU board records the number of times power supply is cut off and the duration of
each cutoff. Then, the PMU board determines which grid type is selected and
correspondingly activates a specific power management mode. In grid types 1 and 2,
batteries can enter a hibernation state in which batteries do not charge or discharge, which
helps prolong battery lifespan.
Power
Supply
Cutoff
Duration
Within 15
Days (Hours)
Grid
Type
Charge and
Discharge
Mode
Current
Limitatio
n Valve
Hibernation
Voltage (V)
Hibernation
Duration
(Days)
Estimated
Battery Lifespan
Improvement
Rate
≤5
1
Mode A
0.10 C
52
13
100%
5 to 30
2
Mode B
0.15 C
52
6
50%
30 to 120
3
Mode C
0.15 C
N/A
N/A
0%
≥ 120
4
Mode C
0.15
N/A
N/A
0%
This function is under license control. In addition, this function is disabled by default and
can be enabled by running an MML command.

Self-protection under high temperature:
When batteries work at a temperature exceeding the threshold for entering the floating
charge state for 5 minutes, they enter this state and no alarms are generated.
When batteries work at a temperature exceeding the threshold for the self-protection
function for 5 minutes, they are automatically powered off or the battery voltage is
automatically adjusted.

Battery runtime display:
After the mains supply is cut off, the eNodeB calculates the runtime of batteries based on
the remaining power capacity, discharge current, and other data. This runtime can be
queried by running an MML command.
The following formula is used to calculate the runtime of batteries:
Runtime of batteries = (Remaining power capacity x Total power capacity x Discharge
efficiency)/(Mean discharge current x Aging coefficient)
Enhancement
None
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Dependencies
This feature only applies to the power module PMU02B.
This feature is not applicable to micro eNodeBs
3.4 Antenna Management
3.4.1 TDLOFD-001024 Remote Electrical Tilt Control
Availability
This feature was introduced in LTE TDD eRAN1.0.
Summary
This feature improves OM efficiency and minimizes the OM cost for adjusting the downtilt of
the remote electrical tilt (RET) antenna. Huawei LTE RET solution complies with AISG2.0
specifications and is backward compatible with AISG1.1 specifications.
Benefits
This feature provides the following benefits:

RET antennas at multiple sites can be adjusted remotely within a short period. This
improves efficiency and reduces the cost of network optimization.

RET antennas can be adjusted in all weather conditions.

RET antennas can be deployed at sites with difficult access.

RET downtilt adjustment keeps the coverage pattern undistorted, strengthening the
antenna signal and reducing neighboring cell interference.
Description
The RET is an antenna system whose downtilt is controlled electrically and remotely.
After an antenna is installed, the downtilt of the antenna must be adjusted to optimize the
network. In this situation, the signal phases that reach the array antenna elements can be
adjusted under the electrical control. The vertical pattern of the antenna can then be changed.
The phase shifter inside the antenna can be adjusted by using the step motor outside the antenna.
The downtilt of the RET antenna can be adjusted when the system is powered on, and the
downtilt can be monitored in real time. Therefore, the remote precise adjustment of the downtilt
of the antenna can be achieved.
Enhancement
None
Dependencies
This feature is unavailable when an RRU3232, RRU3252, or RRU3256 is split into two 2T2R
RRUs.
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This feature is not applicable to micro eNodeBs
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A
Acronyms and Abbreviations
Numerics
1xCS IWS
Circuit Switched Fallback Interworking Solution Function
for 3GPP2 1xCS
3GPP
3rd Generation Partnership Project
A
ACK
acknowledgment
ACL
access control list
AES
advanced encryption standard
AFC
automatic frequency control
AH
authentication header
AMBR
aggregate maximum bit rate
AMC
adaptive modulation and coding
AMR
adaptive multi-rate
ANR
automatic neighbor relation
ARP
allocation/retention priority
ARQ
automatic repeat request
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B
BBU
baseband unit
BCCH
broadcast control channel
BCH
broadcast channel
BE
best effort
BLER
block error rate
C
CAPEX
capital expenditure
CCCH
common control channel
CCO
cell change order
CCU
cell center user
CDMA2000
Code Division Multiple Access 2000
CDMA2000 1xRTT
CDMA2000 1x radio transmission technology
CEU
cell edge user
CGI
cell global identification
C/I
carrier-to-interference power ratio
CME
Configuration Management Express
CP
cyclic prefix
CPICH
common pilot channel
CPRI
common public radio interface
CPU
central processing unit
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CQI
channel quality indicator
CRC
cyclic redundancy check
CPU
central processing unit
CS
circuit switched
D
DCCH
dedicated control channel
DES
data encryption standard
DHCP
Dynamic Host Configuration Protocol
DiffServ
Differentiated Services
DL-SCH
downlink shared channel
DRB
data radio bearer
DRX
discontinuous reception
DSCP
differentiated services code point
DTCH
dedicated traffic channel
E
ECM
EPS control management
EDF
early deadline first
EDGE
Enhanced Data rates for GSM Evolution
EF
expedited forwarding
eHRPD
evolved high rate packet data
EMM
EPS mobility management
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EMS
element management system
eNodeB
E-UTRAN NodeB
EPC
evolved packet core
EPS
evolved packet system
E-RAB
E-UTRAN radio access bearer
ESP
Encapsulation Security Payload
ETWS
Earthquake and Tsunami Warning System
E-UTRAN
evolved universal terrestrial radio access network
F
FCPSS
fault, configuration, performance, security and software
management
FDD
frequency division duplex
FEC
forward error correction
FTP
File Transfer Protocol
G
GBR
guaranteed bit rate
GERAN
GSM/EDGE radio access network
GPS
Global Positioning System
GSM
Global System for Mobile Communications
GUL
GSM/UMTS/LTE
H
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HARQ
hybrid automatic repeat request
HII
high interference indication
HMAC
hash-based message authentication code
HMAC_MD5
HMAC message digest 5
HMAC_SHA
HMAC secure hash algorithm
HO
handover
HRPD
high rate packet data
HSPA
High Speed Packet Access
HSS
home subscriber server
I
ICIC
inter-cell interference coordination
IKEv
Internet Key Exchange version
IMS
IP multimedia service
IPPM
IP performance monitoring
Ipsec
IP security
IRC
interference rejection combining
IV
initial vector
K
KPI
key performance indicator
L
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LAI
location area identity
LMT
local maintenance terminal
LTE
Long Term Evolution
M
M2000
Huawei OMC
MAC
Media Access Control
MCH
multicast channel
MCCH
multicast control channel
MCS
modulation and coding scheme
MGW
media gateway
MIB
master information block
MinBR
minimum bit rate
MIMO
multiple-input multiple-output
MME
mobility management entity
MML
man-machine language
MOS
mean opinion score
MRC
maximum ratio combining
MTCH
multicast traffic channel
MU-MIMO
multi-user MIMO
N
NACC
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network assisted cell changed
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NACK
negative acknowledgment
NAS
non-access stratum
NE
network element
NMS
network management system
NRT
neighboring relation table
O
OCXO
oven controlled crystal oscillator
OFDM
orthogonal frequency division multiplexing
OFDMA
orthogonal frequency division multiple access
OI
overload indicator
OMC
operation and maintenance center
OOK
on-off-keying
OPEX
operating expense
P
PBCH
physical broadcast channel
PCCH
paging control channel
PCFICH
physical control format indicator channel
PCH
paging channel
PCI
physical cell identifier
PDB
packet delay budget
PDCCH
physical downlink control channel
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PDCP
Packet Data Convergence Protocol
PDH
plesiochronous digital hierarchy
PDN
packet data network
PDSCH
physical downlink shared channel
PF
proportional fair
P-GW
PDN gateway
PHB
per-hop behavior
PHICH
physical HARQ indicator channel
PLMN
public land mobile network
PM
performance measurement
PMCH
physical multicast channel
PRACH
physical random access channel
PS
packet switched
PUCCH
physical uplink control channel
PUSCH
physical uplink shared channel
Q
QAM
quadrature amplitude modulation
QCI
QoS class identifier
QoS
quality of service
QPSK
quadrature phase shift keying
R
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RA
random access
RACH
random access channel
RAM
random access memory
RAN
radio access network
RAT
radio access technology
RB
resource block
RCU
radio control unit
RET
remote electrical tilt
RF
radio frequency
RIM
RAN information management
RLC
Radio Link Control
RNC
radio network controller
RRC
radio resource control
RRM
radio resource management
RRU
remote radio unit
RS
reference signal
RSRP
reference signal received power
RSRQ
reference signal received quality
RSSI
received signal strength indicator
RTT
round trip time
RV
redundancy version
RX
receive
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S
S1
interface between the EPC and E-UTRAN
SBT
smart bias tee
SC-FDMA
single carrier frequency division multiple access
SCTP
Stream Control Transmission Protocol
SDH
synchronous digital hierarchy
SDMA
space division multiple access
SeGW
security gateway
SFBC
space frequency block coding
SFN
single frequency network
SFP
small form-factor pluggable
S-GW
serving gateway
SIB
system information block
SID
silence indicator
SINR
signal to interference plus noise ratio
SPID
subscriber profile ID
SRB
signaling radio bearer
SRS
sounding reference signal
SSL
Secure Sockets Layer
STBC
space time block coding
STMA
smart tower-mounted amplifier
T
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TAC
Transport Admission Control
TCP
Transmission Control Protocol
TDD
time division duplex
TMA
tower-mounted amplifier
TMF
traced message files
ToS
type of service
TTI
transmission time interval
TX
transmit
U
UE
user equipment
UL-SCH
uplink shared channel
UMTS
Universal Mobile Telecommunications System
USB
Universal Serial Bus
UTRAN
universal terrestrial radio access network
V
VLAN
virtual local area network
VoIP
voice over IP
W
WRR
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weighted round robin
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X
X2
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interface between eNodeBs
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