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2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V
Huawei Technologies Co. Ltd.
March 11, 2011
. 2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
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2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
PURCHASING 2G/3G INTERGRATED BTS
FOR MOBIFONE NETWORK 2010
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TABLE OF CONTENTS
TABLE OF CONTENTS ............................................................................................................ 1
LIST OF FIGURES ................................................................................................................... 3
LIST OF TABLES ..................................................................................................................... 6
1. Preface .............................................................................................................................. 9
2. SingleRAN Solution Highlights Summary ....................................................................... 10
3. Network Proposal for VMS ............................................................................................. 17
3.1 Requirement Analysis ..................................................................................... 17
3.1.1 Summary of Requirement ..................................................................................... 17
3.1.2 Subscriber Distribution .......................................................................................... 18
3.1.3 Traffic parameters ................................................................................................. 19
3.2 Construction Strategy ..................................................................................... 22
3.3 Networking Design Proposal for VMS ............................................................. 24
3.3.1 Proposed SingleRAN Network ............................................................................... 24
3.3.2 Proposed Transmission Network ........................................................................... 26
3.3.3 Proposed O&M Network ........................................................................................ 27
3.3.4 Proposed Equipment ............................................................................................. 28
3.4 Main Equipment Offered ................................................................................. 43
3.4.1 Offered BSC/RNC Hardware .................................................................................. 44
3.4.2 Offered TC Hardware ............................................................................................ 49
3.4.3 Offered SingleRAN Features .................................................................................. 50
3.4.4 Offered 2G/3G Integrated SingleBTS .................................................................... 58
3.4.5 Offered 2G/3G Integrated SingleBTS RF Connection with Feeder and Antenna .. 64
3.4.6 Offered OMC & PRS server .................................................................................... 66
3.4.7 Offered Transport Node ........................................................................................ 67
4. Network Dimensioning .................................................................................................... 69
4.1 SingleRAN Network Dimensioning .................................................................. 69
4.1.1 BSC Model Dimensioning ....................................................................................... 69
4.1.2 RNC Model Dimensioning ...................................................................................... 74
4.1.3 GTCS Dimensioning ............................................................................................... 88
4.2 2G/3G Integrated SingleBTS Network Dimensioning ....................................... 89
4.3 OMC & PRS Network Dimensioning ................................................................. 91
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5. Highlight of Huawei SingleRAN Solutions ...................................................................... 94
5.1 SingleRAN Product Overview ......................................................................... 94
5.1.1 Multi-mode BSC ..................................................................................................... 94
5.1.2 SingleBTS Introduction .......................................................................................... 95
5.2 Multi-mode Solutions ...................................................................................... 98
5.2.1 Co-cabinet solution for multi-mode ....................................................................... 98
5.2.2 Multi-mode Solution based on Software Defined Radio (SDR) ........................... 100
5.3 Highlight s of Huawei‟s SingleRAN Solution.................................................. 104
5.3.1 Highlight of Huawei’s GSM Solution .................................................................... 104
5.3.2 Highlight of Huawei’s UMTS Solution .................................................................. 119
5.3.3 High Transmission Efficiency /Improved Performance with 2G/3G Integrated .. 135
5.4 Huawei Centralized OMC Solution ................................................................ 137
5.4.1 Overview of Unified OMC .................................................................................... 137
5.4.2 Huawei’s Powerful iMananger M2000 ................................................................. 138
5.4.3 Abundant Northbound Interfaces for OSS Integrated Solution .......................... 139
5.4.4 CME for Graphical Network Configurations and Tuning ...................................... 139
5.4.5 iSStar Offering Customized O&M Development Platform .................................... 140
5.4.6 Software Management and Remote Upgrade Solution to Save OPEX ................ 140
5.5 Inter-working Solution with Existing GSM/GPRS/EDGE System ................... 141
5.5.1 Inter-working Solution Overview ......................................................................... 141
5.5.2 Inter-working Solutions and Strategy ................................................................. 141
6. Huawei Experience & Credibility................................................................................... 146
6.1 Global References ........................................................................................ 146
6.2 IOT Experiences ........................................................................................... 147
6.3 Global Applications and Progress ................................................................. 148
6.3.1 GSM/UMTS Networks in Telefonica/O2, Germany .............................................. 148
6.3.2 SingleRAN Strategic Fit for Vodafone D2 ............................................................ 149
6.3.3 UMTS/HSPA Network in Vodafone, Spain ........................................................... 150
6.3.4 SingleRAN Well Matched for Orange Spain ......................................................... 151
6.3.5 Telenor Keeps Leading with SingleRAN .............................................................. 152
6.3.6 UMTS/HSPA Network in StarHub, Singapore ...................................................... 153
6.3.7 All-IP HSPA Network in eMobile, Japan ............................................................... 154
7. Conclusion .................................................................................................................... 155
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LIST OF FIGURES
Figure 1 Key Figures of SingleRAN ................................................................................................ 10
Figure 2 Huawei SingleRAN BTS Expansion and Evolution ............................................................ 11
Figure 3 MBSC or Integrated BSC/RNC.......................................................................................... 11
Figure 4 Co-Transmission Reduces Transmission Cost .................................................................. 12
Figure 5 Reuse Antenna System .................................................................................................... 12
Figure 6 Co-OAM ............................................................................................................................ 13
Figure 7 Co-RNP/RNO .................................................................................................................... 13
Figure 8 Co-RRM ............................................................................................................................ 13
Figure 9 Co-TRM ............................................................................................................................ 14
Figure 10 Best coverage in VDF Greece with Huawei HSPA+ ....................................................... 15
Figure 11 High Speed performance in VDF Greece with Huawei HSPA+ ...................................... 15
Figure 12 2G/3G Network Layout for Center I and V .................................................................... 24
Figure 13 Proposed Transmission Network Diagram ..................................................................... 26
Figure 14 OMC Network Architecture in Center I (570 sites) ........................................................ 27
Figure 15 OMC Network Architecture in Center V (590 sites) ....................................................... 27
Figure 16 Position of the M2000 in the Network ........................................................................... 35
Figure 17 Configuration of the Processing Modules for Each Offered BSC6900 in Center I.......... 47
Figure 18 Configuration of the Processing Modules for Each Offered BSC6900 in Center V ......... 47
Figure 19 RF Part Interconnection between RF/Antenna/Feeder & Jumper per Sector ................ 64
Figure 20 RF Part for Interconnection between DBS3900 and Antenna, Feeder System ............. 65
Figure 21 RF Part for Interconnection between BTS3900A and Antenna, Feeder System ............ 65
Figure 22 RF Part for Interconnection between BTS3900 and Antenna, Feeder System .............. 66
Figure 23 RNC Hardware Configuration with Normal Traffic Model for Center I ........................... 79
Figure 24 Optimized Hardware Configuration to Meet 3Gbps Throughput for Center I ................ 80
Figure 25 RNC Hardware Configuration with Normal Traffic Model for Center V .......................... 85
Figure 26 Optimized Hardware Configuration to Meet 3Gbps Throughput for Center V ............... 86
Figure 27 Multi-mode BSC ............................................................................................................. 94
Figure 28 Module design BTS ........................................................................................................ 95
Figure 29 The SingleBTS Portfolio ................................................................................................. 96
Figure 30 Huawei convergent BTS expansion and evolution ......................................................... 96
Figure 31 Power consumption cooperation ................................................................................... 97
Figure 32 High Expansibility BBU3900 ........................................................................................... 98
Figure 33 Compact GSM/UMTS Multi-mode indoor BTS ................................................................ 99
Figure 34 Compact GSM/UMTS Multi-mode Outdoor BTS ............................................................. 99
Figure 35 Distributed multi-mode BTS ......................................................................................... 100
Figure 36 Scheme of SDR digital transceiver ............................................................................... 101
Figure 37 Huawei SDR Modules ................................................................................................... 101
Figure 39 Compact GSM/UMTS Multi-mode indoor BTS .............................................................. 102
Figure 40 Compact GSM/UMTS Multi-mode Out BTS .................................................................. 103
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Figure 41 Multi-mode BBU ........................................................................................................... 103
Figure 42 RRU3908 ...................................................................................................................... 104
Figure 43 Abis MUX ...................................................................................................................... 105
Figure 44 BTS Local Switch Solution ............................................................................................ 105
Figure 45 New IC Technology ...................................................................................................... 106
Figure 46 Power Optimization Based on Channel Type ............................................................... 106
Figure 47 TRX Power Amplifier Intelligent Shutdown .................................................................. 107
Figure 48 Dynamic Cell Power Off ............................................................................................... 107
Figure 49 Active Backup Power Control ....................................................................................... 108
Figure 50 Network Synchronization ............................................................................................. 109
Figure 51 IBCA ............................................................................................................................. 109
Figure 52 Enhanced downlink throughput in dual-timeslot extension cell .................................. 111
Figure 53 AMR.............................................................................................................................. 112
Figure 54 EDGE evolution ............................................................................................................ 113
Figure 55 BSS eMLPP+HR Solution .............................................................................................. 114
Figure 56 Service Quality Enhancement Technologies ................................................................ 114
Figure 57 ALL IP BSS ................................................................................................................... 115
Figure 58 Clock Over IP Application............................................................................................. 116
Figure 59 Ethernet OAM .............................................................................................................. 116
Figure 60 MSC Pool ...................................................................................................................... 117
Figure 61 TC Pool ......................................................................................................................... 118
Figure 62 DL throughput comparison of DL MIMO+64QAM vs DL 64QAM ................................. 120
Figure 63 Cell throughput comparison of DL MIMO+64QAM vs DL 64QAM ................................ 120
Figure 64 DC-HSDPA working principle ....................................................................................... 121
Figure 65 DC-HSDPA service coverage comparison with other HSPA users ................................ 122
Figure 66 EMOBILE ...................................................................................................................... 124
Figure 67 Vodafone Greece ......................................................................................................... 124
Figure 68 Huawei MBMS Solution ................................................................................................ 125
Figure 69 Iub Transmission Sharing ............................................................................................ 125
Figure 70 UTRAN IP Transport Solution ...................................................................................... 126
Figure 71 IP Transport based on ATM Transport Network .......................................................... 127
Figure 72 IP Transmission based on IP Transport Network ........................................................ 128
Figure 73 Hybrid IP Transmission Solution .................................................................................. 128
Figure 74 Huawei’s Leading IP RAN Solution............................................................................... 129
Figure 75 Co Site Implementation Procedure .............................................................................. 130
Figure 76 Antenna Sharing Solution ............................................................................................ 130
Figure 77 Space Sharing Solution ................................................................................................ 131
Figure 78 Transmission Sharing Solution of Fractional ATM ....................................................... 131
Figure 79 MOCN ........................................................................................................................... 132
Figure 80 Smooth Evolution to HSPA+/LTE ................................................................................. 133
Figure 81 Co-transmission Solution Based on TDM network ....................................................... 135
Figure 82 Co-transmission Solution Based on IP network ........................................................... 136
Figure 83 Co-RRM Solution .......................................................................................................... 137
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Figure 84 Huawei OMC Solution .................................................................................................. 137
Figure 85 Cell Reselection in Idle Mode ....................................................................................... 144
Figure 86 Coverage Based Inter-RAT Handover .......................................................................... 144
Figure 87 Service and Load Based Inter-RAT Handover ............................................................. 145
Figure 88 IOT Experiences ........................................................................................................... 147
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LIST OF TABLES
Table 1 Benefits from Huawei‟s Innovative SingleRAN Solution ................................................... 16
Table 2 Traffic Parameters for UTRAN Design for Center I & Center V ....................................... 21
Table 3 Equipment Allocation Table in Center I and V .................................................................. 24
Table 4 Proposed OMC network Design ....................................................................................... 28
Table 5 Equipment Version in Center I and V ............................................................................... 28
Table 6 The offered BSC‟s specification ....................................................................................... 29
Table 7 The offered RNC‟s specification ....................................................................................... 30
Table 8 Macro Indoor GSM + Distributed WCDMA (BTS3900+DBS3900) ................................... 31
Table 9 Macro Outdoor GSM + Distributed WCDMA (BTS3900A+DBS3900).............................. 31
Table 10 Distributed GSM + Distributed WCDMA (DBS3900+DBS3900) .................................... 32
Table 11 Baseband Unit BBU3900 ................................................................................................ 32
Table 12 MRFU for Proposed Macro Indoor/Outdoor GSM .......................................................... 33
Table 13 RRU3908 for Proposed Distributed GSM ....................................................................... 33
Table 14 RRU3804 for Proposed Distributed WCDMA ................................................................. 33
Table 15 Proposed IP Clock Server– IPCLK1000 ......................................................................... 34
Table 16 Proposed M2000 Equipment Specification ..................................................................... 35
Table 17 Proposed PRS Equipment Specification ........................................................................ 36
Table 18 Management capability of the PRS server ..................................................................... 36
Table 19 Proposed Transport Node Equipment Specification ...................................................... 37
Table 20 Proposed U2000 Equipment Specification ..................................................................... 38
Table 21 The offered Power Supply and Battery Equipment ........................................................ 39
Table 22 Offered Integrated BSC/RNC and 2G/3G integrated SingleBTS in Center I and V ....... 43
Table 23 Offered BSC Hardware Capacity for Center I & V .......................................................... 44
Table 24 Offered BSC Port Capacity for Center I & V ................................................................... 45
Table 25 Offered RNC Hardware Capacity ................................................................................... 45
Table 26 Offered RNC Port Capacity for Center I & Center V....................................................... 46
Table 27 Main Hardware Configuration of the Offered Integrated BSC/RNC in Center I & Center
V .............................................................................................................................................. 48
Table 28 Main Processing Unit Capacity ....................................................................................... 48
Table 29 Offered Power System and Battery for Each Integrated BSC/RNC in Center I & V ...... 49
Table 30 Offered TC Hardware for each BSC in Center I and V ................................................... 49
Table 31 Offered TC Hardware for Each BSC in Center I and V .................................................. 49
Table 32 Power System for TC ...................................................................................................... 50
Table 33 Offered GSM BSC Optional Features ............................................................................ 50
Table 34 Offered UMTS RNC Optional Features .......................................................................... 53
Table 35 Offered SingleBTS Optional Features ............................................................................ 55
Table 36 Offered OMC-R (M2000) Optional Features .................................................................. 56
Table 37 Supported Huawei GSM BSC Features ......................................................................... 57
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Table 38 Supported Huawei UMTS RNC Features ....................................................................... 57
Table 39 Supported Huawei SingleBTS Features ........................................................................... 58
Table 40 Offered 2G/3G Integrated SingleBTS Models ................................................................ 59
Table 41 Offered 2G/3G Integrated SingleBTS Models with the configured E1 and FE and GE
number. ................................................................................................................................... 60
Table 42 Offered TRX/Carrier/CE/HSPA capacities of 2G/3G Integrated SingleBTS‟s Models ... 61
Table 43 Offered Antenna for 2G/3G Integrated SingleBTS ......................................................... 61
Table 44 2G/3G Integrated SingleBTS Power Consumption List .................................................. 63
Table 45 Offered Power and Battery for 2G/3G Integrated SingleBTS ......................................... 63
Table 46 Cables for power supply, transmission and grounding protection .................................. 66
Table 47 Offered OMC Hardware in Center I and V ...................................................................... 67
Table 48 Offered PRS server Hardware in Center I and V............................................................ 67
Table 49 Transport Node Hardware Configurations in Center I and V .......................................... 67
Table 50 Offered MUX Power Supply and Battery ........................................................................ 68
Table 51 RNP Planned Site/TRX Distribution for each BSC ......................................................... 69
Table 52 Minimum Site/Cell Configuration for Each BSC ............................................................. 69
Table 53 Center I: GSM Throughput Results Dimensioned with the Optimized Traffic Model ..... 70
Table 54 Center I: Erlang Calculation ............................................................................................ 71
Table 55 Center I: Physical Interface Port for Each BSC Model ................................................... 72
Table 56 Center V: GSM Throughput Results Dimensioned with the Optimized Traffic Model .... 73
Table 57 Center V: Erlang Calculation .......................................................................................... 73
Table 58 Center V: Physical Interface Port for Each BSC Model .................................................. 74
Table 59 RNP Planned Site/Cell Distribution for each RNC .......................................................... 74
Table 60 Minimum Site/Cell Configuration for each RNC ............................................................. 75
Table 61 Center I: Throughput Results Dimensioned with Required Traffic Model ...................... 76
Table 62 Center I: Main Processing Unit with 2000 bps PS throughput per subscribers in BH .... 78
Table 63 Center I: Main Processing Unit with 3Gbps throughput ................................................. 79
Table 64 Center I: Summary for Main Processing Unit in RNC..................................................... 80
Table 65 Throughput offered with Optimized Traffic Model (3Gbps) per RNC ............................. 80
Table 66 Center I: Dimensioning result of RNC ............................................................................ 81
Table 67 Center I: Physical Interface Port for Each RNC Model ................................................... 81
Table 68 Center I: Physical Interface Throughput(UL+DL) for Each RNC Model ......................... 82
Table 69 Center V: Throughput Results Dimensioned with Required Traffic Model ..................... 82
Table 70 Center V: Main Processing Unit with 2000 bps PS throughput per subscribers in BH .. 84
Table 71 Center V: Main Processing Unit with 3Gbps throughput ................................................ 85
Table 72 Center V: Summary for Main Processing Unit in RNC ................................................... 86
Table 73 Throughput Results Dimensioned with Optimized Traffic Model (3Gbps) ..................... 86
Table 74 Center V: Dimensioning result of RNC ........................................................................... 87
Table 75 Center V: Physical Interface Port for Each RNC Model ................................................. 87
Table 76 Center V: Physical Interface Throughput(UL+DL) for Each RNC Model ........................ 88
Table 77 Dimension result for GTCS (Transcoder) ....................................................................... 88
Table 78 2G/3G Integrated SingleBTS type distribution................................................................ 89
Table 79 Abis/ Iub Bandwidth Based on RNP Result .................................................................... 89
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Table 80 2G/3G Integrated SingleBTS configuration .................................................................... 90
Table 81 Offered OMC-R System Server Type ............................................................................. 91
Table 82 Center I and V Total Node B and Cell Number with 35% Redundancy ......................... 91
Table 83 Center I and V Total BTS and TRX number with 30% Redundancy .............................. 91
Table 84 Dimensioning Result of Total NodeB and Cell Number for OMC-R Hardware .............. 92
Table 85 Dimensioning Result of Total BTS and TRX Number for OMC-R Hardware ................. 92
Table 86 Essential NEs and OMC-R Server Type ........................................................................ 92
Table 87 Essential NE and PRS server type Summary .................................................................... 93
Table 88 Comparison of Three Solutions .................................................................................... 142
Table 89 Commercial Inter-working Experiences ........................................................................ 147
Table 90 IOT of Iu Interface ......................................................................................................... 148
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1. Preface
As a major player in the telecommunication industry, Huawei Technologies Co., Ltd. (“Huawei”)
provides robust, adaptive and cost-effective solutions to worldwide operators. With its series of
outstanding mobile products, successful end-to-end solutions, experienced radio frequency
planning as well as excellent services, operators can be best assured to enjoy everlasting benefits
from the long-term partnership with Huawei.
To meet the requirement of MobiFone multi-mode network construction (hereinafter referred to as
VMS in accordance to the requirements stated in tender documents), this document is crafted to
provide a comprehensive description of offered system, comprising of Radio Network, OMC
System proposed to VMS in accordance to the requirements stated in tender documents.
The contents of this proposal are organized as follows:
Chapter 1: Preface.
Chapter 2: Summarizes the overview of SingleRAN solution highlights.
Chapter 3: Discusses the requirements of VMS 2G/3G network, followed by the SingleRAN
proposed network architecture, configuration and equipment.
Chapter 4: Describes the network dimensioning results obtained for the VMS network.
Chapter 5: Introduces the highlights of offered Huawei‟s SingleRAN equipment and provides
in-depth description of Huawei‟s SingleRAN solution, specially tailored for VMS.
Chapter 6: Defines Huawei’s strength and credibility in the telecommunication market as a
major player and leading vendor of the industry.
Chapter 7: Conclusion
Huawei believes the proposed total solution can ultimately fulfill the requirements of system
capacity alongside with quality of service, ensuring the best of both the project target and long-term
market strategy of VMS. Having taken into consideration the economic scale and the
developmental factors at all times, operators can take pleasure in effective cost savings on network
construction as well as realizing future expansions.
Huawei expresses great interest and is always looking forward to foster a long-term business
partnership with VMS. Huawei‟s unique bond will henceforth always focus on the customer‟s
market need and challenge, warrant the growth and development of both parties, as well as
contribute to telecommunication blooming.
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2. SingleRAN Solution Highlights Summary
Huawei‟s SingleRAN solution is an industry first, unique convergent solution for operators who
run more than one network, especially for GSM/UMTS multi-mode network. It is a series of
future-oriented and convergent network solutions (such as Multi-mode BSC, SingleBTS, IP
RAN, GSM/UMTS inter-working algorithm, etc.) in relation to network architecture,
transmission, facilities and O&M system. SingleRAN makes the technology choices and
network evolution simple and greatly reduce access to the site, the equipment room building,
transmission and other ancillary costs of the OPEX.
Huawei‟s SingleRAN solution embraces three essential elements (Uni-equipment, Uni-site
and Uni-operation):
Figure 1 Key Figures of SingleRAN
Uni-equipment: “One Network” Guarantee Flexible Evolution & Investment Protection
SingleBTS: SingleBTS (also known as 2G/3G integrated SingleBTS) makes Uni-site
(Co-transmission & Co-auxiliary facilities) a reality. The modular and multi-mode design of Huawei‟s
SingleBTS, supporting 2G and 3G in one compact cabinet, presents the ultimate solution. With its
integrated SDR and MCPA technologies (software defined radio and multiple carrier power
amplifiers), the SingleBTS also supports software upgrades from GSM to UMTS on a single module
– protecting operators‟ earlier investments in existing GSM equipment and sharply reducing the time
of UMTS deployment.
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Figure 2 Huawei SingleRAN BTS Expansion and Evolution
MBSC: MBSC (also known as integrated BSC/RNC) makes Uni-Operation a reality. Huawei‟s solution
provides the integration of GSM BSC and UMTS RNC into a multi-mode BSC (MBSC). MBSC is
designed with the unified PARC platform, which can support 2G and 3G in the same cabinet and provide
IP/TDM dual-switching plane. 2G and 3G can share many boards in MBSC, thus it saves a lot in spare
management.
Furthermore, SingleRAN solution is compatible with technologies evolution to guarantee long term viability.
All of its products are ready to evolve to LTE system.
Figure 3 MBSC or Integrated BSC/RNC
Uni-site: “One Deployment” Bring TCO Saving
Co-Transmission With Huawei‟s multi-mode BSC and the SingleBTS, transmission sharing is
achievable within the system and allows future service convergence. The value of Huawei‟s dual
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stack transmission mechanism for ATM and IP, and hybrid transmission and clock synchronization
over IP, translates into ultimately smooth and flexible network evolution.
Figure 4 Co-Transmission Reduces Transmission Cost
Co-Auxiliary Facilities With SingleBTS, operators deploy multi-mode networks by one time and
both GSM and UMTS networks can share the same facilities, such as cabinet, antenna system,
feeder system, power system, battery and etc.
Figure 5 Reuse Antenna System
With one time deployment, operators can now reduce not only cost (footprint saving brings less lend
cost, one time deployment brings less engineering cost), but also the time previously spent on
construction and deployment.
Uni-operation: “One Team” Improve Network Performance and Maintenance Efficiency
Co-OAM (operation and maintenance) combines all operations on one platform to facilitate network
operation and maintenance most. By one team, human resources efficiency is largely optimized.
Around 30-40% cost can be saved in NOC and field operation, spare parts management and
network performance optimization by incorporative operation.
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Figure 6 Co-OAM
Co-RNP/RNO (Radio network planning & optimization) allows constant 2G/3G network
performance monitoring for further analysis. Project sharing, joint parameter management and
common tools are used for multi-mode network planning and optimization (coverage, capability, and
neighboring cell) to realize high quality of “one network”.
Figure 7 Co-RNP/RNO
With Co-RRM (Radio Resource Management) RNC and BSC are unified as one network element
and Co-RRM function is core network- independent. Co-RRM auto-allocates radio resources
between 2G and 3G networks based on service and load. Data service throughput improves by as
much as 25%. SingleRAN solution dynamically allocates radio resources to ensure the most optimal
usage, which results in 10% handover.
Figure 8 Co-RRM
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With Co-TRM (Transmission Resource Management), transmission sharing can be implemented
for both voice and data services, guaranteeing QoS and improving transmission efficiency up to
10%.
Figure 9 Co-TRM
Huawei‟s pioneering SingleRAN solution can support GSM/UMTS/LTE simultaneously, which will
help the operator to realize one network for multi-mode, and a single OMC can support the
management of multi-mode networks. All these features can facilitate our customer in great amount
to cut off their TCO drastically. Allowing operators a first-time opportunity of truly deriving those
ultimate benefits, Huawei‟s SingleRAN solution will help operators establish a “maintenance-easy”
infrastructure so that operators can focus on market. With an enhanced single service platform,
quality of service can be maintained, new applications quickly introduced, and ARPU increased, and
competitive strengths enhanced. Huawei‟s SingleRAN truly affords our expanding wireless world a
viable solution that is “One For All.”
High Performance HSPA+ for Mobile Broadband
a) HSPA+ Phase 1 solution supports 21Mbps and 28Mbps in downlink with 64QAM and 2x2
MIMO respectively. HSPA+ Phase 1 can be evolved to HSPA+ Phase 2 smoothly.
b) Huawei RAN12 includes a new series of important functions concerning the improvement in
HSPA+ data throughput, these features include Dual Cell-HSDPA (DC-HSDPA), DL
64QAM+MIMO and UL 16QAM introduction.
c) HSPA+ Phase 2 solution supports 42Mbps in downlink with combination of 64QAM and 2x2
MIMO or DC-HSDPA. And in uplink HSPA+ Phase 2 solution supports 11.5Mbps with uplink
16QAM.
d) For HSPA+ commercial application, Huawei is the leading vendor now. By Q4 2010, Huawei
had already won more than 48 commercial HSPA+ contracts (market share 46%).
e) Huawei HSPA+ Solution help VDF provide best coverage and break every speed record in
Greece.
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Figure 10 Best coverage in VDF Greece with Huawei HSPA+
Figure 11 High Speed performance in VDF Greece with Huawei HSPA+
Field Proven industry leading IP solution
a) Huawei is the 1st vendor to provide native IPRAN solution instead of pseudo wire technology
since 2006Q4, which is 2 years ahead of other vendors‟.
b) Clock over IP is utilized in Huawei IPRAN solution to get synchronization without external GPS
or E1. Innovative IP clock solution saves GPS investment.
c) Customized IP solution based on existing transmission topology that provide the maximum
investment protection. Huawei could provide IP over ATM solution, Hybrid ATM/IP solution,
and All IP solution.
d) Hardware ready for IP transmission avoids upgrade cost dramatically (Hardware are ready
with IP-based integration to avoid massive upgrade cost).
e) Abundant experience in IP solution helps to minimize the risk of evolution to all-IP network.
Huawei is the 1st vendor to provide native IPRAN solution instead of pseudo wire technology
since 2006Q4, which is 2 years ahead of other vendors‟. Huawei IPRAN has been deployed in
commercial UMTS networks by mobile operators such as Etisalat in UAE, eMobile in Japan,
Etisalat in Egypt, and StarHub in Singapore. And it also passed the stringent tests performed
by operators such as Vodafone, Spain; France-Telecom Orange, France; TI, Italy, etc.
Huawei unique MIMO solution: 2 years ahead industry for hardware ready
a) Huawei is the only Vendor to support MIMO DBS, achieving up to 85% gain in performance.
b) Huawei unique Co-Carrier MIMO solution helps to improve more than 20% cell throughput.
c) MIMO brings negative gain to legacy UE when MIMO and HSPA co-carrier, Huawei is the only
one vendor can minimize the impact.
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Green for Energy Conservation and Emission Reduction
a) Huawei NodeB features lowest power consumption (400W@S1/1/1) in the industry with
advanced power amplifier technology (DPD+A-Doherty) and excellent engineering design.
b) Based on energy-efficiency-improvement technologies of both Node B and its site facility, it is
possible to utilize the reproducible energy such as wind or solar energy.
c) With innovative DNBS solution, operators can achieve green delivery of easier site acquisition,
easier civil work, easier delivery, etc.
Innovative SingleRAN for TCO Saving and Smooth Migration
a) MSR based SingleRAN enables flexible evolution among GSM/UMTS/LTE on the same
frequency, especially for UMTS900&GSM900, GSM1800<E1800 in same RRU, thus avoid
huge reduplicate investment and ensure smooth evolution for 900MHz/1800MHz radio
frequency resource.
b) Industry leading 6-carrier technology enable once for all hardware deployment, thus minimize
the OPEX cost due to future expansion.
c) The BBU hardware is ready for HSPA+ phase 2 (Combination of downlink 64QAM and MIMO
2 x 2 or DC-HSDPA) upgrade and can be further upgraded to HSPA+ phase 3 with additional
new baseband card and LTE respectively, thus make the upgrade much easier.
d) Dual Mode RNC and BSC enable simplified network architecture, less number of BSC and
RNC. Based on Dual Mode RNC&BSC, Co-TRM with higher transmission efficiency saves
huge amount of transmission resources, Co-RRM can balance the traffic between GSM and
UMTS intelligently, and then switch off the idle carriers to save power consumption. Co-OAM
with higher human resources efficiency brings OPEX saving.
Table 1 Benefits from Huawei‟s Innovative SingleRAN Solution
Item
TCO Saving Revenue
Increasing
Performance
improvement CAPEX
Saving
OPEX
Saving
Multi-carrier technology √ √ √
High power efficiency √ √ √
High performance HSPA/HSPA+ √ √ √ √
Smooth evolution to LTE √ √ √ √
IP based, Uni-Platform Dual Mode
RNC&BSC √ √ √
e) Huawei UMTS and GSM even LTE hardware are designed with unified platform for
multi-mode application. UTRAN solution is hence backward compatible with GSM/EDGE
network and supports future migration to HSPA+/LTE.
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3. Network Proposal for VMS
3.1 Requirement Analysis
3.1.1 Summary of Requirement
As one of the top three major mobile communication operators in Vietnam, VMS is
facing fierce competition and long-term challenge in the matured 2G mobile market.
Undoubtedly, introduction to 3G is able to stimulate service to keep VMS in the leading
position. However, with the coexistence of multiple network technologies, it demands
VMS to construct separate networks leading to increased OPEX and CAPEX. In this
proposal, Huawei offers SingleRAN solution which can integrate the functions of the
GSM and UMTS, and provide the highest capacity with the smallest footprint in the
market. It is also able to enhance the service coverage and to meet increasing mobile
broadband demand in Vietnam. With one purchase decision, VMS can now realize the
optimal benefits of ownership from a cost and time efficient solution for multiple network
investment protection, enhanced performance, reduced OPEX and CAPEX, and
improved TCO.
Huawei has been the supplier in Vietnam telecommunications market for more than
nine years, which is one of the experienced players in the telecommunication to promise
innovative technologies and cost-effective solutions. Based on Huawei‟s understanding
of Vietnam market, studying the requirement documents and VMS‟s network
environments, Huawei is convinced to have ability to fulfill VMS requirements in such
aspects as below:
Construct a 2G/3G SingleRAN system including 2G/3G integrated SingleBTS
equipment, BSC/RNC equipment and uniform OMC system for VMS Center I
and V.
Maximum output static power of each GSM TRX measured at the top of cabinet
(TOC) must be at least 20W; Maximum output static power of each UMTS carrier
measured at the top of cabinet (TOC) must be at least 20W.
The proposed 2G/3G integrated SingleBTS is configured with singleband
GSM900 S4/4/4 or dualband GSM900 S2/2/2 + GSM1800 S2/2/2 or distributed
GSM900 S4/4/4, and distributed WCDMA S2/2/2 (Band 2100M, 384CE UL/
384CE DL, HSDPA+ 21Mbps per cell, HSUPA 5.76Mbps per cell).
Fast deploy a complete GSM/UMTS network, save time-to-market, to gain
competitive edge in Vietnam market by cooperating with vendor who have strong
local presence and hold a good track record of accomplishment in Vietnam.
The proposed SingleRAN equipment is hardware ready for IP RAN to realize
All-IP solution in near future.
Offered network elements for this northern region include 1160 2G/3G integrated
SingleBTSs (570 for Center I and 590 for Center V), 11 integrated BSC/RNCs (5
for Center I and 6 for Center V), 2 OMC-R (1 OMC-R for each Center I and V),
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230 sets of additional materials for split and re-installation (200 sets for Center I
and 30 sets for Center V), 33 Transport Nodes for supporting transmission
between NodeB and RNC (15 for Center I and 18 for Center V), 2 sets of
Management System for Transport Nodes (1 Transport Node Management
System for each Center I and V), and related installation accessories.
The proposed network flexibly and smoothly evolves to HSPA+ supporting
downlink of 21 Mbps, HSPA+ Phase 2 supporting downlink of 42 Mbps and LTE
system in future.
3.1.2 Subscriber Distribution
From VMS‟s 2G subscriber number requirement, the total subscriber number for
Center I is given as 2.3 Million while the total subscriber number for Center V is given
as 2.2 Million. Therefore the northern region (Center I and Center V) has total
subscriber number of 4.5 Million.
However, in order to meet VMS‟s minimum requirement of 2048 TRXs as well as the
30% capacity redundancy, the maximum total subscriber for 5 BSC in Center I is
dimensioned and supported up to 2.88 million (subs) while the maximum total
subscriber for 6 BSC in Center V is dimensioned and supported up to 3.45 million
(subs). Therefore, the total subscriber number for the northern region (total 11 BSCs
for Center I and V) is approximately 6.33 million subscribers where is much higher
than the given total subscriber for the Northern region..
For 3G, the total subscribers number given in Center I is 2 million (sub) while the total
subscribers number given in Center V is 1.8 million (sub) respectively based on the
VMS‟s requirement. From the details obtained from VMS‟s RFP requirement, there are
total 11 integrated BSC/RNC in Center I and Center V which is 5 integrated BSC/RNC
for Center I and 6 integrated BSC/RNC for Center V. By assigning the total subscriber
number evenly in each integrated BSC/RNC for Center I and Center V, the subscriber
number is equals to 400,000 (3G sub) for Center I and 300,000 (3G sub) for Center V.
Furthermore, the VMS‟s minimum requirements of 3Gbps total throughput, at least 300
NodeBs/900 Cells as well as the 35% capacity redundancy for each integrated
BSC/RNC are fulfilled.
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3.1.3 Traffic parameters
3.1.3.1 GBSS traffic parameters
The offered GBSS systems are designed by following closely to the dimensioning and
configuration requirements stated in tender documents as the following:
30% capacity redundancy.
Quality of Trunking (Erlang B)
GoS (BSC-MSC): 1%.
GoS radio part: 3%.
GoS Signaling Channel: < 0.2%.
Subscribers with Prepaid service: 75%.
Subscribers with Postpaid service: 25%.
Prepaid or postpaid busy hour traffic per subscriber: 25 mErlang.
BHCA/prepaid or postpaid subscriber at peak: 1.5.
% of outgoing call of prepaid or postpaid subs at peak: 68%.
% of incoming call of prepaid or postpaid subs at peak: 32%.
Prepaid or postpaid average holding time: 60 sec.
Number of SMS call per subscriber at peak: 0.3.
Number of Hand-overs per call (BH): 1.
Subscriber with SMS: 80%.
Subscriber with VMS: 20%.
Subscriber with Data/Fax: 1%.
Data/Fax call per subscriber per day: 0,1.
VMS call forwarding per subscriber at peak: 1.
Data/Fax call per subscriber per day: 0,1.
IN prepaid signaling protocol CAMEL phase 2, CAMEL phase 3
Following is the traffic model for 2G based on VMS‟s requirement with the parameter used
in dimensioning and designing the BSC model in Center I and V. In the cases where
necessary input data are not provided or unclear, Huawei‟s default values are
recommended as assumed parameters for network dimensioning.
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Table 1 2G Traffic Model
Traffic Parameters Unit Value Remarks
Average voice traffic per subscriber@BH Erl 0.025 Required
Average Call Duration Second 60 Required
Number of SMS/BH/SUB(MO) - 0.2 Required
Number of SMS/BH/SUB(MT) - 0.1 Required
Location update/BH/SUB - 1.5 Assumed
Signaling Gateway Parameters
64k SS7 signaling links load - 0.2 Assumed
2M SS7 signaling links load - 0.2 Assumed
GoS Parameters
Um Interface % 3% Required
A Interface % 1% Required
Note: GPRS percentage is assumed to be 10% of total subscriber number.
3.1.3.2 UTRAN traffic parameters
The offered UTRAN systems are designed by following closely to the dimensioning
and configuration requirements stated in tender documents as the following:
35% redundancy for RNC (handling capacity, C7 signaling and trunk interfaces)
and OMC (hardware for management capacity).
Quality of Trunking (Erlang B)
GoS Iu-CS interface: 1%.
GoS Iu-PS interface: 1%.
GoS Uu interface: 2%.
GoS Other interfaces: 1%.
GoS of Signaling Channel: 0.01%.
Erlang per C7 Link (64Kbps) < 0.2 Erl.
Erlang per C7 HSL (2Mbps) < 0.4 Erl.
BHCA/sub = 1.5.
BHSM/sub = 0.3.
Handover/call = 1.
LUP/sub = 1.2.
MOC = 35%.
MTC = 45%.
MMC = 20%.
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Following table lists the necessary traffic model parameters being used in capacity
dimensioning and transmission calculation for Center I and Center V respectively. In
the cases where necessary input data are not provided or unclear, Huawei‟s default
values are recommended as assumed parameters for network dimensioning.
Table 2 Traffic Parameters for UTRAN Design for Center I & Center V
Traffic Parameters Unit Value Remarks
CS Voice Call
CS Voice Penetration Ratio % 100.00% Required
Voice Traffic per CS voice sub in BH Erl 0.025 Required
CS voice call duration Second 60 Derived
BHCA per sub S 1.5 Required
CS Video Call
CS Data(voice Phone 64k) Penetration Ratio % 30% Required
CS data traffic per CS data (video Phone 64k)
sub in BH Erl 0.0025 Required
CS data (Video Phone 64k) call duration second 60 Derived.
BHCA per sub S 0.15 Assumed
PS Data Call
PS (including R99 and HSPA) Penetration
Ratio % 100% Required
PS throughput (including R99 and HSPA,
UL+DL) per PS sub in BH bps 2000 Optimized
Proportion of UL PS (Including R99 and
HSPA) throughput % 15.00% Required
Proportion of DL PS (Including R99 and
HSPA) throughput % 85.00% Required
R99 share of DL PS throughput per sub % 61.50% Required
HSDPA share of DL PS throughput per
sub % 38.50% Required
R99 share of UL PS throughput per sub % 90.00% Assumed
HSUPA share of UL PS throughput per sub % 10.00% Assumed
Other Traffic Parameters
Soft Handover % 30% Required
Note: In order to fulfill the minimum throughput requirement of 3Gbps, the given PS
throughput traffic parameter is not able to meet the requirement, thus the PS
throughput per sub traffic parameter is changed to 2000 bps for Center I and Center V.
Please refer to Chapter 4.1.2 for more detail explanation.
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3.2 Construction Strategy
Taking into account the challenges VMS faces in the Vietnam market, Huawei would
like to present the following compelling business propositions which are able to deliver
the best business values to VMS:
Adopt 2G/3G integrated SingleBTS equipment (also known as SingleBTS) that is
able to support SDR (Software Defined Radio). Its RF module can migrate from
GSM to UMTS and then to LTE in 900MHz GSM frequency band, from GSM to
LTE in 1800MHz GSM frequency band, and from UMTS to LTE in 2100MHz
UMTS frequency band only by software upgrade without any radio hardware
replacement. It allows flexible configuration between 2G and 3G and can be
smoothly evolved to LTE.
Propose Huawei MRFU with total 80W output power supports 6 TRX/MRFU in
GSM only and 4 carriers/MRFU in UMTS only and flexible configuration between
GSM and UMTS. It supports static 20W TOC power in case of S4 configuration
due to total 80W output power per MRFU for one cell for SingleBTS 2G RF. For
SingleBTS 3G RF, it supports 20W power in case of S3 configuration due to total
60W output power per RRU3804 for one cell.
Adopt SingleBTS that is based on new technologies including MCPA design and
DPD and Doherty technology both in 2G and 3G parts to enhance PA efficiency
to 40% both in 2G and 3G part. It also supports maximum 6TRX per 2G MRFU
unit and 4 carriers per 3G 3804 unit so that can support future expansion to
12/12/12 GSM (6/6/6 GSM900 + 6/6/6 GSM1800) and 3/3/3 UMTS configuration.
Besides, the proposed SingleBTS 3G NodeB supports 384/384(DL/UL) CE both
in hardware and software license.
All of Huawei‟s SingleBTS offered to VMS GSM/UMTS network support full
performance EDGE, HSDPA and HSUPA before CLR (Commercial Launch
Ready) to meet VMS‟s mobile broadband requirements. It supports HSPA+ with
the maximum peak rate up to DL 21 Mbps / UL 5.76 Mbps per cell and supports
HSPA+ Phase 2 (DL 42Mbps / UL 11Mbps) through upgrading.
Propose interface of TDM/E1, ATM/E1 and IP/FE and GE solution for SingleBTS.
In addition to TDM/E1 synchronization solution, IP Clock (1588V2)
synchronization solution is proposed for SingleBTS to get clock signaling from
VMS‟s ME+ network.
Deploy distributed DBS that could save more than 30% of Total Cost of
Ownership (TCO) including cost of site location, equipment installing, power
consumption, TMA, maintenance etc. Huawei‟s DBS3900 includes two parts,
BBU and RRU. With different integrated methods of BBU and RRU, Distributed
BTS can fit for different application scenarios.
2G/3G Smooth Evolution – The 3G and IP based design can ensure the GSM
system evolves to the 3G system easily. For instance, Huawei BSC shares the
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same hardware platform with Huawei RNC. VMS can upgrade from BSC to RNC
according to capacity requirements flexibly and smoothly. The 2G BTS can also
support 2G/3G co-cabinet (or 2G/3G dual mode). TDM/IP Co-transmission,
Co-OM, Co-RNP/RNO, Co-RRM, Future proof design to protect VMS initial
investment.
Deploy large capacity integrated BSC/RNC (also known as MBSC) to decrease
the number of network elements, simplify network topology, allows easy
maintenance that result in reduced OPEX. Its high packet throughput can fully
meet the traffic requirements of EDGE/HSDPA/HSUPA. It can support up to 4096
TRX per BSC (PCU embedded) with standalone TC, and up to 12Gbps per RNC.
Propose three kinds of power supply to meet the power requirement for different
equipment individually including indoor and outdoor BTS, BSC, TC and
Transporting Node. The proposed battery and power systems are based on the
maximum load design with N+1 redundancy in rectifier module and 6 hours
backup time in battery.
Adopt large capacity for OMC-R by offering one OMC-R for each center. It can
manage 2G/3G simultaneously and support all IP connections.
Deploy OSN7500 at hub-site transport node and OSN7500+NE40E at RNC-site
transport node. OSN7500 is offered as the SDH layer equipment, and NE40E is
offered as packet layer equipment.
Huawei hopes that the above principles are suitable and beneficial for VMS project.
Huawei looks forward to working closely with VMS to generate the final solution that
concur with the requirements specified.
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3.3 Networking Design Proposal for VMS
3.3.1 Proposed SingleRAN Network
Figure 12 2G/3G Network Layout for Center I and V
The proposed equipment include 11 integrated BSC/RNCs, 11 TCs, 1160 2G/3G
integrated SingleBTSs, 22 IP clock servers and 2 OMC-R & PRS servers in Center I & V
regions. The detailed distribution of integrated BSC/RNC and 2G/3G integrated
SingleBTS in VMS Center I and Center V are shown in the table as below.
The equipment allocations are:
Table 3 Equipment Allocation Table in Center I and V
Product Center I Center V Total
BTS3900 GSM (900M S444) + DBS
WCDMA S222
130 120 250
BTS3900 GSM (900M S222 + 1800M
S222) + DBS WCDMA S222
110 190 300
BTS3900A GSM (900M S222 + 1800M
S222) + DBS WCDMA S222
230 180 410
DBS3900 GSM 900M S444 + DBS
WCDMA S222
100 100 200
Integrated BSC/RNC 5 6 11
TC 5 6 11
OMC server 1 1 2
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PRS server 1 1 2
Note:
Configuration separated power system and battery for 2G/3G integrated
SingleBTS system, integrated BSC/RNC, TC, and Transport Node, antenna &
feeder are included accordingly.
3.3.1.1 2G/3G Integrated SingleBTS
In this proposal, Huawei offers three types of 2G/3G integrated SingleBTS solutions to
meet VMS‟ requirement. All offered 2G/3G integrated SingleBTS support IP over E1, FE
and GE hybrid transmission as well as IP with ATM dual stack transmission.
Each 2G/3G integrated SingleBTS is configured with 8 E1, 2 electrical FE and 2
optical GE in the transmission interface.
3.3.1.2 2G/3G Integrated BSC
Each BSC is dimensioned with STM-1 and optical GE interfaces for interconnection with
2G BTSs. Each RNC is dimensioned with STM-1 and optical GE interfaces for
interconnection with 3G NodeBs.
Considering that the BSC and RNC need to inter-work with the existing Core
Network equipment from other vendors, A interface is designed with FE interface,
and IuCS interface is designed with both STM-1 and GE interface, and Gb interface
is designed with both optical FE and E1, and IuPS interface is designed with both
optical GE and STM-1 interface for VMS flexible deployment.
3.3.1.3 OMC-R and PRS server
One OMC-R server and one PRS server are configured to each Center I and V in
order to manage all the integrated BSC/RNC. One O&M terminal and one alarm
terminal are configured in the central room and remote room respectively.
3.3.1.4 GTCS (Transcoder)
Based on the requirement, TC is not embedded inside the BSC model, thus Huawei
proposes standalone TC for each BSC, with total of 5 TCs for Center I and another 6
TCs for Center V. Besides, Huawei also proposes STM-1 for Ater interface and A
interface to meet VMS‟s requirement for the transmission purpose.
3.3.1.5 IP Clock Server
In order to achieve IP clock synchronization from integrated BSC/RNC side to 2G/3G
integrated SingleBTS, two IP clock servers co-locating with the integrated BSC/RNC
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equipment are offered in this proposal. Each IP clock server is for BSC and RNC
respectively. One IP clock server is configured for each BSC and RNC respectively.
3.3.1.6 Power Supply and Battery
There are 3 types of power systems and 2 types of batteries that proposed for the
integrated BSC/RNC, 2G/3G integrated SingleBTS system, TC, and Transport Node.
3.3.1.7 Antenna / feeder / Accessories.
There are 6 types of antenna required in this tender which include Antenna Single Band
1800MHz, Antenna Single Band 2100MHz, Antenna Dual Band 900M/1800MHz-2
connectors, Antenna Dual Band 3 in 1 cluster, Antenna Triple Band
(900MHz/1800MHz,2100MHz)-6 connectors, Antenna Triple Band 3 in 1 cluster. The
feeder type required which includes 7/8 feeder and 1/2 feeder and other related
accessories have been proposed.
3.3.2 Proposed Transmission Network
For transmission network design, Huawei proposes OSN7500 as the Hub-sites
transport Node and OSN7500+NE40E as the RNC-site transport nodes.
In Hub-sites, OSN7500 will connect all the PDH and Ethernet service and
convergence to STM-1, GE or 10GE services.
In RNC-sites, OSN7500 will work as the SDH layer equipment to process all the PDH
and SDH services. And NE40E will work as the packet layer equipment to process all
the Ethernet services and provide L3 and IP routing functions.
All the OSN7500 and NE40E will be managed by iManager U2000 system, each
center of VMS will have one to manage the transmission node independently.
Figure 13 Proposed Transmission Network Diagram
RNC
Microwave
Optical DWDM or Core SDH E1
FE Node B
FE
Node B GE LL
Hub sites Transport Node RNC sites Transport Node
STM-1 LL E1+FE
Core
GE/STM-1
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3.3.3 Proposed O&M Network
Huawei OMC solution (iManager M2000 system), known as an element
management system (EMS), includes Server, Clients, Alarm Boxes, and other OM
networking equipments. It supports the network operation and maintenance via
centralized OMC or local LMT via LAN connection.
Figure 14 OMC Network Architecture in Center I (570 sites)
Figure 15 OMC Network Architecture in Center V (590 sites)
The proposed OMC network topology is illustrated in the figure above. And the OMC
design is based on the following principle:
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Table 4 Proposed OMC network Design
M2000 Design
OMC Location Each center needed to be equipped with one OMC-R
system.
M2000 Server SUN
PRS Server HP
Central Room
M2000 server is defined as one central room for each
Center I and V, configured with one O&M Terminal and
one Alarm Terminal for each central room.
M2000 Network connection IP
Remote Room
Each integrated BSC/RNC is defined as one remote
room, total 5 remote rooms for Center I and 6 remote
rooms for Center V.
O&M Terminal Each remote room has one O&M Terminal, total 5 for
Center I and 6 for Center V.
Alarm Terminal Each remote room has one Alarm Terminal, total 5 for
Center I and 6 for Center V.
Huawei iManager M2000 supports centralized full network management function for
BSS and RAN maintenance. The OM network is IP networking. All BTS can be
managed through BSC and Node Bs can be managed through RNC.
3.3.4 Proposed Equipment
As a summary of Huawei‟s network design for VMS network, the following equipment
are proposed and shown in the below tables. (Please refer to more details in the
submitted BOQ)
Table 5 Equipment Version in Center I and V
Network Element Name Product Name
SingleRAN
Integrated BSC/RNC BSC6900 V900R012
Distributed Macro Node B DBS3900 V200R012
Indoor Macro BTS BTS3900 V100R012
Outdoor Macro BTS BTS3900A V100R012
Distributed Macro BTS DBS3900 V100R012
IP Clock IP Clock Server IPCLK1000 V100R002
OMC-R OMC for Radio M2000 V200R011
PRS server Performance Report Server PRS V100R007
OMC-T OMC for Transmission U2000 V100R002
MUX Hub-site Transport Node OSN7500 V200R011
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MUX RNC-site Transport Node OSN7500 V200R011 + NE40E-X3
V600R001
Power
Power for integrated BSC/RNC TP48600B
Power for TC TP48300/A
Power for MUX TP48300/A
Power for Indoor BTS + Distributed NodeB TP48300/A
Power for Outdoor BTS + Distributed
NodeB
TP48200A
Power for Distributed BTS + Distributed
NodeB
TP48300/A
Battery Battery Shuangdeng Battery
All the proposed equipments are based on Huawei newest hardware and software
version.
3.3.4.1 Proposed BSC Equipment
Huawei BSC6900 GSM is an industry leading All-IP Base Station Controller which
supports embedded PCU. In addition, it has large capacity, high integration with
excellent performance, less power consumption and supports smooth evolution.
Table 6 The offered BSC‟s specification
BSC Item Specification
BSC6900 GSM
Dimension (H x W x D) 2200mm x 600mm x 800mm
Weight (Kg) One cabinet full configuration: ≤ 320kg
BHCA 5900k (Calculated based on Huawei traffic
model)
Max. voice traffic 24000 Erlang
Physical Gb Throughput 1536Mbps
Number of configured
PDCHs 30720
Number of active
PDCHs (MCS-9) 16384
Max. num of TRX 4096
Operation Temperature Short-term working condition -5°C to + 55°C
Long-term working condition 0°C to 45°C
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3.3.4.2 Proposed RNC Equipment
For RNC, Huawei proposes IP based, high capacity and high reliability BSC6900 UMTS
to meet high-speed and large-volume data services of HSPA era requirement VMS will
face in the near future.
Table 7 The offered RNC‟s specification
RNC Item Specification
BSC6900 UMTS
Dimension (H x W x D) 2200mm x 600mm x 800mm
Weight (Kg) One cabinet full configuration: ≤ 320kg
BHCA 3220k (Calculated based on Huawei traffic
model)
Max. voice traffic 80400 Erlang
PS data capacity
(UL+DL) 12.0G bps
Max. num. of NodeB 3060
Max. num of cells 5100
Operation Temperature Short-term working condition -5°C to + 55°C
Long-term working condition 0°C to 45°C
Note: Both BSC and RNC are in fact one system, which is called as MBSC or integrated
BSC/RNC.
3.3.4.3 Proposed 2G/3G integrated SingleBTS Equipment
There are 3 types of models for 2G/3G integrated SingleBTS: For Macro Indoor GSM
and Distributed WCDMA, Huawei proposes BTS3900 + DBS3900. For Macro Outdoor
GSM and Distributed WCDMA, Huawei proposes BTS3900A + DBS3900. For
Distributed GSM and Distributed WCDMA, Huawei proposes DBS3900 + DBS3900
With Distributed GSM and Distributed WCDMA, VMS can efficiently deploy a
high-performance 3G network with a low TCO since The baseband processing unit
(BBU) of DBS3900 is characterized by a small footprint, easy installation, and low
power consumption. In addition, the BBU can be installed in the spare space of an
existing site. The remote radio unit (RRU) of DBS3900 also has a compact design and
light weight, and it can be installed close to the antenna to decrease feeder loss and
improve system coverage performance.
Macro Indoor/Outdoor GSM is for compact installation with smaller footprint, fewer
module types, G/U co-cabinet capability and excellent expandability.
The detailed specifications of each type of 2G/3G integrated SingleBTS are interpreted
in the following table.
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Table 8 Macro Indoor GSM + Distributed WCDMA (BTS3900+DBS3900)
BTS Item Specification
BTS3900 GSM +
DBS3900 WCDMA
Size 900 x 600 x 450 mm
Weight Cabinet (with BBU and three
MRFUs): ≤ 97 kg
Cabinet (with BBU and six
MRFUs): ≤ 132 kg
Capacity 6*RFU(2G)+3*RRU(3G)
Power supply –48 V DC, 110V AC, +24V DC,
220V AC
Operation temperature –20°C to +55°C
short-term: –50°C to +55°C
Relative humidity 5% to 95%
Transmission Support E1, IP
Table 9 Macro Outdoor GSM + Distributed WCDMA (BTS3900A+DBS3900)
BTS Item Specification
BTS3900A GSM +
DBS3900 WCDMA
Size RFC: 700 x 600 x 480 mm
TMC11H: 700 x 600 x 480 mm
Weight In full configuration: ≤ 210 kg
(RF cabinet with 6 RFUs and
without batteries)
Capacity 6*RFU(2G)+3*RRU(3G)
Power supply –48 V DC, 110V AC, 220V AC
Operation temperature –40°C to +55°C
(short-term: –50°C to +55°C)
Relative humidity 5% to 100%
Transmission Support E1, IP
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Table 10 Distributed GSM + Distributed WCDMA (DBS3900+DBS3900)
BTS Item Specification
DBS3900 GSM +
DBS3900 WCDMA
Size BBU3900: 86 x 442 x 310 mm
RRU3804: 485 x 285 x 170 mm
RRU3908: 485 x 380 x 170 mm
Weight BBU3900: ≤ 12 kg (in full
configuration)
RRU3908: 23 kg (with housing)
RRU3804: 17kg (with housing)
Capacity 3*RRU(2G)+3*RRU(3G)
Power Supply –48 V
Operation temperature BBU: –20°C to +55°C
RRU: –40°C to +50°C
Relative humidity BBU: 5% to 95%
RRU: 5% to 100%
Transmission Support E1, IP
BBU3900:
Table 11 Baseband Unit BBU3900
GSM only UMTS only GSM+UMTS
Capacity 72 TRXs: 24/24/24 24 carriers: 8/8/8 G24/24/24+U8/8/8
Transmission 8 E1/T1, 2 FE 48 E1/T1, 2 FE 40 E1, 2FE
GE Transmission 2 Optical GE
Capacity GSM only: 24/24/24
UMTS only: 8/8/8 (1536 CE for both DL, UL)
G+U: 24/24/24+ 8/8/8 (1536 CE for both DL, UL)
Size 86mm(H)*442mm(W)*310mm(D)
Working temp -20~55℃
Board Description
Common Bard FAN: the FAN unit
UPEU: Power module
GSM Board GTMU: the main control board
UMTS Board WMPT: WCDMA Main Processing Transmission unit
WBBP: WCDMA Baseband Processing unit.
GE Transmission Board UTRP: Universal Transmission Processing unit
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RF Unit:
Table 12 MRFU for Proposed Macro Indoor/Outdoor GSM
RF Unit Item Specification
MRFU/GSM
Frequency band 900M or 1800M
Output power 80W
Size(H*W*D) 485mm*380mm*170mm
Weight 23KG
Capacity GSM: 6TRXs with static TOC as below: 1 TRX: 60W, 2 TRX: 40W, 3 TRX: 27W, 4 TRX: 20W, 5 TRX: 16W, 6 TRX:12W
Working temp -40~50℃
Table 13 RRU3908 for Proposed Distributed GSM
RF Unit Item Specification
RRU3908/GSM
Frequency band 1900M/1800M/900M/850M
Output power 80W
Size(H*W*D) 485mm×380mm×170mm
Weight 23KG
Capacity GSM: 6 TRXs with static TOC as below: 1 TRX: 40W, 2 TRX: 40W, 3 TRX: 20W, 4 TRX: 15W, 5 TRX: 12W, 6 TRX: 10W
Working temp -40~50℃ (without solar radiation)
Table 14 RRU3804 for Proposed Distributed WCDMA
RF Unit Item Specification
RRU3804/WCDMA
Frequency band 2100M/AWS/1900M/850M
Output power 60W
Size(H*W*D) 485mm×285mm×170mm
Weight 17KG
Capacity UMTS :4 Carriers with static TOC as below: 1 carrier: 60W, 2 carrier: 30W, 3 carrier: 20W, 4 carrier: 15W
Working temp -40~55℃ (without solar radiation)
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3.3.4.4 Proposed IP Clock Server Equipment
For IP clock server, Huawei proposes IPCLK1000. It uses the same service data
transmission protocols as those for data transmission between the integrated
BSC/RNC and the BTS/NodeB. While the integrated BSC/RNC and BTS/NodeB have
embedded the function of IP Clock client, therefore, the introduction of IPCLK1000 has
no additional requirements for topologies or for Qos performance of networks. Besides,
it can be installed alone, in an integrated BSC/RNC cabinet or any other cabinet that is
300 mm in depth. In this proposal, Huawei provides one IP clock server for BSC and
one IP clock server for RNC.
Table 15 Proposed IP Clock Server– IPCLK1000
IP Clock Item Specification
IPCLK1000
Capacity 512 BTS/NodeBs
Dimensions 436 mm (width) x 240 mm
(depth) x 43.6 mm (height)
Weight ≤ 5 kg
Power Consumption < 50 W
System availability ≥ 99.999%
MTBF (Mean Time Between Failures) ≥ 355,000 h
MTTR (Mean Time To Repair) ≤ 1 h
Clock hold duration after the loss of
clock source Seven days
Operation Temperature
Short-term working condition
-5°C to + 55°C
Long-term working condition
0°C to 45°C
3.3.4.5 Proposed OMC-R Equipment
In the Telecommunication Management Network (TMN), the M2000 is on the Element
Management-layer (EM-layer). The M2000 also provides a network management
interface for the Network Management System (NMS).
Huawei proposes M2000 can manage both GSM and UMTS equipments, from
NodeB/BTS to integrated BSC/RNC and also includes the IP clock server.
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Figure 16 Position of the M2000 in the Network
Considering the existing type of VMS‟s M2000 server is SUN server, so proposed
M2000 server in this project is also a SUN server and the specification is shown as
below:
Table 16 Proposed M2000 Equipment Specification
M2000 Item Specification
M5000 Server
Server Model Sun Sparc Enterprise M5000
Server
Number of CPUs 4
Number of Essential NEs Center I: <190
Center V: <190
Cabinet N610E
Cabinet dimensions (W x D x H) 600 mm x 1,000 mm x 2,200
mm
Power input (V) AC: 220V (100 to 240)
DC: -48 to 60V
Main frequency of the CPU 2.53 GHz
Memory 32 GB
Operating system Solaris 10/English
documentation
Database Sybase 15.0.2 or above
Working Temperature Nominal: 5°C to 35°C
Safe: 0°C to 40°C
3.3.4.6 Proposed PRS Equipment
The PRS is a platform used to manage mobile network performance reports and analyze
network performance. The PRS is responsible for managing the performance data
collected by multiple mobile network devices such as WRAN devices, GBSS devices,
SingleRAN devices, Core Network devices, CDMA devices, WiMAX devices, TD-SCDMA
devices, LTE devices, uBro devices, and IMS devices.
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Table 17 Proposed PRS Equipment Specification
Object Configuration Requirement
PRS server Server type: HP DL785G6
CPU: 8 x 2.8GHz 8439 SE (six-core)
Memory: 16 x 4GB
Hard disk: 2 x 300 GB
S2600 Storage Array (12 x 450 GB) + D120S Disk Management
Enclosure (12 x 450 GB)
Tape drive: HP LTO4
Integrated NIC (dual ports) + 1000M NIC (four ports)
1Port 8Gb Fibre HBA: 2
SAS card: 1
Accessories: DVD
PRS client Client type: a common PC
CPU: E5300 or above
Memory: 4 GB
Hard disk: 320 GB or above
Accessories: DVD-RW/ NIC/19 inch wide LCD
The PRS manages different NEs of different network systems. The processing
efficiency varies depending on the NE type and the network system. When the PRS
server uses different server types, the management capability can be measured by
equivalent NEs. For details, please see the following table.
Table 18 Management capability of the PRS server
Server Type Management Capability (Number of
Equivalent NEs)
HP DL785 ≤ 800
3.3.4.7 Proposed Transport Equipment
OSN7500 is offered as the SDH layer equipment, and NE40E is offered as packet layer
equipment. OSN7500 will be deployed at hub-site transport node, OSN7500+NE40E will
be deployed at RNC-site transport node. Its specification in detail is listed below:
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Table 19 Proposed Transport Node Equipment Specification
MUX Equipment Item Specification
OSN7500
Physical frame 496.4mm (W) x 295mm (D)
x 756.7mm (H)
Switch matrix 360G SDH switch
160G packet switch
Equipment resilience XCS, SCA: 1+1 redundancy
Clock and timing: 1+1
redundancy
Power: 1+1 redundancy
E1: 1:4 TPS
Interface Type Entire Equipment Access
Capability
Fast Ethernet (FE) services 64
Gigabit Ethernet (GE) services 96
10 Gigabit Ethernet (10GE)
services
44
CES (E1) services 252
CES (channelized STM-1)
services
32
Fast Ethernet (FE) services 64
Gigabit Ethernet (GE) services 96
Weight Rack: 35kg;
Full configuration: 60kg
Operation Temperature
Short-term working
condition -5°C to + 55°C
Long-term working condition
0°C to 45°C
Gigabit Ethernet (GE) services 96
MUX Equipment Unit Equipment Parameter
NE40 E-X3
Physical frame DC:442(W)*650(D)*175(H)
AC:442(W)*650(D)*220(H)
Switch matrix 1.08Tbps
Equipment resilience MPU 1:1 backup
Power 1+1 backup
Fan 1+1 backup
Clock and timing: 1+1
redundancy
Interface Type Entire Equipment Access
Capability
Fast Ethernet (FE) services 120
Gigabit Ethernet (GE) 120
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services
10 Gigabit Ethernet (10GE)
services
12
CES (E1) services 288
CES (channelized STM-1)
services
24
Fast Ethernet (FE) services 120
Gigabit Ethernet (GE)
services
120
Weight DC:41KG
AC:51KG
Operation Temperature -40°C~70°C
Gigabit Ethernet (GE)
services
120
Huawei‟s packet transport network, achieves SDH-like mobile transport network with
carrier class performance. It enables the same performance as the existing mobile
transmission networks. OSN7500 and NE40E offers the same operational and
maintenance capabilities as the existing mobile transmission networks such as E2E
provisioning, alarm and performance monitoring.
3.3.4.8 Proposed OMC-T Equipment
For OMC-T, Huawei proposes iManager U2000 OptiX Management System (hereafter
referred to as the U2000). The U2000 can perform centralized management on
transmission NEs provided by Huawei. These NEs include NE Routers, PTN series
packet transmission equipment, OSN series and metro series SDH transmission
equipment, RTN series microwave equipment and DWDM equipment. In this proposal,
the offered U2000 server type Sun T5220 with 4 CPUs.
Table 20 Proposed U2000 Equipment Specification
U2000 Item Specification
T5520 Server
Server model Sun T5220 Single Server
Number of CPUs 4C*1.2GHz,
Memory (GB) 16G(8*2G
Hard disk (GB) 6*146GB
Cabinet dimensions (W x D x H) 600 mm x 1,000 mm x 2,200
mm
Cabinet power input (V) 100V~240VAC
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3.3.4.9 Proposed Power Supply and Battery Equipment
Table 21 The offered Power Supply and Battery Equipment
TP48300/A
Maximum Capacity 300A(6*50A rectifier)
Dimension 420mm(with)x360mm(depth)x700mm(height)
Working
temperature
-20°C to +50°C (working for a short period when
the temperature ranges from 50°C to 65°C)
Working humidity 5% to 95%
Input voltage 90 V AC to 290 V AC (220 V AC by default)
Input frequency 45 Hz to 65 Hz (50 Hz by default)
Input mode Three-phase four-line mode by default (L1, L2,
L3, and N)
If the power supply is in single-phase mode (L
and N), connect the three lines (L1, L2, and L3)
of the AC input circuit breaker, and then
connect them to the L line.
Dual-live wire
Output voltage 43.2 V DC to 57.6 V DC; rated voltage: 53.5 V
Output power
For the EPW50-48A rectifier modules:
The input voltage ranges from 176 V AC to 290
V AC. The power output of a single module is
2900 W, and the power output of six modules
is 17400 W.
The input voltage ranges from 90 V AC to 175 V
AC. The power output of a single module is 1200 W,
and the power output of six modules is 7200 W.
DC power
distribution
Battery branch: Two circuits, 160 A
Branch of the LLVD load(default): Two 80 A
circuit breakers, one 100 A circuit breaker, and
position reserved for five circuit breakers
Branch of the BLVD load(default): One 32 A
circuit breakers, two 16 A circuit breakers, and
one 63 A circuit breaker, and position reserved
for two circuit breakers
Maximum Capacity 200A(4*50A rectifier)
Dimension 600 mm(width) x 480 mm(depth) x 1200
mm(height)
Working
temperature
-33°C (-27.4°F) to +50°C (122°F) (without sun
radiation). 50°C (122°F) to 65°C (149°F) is the
temperature for short-term operation.
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TP48200A
Working humidity 5% to 95%
Input voltage 90 V AC to 290 V AC single-phase voltage
Input frequency 45 Hz to 65 Hz (50 Hz by default)
Input mode Three-phase five-line cable (L1, L2, L3, N,
PE)/Single-phase three-line cable (L, N, PE)
Output voltage 43.2 V to 57.6 V
Output power
11,600 W for single-phase input voltage from
176 V AC to 290 V AC;
4,800 W for single-phase input voltage from 90 V
AC to 175 V AC
DC power
distribution
Battery branch: 125 A MCB x 2
Battery Low Voltage Disconnection (BLVD/LVD):
32 A MCB x 1; 16 A MCB x 4; 10 A MCB x 1
Low Voltage Disconnection (LLVD/NPLD): 100 A
MCB x 2; 20 A MCB x 6
TP48600B
Maximum Capacity 600A
Dimension 600 mm(width) x 450 mm(depth) x 1600
mm(height)
Working
temperature
-20°C to +50°C (working for a short period when
the temperature is between 50°C and 65°C)
Working humidity 5% to 95%
Input voltage 90 V AC to 290 V AC phase voltage (380 V AC
line voltage by default)
Input frequency 45 Hz to 65 Hz (50 Hz by default)
Input mode Three-phase four-line mode (L1, L2, L3, and N)
Output voltage 43.2 V to 57.6 V
Max Output power
34800 W for single-phase input voltage between
176 V AC and 290 V AC;
14400 W for single-phase input voltage between
90 V AC and 175 V AC
DC power
distribution
Battery branch: 500 A x 2 (FUSE)
Load shutdown: 100 A x 6 (FUSE), 63 A x 6, 32 A
x 4, 10 A x 2
Battery shutdown: 63 A x 2, 32 A x 2, 10 A x 2
Advantages of TP48300/A:
Mini Size: It is a mini telecom power supply system. It is compact and lightweight,
saving the space of the equipment room.
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Abundant Installation Scenarios: It can be installed on the battery shelf, ground,
or 19-inch open rack.
Easy Module Installation: The monitoring module and rectifier module can be
easily inserted into or removed from subracks without tools.
Intelligent Sleep Mode Technology: According to the load power, the power
supply system automatically starts or shuts down one or more rectifier modules.
Remote Monitoring: The TP48300/A provides sound management of the power
supply system and storage batteries. The monitoring module communicates with
the rectifier module through the RS-485 serial port and communicates with the
host through the RS-422 or RS-232 serial port.
Advantages of TP48200A:
The TP48200A is an integrated backup power system that applies to class B outdoor
application scenarios. It provides the stable -48 V DC output, backup power for 1
battery-string, and 6 U installation space for customer devices. The TP48200A has
features such as easy installation of modules, intelligent module sleep, remote
monitoring, and wide range of AC input voltage.
Easy Installation of Modules: The monitoring module (PMU) and rectifier
module (PSU) are hot-swappable, thus facilitating the installation, saving
maintenance time, and reducing the OPEX.
Intelligent Sleep Technology: According to the load power, the power system
automatically enables one or more PSUs to enter the sleep mode.
Remote Monitoring: The TP48200A power system provides comprehensive
management on itself and storage batteries. The PMU communicates with the
PSU through the RS485 serial port and communicates with the main equipment
through the RS232/422/485 serial port. In addition, the SNMP communication
module enables the monitoring over the Ethernet. This feature helps to reduce the
OPEX by implementing the remote monitoring and unattended operations.
Wide Range of AC Input Voltage: The AC input voltage of the system ranges
from 90 V AC to 290 V AC phase voltage
Advantages of TP48600B:
Easy Module Installation: The monitoring module and rectifier module are
hot-swappable, thus facilitating the installation, saving maintenance time, and
reducing the OPEX.
Intelligent Sleep Technology: According to the load power, the power system
automatically starts the sleep mode of rectifier modules to save power.
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Remote Monitoring: The TP48600B power system provides comprehensive
management on itself and storage batteries. The monitoring module
communicates with the rectifier module through the RS-485 serial port and
communicates with the host through the RS-232/422/485 serial port, thus
realizing remote monitoring and unattended operations. This helps to reduce the
OPEX.
Extended AC Input Voltage Range: The AC input phase voltage of the system
ranges from 90 V AC to 290 V AC.
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3.4 Main Equipment Offered
According to VMS‟s requirements of 2G/3G system, Huawei designs and proposes
corresponding equipment as described in Chapter 3.3.
Table 22 Offered Integrated BSC/RNC and 2G/3G integrated SingleBTS in Center I
and V
Site configuration Center I and V
Center Location Center I Center V
Total TRXs per BSC 2048 2048
Maximum 2G
Subscriber Number
supported per Center
2.88 million 3.45 million
Total Subs per RNC 400,000 300,000
Total Integrated
BSC/RNC 5 6
Total 3G Subscriber
Number per Center 2,000,000 1,800,000
2G/3G integrated
SingleBTS Type
Site
Qty (I)
TRX
Qty (I)
Cell
Qty (I)
Site
Qty
(V)
TRX
Qty (V)
Cell
Qty (V)
Total
Site
(I+V)
Total
TRX
(I+V)
Total
Cell
(I+V)
BTS3900 GSM
900MHz S444+DBS
UMTS S222 130 1560 780 120 1440 720 250 3000 1500
BTS3900 GSM
900MHz
S222+1800MHz
S222+DBS UMTS
S222 110 1320 660 190 2280 1140 300 3600 1800
BTS3900A GSM
900MHz
S222+1800MHz
S222+DBS UMTS
S222 230 2760 1380 180 2160 1080 410 4920 2460
DBS3900 GSM
900MHz S444+DBS
UMTS S222 100 1200 600 100 1200 600 200 2400 1200
Total 570 6840 3420 590 7080 3540 1160 13920 6960
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3.4.1 Offered BSC/RNC Hardware
For 2G, in order to support at least 2048 TRXs, the offered hardware capability of each
BSC is listed in the following table.
Table 23 Offered BSC Hardware Capacity for Center I & V
BSC Name
Center I
TRX Qty
Supported by
Hardware
Erlang
Supported by
Hardware
CIC
Supported by
Hardware
BHCA
supported by
Hardware
SS7
supported
by
Hardware
PDCH Qty
supported
by
Hardware
Gb
Throughput
supported
by
Hardware
(Mbps)
BSC 1 2560 14406 14336 4200000 32 1024 64
BSC 2 2560 14406 14336 4200000 32 1024 64
BSC 3 2560 14406 14336 4200000 32 1024 64
BSC 4 2560 14406 14336 4200000 32 1024 64
BSC 5 2560 14406 14336 4200000 32 1024 64
BSC Name
Center V
TRX Qty
Supported by
Hardware
Erlang
Supported by
Hardware
CIC
Supported by
Hardware
BHCA
supported by
Hardware
SS7 Link
supported
by
Hardware
PDCH Qty
supported
by
Hardware
Gb
Throughput
supported
by
Hardware
(Mbps)
BSC 1 2560 14406 14336 4200000 32 1024 64
BSC 2 2560 14406 14336 4200000 32 1024 64
BSC 3 2560 14406 14336 4200000 32 1024 64
BSC 4 2560 14406 14336 4200000 32 1024 64
BSC 5 2560 14406 14336 4200000 32 1024 64
BSC 6 2560 14406 14336 4200000 32 1024 64
The BSC minimum TRX requirement is 2048 TRXs, with 30% hardware capacity redundancy.
Each BSC is designed with 2048 TRX where the hardware can support at maximum up to
2560 number of TRX
The table shows the interface bearer type and capacity supported by the offered BSC in both
Center I and Center V. All 11 BSC models have the same configuration.
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Table 24 Offered BSC Port Capacity for Center I & V
Network
Unit Interface
Interface
Type
Interface Port
Required in RFP
(Active + Standby)
Interface Port
Supported by Hardware
(Active + Standby)
BSC6900
(GSM)
Abis TDM/STM-1 8+8 11+11
IP/GE 2+2 4+4
A TDM/STM-1 2+2 3+3
Gb FR/E1 32+32 64+64
IP/FE 1+1 12+12
A IP/FE 1+1 12+12
All the interface ports comply with active and standby redundancy configuration.
For 3G, in order to support 300NodeBs/900Cells and 3Gbps throughput, the offered hardware
capability of each RNC is listed in the following table.
Table 25 Offered RNC Hardware Capacity
RNC Name
Center I
NodeB Qty
Supported by
Hardware
Cells Qty
Supported by
Hardware
Throughput
Supported by
Hardware (Mbps)
Iub Capacity
Supported by
Hardware (Erl)
BHCA (K)
supported by
Hardware
RNC 1 1440 3,000 5,000 33,500 1033
RNC 2 1440 3,000 5,000 33,500 1033
RNC 3 1440 3,000 5,000 33,500 1033
RNC 4 1440 3,000 5,000 33,500 1033
RNC 5 1440 3,000 5,000 33,500 1033
RNC Name
Center V
NodeB Qty
Supported by
Hardware
Cells Qty
Supported by
Hardware
Throughput
Supported by
Hardware (Mbps)
Iub Capacity
Supported by
Hardware (Erl)
BHCA (K)
supported by
Hardware
RNC 1 1080 2,700 4,500 30,150 774
RNC 2 1080 2,700 4,500 30,150 774
RNC 3 1080 2,700 4,500 30,150 774
RNC 4 1080 2,700 4,500 30,150 774
RNC 5 1080 2,700 4,500 30,150 774
RNC 6 1080 2,700 4,500 30,150 774
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In order to meet the Iub throughput requirement of 3Gbps, the offered RNC throughput is shown
as table above. In Chapter 4.1.2.1, the details of the dimension process in Center I will be
described. In Chapter 4.1.2.2, the details of the dimension process in Center V will be described.
The table shows the interface bearer type and capacity supported by the offered RNC.
Table 26 Offered RNC Port Capacity for Center I & Center V
Network
Unit Interface Interface Type
Interface Port
Required in RFP
(Active + Standby)
Interface Port
Supported by Hardware
(Active + Standby)
BSC6900
(UMTS)
Iub
ATM/STM-1
VC-12 12+12 20+20
IP/GE 8+8 12+12
IuCS ATM/STM-1 VC-4 4+4 8+8
IP/GE optical 2+2 4+4
IuPS ATM/STM-1 VC-4 4+4 8+8
IP/GE optical 2+2 8+8
Iur
ATM/STM-1 VC-4 Share with IuCS Share with IuCS
IP/GE optical Share with IuCS Share with IuCS
All the interface ports comply with active and standby redundancy configuration. The 35%
redundancy based on VMS‟s requirement has been considered in the interface port
configuration as the table above.
The following diagrams show the offered integrated BSC/RNC model with the complete
configuration of the processing modules in Center I and Center V respectively. From the
diagram below, in Center I and Center V, one GSM cabinet, one UMTS cabinet, 3 GSM
sub-racks and 3 UMTS sub-racks are configured and offered for the integrated BSC/RNC
model respectively.
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Figure 17 Configuration of the Processing Modules for Each Offered BSC6900 in Center I
Figure 18 Configuration of the Processing Modules for Each Offered BSC6900 in Center V
The following table shows the main hardware configuration of the offered BSC model which fulfills
the integrated BSC/RNC capacity.
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Table 27 Main Hardware Configuration of the Offered Integrated BSC/RNC in Center I & Center V
Main
Hardware
Configuration
per RNC
Board
Quantity
Center I
Board
Quantity
Center V
Total Capacity
Supported
Center I
Total Capacity
Supported
Center V
Redundancy
UMTS Data
Processing
Unit (DPUe)
10 9
PS throughput:
5000 Mbps or CS
Erlang: 33500 Erl
PS throughput:
4500 Mbps or CS
Erlang: 30150 Erl
Resource
Pool
UMTS
Signaling
Processing
Unit (SPUb)
8+8 6+6 1033K (BHCA) 774K (BHCA) 1+1
GSM Data
Processing
Unit (DPUd)
1+1 1+1 1024 PDCH 1024 PDCH N+1
GSM
Extensible
Processing
Unit (XPUb)
4+4 4+4 2560 TRX 2560 TRX 1+1
General Clock
Unit (GCUa) 2+2 2+2 - - 1+1
The following table shows the offered main processing unit with the capacity configuration.
Table 28 Main Processing Unit Capacity
Main processing unit Capacity per unit Redundancy
UMTS Data Processing Unit (DPUe) 3350 Erl / 500Mbps Resource Pool
UMTS Signaling Processing Unit
(SPUb)
The BHCA varies by
operator traffic model ,
maximum support 140k
BHCA per unit 1+1
GSM eXtensible Processing Unit
(XPUb) 640 TRX 1+1
GSM Data Processing Unit (DPUd) 1024 PDCH N+1
General Clock Unit (GCU) N/A 1+1
The power system for BSC is sharing with RNC. The table below shows the power system
and battery being offered for each integrated BSC/RNC.
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Table 29 Offered Power System and Battery for Each Integrated BSC/RNC in
Center I & V
Power Consumption (W) Backup Time Power system Rectifier Battery
10200 6 TP48600B 8*50A 2*800Ah
Note: The power consumption as stated above is the power consumption for the integrated
BSC/RNC model and the battery backup time is designed to be 6 hours based on the
requirement.
3.4.2 Offered TC Hardware
According to VMS‟s requirement in RFP, the total TC capacity needs to support at least 7
STM-1 interface for Ater interface and 27 STM-1 interface for A interface for total 5 TC in
Center I, while need to support at least 7 STM-1 interface for Ater interface and 28 STM-1
interface for A interface for total 6 TC in Center V. Therefore, for each TC in Center I, at least
3 STM-1 interface for Ater interface and 8 STM-1 interface for A interface while for each TC in
Center V, at least 3 STM-1 interface for Ater interface and 7 STM-1 interface for A interface is
offered with the consideration of the 30% redundancy requirement.
Table below shows the port capacity supported by each offered TC.
Table 30 Offered TC Hardware for each BSC in Center I and V
Network Unit Interface Interface Type Interface Port Supported by
Hardware (Active + Standby)
TC in Center I
Ater TDM/STM-1
VC-12 3+3
A TDM/STM-1
VC-12 8+8
TC in Center
V
Ater TDM/STM-1
VC-12 3+3
A TDM/STM-1
VC-12 7+7
The hardware configuration for each TC that can support the minimum requirement on port
numbers and the TC capacity is shown as the table below.
Table 31 Offered TC Hardware for Each BSC in Center I and V
Hardware Center I Qty Center V Qty
Cabinet + Subracks 1+2 1+2
Data Processing Unit
for Transcoder 14 14
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TDM Interface Unit
(STM-1, Chn) for Ater
interface
3+3 3+3
TDM Interface Unit
(STM-1, Chn) for A
interface
8+8 7+7
The power consumption for TC unit is offered as below and the battery backup time is
6 hours as required.
Table 32 Power System for TC
Power Consumption (W) Backup Time Power system Rectifier Battery
3400 6 TP48300/A 4*50A 4*150Ah
3.4.3 Offered SingleRAN Features
Huawei offers the software feature package to meet VMS requirements including GSM,
UMTS and OMC-R functions covering the requirement in scope of supply, technical
specification, Appendix 2 - Required Features.
The software feature package Huawei offered includes all Huawei basic features, for
details, please refer to the “2.7 Feature List & Description”, Secondly, this software
feature package includes Huawei optional features required by VMS in this project,
which is listed as below table
The detailed features have been listed out in the following.
3.4.3.1 Offered Huawei BSC Optional Features:
Table 33 Offered GSM BSC Optional Features
No. GSM BSC Optional Feature list
1 Coverage Enhancement
1.1 Dynamic Transmit Diversity (per TRX)
1.2 Dynamic PBT (per TRX)
1.3 TD/4RD Diversity
2 Wide Coverage
2.1 Extended Cell (per Cell)
3 Voice Capacity Improvement
3.1 Concentric Cell (per TRX)
3.2 900M/1800M Co-BCCH (per TRX)
3.3 Multi-band sharing one BSC (per TRX)
3.4 Enhanced Dual-Band Network (per TRX)
3.5 Flex MAIO (per TRX)
4 Frequency efficiency improvement
4.1 Frequency Hopping (per TRX)
4.2 BCCH Carrier Frequency Hopping (per TRX)
4.3 Antenna Frequency Hopping (per TRX)
4.4 E-GSM and R-GSM RF Band (per TRX)
5 Network Synchronization
5.1 BSS Soft-Synchronized Network (per TRX)
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5.2 BTS GPS Synchronization (per TRX)
5.3 Clock Over IP(per TRX)
5.4 Clock over IP support 1588V2(per TRX)
6 Energy Saving
6.1 HUAWEI III Power Control Algorithm (per TRX)
6.2 Discontinuous Transmission(DTX) Downlink (per TRX)
6.3 Discontinuous Transmission(DTX) Uplink (per TRX)
6.4 TRX Power Amplifier Intelligent Shutdown (per TRX)
6.5 TRX Power Amplifier Intelligent Shutdown on the timeslot level (per TRX)
6.6 Intelligent Combiner Bypass (per TRX)
6.7 Active Backup Power Control (per TRX)
6.8 Power Optimization Based on Channel Type (per TRX)
6.9 PSU Smart Control (per TRX)
6.10 Enhanced BCCH Power Consumption Optimization (per TRX)
6.11 TRX Working Voltage Adjustment(per TRX)
6.12 Dynamic Cell Power Off (per TRX)
6.13 Multi-Carrier Intelligent Voltage Regulation (per TRX)
7 Abis Transmission Saving
7.1 16K LAPD (per TRX)
7.2 Flex Abis (per TRX)
7.3 Abis Transmission Optimization (per TRX)
7.4 Abis Congestion Trigger HR Distribution (per TRX)
8 A Transmission Saving
8.1 Flex Ater (per TRX)
8.2 Ater Compression Transmission (per TRX)
9 Hardware Saving
9.1 TrFO (per TRX)
10 Networking Framework
10.1 Multi-cell Function (per TRX)
11 System reliability
11.1 Ring topology (per TRX)
11.2 TRX Cooperation (per TRX)
11.3 MSC Pool (per TRX)
11.4 Abis Bypass (per BTS)
11.5 Robust Air Interface Signaling (per TRX)
11.6 Abis Transmission Backup(per TRX)
11.7 TC Pool (per TRX)
12 High Speed Coverage
12.1 High Speed PBGT Switch (per TRX)
13 2G/3G Seamless Coverage
13.1 GSM/WCDMA Interoperability (per TRX)
13.2 GSM/WCDMA Service Based Handover (per TRX)
13.3 GSM/WCDMA Load Based Handover (per TRX)
13.4 2G/3G Cell Reselection Based on MS State (per TRX)
13.5 Fast 3G Reselection at 2G CS Call Release (per TRX)
14 Big Capacity BSC
14.1 High Speed Signaling (per TRX)
14.2 Local Multiple Signaling Points (per TRX)
15 Maintainability
15.1 Semi-Permanent Connection (per Link)
15.2 End-to-End MS Signaling Tracing (per TRX)
15.3 Maintenance Mode Alarm (per TRX)
16 Power Control Algorithm
16.1 Positive Power Control (per TRX)
17 Network Security
17.1 Encryption(A5/1,A5/2) (per TRX)
17.2 Encryption(A5/3) (per TRX)
17.3 A5/1 Encryption Flow Optimization (per TRX)
17.4 Encrypted Network Management (per TRX)
17.5 NAT Beside OM(per TRX)
18 Enhanced Voice Service
18.1 Enhanced Full-Rate Voice Software (TS11) (per TRX)
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18.2 Half Rate Speech (perTRX)
18.3 Dynamic Adjustment Between FR and HR (perTRX)
19 Cell Broadcast
19.1 Cell Broadcasting Short message Software (per TRX)
19.2 Simplified Cell Broadcast (per TRX)
20 CS General Enhancement
20.1 Automatic Level Control (per TRX)
20.2 Acoustic Echo Cancellation (per TRX)
20.3 Automatic Noise Restraint (ANR) (per TRX)
20.4 TFO (per TRX)
20.5 Automatic Noise Compensation (ANC) (per TRX)
20.6 Enhancement Packet Loss Concealment(EPLC) (per TRX)
20.7 Voice Quality Index (VQI) (per TRX)
20.8 Enhanced Measurement Report(EMR) (per TRX)
20.9 BTS power lift for handover (per TRX)
20.10 Dynamic HR/FR Adaptation (per TRX)
21 AMR Package
21.1 AMR FR (per TRX)
21.2 AMR HR (per TRX)
21.3 AMR Power Control (per TRX)
21.4 AMR FR/HR Dynamic Adjustment (per TRX)
21.5 AMR Wireless Link Timer (per TRX)
21.6 AMR Coding Rate Threshold Adaptive Adjustment (per TRX)
22 PS QOS
22.1 Support Streaming QoS Guarantee (per 64Kbps)
22.2 QoS ARP&THP (per 64Kbps)
22.3 PS Active Package Management(per 64Kbps)
22.4 PoC QoS(per TRX)
22.5 Conversational QoS (per 64Kbps)
22.6 PS Service in Priority (per 64Kbps)
23 Cell Reselection of PS Domain
23.1 Network-Controlled Cell Reselection (NC2) (per TRX)
23.2 Network Assisted Cell Change (NACC) (per TRX)
23.3 Packet SI status (per 64Kbps)
24 GPRS/EGPRS Service
24.1 GPRS Software (per TRX)
24.2 Network Operate Model 1 Function (per 64Kbps)
24.3 Support CS3/CS4 Translate Mode (per 64Kbps)
24.4 EDGE Service (per TRX)
24.5 Dynamic Allocation of PDCH (per TRX)
24.6 Gb over FR (per 64Kbps)
25 GPRS/EGPRS Service Enhancement
25.1 11-Bit EGPRS Access (per 64Kbps)
25.2 Packet Assignment Taken Over by the BTS (per 64Kbps)
25.3 Extended Uplink TBF (per 64Kbps)
25.4 Dynamically Adjusting the Uplink MCS Coding (per 64Kbps)
25.5 Dynamically Adjusting the RRBP Frequency (per 64Kbps)
25.6 Channel Dispatching (per 64Kbps)
25.7 Load Sharing (per 64Kbps)
25.8 Adaptive Adjustment of Uplink and Downlink Channels (per 64Kbps)
25.9 BSS Paging Coordination(per TRX)
25.10 PS Handover (per 64Kbps)
25.11 Early TBF Establishment (per 64Kbps)
25.12 PS Power Control (per 64Kbps)
26 High Speed Data Service
26.1 EDA (per 64Kbps)
26.2 MS High multislot classes (per 64Kbps)
26.3 DTM(per 64Kbps)
26.4 HMC DTM(per 64Kbps)
26.5 14.4Kbps Circuit Switched Data (per TRX)
27 VIP Service Support
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27.1 Resource Reservation (per TRX)
27.2 Enhanced Multi-Level Precedence and Preemption (per TRX)
27.3 Flow Control Based on Cell Priority (per TRX)
28 LCS
28.1 NSS-based LCS (Cell ID + TA) (per TRX)
28.2 BSS-based LCS (Cell ID + TA) (per TRX)
28.3 Simple Mode LCS (Cell ID + TA) (per TRX)
28.4 Lb Interface (per TRX)
29 Abis IP
29.1 Abis over IP (per TRX)
29.2 Abis IP over E1/T1 (per TRX)
29.3 Abis MUX (per TRX)
30 A IP
30.1 A over IP (per TRX)
30.2 A IP over E1/T1 (per TRX)
30.3 UDP MUX for A Transmission (per TRX)
30.4 TDM/IP Dual Transmission over A Interface (per TRX)
31 Gb IP
31.1 Gb over IP (per 64Kbps)
32 IP Enhancement
32.1 IP QOS(per TRX)
32.1 IP Performance Monitor(per TRX)
32.1 IP Fault Detection Based on BFD (per TRX)
32.1 Ethernet OAM (per TRX)
33 Handover
33.1 HUAWEI II Handover (per TRX)
33.2 Handover Re-establishment (per TRX)
34 RAN Sharing
34.1 IMSI-Based Handover (per TRX)
35 EDGE Evolution
35.1 MSRD (per TRX)
35.2 Dual Carriers in Downlink (per TRX)
35.3 Uplink EGPRS2-A (per TRX)
35.4 Downlink EGPRS2-A (per TRX)
35.5 Latency Reduction (per 64Kbps)
36 Perfomance Analysis Toolkit
36.1 2G/3G Neighboring Cell Automatic Optimization (per TRX)
37 Emergency Communications
37.1 License Control for Urgency (per TRX)
38 GSM and UMTS and LTE Common Transmission
38.1 2G and 3G Co-transmission by TDM Switching (per TRX)
39 Paging Capability Improvement
39.1 Multiple CCCHs (per TRX)
3.4.3.2 Offered Huawei RNC Optional Features:
Table 34 Offered UMTS RNC Optional Features
No. UMTS RNC Optional Feature list
1 Multiple RAB Package (PS RAB >=2) (per Mbps/Erl)
2 AMR-WB (Adaptive Multi Rate Wide Band) (per Erl)
3 CS voice over HSPA/HSPA+ (per Mbps)
4 HSDPA Introduction Package (per Mbps)
5 HSDPA Enhanced Package (per Mbps)
6 Streaming Traffic Class on HSDPA (per Mbps)
7 32 HSDPA Users per Cell (per Mbps)
8 64 HSDPA Users per Cell (per Mbps)
9 HSDPA 3.6Mbps per User (per Mbps)
10 HSDPA 7.2Mbps per User (per Mbps)
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11 HSDPA 13.976Mbps per User (per Mbps)
12 HSDPA over Iur (per Mbps)
13 SRB over HSDPA (per Mbps)
14 HSUPA Introduction Package (per Mbps)
15 HSUPA Phase 2 (per Mbps)
16 Streaming Traffic Class on HSUPA (per Mbps)
17 60 HSUPA Users per Cell (per Mbps)
18 HSUPA over Iur (per Mbps)
19 SRB over HSUPA (per Mbps)
20 HSPA+ Downlink 21Mbps per User (Per Mbps)
21 HSPA+ Downlink 28Mbps per User (Per Mbps)
22 Downlink Enhanced L2 (per Mbps)
23 MBMS Introduction Package (per Mbps)
24 MBMS Phase 2 (per Mbps)
25 Cell Broadcast service (per Mbps/Erl)
26 Simplified Cell Broadcast(per Mbps/per Erl)
27 Cell ID + RTT Function Based LCS (per Mbps/Erl)
28 OTDOA Based LCS (per Mbps/Erl)
29 A-GPS Based LCS (per Mbps/Erl)
30 Iu-PC Interface for LCS service (per Mbps/Erl)
31 LCS Classified Zones (per Mbps/Erl)
32 Differentiated Service Based on SPI Weight (Per Mbps)
33 Fractional ATM Function (per Mbps/Erl)
34 Fractional IP Function on Iub interface (per Mbps/Erl)
35 IP transmission(lub) (per Erl )
36 IP transmission(lub) (per Mbps)
37 IP transmission(lu) (per Erl )
38 IP transmission(lu) (per Mbps)
39 UDP MUX for Iu-CS Transmission (Per Erl)
40 IP transmission(lur) (per Mbps/Erl)
41 ATM/IP Dual Stack NodeB (per Mbps/Erl)
42 FP MUX for IP Transmission (per Mbps/Erl)
43 Dynamic Bandwidth Control of Iub IP (per Mbps/Erl)
44 Traffic Priority Mapping on Transport (per Mbps/Erl)
45 Hybrid Iub IP Transmission (per Mbps/Erl)
46 Overbooking on ATM Transmission (per Mbps/Erl)
47 Overbooking on IP Transmission (per Mbps/Erl)
48 Access Class Restriction (per Mbps/Erl)
49 IMSI Based Handover(InterRAT or Intra RAT) (per Mbps/Erl)
50 Iu FLEX Introduction (per Mbps/Erl)
51 Iu Flex Load Distribution Management (per Mbps/Erl)
52 Active Queue Management (AQM) (per Mbps)
53 Inter Frequency Hard Handover Based on Coverage (per Mbps/Erl)
54 Inter Frequency Hard Handover Based on DL QoS (per Mbps/Erl)
55 SRNS Relocation Introduction Package (per Mbps/Erl)
56 Inter-RAT Handover Based on Coverage (per Mbps/Erl)
57 Video Telephony Fallback to Speech (AMR) (per Erl)
58 PS Inter-RAT Handover Phase 2 (per Mbps)
59 3G/2G Common Load Management (per Mbps/Erl)
60 TFO/TrFO (per Erl)
61 AMR/WB-AMR Speech Rates Control (per Erl)
62 Intra Frequency Load Balance (per Mbps/Erl)
63 Queuing and Pre-Emption (per Mbps/Erl)
64 RAB Quality of Service Renegotiation over Iu Interface (per Mbps)
65 Rate Negotiation at Admission Control (per Mbps)
66 License Control for Urgency (per Mbps/Erl)
67 DRD Introduction Package (per Mbps/Erl)
68 Inter-RAT Redirection Based on Distance (per Mbps)
69 Measurement Based Direct Retry (per Mbps)
70 Inter Frequency Load Balance (per Mbps/Erl)
71 Inter-RAT Handover Based on Load (per Mbps/Erl)
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72 Inter-RAT Handover Based on Service (per Mbps/Erl)
73 Inter-RAT Handover Based on DL QoS (per Mbps/Erl)
74 RNC One Tunnel (per Mbps)
75 Multi-Carrier Switch off Based on Traffic Load (per Mbps/Erl)
76 Service Steering and Load Sharing in RRC Connection Setup (per Mbps/Erl)
77 Downlink TCP Accelerator (Per Mbps)
78 Uplink Flow Control of User Plane (per Mbps/Erl)
3.4.3.3 Offered Huawei SingleBTS Optional Features:
Table 35 Offered SingleBTS Optional Features
No. SingleBTS Optional Feature list
1 ==Multi-Mode Software ==
1.1 Multi-mode TDM Co-Transmission (GBTS)
1.2 Multi-mode TDM Co-Transmission (NodeB)
1.3 Multi-mode IP Co-Transmission (GBTS)
1.4 Multi-mode IP Co-Transmission (NodeB)
1.5 Multi-mode BS Common Reference Clock (GBTS)
1.6 Multi-mode BS Common Reference Clock (NodeB)
1.7 Multi-mode Dynamic Power Sharing (GSM)
1.8 Multi-mode Dynamic Power Sharing (UMTS)
1.9 Multi-mode Bandwidth sharing of Co-Transmission (GBTS)
1.10 Multi-mode Bandwidth sharing of Co-Transmission (NodeB)
2 ==HSDPA==
2.1 HSDPA
2.2 HSDPA Code No. per Site
2.3 Dynamic Allocation HSDPA
3 ==HSUPA==
3.1 HSUPA
3.2 Dynamic CE Resource Management
3.3 HSUPA Iub Flow Control
4 ==HSPA+==
4.1 DL 64QAM
4.2 2*2 MIMO
5 ==MBMS Function==
5.1 MBMS or Not
5.2 No. of MBMS Channels per Cell
5.3 No. of MBMS Cells
6 ==RAN Capacity Enhancement ==
6.1 4-Antenna Receive
6.2 Flexible frequency bandwidth of UMTS carrier
6.3 Multi-Carrier Switch off Based on Power Backup(per NodeB)
6.4 Dynamic Power Sharing in Multi-Carriers
7 ==IP Transmission==
7.1 IP Clock Synchronization
7.2 Ethernet Synchronization
7.3 Ethernet Operation and Maintenance
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3.4.3.4 Offered Huawei OMC-R (M2000) Optional Features:
Table 36 Offered OMC-R (M2000) Optional Features
No. M2000 Optional Feature list
1 Alarm CORBA Interface-GBSS(per TRX)
2 Alarm CORBA Interface-WRAN(per Cell)
3 CORBA Performance Interface-GBSS(per TRX)
4 CORBA Performance Interface-WRAN(per Cell)
5 File Alarm Data Interface-GBSS(per TRX)
6 File Alarm Data Interface-WRAN(per Cell)
7 File Performance Data Interface-GBSS(per TRX)
8 File Performance Data Interface-WRAN(per Cell)
9 File Configuration Data Interface-GBSS(per TRX)
10 File Configuration Data Interface-WRAN(per Cell)
11 File Inventory Interface-GBSS(per TRX)
12 File Inventory Interface-WRAN(per Cell)
13 SNMP Alarm Interface-GBSS(per TRX)
14 SNMP Alarm Interface-WRAN(per Cell)
15 NE Software Management (per TRX)
16 NE Software Management-WRAN(per Cell)
17 Inventory Management-GBSS(per TRX)
18 Inventory Management-WRAN(per Cell)
19 Alarm remote notification-GBSS(per TRX)
20 Alarm remote notification-WRAN(per Cell)
21 Real-Time Performance Monitoring-GBSS(per TRX)
22 Real-Time Performance Monitoring-WRAN(per Cell)
23 GBSS Cell Measurement Statistics and Special Analysis (per TRX)
24 Integrated Network Monitoring of RAN-GBSS(per TRX)
25 Integrated Network Monitoring of RAN-WRAN(per Cell)
26 Network Time Synchronization Solution-GBSS(per TRX)
27 Network Time Synchronization Solution-WRAN(per Cell)
28 iSStar-WRAN(per Cell)
29 iSStar-GBSS(per TRX)
30 IP QoS Management-WRAN(per Cell)
31 Antenna Fault Detector-GBSS (per TRX)
32 GSM Compact BTS Automatic Planning(per TRX)
33 GSM Compact BTS Frequency Automatic Optimizing(per TRX)
34 GSM Compact BTS Automatic Capacity Planning (per TRX)
35 SingleBTS management-GBSS(per TRX)
36 SingleBTS management-WRAN (per Cell)
37 Device Panel of SingleBTS-WRAN (per Cell)
38 Device Panel of SingleBTS-GBSS(per TRX)
39 SingleBTS Auto-Deployment -GBSS(per TRX)
40 SingleBTS Auto-Deployment -WRAN(per cell)
41 NodeB Auto-Deployment-WRAN(per cell)
42 BTS Auto-Deployment -GBSS (per TRX)
43 Antenna Manangement System -GBSS(per TRX)
44 Centralized User Management Interface based on LDAP (per system)
45 Centralized User Authentication Interface based on LDAP (per system)
46 Antenna Manangement System-WRAN(per cell)
47 WRAN CME-NodeB Reparenting(per Cell)
48 SingleBTS Site Creation-GBSS (per TRX)
49 SingleBTS Site Creation-WRAN (per cell)
50 CME-SingleBTS Public Resource Consistency Check-WRAN (per Cell)
51 CME-SingleBTS Public Resource Consistency Check-GBSS (per TRX)
52 Antenna Fault Detector-WRAN(per cell)
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Thirdly, Huawei also fulfills the features on GSM BSC, UMTS RNC, SingleBTS and
OMC-R, which is marked as “Optional” by VMS in this project and listed as below:
3.4.3.5 Supported Huawei GSM BSC Features:
Table 37 Supported Huawei GSM BSC Features
1 GSM BSC Support Feature list
2 Voice Capacity Improvement
2.1 ICC(Inference Counteract Combine) (per TRX)
2.2 EICC (per TRX)
3 Frequency efficiency improvement
3.1 IBCA (Interference Based Channel Allocation) (per TRX)
4 Network Synchronization
4.1 Synchronous Ethernet (per TRX)
5 Abis Transmission Saving
5.1 BTS Local Switch (per TRX)
6 A Transmission Saving
6.1 BSC Local Switch (per TRX)
7 Networking Framework
7.1 SGSN Pool (per 64Kbps)
7.2 Ring Network Fast Switching (per TRX)
7.3 BSC Node Redundancy (per TRX)
7.4 OML Backup (per TRX)
8 BTS Satellite Transmission
8.1 Satellite transmission mode(Abis interface) (per BTS)
9 BSC Satellite Transmission
9.1 Satellite Transmission Mode(A interface) (per BSC)
9.2 Satellite transmission mode(Ater interface) (per BSC)
9.3 Satellite transmission mode(Pb interface) (per BSC)
9.4 Satellite Transmission over Gb Interface (per 64Kbps)
10 AMR Package
10.1 WB AMR (per TRX)
11 High Speed Data Service
11.1 Class11 DTM(per 64Kbps)
12 Terminal Package
12.1 Network Support SAIC (per TRX)
13 RAN Sharing
13.1 RAN Sharing (per TRX)
13.2 MOCN Shared Cell (per TRX)
14 GSM and UMTS Common Radio Resource Management Based on Iur-g
14.1 Load Based Handover Enhancement on Iur-g (per TRX)
14.2 NACC Procedure Optimization Based on Iur-g between GSM and UMTS (per TRX)
14.3 GSM and UMTS Load Balancing Based on Iur-g (per TRX)
14.4 GSM and UMTS Traffic Steering Based on Iur-g (per TRX)
15 GSM and LTE Seamless Coverage
15.1 Cell Reselection Between GSM and LTE (per TRX)
3.4.3.6 Supported Huawei UMTS RNC Features:
Table 38 Supported Huawei UMTS RNC Features
No. Supported UMTS RNC Feature list
1 VoIP over HSPA/HSPA+ (per Mbps)
2 96 HSDPA Users per Cell (per Mbps)
3 128 HSDPA Users per Cell (per Mbps)
4 96 HSUPA Users per Cell (per Mbps)
5 128 HSUPA Users per Cell (per Mbps)
6 CPC - DTX / DRX (Per Mbps)
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7 CPC - HS-SCCH less operation (Per Mbps)
8 Enhanced CELL-FACH (Per Mbps)
9 HSPA+ Downlink 42Mbps per User (per Mbps)
10 MBMS 8 channels per cell (per Mbps)
11 256Kbps Channel Rate on MBMS (per Mbps)
12 MBMS FLC(Frequency Layer Convergence)/FLD(Frequency Layer Dispersion) (per Mbps)
13 MBMS 16 channels per Cell (per Mbps)
14 MBMS over Iur (per Mbps)
15 Dynamic Power Estimation for MTCH (per Mbps)
16 MSCH and MSCH Scheduling (Per Mbps)
17 MBMS Channel Audience Rating Statistics (Per Mbps)
18 LCS over Iur (per Mbps/Erl)
19 Satellite Transmission on Iub Interface (per E1)
20 Satellite Transmission on Iu Interface (per E1)
21 RAN Sharing Introduction Package (per Mbps/Erl)
22 RAN Sharing Phase 2 (per Mbps/Erl)
23 Mobility Between UMTS and LTE Phase 1 (per Mbps)
25 Load Based Inter-RAT Handover Enhancement Based on Iur-g(per Mbps/Erl)
26 NACC Procedure Optimization Based on Iur-g(per Mbps)
27 GSM and UMTS Load Balancing Based on Iur-g(per Mbps/Erl)
28 GSM and UMTS Traffic Steering Based on Iur-g(per Mbps/Erl)
29 MOCN Introduction
3.4.3.7 Supported Huawei SingleBTS Features:
Table 39 Supported Huawei SingleBTS Features
No. SingleBTS Supported Feature list
1 ==HSPA+==
1.2 DL 64QAM+MIMO
1.3 UL 16QAM
1.4 DC-HSDPA
2 ==RAN Architecture & Functions==
2.1 Transmit Diversity
2.2 Extended Cell Coverage
2.3 MOCN Introduction
3 ==Capacity Enhancement==
3.1 IC Function
3.2 FDE Function
3.3 UL L2 Enhanced
3.4.4 Offered 2G/3G Integrated SingleBTS
Huawei offered 2G/3G integrated SingleBTS fully comply with VMS‟s requirements:
Frequency Band:
900MHz (890MHz - 915MHz Uplink and 935MHz - 960MHz Downlink).
1800MHz (1710MHz - 1785MHz Uplink and 1805MHz - 1880MHz Downlink).
2100MHz (1920MHz - 1980MHz Uplink and 2110MHz - 2170MHz Downlink).
Radio Module Type (SDR):
For GSM: MRFU with static 20W/TRX and RRU3908 with static 20W/TRX.
For UMTS: RRU3804 with static 20W/Carrier.
Hardware:
GSM S4/4/4 900MHz, GSM S4/4/4 1800MHz
UMTS S4/4/4 2100MHz
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384 CE UL/384CE DL;
HSDPA peak rate up to 21Mbps per cell;
HSUPA peak rate up to 5.76Mbps per cell.
RTU:
GSM S4/4/4 900MHz, GSM S2/2/2 1800MHz, with static TOC 20W
UMTS S2/2/2 2100MHz, with static TOC 20W per carrier
384 CE UL/384 CE DL;
HSDPA 21Mbps & HSUPA 5.76Mbps per cell;
IP clock synchronization.
Antenna:
Antenna Single Band, 1800MHz
Antenna Single Band, 2100MHz
Antenna Dual Band, 900M/1800MHz
Antenna Dual Band 3 in 1 cluster
Antenna Triple Band (900MHz/1800MHz,2100MHz)
Antenna Triple Band 3 in 1cluster
Trasmission interface:
ATM with at least 04 E1 interfaces towards RNC (Iub);
TDM with at least 04 E1 interfaces towards BSC (Abis);
Native IP with total 02 electrical FE and 02 optical GE interfaces
For details of 2G/3G integrated SingleBTS configuration, please refer to the submitted
BOQ.
Based on the above minimum requirements, totally 4 types of 2G/3G integrated
SingleBTS models have been offered by Huawei, as shown in the table below.
Table 40 Offered 2G/3G Integrated SingleBTS Models
Module Type
BTS3900 GSM
(900M S444)+DBS
WCDMA S222
BTS3900 GSM (900M
S222+1800M
S222)+DBS WCDMA
S222
BTS3900A GSM (900M
S222+1800M
S222)+DBS WCDMA
S222
DBS3900 GSM
(900M S444)+DBS
WCDMA S222
Base Station Baseband
Unit (BBU) Box 1 1 1 1
WCDMA Main
Processing
&Transmission Unit
(WMPT) (4E1&1
electrical FE&1 optical
FE)
1 1 1 1
WCDMA Baseband
Processing & Interface
Unit (WBBPd1)(6Cell,CE:
UL 192/DL192)
2 2 2 2
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GSM Main Control and
Transport unit(4E1&1
electrical FE&1 optical FE
with 72 TRX)
1 1 1 1
IP Interface Unit (2 FE/GE
Optical) 1 1 1 1
RF Unit for Multi-Mode
900MHz (80W) 3 3 3 NA
RF Unit for Multi-Mode
1800MHz (80W) NA 3 3 NA
RRU for WCDMA
2100MHz (60W) 3 3 3 3
RRU for Multi-Mode
900MHz (80W) NA NA NA 3
RRU for Multi-Mode
1800MHz (80W) NA NA NA NA
DCDU 1 1 1 1
Notes:
Huawei proposes WBBPd1 as the WCDMA NodeB baseband processing board,
which can provides 192/192CE DL/UL and support 6 cells and it is hardware
ready for HSPA+ Phase 2.
The following table shows the configured number of E1, electrical FE and optical GE for each
offered SingleBTS models.
Table 41 Offered 2G/3G Integrated SingleBTS Models with the configured E1 and FE and GE
number.
Site Type No. of E1/FE electrcial/GE optical
BTS3900 GSM (900M S444)+DBS
WCDMA S222 8 E1 + 2 FE electrical + 2 GE optical
BTS3900 GSM (900M S222+1800M
S222)+DBS WCDMA S222 8 E1 + 2 FE electrical + 2 GE optical
BTS3900A GSM (900M S222+1800M
S222)+DBS WCDMA S222 8 E1 + 2 FE electrical + 2 GE optical
DBS3900 GSM (900M S444)+DBS
WCDMAS222 8 E1 + 2 FE electrical + 2 GE optical
The corresponding TRX/Carrier/Power/CE/HSPA capacities with RTU licenses are listed out for
further reference in the following table.
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Table 42 Offered TRX/Carrier/CE/HSPA capacities of 2G/3G Integrated SingleBTS‟s Models
Configuration
Site Type
BTS3900 GSM
(900M S444)+DBS
UMTS S222
BTS3900 GSM (900M
S222+1800M
S222)+DBS UMTS
S222
BTS3900A GSM
(900M S222+1800M
S222)+DBS UMTS
S222
DBS3900 GSM
(900M S444)+DBS
UMTS S222
GSM TRX Qty
Supported by Hardware 18 (S666 900M)
36 (S666 900M + S666
1800M)
36 (S666 900M + S666
1800M) 18 (S666 900M)
RTU for GSM TRX 12 (S444 900M) 12 (S222 900M +S222
1800M)
12 (S222 900M +S222
1800M) 12 (S444 900M)
WCDMA Cell Qty
Supported by Hardware 12 12 12 12
UL CE Supported by
Hardware 384 384 384 384
DL CE Supported by
Hardware 384 384 384 384
HSDPA Capacity
HSPA+ 21Mbps per
cell
( 6*15 codes +
64QAM)
HSPA+ 21Mbps per
cell
( 6*15 codes + 64QAM)
HSPA+ 21Mbps per
cell
( 6*15 codes + 64QAM)
HSPA+ 21Mbps per
cell
( 6*15 codes +
64QAM)
HSUPA Capacity HSUPA Phase2 with
5.76Mbps per cell
HSUPA Phase2 with
5.76Mbps per cell
HSUPA Phase2 with
5.76Mbps per cell
HSUPA Phase2 with
5.76Mbps per cell
RTU for CE UL 384 384 384 384
RTU for CE DL 384 384 384 384
For all WCDMA S222 sites, the BBU is configured with one WBBPd1 (WCDMA BaseBand
Processing unit) card to support 6 cells and ready to support up to 12 cells with the supported
CE 384/384 for DL/UL. Therefore, this fulfilled the VMS RFP requirement where the 2G/3G
integrated SingleBTS is ready to expand to S333 UMTS configuration as well as S444
UMTS configuration.
Totally 7230 sets of antenna are offered for this proposal. Antenna type and number have
been listed herein.
Table 43 Offered Antenna for 2G/3G Integrated SingleBTS
Site Type Sector
no. Site Qty Model Antenna description
Antenna
Quantity
Marco indoor GSM900
S444+3G DBS S222 3 250
ADU451700
Dual
band,824~960/1710~2170MHz-17.5dBi
/18dBi-65deg/65deg-2 connectors
750
A19451803 Single band antenna,
1710~2170MHz,18dBi,65deg 750
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Marco indoor GSM900
S222+GSM1800
S222+3G DBS S222
3 300
ADU451700
Dual
band,824~960/1710~2170MHz-17.5dBi
/18dBi-65deg/65deg-2 connectors
780
A19451803 Single band antenna,
1710~2170MHz,18dBi,65deg 780
ATR451703
Triple band antenna,
824~960/1710~2170/1710~2170MHz,
18/17.5/17.5dBi-65deg/65deg/65deg-6
connectors
60
TTS-809017/1
82017/182017
DE-65F
Triple-band 3 in 1 cluster antenna,
824~960/1710~2170/1710~2170MHz, 20
Marco outdoor GSM900
S222+GSM1800
S222+3G DBS S222
3 410
ADU451700
Dual
band,824~960/1710~2170MHz-17.5dBi
/18dBi-65deg/65deg-2 connectors
1110
A19451803 Single band antenna,
1710~2170MHz,18dBi,65deg 1110
ATR451703
Triple band antenna,
824~960/1710~2170/1710~2170MHz,
18/17.5/17.5dBi-65deg/65deg/65deg-6
connectors
60
TTS-809017/1
82017/182017
DE-65F
Triple-band 3 in 1 cluster antenna,
824~960/1710~2170/1710~2170MHz, 20
DBS GSM900 S444+3G
DBS S222 3 200
ADU451700
Dual
band,824~960/1710~2170MHz-17.5dBi
/18dBi-65deg/65deg-2 connectors
540
A19451803 Single band antenna,
1710~2170MHz,18dBi,65deg 540
TTS-809017/1
82018DE-65F(
C2)
dualband-band 3 in 1 cluster antenna,
824~960/1710~2170MHz 20
additional materials for
split and re-installation
of existing high
configuration BTS
3 230 A19451803 Single band antenna,
1710~2170MHz,18dBi,65deg 690
Total 7230
The corresponding power consumption of each type of 2G/3G integrated configuration is
listed in the table below. For more details, please refer to Product Description.
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Table 44 2G/3G Integrated SingleBTS Power Consumption List
2G/3G Integrated SingleBTS Name Avg Power per
NE (DC,W)
Max Power per
NE (DC,W)
BTS3900 GSM S4/4/4+DBS3900 WCDMA S2/2/2
(GSM:900MHz; WCDMA 2100MHz) 1170 1890
BTS3900 GSM S2/2/2&S2/2/2+DBS3900
WCDMA S2/2/2 (GSM:900MHz&1800MHz;
WCDMA 2100MHz)
1620 2310
BTS3900A GSM S2/2/2&S2/2/2+DBS3900
WCDMA S2/2/2 (GSM:900MHz&1800MHz;
WCDMA 2100MHz)
1620 2350
DBS3900 GSM S4/4/4+DBS3900 WCDMA S2/2/2
(GSM:900MHz; WCDMA 2100MHz) 1180 1780
Based on the power consumption, 4 types of different power and battery configurations are
being offered:
Table 45 Offered Power and Battery for 2G/3G Integrated SingleBTS
BTS Type Backup Time Power system Rectifier Battery
BTS3900 GSM S4/4/4+DBS3900
WCDMA S2/2/2 (GSM:900MHz;
WCDMA:Band 1 2100MHz;
WCDMA:CE U:384 D:384; DC -48V)
6 hours TP48300/A 3*50A 2*150Ah
BTS3900 GSM
S2/2/2&S2/2/2+DBS3900 WCDMA
S2/2/2 (GSM:900MHz&1800MHz;
WCDMA:Band 1 2100MHz;
WCDMA:CE U:384 D:384; DC -48V)
6 hours TP48300/A 3*50A 3*150Ah
BTS3900A GSM
S2/2/2&S2/2/2+DBS3900 WCDMA
S2/2/2 (GSM:900MHz&1800MHz;
WCDMA:Band 1 2100MHz;
WCDMA:CE U:384 D:384; DC -48V)
6 hours TP48200A 3*50A 3*150Ah
DBS3900 GSM S4/4/4+DBS3900
WCDMA S2/2/2 (GSM:900MHz;
WCDMA:Band 1 2100MHz;
WCDMA:CE U:384 D:384; DC -48V;
Indoor)
6 hours TP48300/A 3*50A 2*150Ah
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3.4.5 Offered 2G/3G Integrated SingleBTS RF Connection with Feeder and Antenna
The following diagram shows the RF part of interconnection between Macro/ Distributed
2G/3G integrated SingleBTS, antenna and feeder system.
Considering Huawei‟s RFU/RRU can support 6 TRXs or 4 Carriers with just one unit of
hardware, so the RF connection is very convenient, just one RF unit for one sector is enough,
whatever regardless it is the Outdoor Macro BTS (BTS3900A), Indoor Macro BTS (BTS3900),
Distributed BTS (DBS3900) or the Distributed NodeB (DBS3900).
Figure 19 RF Part Interconnection between RF/Antenna/Feeder & Jumper per Sector
Following figures show the detailed connection and installation auxiliaries for DBS3900
/BTS3900A /BTS3900.
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Figure 20 RF Part for Interconnection between DBS3900 and Antenna, Feeder System
Figure 21 RF Part for Interconnection between BTS3900A and Antenna, Feeder System
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Figure 22 RF Part for Interconnection between BTS3900 and Antenna, Feeder System
The number and model of all equipment using for RF connection are shown in the
following table (duplexer, diplexer, combiner, antenna…).
With Huawei advanced RF design, the function of the duplexer and multi-carrier power
amplifier have been implemented in the RF unit, so there is no external duplexer or
combiner are needed, only the jumper and feeder are needed to connect with antenna.
Following shows the cables for power supply, transmission and grounding protection.
Table 46 Cables for power supply, transmission and grounding protection
3.4.6 Offered OMC & PRS server
According to VMS‟s requirement, the OMC main equipments, central room equipment,
as well as remote room equipment offered in Center I and V is shown as the table
below. For details, please refer to the submitted BOQ.
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Table 47 Offered OMC Hardware in Center I and V
Main Equipment Center I Quantity Center V Quantity
Center Room Equipment
Center Room 1 1
Server Module Support 190 NE
(SUN M5000, 4 CPU, Single
Server)
1 1
Ethernet Switch (24FE+4GE) 2 2
Operating & Maintenance
Terminal 1 1
Alarm Terminal 1 1
Remote Room Equipment
Remote Room 5 6
Ethernet Switch (24FE+4GE) 10 12
Operating & Maintenance
Terminal 5 6
Alarm Terminal 5 6
In addition, the offered equipment of PRS server for Center I & V is shown as the table
below. For more details, please refer to the submitted BOQ.
Table 48 Offered PRS server Hardware in Center I and V
Main Equipment Center I
Quantity
Center V
Quantity
PRS server Equipment
iManager Server Module(HP
DL785G6) 1 1
Ethernet Switch (24FE+4GE) 2 2
3.4.7 Offered Transport Node
There are total 33 transport nodes for supporting transmission between 2G/3G
integrated SingleBTS and RNC. DDF, ODF, power supply land U2000 equipment are
also included.
Table 49 Transport Node Hardware Configurations in Center I and V
HUB-site Transport Node Quantity
Center I 126 E1, 16 FE (electrical), 04 STM-1 (S1.1) and 04 GE (optical,
1000Base LX) interfaces. 360G SDH switch and 160G packet
switch
10
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Center V 126 E1, 16 FE (electrical), 04 STM-1 (S1.1) and 04 GE (optical,
1000Base LX) interfaces. 360G SDH switch and 160G packet
switch
12
RNC-site Transport Node Quantity
Center I 252 E1, 20 FE (optical, 100BaseFX), 20 STM-1 (S1.1), 04
STM-4 (S4.1), 24 GE (optical, 1000Base LX) and 04 10xGE
(optical, 10GE-ER) interfaces. OSN7500: 360G SDH switch
and 160G packet switch and NE40E: 1.08Tbps
5
Center V 252 E1, 20 FE (optical, 100BaseFX), 20 STM-1 (S1.1), 04
STM-4 (S4.1), 24 GE (optical, 1000Base LX) and 04 10xGE
(optical, 10GE-ER) interfaces. OSN7500: 360G SDH switch
and 160G packet switch and NE40E: 1.08Tbps
6
U2000 Sun T5220 server with software and license
DDF&ODF 33 sets
Power supply 33 sets
The power consumption and system for each set of equipment in both Hub-site and
RNC-site transport nodes are shown in the following table.
Table 50 Offered MUX Power Supply and Battery
TN Type Consumption (W) Backup Time Power system Rectifier Battery
TN (HUB) 1100 6 TP48300/A 2*50A 2*150Ah
TN (RNC) 2200 6 TP48300/A 3*50A 3*150Ah
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4. Network Dimensioning
The proposed network topology and dimensioning results (throughput and physical
ports) are given, for SingleRAN and OMC respectively, in the following sections.
4.1 SingleRAN Network Dimensioning
4.1.1 BSC Model Dimensioning
There are 5 BSC offered for 570 sites in Center I and 6 BSC offered for 590 sites in
Center V. According to VMS‟s requirement, Huawei RNP plans the site/TRX distribution
as below:
Table 51 RNP Planned Site/TRX Distribution for each BSC
Center I Site No. TRX No.
BSC 1 114 1368
BSC 2 114 1368
BSC 3 114 1368
BSC 4 114 1368
BSC 5 114 1368
Center V Site No. TRX No.
BSC 1 99 1180
BSC 2 99 1180
BSC 3 99 1180
BSC 4 99 1180
BSC 5 99 1180
BSC 6 99 1180
Considering 30% throughput redundancy requirement and minimum 2048 TRXs
capability for BSC, the actual sites and TRXs configuration for each BSC are shown as
below.
Table 52 Minimum Site/Cell Configuration for Each BSC
Center I
*30% Redundancy BSC Capacity
Site No. TRX No. Min TRX No.
Required
TRX No.
Dimensioned
BSC 1 149 1779 2048 2048
BSC 2 149 1779 2048 2048
BSC 3 149 1779 2048 2048
BSC 4 149 1779 2048 2048
BSC 5 149 1779 2048 2048
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Center V Site No. TRX No. Min TRX No.
Required
TRX No.
Dimensioned
BSC 1 129 1534 2048 2048
BSC 2 129 1534 2048 2048
BSC 3 129 1534 2048 2048
BSC 4 129 1534 2048 2048
BSC 5 129 1534 2048 2048
BSC 6 129 1534 2048 2048
Refer to the Table 51 and Table 52 as above:
In Center I, with 30% redundancy, the TRX number calculated for each BSC model
= 1368 * (100% + 30%) = 1779 TRX.
In Center V, with 30% redundancy, the TRX number calculated for each BSC
model = 1180 * (100% + 30%) = 1534 TRX.
As stated in the tender document, the minimum configuration for each BSC is to
support 2048 TRXs.
Since the TRX number for each BSC in Center I and Center V is still less than the
minimum TRX requirement from VMS after considering the 30% redundancy, therefore,
the TRX number is dimensioned and designed as 2048 TRXs for each BSC in Center I
and Center V.
4.1.1.1 Center I
The following shows the formulae for the BSC model throughput in Center I.
A-CIC Channel = ErlangB_Device (A-Erlang, A GOS)
A-Erlang = ErlangB (average TCH-PDCH)*(1+HR ratio), Abis GOS)*3*BTS
number*A:Um ratio*Index ratio.
PDCH Channel= (Static PDCH / Cell +Dynamic PDCH / Cell *Dynamic PDCH Active
ratio) * BTS Cell number
Gb throughput = subs*throughput per user/1024/1024/Gb utilization ratio
Based on the mentioned formula above, the calculation result shown in the table below;
Table 53 Center I: GSM Throughput Results Dimensioned with the Optimized Traffic Model
BSC Model Throughput
A Erl Requirement 11,975
HR Active Ratio Requirement 0.3
A-CIC Requirement 11,927
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BHCA Requirement (CS) 2,130,952
SS7 Link Requirement (High Speed Link) 3
PDCH Requirement 684
Gb Throughput Requirememnt (Mbps) 7.832
The detailed calculation (2048 TRXs/BSC) is shown as below;
A-Erlang = ErlangB((average TCH-PDCH)*(1+HR ratio), Abis GOS)*3*BTS
number*A:Um ratio*Index ratio.
Taking HR ratio: 30%; Um GOS / Abis GOS: 1% / 3%, A:Um ratio: 80%, BTS Qty: 114
Average TRX per cell: 2048/3/114 = 5.9883 = 6
Table 54 Center I: Erlang Calculation
TRX per
cell BCCH
HR
SDCCH PDCH
HR
Ratio HR+FR TCH
Um
Gos Traffic
6 1 6 1 30% (6*8-1-6-1)*(1+30%)=52 0.03 erlangb_traffic(52,
0.03)=43.85
So, A-Erlang = 43.85 * 3 * 114 * 80% * (5.9883/6) = 11,975 Erl
A CIC Channel = ErlangB_Device (A Erlang, A GOS)
= ErlangB_ Device(11,975, 1%)
= 11,927
PDCH Channel= (Static PDCH / Cell +Dynamic PDCH / Cell *Dynamic PDCH Active
ratio) * BTS Cell number
= (1 + 2*0.5) * 114 * 3 = 684
Gb throughput = subs*throughput per user/1024/1024/Gb utilization ratio
The active percentage of the GPRS is assumed to be 10%
GPRS Subs = Total Erl / Average voice traffic per subscriber (Erlang) * 10%
= 11975/ 0.025*10%
= 47,900 subs
Gb throughput = 47900 *120bps/1024/1024/ 0.7
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= 7.832Mbps
Maximum Subscribers supported (each BSC)
= 576,240
The specific dimensioning result of physical interface port numbers of each interface
is shown as below (all the interface ports comply with active and standby redundancy
configuration).
Table 55 Center I: Physical Interface Port for Each BSC Model
BSC Name Interface Name Bear Type
Number of Ports
required in RFP
(Active + Standby)
Number of Ports
(Active + Standby)
BSC 1 to
BSC 5
Abis
TDM over
STM-1 8+8 11+11
IP over GE 2+2 4+4
A TDM over
STM-1 2+2 3+3
A FE 1+1 12+12
Gb E1 32+32 64+64
FE 1+1 12+12
According to the dimensioning result, the BSC offered in Chapter 3.3.4.1 have fully
met with VMS dimensioning requirements.
4.1.1.2 Center V
The following shows the formulae for the BSC model throughput in Center V.
A-CIC Channel = ErlangB_Device (A-Erlang, A GOS)
A-Erlang = ErlangB (average TCH-PDCH)*(1+HR ratio), Abis GOS)*3*BTS
number*A:Um ratio*Index ratio.
PDCH Channel= (Static PDCH / Cell +Dynamic PDCH / Cell *Dynamic PDCH Active
ratio) * BTS Cell number
Gb throughput = subs*throughput per user/1024/1024/Gb utilization ratio
Based on the mentioned formula above, the calculation result shown in the table below:
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Table 56 Center V: GSM Throughput Results Dimensioned with the Optimized Traffic Model
BSC Model Throughput
A Erl Requirement 12,297
HR Active Ratio Requirement 0.3
A-CIC Requirement 12,246
BHCA Requirement (CS) 2,188,252
SS7 Link Requirement (High Speed Link) 3
PDCH Requirement 594
Gb Throughput Requirememnt (Mbps) 8.042
The detailed calculation (2048 TRXs/BSC) is shown as below;
A-Erlang = ErlangB((average TCH-PDCH)*(1+HR ratio), Abis GOS)*3*BTS
number*A:Um ratio*Index ratio.
Taking HR ratio: 30%; Um GOS / Abis GOS: 1% / 3%, A:Um ratio: 80%, BTS Qty: 99
Average TRX per cell: 2048/3/99 = 6.8956= 7
Table 57 Center V: Erlang Calculation
TRX per
cell BCCH
HR
SDCCH PDCH
HR
Ratio HR+FR TCH
Um
Gos Traffic
7 1 7 1 30% (7*8-1-7-1)*(1+30%)=61.1 0.03 erlangb_traffic(61.1,
0.03)=52.54
So, A-Erlang = 52.54 * 3 * 99 * 80% * (6.8956/7) = 12,297.32145 Erl = 12,297 Erl
A CIC Channel = ErlangB_Device (A Erlang, A GOS)
= ErlangB_ Device(12,297, 1%)
= 12,246
PDCH Channel= (Static PDCH / Cell +Dynamic PDCH / Cell *Dynamic PDCH Active
ratio) * BTS Cell number
= (1 + 2*0.5) * 99 * 3 = 594
Gb throughput = subs*throughput per user/1024/1024/Gb utilization ratio
The active percentage of the GPRS is assumed to be 10%
GPRS Subs = Total Erl / Average voice traffic per subscriber (Erlang) * 10%
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= 12297/ 0.025*10%
= 49,188 subs
Gb throughput = 49188 *120bps/1024/1024/ 0.7
= 8.042Mbps
Maximum Subscribers supported (each BSC)
= 576,240
The specific dimensioning result of physical interface port numbers of each
interface is shown as below (all the interface ports comply with active and standby
redundancy configuration).
Table 58 Center V: Physical Interface Port for Each BSC Model
BSC Name Interface Name Bear Type
Number of Ports
required in RFP
(Active + Standby)
Number of Ports
(Active + Standby)
BSC 1 to
BSC 6
Abis
TDM over
STM-1 8+8 11+11
IP over GE 2+2 4+4
A TDM over
STM-1 2+2 3+3
A FE 1+1 12+12
Gb E1 32+32 64+64
FE 1+1 12+12
4.1.2 RNC Model Dimensioning
According to VMS‟s requirement, Huawei RNP plans the site/cell distribution as
below:
Table 59 RNP Planned Site/Cell Distribution for each RNC
Center I Site No. Cell No.
RNC 1 114 684
RNC 2 114 684
RNC 3 114 684
RNC 4 114 684
RNC 5 114 684
Center V Site No. Cell No.
RNC 1 99 590
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RNC 2 99 590
RNC 3 99 590
RNC 4 99 590
RNC 5 99 590
RNC 6 99 590
Considering 35% throughput redundancy requirement and minimum 300 NodeBs
/900 Cells capability for RNC, so the actual sites and cells configuration for each
RNC shows as below.
Table 60 Minimum Site/Cell Configuration for each RNC
*35% Redundancy RNC Capacity
Center I Site No. Cell No. Site No. Cell No.
RNC 1 154 924 300 924
RNC 2 154 924 300 924
RNC 3 154 924 300 924
RNC 4 154 924 300 924
RNC 5 154 924 300 924
Center V Site No. Cell No. Site No. Cell No.
RNC 1 134 797 300 900
RNC 2 134 797 300 900
RNC 3 134 797 300 900
RNC 4 134 797 300 900
RNC 5 134 797 300 900
RNC 6 134 797 300 900
Refer to the Table 59 and Table 60:
In Center I, with 35% redundancy,
Total site number for each RNC = 114 * (100%+35%) = 154 sites
Total cell number for each RNC = 684 * (100%+35%) = 924 cells
In Center V, with 35% redundancy,
Total site number for each RNC = 99 * (100%+35%) = 134 sites
Total cell number for each RNC = 590 * (100%+35%) = 797 cells
As stated in the tender document, the minimum configuration for each RNC is to support
300 sites/900 cells, therefore, each RNC in Center I is dimensioned and designed with
300 sites/924 cells while each RNC in Center V is dimensioned and designed with 300
sites/900 cells. On the other hand, the minimum requirement for the RNC throughput is
at least support up to 3Gbps capacity throughput, however, this throughput requirement
cannot be met if the traffic parameter of PS throughput per sub is 152 bps.
So, in order to meet the minimum requirement as mentioned as above, the traffic model
for Center I and Center V are designed and dimensioned accordingly in adjusting the PS
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throughput per PS subscriber in Busy Hour (bps) to 2000 bps with the given total
subscribers number per integrated BSC/RNC based on Huawei‟s RNP calculation.
4.1.2.1 Center I
By optimizing the PS throughput per PS subscriber in Busy Hour to 2000 bps, the total
throughput is resulted to 1178.4 Mbps for each integrated BSC/RNC in Center I. The
following table shows that the total throughput resulted with the optimized traffic model in
Center I.
Table 61 Center I: Throughput Results Dimensioned with Required Traffic Model
IuB interface throughput
Iub CS voice (including SHO) (Erl) 13,000
Iub CS data (including SHO) (Erl) 390
Iub DL / UL payload throughput for CS voice (Mbps) 160
Iub DL / UL payload throughput for CS data (Mbps) 50.4
Iub DL payload throughput for PS R99 (including SHO) (Mbps) 544
Iub UL payload throughput for PS R99 (including SHO) (Mbps) 144
HSDPA throughput (Mbps) 264
HSUPA throughput (Mbps) 16
Total Payload Throughput (Mbps) 1178.4
Note:
The CS and PS total throughput (CS voice + CS data + PS(DL/UL)) fulfills and
satisfies the VMS’s requirement which is able to support 400,000 subscribers
number per RNC.
Following formulas well interpreted the calculation process of the Iub throughput.
Iub CS voice (including SHO) (Erl)
= Subscribers * CS voice penetration ratio * Voice Traffic per sub per BH * (1+ SHO Ratio)
=400000 * 100% * 0.025erlang * (1+ 30%)
=13,000 Erl
Iub CS data (including SHO) (Erl)
= Subscribers * CS data penetration ratio * CS data traffic per sub per BH *(1+ SHO Ratio)
=400000 * 30% * 0.0025erlang * (1+ 30%)
=390 Erl
Iub DL / UL payload throughput for CS voice (Mbps)
= Iub CS voice (including SHO) (Erl) * 2 (UL+DL) * CS Voice Active Factor * 0.0122Mbps
=13000 * 2 * 50% * 0.0122
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=160 Mbps
Iub DL / UL payload throughput for CS data (Mbps)
= Iub CS data (including SHO) (Erl) * 2 (UL+DL) * CS data Active Factor * 0.064Mbps
=243.75 * 2 * 1 * 0.064
=50.4 Mbps
Iub DL payload throughput for PS R99 (including SHO) (Mbps)
= Subscribers * PS penetration ratio * PS R99 DL payload throughput per sub / 1000
=400000 * 100% * 1.36kbps / 1000
=544 Mbps
(PS R99 DL payload throughput per sub
= Total PS throughput per user per BH * Proportion of DL PS throughput *
R99 share of DL PS throughput per sub * (1+ Proportion of SHO for PS call) / 1000
= 2000bps * 85% * 61.5% * (1+ 30%) / 1000
= 1.36 kbps)
Iub UL payload throughput for PS R99 (including SHO) (Mbps)
= Subscribers * PS penetration ratio * PS R99 UL payload throughput per sub / 1000
=400000 * 100% * 0.36kbps / 1000
=144 Mbps
(PS R99 UL payload throughput per sub
= Total PS throughput per user per BH * Proportion of UL PS throughput *
R99 share of UL PS throughput per sub * (1+ Proportion of SHO for PS call) / 1000
=2000bps * 15% * 90% * (1+ 30%) / 1000
=0.36 kbps)
HSDPA throughput (Mbps)
= Subscribers * PS penetration ratio * PS HSDPA DL payload throughput per sub / 1000
=400000 * 100% * 0.66kbps / 1000
=264 Mbps
(PS HSDPA DL payload throughput per sub
= Total PS throughput per user per BH * Proportion of DL PS throughput *
HSDPA share of DL PS throughput per sub / 1000
=2000bps * 85% * 38.5% / 1000
= 0.66 kbps)
HSUPA throughput (Mbps)
= Subscribers * PS penetration ratio * PS HSUPA UL payload throughput per sub / 1000
=400000 * 100% * 0.04kbps / 1000
=16 Mbps
(PS HSUPA UL payload throughput per sub
= Total PS throughput per user per BH * Proportion of UL PS throughput *
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HSUPA share of UL PS throughput per sub* ( 1+ Proportion of SHO for PS call)
/ 1000
=2000bps * 15% * 10% * (1+ 30%) / 1000
= 0.04kbps)
Total Payload Throughput of Iub (Mbps)
= Iub DL / UL payload throughput for CS voice (Mbps)
+ Iub DL / UL payload throughput for CS data (Mbps)
+ Iub DL payload throughput for PS R99 (including SHO) (Mbps)
+ Iub UL payload throughput for PS R99 (including SHO) (Mbps)
+ HSDPA throughput (Mbps)
+ HSUPA throughput (Mbps)
= 160+50.4 + 544+ 264 + 144+ 16
=1178.4 Mbps
All RNC are designed to be the same one to fulfill the minimum requirement of
300NodeB/900Cells..
Following table shows the quantity of main processing unit needed in order to support
400,000 subscribers number per RNC in Center I with the optimized 2000 bps PS
throughput per subscribers in Busy Hour.
Table 62 Center I: Main Processing Unit with 2000 bps PS throughput per subscribers in BH
Main Processing Unit Quantity
UMTS Data Processing Unit (DPUe) 7
UMTS Signaling Processing Unit
(SPUb) 8+8
Based on the total throughput of 1178.4 Mbps for each RNC, the hardware
configuration shall configure as below:
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Figure 23 RNC Hardware Configuration with Normal Traffic Model for Center I
However, the total throughput obtained to be 1178.4 Mbps cannot meet VMS‟s total
throughput requirement of 3Gbps. Therefore, by remaining the total subscriber number
and CS Erlang throughput, PS throughput need to be increased to 2032 Mbps by
adding UMTS Data Processing Unit and Hardware License.
The following table shows the total number of main processing unit for 3Gbps
throughput.
Table 63 Center I: Main Processing Unit with 3Gbps throughput
Main Processing Unit Quantity
UMTS Data Processing Unit (DPUe) 10
UMTS Signaling Processing Unit
(SPUb) 8+8
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Figure 24 Optimized Hardware Configuration to Meet 3Gbps Throughput for Center I
Therefore, the configuration of RNC can be summarized as the table below.
Table 64 Center I: Summary for Main Processing Unit in RNC
Hardware
Configuration
Normal Traffic
(1178.4Mbps)
Optimized Traffic
(3000Mbps)
UMTS Data
Processing Unit
(DPUe) QTY
7 10
UMTS Signaling
Processing Unit
(SPUb) QTY
8+8 8+8
Total Maximum
Throughput
Capacity
supported (Mbps
or Erlang)
PS throughput :3,500 Mbps
or CS Erlang : 23,450Erl
PS throughput :5,000 Mbps
or CS Erlang : 30,150Erl
The table below shows the interface throughput which satisfies the 3Gbps total
throughput requirement.
Table 65 Throughput offered with Optimized Traffic Model (3Gbps) per RNC
Iub interface throughput
Iub CS voice (including SHO) (Erl) 13,000
Iub CS data (including SHO) (Erl) 390
Iub DL / UL payload throughput for CS voice (Mbps) 160
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Iub DL / UL payload throughput for CS data (Mbps) 50.4
Iub DL payload throughput for PS R99 (including SHO) (Mbps) 1,576
Iub UL payload throughput for PS R99 (including SHO) (Mbps) 408
HSDPA throughput (Mbps) 760
HSUPA throughput (Mbps) 48
Total Payload Throughput (Mbps) 3002.4
All RNC are designed to be the same one to fulfill the minimum capacity requirement of
3Gbps throughput and 300NodeB/900Cells. The following table shows the number of Node
B and cell, and throughput configuration for each RNC models.
Table 66 Center I: Dimensioning result of RNC
RNC
Name
Subscribers
Qty
NodeB
Qty Cell Qty
Total Iub
Throughput
(Mbps)
Throughput
Iub PS
(Mbps)
Traffic Iub
CS Voice
(Erl)
Traffic Iub
CS VP
(Erl)
RNC 1 400000 300 924 3002.4 2792 13000 390
RNC 2 400000 300 924 3002.4 2792 13000 390
RNC 3 400000 300 924 3002.4 2792 13000 390
RNC 4 400000 300 924 3002.4 2792 13000 390
RNC 5 400000 300 924 3002.4 2792 13000 390
The specific dimensioning result of physical interface port numbers and physical throughput
of each interface are shown as below (all the interface ports comply with active and standby
redundancy configuration).
Note: The 35% redundancy based on VMS’s requirement has been considered in the
interface port configuration.
Table 67 Center I: Physical Interface Port for Each RNC Model
RNC
Name
Interface
Name Bear Type
Number of Ports
required in RFP
(Active + Standby)
Number of Ports
(Active + Standby)
RNC 1
to
RNC 5
To MGW
(Iu-CS, Mbps)
ATM over
STM-1 4+4 8+8
IP over Ge 2+2 4+4
To SGSN
(Iu-PS, Mbps)
ATM over
STM-1 4+4 8+8
IP over Ge 2+2 8+8
To NodeB
(Iub, Mbps)
ATM over
STM-1 12+12 20+20
IP over Ge 8+8 12+12
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To other
MBSC (Iur,
Mbps)
Share with
IuCS Share with IuCS Share with IuCS
Table 68 Center I: Physical Interface Throughput(UL+DL) for Each RNC Model
RNC Name Interface Name
Total UL+DL
Throughput
(Mbps)
RNC 1 to RNC 5
To MGW (Iu-CS) 313.75
To SGSN (Iu-PS) 2,588.82
To NodeB (Iub) 3,881.94
To other MBSC
(Iur) 385.53
4.1.2.2 Center V
By optimizing the PS throughput per PS subscriber in Busy Hour to 2000 bps, the total
throughput is resulted to 883.8 Mbps for each integrated BSC/RNC in Center V. The
following table shows that the total throughput resulted with the optimized traffic model in
Center V.
Table 69 Center V: Throughput Results Dimensioned with Required Traffic Model
IuB interface throughput
Iub CS voice (including SHO) (Erl) 9,750
Iub CS data (including SHO) (Erl) 292.5
Iub DL / UL payload throughput for CS voice (Mbps) 120
Iub DL / UL payload throughput for CS data (Mbps) 37.8
Iub DL payload throughput for PS R99 (including SHO) (Mbps) 408
Iub UL payload throughput for PS R99 (including SHO) (Mbps) 108
HSDPA throughput (Mbps) 198
HSUPA throughput (Mbps) 12
Total Payload Throughput (Mbps) 883.8
Note:
The CS and PS total throughput (CS voice + CS data + PS(DL/UL)) fulfilled and
satisfied the VMS’s requirement which is able to support 300,000 subscribers
number per RNC.
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Following formulas well interpreted the calculation process of the Iub throughput.
Iub CS voice (including SHO) (Erl)
= Subscribers * CS voice penetration ratio * Voice Traffic per sub per BH * (1+ SHO Ratio)
=300000 * 100% * 0.025erlang * (1+ 30%)
=9,750 Erl
Iub CS data (including SHO) (Erl)
= Subscribers * CS data penetration ratio * CS data traffic per sub per BH *(1+ SHO Ratio)
=300000 * 30% * 0.0025erlang * (1+ 30%)
=292.5 Erl
Iub DL / UL payload throughput for CS voice (Mbps)
= Iub CS voice (including SHO) (Erl) * 2 (UL+DL) * CS Voice Active Factor * 0.0122Mbps
=9750 * 2 * 50% * 0.0122
=120 Mbps
Iub DL / UL payload throughput for CS data (Mbps)
= Iub CS data (including SHO) (Erl) * 2 (UL+DL) * CS data Active Factor * 0.064Mbps
=292.5 * 2 * 1 * 0.064
=37.8 Mbps
Iub DL payload throughput for PS R99 (including SHO) (Mbps)
= Subscribers * PS penetration ratio * PS R99 DL payload throughput per sub / 1000
=300000 * 100% * 1.36kbps / 1000
=408 Mbps
(PS R99 DL payload throughput per sub
= Total PS throughput per user per BH * Proportion of DL PS throughput *
R99 share of DL PS throughput per sub * (1+ Proportion of SHO for PS call) / 1000
= 2000bps * 85% * 61.5% * (1+ 30%) / 1000
= 1.36 kbps)
Iub UL payload throughput for PS R99 (including SHO) (Mbps)
= Subscribers * PS penetration ratio * PS R99 UL payload throughput per sub / 1000
=400000 * 100% * 0.36kbps / 1000
=108 Mbps
(PS R99 UL payload throughput per sub
= Total PS throughput per user per BH * Proportion of UL PS throughput *
R99 share of UL PS throughput per sub * (1+ Proportion of SHO for PS call) / 1000
=2000bps * 15% * 90% * (1+ 30%) / 1000
=0.36 kbps)
HSDPA throughput (Mbps)
= Subscribers * PS penetration ratio * PS HSDPA DL payload throughput per sub / 1000
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=300000 * 100% * 0.66kbps / 1000
=198 Mbps
(PS HSDPA DL payload throughput per sub
= Total PS throughput per user per BH * Proportion of DL PS throughput *
HSDPA share of DL PS throughput per sub / 1000
=2000bps * 85% * 38.5% / 1000
= 0.66 kbps)
HSUPA throughput (Mbps)
= Subscribers * PS penetration ratio * PS HSUPA UL payload throughput per sub / 1000
=300000 * 100% * 0.04kbps / 1000
=12 Mbps
(PS HSUPA UL payload throughput per sub
= Total PS throughput per user per BH * Proportion of UL PS throughput *
HSUPA share of UL PS throughput per sub* ( 1+ Proportion of SHO for PS call)
/ 1000
=2000bps * 15% * 10% * (1+ 30%) / 1000
= 0.04kbps)
Total Payload Throughput of Iub (Mbps)
= Iub DL / UL payload throughput for CS voice (Mbps)
+ Iub DL / UL payload throughput for CS data (Mbps)
+ Iub DL payload throughput for PS R99 (including SHO) (Mbps)
+ Iub UL payload throughput for PS R99 (including SHO) (Mbps)
+ HSDPA throughput (Mbps)
+ HSUPA throughput (Mbps)
= 120+37.8 + 408+ 108 + 198+ 12
=883.8 Mbps
All RNC are designed to be the same one to fulfill the minimum requirement of
300NodeB/900Cells..
Following table shows the quantity of main processing unit needed in order to support
300,000 subscribers number per RNC in Center V with the optimized 2000 bps PS
throughput per subscribers in Busy Hour.
Table 70 Center V: Main Processing Unit with 2000 bps PS throughput per subscribers in BH
Main Processing Unit Quantity
UMTS Data Processing Unit (DPUe) 5
UMTS Signaling Processing Unit
(SPUb) 6+6
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Based on the total Throughput of 883.8 Mbps for each RNC, the hardware
configuration shall configure as below:
Figure 25 RNC Hardware Configuration with Normal Traffic Model for Center V
However, the total throughput obtained to be 883.8 Mbps cannot meet VMS‟s total
throughput requirement of 3Gbps. Therefore, by remaining the total subscriber number and
CS Erlang throughput, the PS throughput need to be increased to 2274 Mbps by adding
UMTS Data Processing Unit and Hardware License.
The following table shows the total number of main processing unit for 3Gbps
throughput.
Table 71 Center V: Main Processing Unit with 3Gbps throughput
Main Processing Unit Quantity
UMTS Data Processing Unit (DPUe) 9
UMTS Signaling Processing Unit
(SPUb) 6+6
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Figure 26 Optimized Hardware Configuration to Meet 3Gbps Throughput for Center V
Therefore, the configuration of RNC can be summarized as the table below.
Table 72 Center V: Summary for Main Processing Unit in RNC
Hardware Configuration Normal Traffic
(883.8Mbps)
Optimized Traffic
(3000Mbps)
UMTS Data Processing Unit
(DPUe) QTY 5 9
UMTS Signaling Processing
Unit (SPUb) QTY 6+6 6+6
Total Maximum Throughput
Capacity supported(Mbps or
Erlang)
PS throughput :2,500
Mbps or CS Erlang :
16,750Erl
PS throughput :4,500
Mbps or CS Erlang :
30,150Erl
The table below shows the interface throughput which satisfies the 3Gbps total
throughput requirement.
Table 73 Throughput Results Dimensioned with Optimized Traffic Model (3Gbps)
Iub interface throughput
Iub CS voice (including SHO) (Erl) 9,750
Iub CS data (including SHO) (Erl) 292.5
Iub DL / UL payload throughput for CS voice (Mbps) 120
Iub DL / UL payload throughput for CS data (Mbps) 37.8
Iub DL payload throughput for PS R99 (including SHO) (Mbps) 1608
Iub UL payload throughput for PS R99 (including SHO) (Mbps) 417
HSDPA throughput (Mbps) 774
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HSUPA throughput (Mbps) 48
Total Payload Throughput (Mbps) 3004.8
All RNC are designed to be the same one to fulfill the minimum capacity requirement of
3Gbps throughput and 300NodeB/900Cells. The following table shows the number of
Node B and cell, and throughput configuration for each RNC models.
Table 74 Center V: Dimensioning result of RNC
RNC
Name
Subscribers
Qty
NodeB
Qty Cell Qty
Total Iub
Throughput
(Mbps)
Throughput
PS (Mbps)
Traffic CS
Voice (Erl)
Traffic CS
VP (Erl)
RNC 1 300000 300 900 3004.8 2847 9750 292.5
RNC 2 300000 300 900 3004.8 2847 9750 292.5
RNC 3 300000 300 900 3004.8 2847 9750 292.5
RNC 4 300000 300 900 3004.8 2847 9750 292.5
RNC 5 300000 300 900 3004.8 2847 9750 292.5
RNC 6 300000 300 900 3004.8 2847 9750 292.5
The specific dimensioning result of physical interface port numbers and physical throughput of
each interface are shown as below (all the interface ports comply with active and standby
redundancy configuration).
Note: The 35% redundancy based on VMS’s requirement has been considered in the
interface port configuration.
Table 75 Center V: Physical Interface Port for Each RNC Model
RNC
Name
Interface
Name Bear Type
Number of Ports
required in RFP
(Active + Standby)
Number of Ports
(Active + Standby)
RNC 1
to
RNC 6
To MGW
(Iu-CS, Mbps)
ATM over
STM-1 4+4 8+8
IP over Ge 2+2 4+4
To SGSN
(Iu-PS, Mbps)
ATM over
STM-1 4+4 8+8
IP over Ge 2+2 8+8
To NodeB (Iub,
Mbps)
ATM over
STM-1 12+12 20+20
IP over Ge 8+8 12+12
To other
MBSC (Iur,
Mbps)
Share with
IuCS Share with IuCS Share with IuCS
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Table 76 Center V: Physical Interface Throughput(UL+DL) for Each RNC Model
RNC Name Interface Name
Total UL+DL
Throughput
(Mbps)
RNC 1 to RNC 6
To MGW (Iu-CS) 235.31
To SGSN (Iu-PS) 2,644.75
To NodeB (Iub) 3,888.92
To other MBSC
(Iur) 386.19
According to the dimensioning result, we can see what had been offered in Chapter 3.3.4.1
(Center I) and Chapter 3.3.4.2 (Center V) have fully meet with VMS dimensioning
requirements.
4.1.3 GTCS Dimensioning
From the Dimensioning Flow of BSC diagram, the transcoder unit is dimensioned by the A
CIC channel. The following table shows the dimension result of a GTCS (Transcoder).
Table 77 Dimension result for GTCS (Transcoder)
TC
Center I Center V
Capacity
Min Port
required by
RFP
HW Capacity
Supported Capacity
Min Port
required
by RFP
HW
Capacity
Supported
CIC Channel 11,927 NA 14,406 12,246 NA 14,406
Ater STM-1 port 3+3 3+3 3+3 3+3 3+3 3+3
A STM-1 port 8+8 8+8 8+8 7+7 7+7 7+7
Data Processing Unit
(N+1) 14 NA 14 14 NA 14
Cabinet 1 NA 1 1 NA 1
Subrack 2 NA 2 2 NA 2
The calculation of dimensioning for Data Processing Unit quantity with N+1 redundancy is
base on the A CIC,
Data Processing Unit quantity = (Total CIC channel / 960 CIC) +1
= 14
Where 960 CIC is the capability of each Data Processing Unit.
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4.2 2G/3G Integrated SingleBTS Network Dimensioning
The traffic model of voice/data/ signaling in Huawei‟s dimensioning fully follows RFP
requirement in both 2G and 3G RAN capacity calculation.
Table 78 2G/3G Integrated SingleBTS type distribution
Site type Site Model GSM Config
(900/1800)
UMTS Config
2100M
Center I
QTY
Center V
QTY
BTS3900 GSM (900M
S444)+DBS UMTS
S222
BTS 3900 +
DBS3900 900M:S4/4/4 S2/2/2 130 120
BTS3900 GSM (900M
S222+1800M
S222)+DBS UMTS
S222
BTS 3900 +
DBS3900
900M:S2/2/2 +
1800M:S2/2/2 S2/2/2 110 190
BTS3900A GSM (900M
S222+1800M
S222)+DBS UMTS
S222
BTS 3900A +
DBS3900
900M:S2/2/2 +
1800M:S2/2/2 S2/2/2 230 180
DBS3900 GSM (900M
S444)+DBS UMTS
S222
DBS 3900 +
DBS3900 900M:S4/4/4 S2/2/2 100 100
Total 570 590
Table 79 Abis/ Iub Bandwidth Based on RNP Result
Site type
BTS3900 GSM
(900M S444)+DBS
UMTS S222
BTS3900 GSM
(900M S222+1800M
S222)+DBS UMTS
S222
BTS3900A GSM
(900M S222+1800M
S222)+DBS UMTS
S222
DBS3900
GSM (900M
S444)+DBS
UMTS S222
GSM Config
(900M/1800M) 900M:S4/4/4
900M:S2/2/2
1800M: S2/2/2
900M:S2/2/2
1800M: S2/2/2 900M:S4/4/4
GSM Erlang/ site 73.95 63.3 63.3 73.95
UMTS Config (2100M) S2/2/2 S2/2/2 S2/2/2 S2/2/2
Uplink CE/ site 384 384 384 384
Downlink CE/site 384 384 384 384
CS Erl/site 59.85 59.85 59.85 59.85
CS Data Erl/site 1.7955 1.7955 1.7955 1.7955
Avg CS Iub (kbps)/site 944 944 944 944
Avg PS Iub (kbps)/site 6536 6536 6536 6536
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The scalability of Abis/Iub throughput calculated by RNP above are based on tender required traffic
model with the 2G CS traffic per sub is 0.025erl and 3G PS throughput per sub is 2000 bps.
Table 80 2G/3G Integrated SingleBTS configuration
Site Type
2G Configuration 3G Configuration
GSM
Config
(900M/1
800M)
RF
Unit ,
Power/
unit (W)
TOC
Power
Static
/TRX (W)
UMTS
config
Baseband
unit
HW
UL/
DL
CE
SW
CE
DL/
UL
RF
Unit
Power
(W)
TOC
Power
Static
/Cell(W)
BTS3900
GSM (900M
S444)+DBS
UMTS S222
900M:
S4/4/4
MRFU,
80W 20 S2/2/2
(WBBPd1
, 6 cell) * 2
384/
384
384/
384
RRU
3804 ,
60W
20
BTS3900
GSM (900M
S222+1800M
S222)+DBS
UMTS S222
900M:
S2/2/2 +
1800M:
S2/2/2
MRFU,
80W 20 S2/2/2
(WBBPd1
, 6 cell)*2
384/
384
384/
384
RRU
3804 ,
60W
20
BTS3900A
GSM (900M
S222+1800M
S222)+DBS
UMTS S222
900M:
S2/2/2 +
1800M:
S2/2/2
MRFU,
80W 20 S2/2/2
(WBBPd1
, 6 cell)*2
384/
384
384/
384
RRU
3804 ,
60W
20
DBS3900
GSM (900M
S444)+DBS
UMTS S222
900M:
S4/4/4
RRU
3908,
80W
20 S2/2/2 (WBBPd1
, 6 cell)*2
384/
384
384/
384
RRU
3804 ,
60W
20
Hardware:
GSM S4/4/4 900MHz, GSM S4/4/4 1800MHz
UMTS S4/4/4 2100MHz
384 CE UL/384CE DL;
HSDPA peak rate up to 21Mbps per cell;
HSUPA peak rate up to 5.76Mbps per cell.
RTU:
GSM S4/4/4 900MHz, GSM S2/2/2 1800MHz, with static TOC 20W
UMTS S2/2/2 2100MHz, with static TOC 20W per carrier
384 CE UL/384 CE DL;
HSDPA 21Mbps & HSUPA 5.76Mbps per cell;
IP clock synchronization.
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For more details on 2G/3G integrated SingleBTS hardware and software, please refer to
the submitted BOQ.
4.3 OMC & PRS Network Dimensioning
For this proposal, one OMC-R server type is configured as shown in the following table.
Table 81 Offered OMC-R System Server Type
Server Hardware Maximum Management Capacity
Sun M5000 Single Server
SUN M5000 (4CPU) maximum supports 190 essential NE.
50 Cells equals 1 essential NE for WCDMA and 125 TRXs equals to 1 essential
NE for GSM.
Since the offered OMC-R server hardware can support up to 190 equivalent NEs, the
maximum number of cells can be derived as the following:
Maximum number of cells for RNC+Node B
= 190 equivalent NEs x 50 cells/1 equivalent NE
= 9,500 cells
Maximum number of TRXs for BSC+BTS
= 190 equivalent NEs x 125 TRXs/1 equivalent NE
= 23,750 TRX
For northern region (Center I and V), the actual site number and cell number with 35%
redundancy are shown as below:
Table 82 Center I and V Total Node B and Cell Number with 35% Redundancy
Location Node B No. RAN Cell No. 35% Redundancy
Node B No.
35% Redundancy
RAN Cell No.
Center I 570 3420 770 4617
Center V 590 3540 797 4779
For northern region (Center I and V), the actual site number and TRX number with 30%
redundancy as shown as below:
Table 83 Center I and V Total BTS and TRX number with 30% Redundancy
Location BTS No. TRX No. 30% Redundancy
BTS No.
30% Redundancy
TRX No.
Center I 570 6840 741 8892
Center V 590 7080 767 9204
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Also considering the minimum requirement of the OMC capacity from VMS (the
hardware of each OMC system must be dimensioned for supporting up to 10000
TRXs/5000 cells), the cell number for Center I is increased from 4,617 to 5,000 and the
cell number for Center V is increased from 4,779 to 5,000. For the TRX dimensioning
part, the TRX number for Center I is increased from 8,892 to 10,000 TRXs and the TRX
number for Center V is increased from 9,204 to 10,000 TRXs. The final dimensioning
result of OMC-R capacity requirement for Center I and V are listed as below:
Table 84 Dimensioning Result of Total NodeB and Cell Number for OMC-R Hardware
Location
Dimensioning result of OMC-R
hardware capacity for NodeB
No.
Dimensioning result of OMC-R
hardware capacity for Cell No.
Center I 770 5000
Center V 797 5000
Table 85 Dimensioning Result of Total BTS and TRX Number for OMC-R Hardware
Location in
Northern
Dimensioning result of OMC-R
hardware capacity for BTS No.
Dimensioning result of OMC-R
hardware capacity for TRX No.
Center I 741 10000
Center V 767 10000
On top of above dimensioning principle, the total cells numbers and total TRXs numbers
of each OMC-R is 5000 Cells/10000 TRXs for Center I and 5000 Cells/10000 TRXs for
Center V, thus the total essential NEs of each OMC-R can be calculated in the following
formula: (Total Cells number / 50 Cells + Total TRXs number /125 TRX), where the total
essential NEs is 180 for both Center I and Center V, which is smaller than 190, so the
type of M5000 with 4CPU can support the particular capacity requirements, because it
is hardware ready to support 9500 cells/23750 TRXs and 190 essential NEs.
Table 86 Essential NEs and OMC-R Server Type
Location NodeB/BTS No. RAN Cell/
TRX No.
Dimensioning
Essential NE
Server
Type
Server hardware
capacity
Center I 770 / 741 5000 /
10000 180
SUN
M5000 (4
CPU)
190 essential
NEs/9500cells/23750
TRXs (4 CPU)
Center V 797 / 767 5000 /
10000 180
SUN
M5000 (4
CPU)
190 essential
NEs/9500cells/23750
TRXs (4 CPU)
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For the PRS server dimensioning, the iManager server module proposed is HP DL785
where can cover on the large sized networks, where the supported equivalent NE is less
or equal to 800 NEs.
In Center I & V, the OMC-R system is configured on 5000 TRXs/10000 Cells,
Total essential NEs in PRS = 5000/62.5 + 10000/125 = 160 NE
Since the offered PRS server hardware can support up to 800 equivalent NEs, the
maximum number of cells can be derived as the following:
Maximum number of cells
= 800 equivalent NEs x 62.5 cells/1 equivalent NE
= 50,000 cells
Maximum number of TRXs
= 800 equivalent NEs x 125 TRXs/1 equivalent NE
= 100,000 TRX
Table 87 Essential NE and PRS server type Summary
Location RAN Cell/ TRX
No.
Dimensioning PRS Server
Type
Server hardware
capacity Essential NE
Center I 5000 / 10000 160 HP DL785
800 essential
NEs/50,000cells/100,000
TRXs
Center V 5000 / 10000 160 HP DL785
800 essential
NEs/50,000cells/100,000
TRXs
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5. Highlight of Huawei SingleRAN Solutions
5.1 SingleRAN Product Overview
5.1.1 Multi-mode BSC
Figure 27 Multi-mode BSC
Inherit unified platform
Huawei‟ multi-mode BSC6900 is based on self-developed PARC (Platform of Advanced
Radio Controller) platform with IP/TDM dual-switching plane and high reliability. Because of
Huawei‟s durative R&D strategy, legacy BSC (BSC6000 for GSM&BSC6810 for UMTS) can
be upgraded to BSC6900.
First-in-class capacity and density
BSC6900 has a First-in-class capacity (5100Cells and 12Gbps throughput for UMTS
only/4096TRXs for GSM only) in industry. BSC6900 has only 7 board types (excluded
interface board), it saves a lot in spare management. This large capacity and multi-mode
BSC not only provide a more flexible solution, but also meet the needs for the wireless
broadband, which greatly protect our customer‟s investment and being ready for the future
technologies.
TCO saving
The combined multi-mode BSC causes simple network architecture, less number of BSC is
needed. Co-TRM with higher transmission efficiency saves huge amount of transmission
resources, Co-RRM can balance the traffic between GSM and UMTS intelligently, and then
switch off the idle carriers to save power consumption. Co-OAM with higher human
resources efficiency brings OPEX saving.
Multimode brings flexible configuration and uni-operation
To meet different networking requirements, BSC6900 can support GSM only or UMTS only
or GSM/UMTS in same cabinet; share the same sub-rack and the same boards. The
capacity of each mode can be transferred dynamically according to the trend of
traffic.BSC6900 is a milestone of Multi-mode BSC, it supports Co-TRM, Co-RRM, Co-OAM,
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Co-RNP, all these features benefits operators with not only TCO saving but also better
network performance.
Improve network performance through optimized Co-RRM algorithm
The Co-Radio Resource Management (Co-RRM) algorithm performs unified management
and intelligent scheduling on the radio resources in the GSM network and UMTS network.
As the traditional Co-RRM algorithm exchanges the 2G/3G load information between the
GSM network and the UMTS network through signaling procedures across the core
networks (CNs). The BSC6900 optimized Co-RRM algorithm enables rapid transmission of
2G/3G load information (used as internal messages) with an internal procedure. The
advantages are as follows:
Having no dependency on the equipment in the core network
Reducing latency, adjusting the load in real time, and increasing the success rate of
inter-RAT handovers
Decreasing the signaling flow on the standard interface and saving interface resources
The optimized Co-RRM algorithm maximizes the sharing of radio resources between the
GSM network and the UMTS network, thus increasing the network capacity.
5.1.2 SingleBTS Introduction
Convergence
Figure 28 Module design BTS
Huawei SingleBTS 3900 series are based on self-developed platform HERT and adopt modular
design. The 3900 series BTS include 3 parts, RRU (Remote Radio Unit)/RFU (Radio Frequency
Unit)/BBU (Base Band Unit), which can be combined in different ways in order to adapt various
scenarios. Modular design also simplifies the transportation, installation, maintenance of the BTS
and the most significant is that the SingleBTS can support GSM/UMTS/LTE simultaneously.
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Figure 29 The SingleBTS Portfolio
To come across various capacity and coverage requirements of operator, Huawei delivers a
comprehensive BTS family that includes the Macro BTS, Distributed BTS, Micro BTS, etc to
achieve seamless coverage. It is convergent platform between different BTS portfolio as well as
convergent platform between GSM, UMTS and LTE.
Evolution
Figure 30 Huawei convergent BTS expansion and evolution
Cabinet based macro indoor BTS (BTS3900) and outdoor BTS (BTS3900A) is suitable for
centralized installation as well as G/U multi-mode and multi-band scenarios. It can support
72TRXs for GSM or 24 cells for UMTS in all.
The 3900 series multi-mode base stations provide multiple evolution solutions and support the
evolution from GSM to UMTS and further to LTE. BBU can be reused when evolve to UMTS or
LTE, only need to insert relative two sub-boards into BBU: WMPT or LMPT for control and
transmission, WBBP or LBBP for baseband processing.
Application of the SDR technology
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With the SDR technology, RF modules can support any type of dual-mode among GSM, UMTS,
and LTE in the same frequency through software update, so to meet operator‟s requirements that
need fast and one-time deployment.
Co-cabinet solution
RF modules serving different modes (includes SDR module) can be installed in the same cabinet
so that the single-mode or any type of dual-mode among GSM, UMTS, and LTE is applicable to
the base station. RF modules operating in different frequency bands can also be housed in the
same cabinet. In this way, the multi-mode and multi-band application is available.
Green
Stackable design makes it possible for hand carry installation and flexible expansion. The macro
outdoor BTS (BTS3900A) can work stably in the range of -40 to +50 degree Celsius. Air
direct-ventilation design makes it more reliable without air condition or heat-exchanger for
temperature adjustment. It has the same baseband and radio performance with indoor macro
BTS.
Distributed BTS (DBS3900) separates traditional cabinet BTS into two parts, baseband unit (BBU)
and remote radio unit (RRU). RRU can be mounted near the antenna to save feeder loss of 3 dB
and TMA (Tower Mounted Amplifier). They mark small size, large capacity and high integration.
Therefore, we can provide a zero footprint solution thus fulfilling the desire of easier, faster site
acquisition, installation and network deployment.
Huawei SingleBTS can support multiplicate methods on power control, there are two main kinds:
1. dynamically shut down idle resources, like cell, TRX and PSU boards, 2. allocate accurate
power according to actual traffic requirement, like BCCH power optimization and power
optimization based on channel type. Based on these advanced and innovative power control
technologies, Huawei SingleBTS can bring extra 10-25% power consumption saving.
High effective digital power amplifier (DPA) saves the electrical power cost. With DPD+ A-Doherty
technology, the PA efficiency is up to 40%. DBS3900 S111 typical power consumption is only
400W compared to the traditional common Node B of 1500W.
Figure 31 Power consumption cooperation
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5.2 Multi-mode Solutions
With the development of UMTS, more and more traditional GSM operators migrated to the
UMTS network in order to provide high speed data service and carry superior service
experience. Based on UMTS network, operators are able to launch more abundant and
differentiated services to end users, and attract more subscribers. Meanwhile, UMTS
network helps operators improve the ARPU and MOU, and keep leading in the market.
With the evolution of GSM network to EDGE all over the world, GSM/EDGE and UMTS will
co-exist for a long time, the inter-working and traffic balance between GSM/EDGE and
UMTS is still significant
For mobile operators, balancing the investment between GSM and UMTS and acquire most
profit in GSM/UMTS deployment is becoming more important.
Based on all theses requirements of our customer, Huawei would provide different
multi-mode solutions to meet different needs in typical scenarios.
Figure 32 High Expansibility BBU3900
Thanks to Huawei‟s unified HERT platform, baseband module, BBU3900 can be applied in
GSM or UMTS mode by plugging in different daughter card. Meanwhile, baseband and
transmission can be expanded separately. It also can be smoothly evolved to LTE by adding
LTE baseband daughter card. Different combination of RF module and BBU3900 realize two
multi-mode solutions: Co-cabinet solution and SDR solution.
5.2.1 Co-cabinet solution for multi-mode
In order to meet the requirement of operators‟ GSM/UMTS deployment, Huawei presents
multi-mode BTS solution, which is applicable for GSM/UMTS multi-mode deployment and
capable of smooth evolution from EDGE to HSPA to HSPA+ to LTE.
Huawei‟s multi-mode BTS solution supports cabinet-based multi-mode and distributed
multi-mode.
Cabinet-based multi-mode BTS: BTS3900 and BTS3900A.
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The cabinet-based multi-mode application has minimized footprint by sharing common G/U
platform and using different G/U RF module. The stackable cabinet is easy to hand carry to site,
and it makes expansion more flexible. Cabinet-based multi-mode BTS is capable of evolution to
LTE.
Indoor BTS3900
Figure 33 Compact GSM/UMTS Multi-mode indoor BTS
BBU (Base Band Unit) can be shared by GSM and UMTS and inserted into the 2U space
reserved in the BTS cabinet. GSM, UMTS and LTE radio units are inter-changeable. The
stackable cabinet, easy for transportation and installation, only need 1 cabinet footprint, 100%
reuse site facilities: minimum investment on power, battery, feeder and antenna.
Outdoor BTS3900A
Figure 34 Compact GSM/UMTS Multi-mode Outdoor BTS
Both the indoor and outdoor BTS support stackable configuration, which simplifies the
transportation, installation and expansion. Based on the all-in-one design architecture, the power
consumption is reduced considerably, which enables saving the investment on the site
infrastructure and OPEX.
Distributed multi-mode BTS: DBS3900 (BBU3900 + RRU3008+RRU3804)
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Figure 35 Distributed multi-mode BTS
Distributed multi-mode BTS is application of module-based multi-mode. In this application, RF
module and baseband module can support GSM and UMTS respectively. The BBU and RRU are
connected with optical fiber, so there is no feeder loss, and RRU can be mounted near the
antenna to realize wider coverage.
RF module, RRU3008 can support 6 TRX in 1 module. RRU 3804 can support 4 cells in 1 module
and have the ability to evolve to LTE. Baseband module, BBU3900 can be applied in
GSM/UMTS/LTE mode by plugging in different daughter card. Meanwhile, baseband and
transmission can expand separately.
5.2.2 Multi-mode Solution based on Software Defined Radio (SDR)
SDR is the abbreviation of “software defined radio”. It means taking the hardware as an unified
platform, and re-program and reconstruct the equipment by software (Much of the waveforms,
e.g., frequency, modulation/demodulation, coding, etc) to support multi-mode. The signal path
can be reconfigured in software without requiring any hardware modifications. In conclusion, SDR
is a new wireless framework based on DSP/FPGA and software. To be emphasized, the research
of SDR technology is just in initial phase, SDR mentioned in this proposal is just for dual-mode in
the same frequency.
SDR is considered as a trend for 3G and the evolution afterwards 3G by ITU. And it‟s gradually
recognized by the industry for its smoothly evolution. Huawei keeps leading in SDR R&D, and has
integrated series of SDR products including RRU3908 and MRFU covering 850 MHz/900
MHz/1800 MHz/1900 MHz. After Huawei deploy the 1st SDR commercial network in Panama
AM(GSM/UMTS@1900MHz) in 2008 and 1st SDR commercial network comply with ETSI in
Finland Teliasonera in 2009, over 10 operators have chosen Huawei SDR BTS to construct G/U
multi-mode network. All these prove that Huawei SDR technology is mature and available for
great scale deployment.
SDR can be widely used for dual-mode network construction, e.g.: GSM&UMTS modernization,
GSM900MHz refarming, GSM850M/1900MHz refarming, new network for future evolution. It can
bring long-term TCO saving and has great advantage in smooth evolution,
Scheme of SDR Digital Transceiver
SDR digital transceiver includes wideband antenna, RF front-end, wideband ADC&DAC, DSP, and etc:
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Figure 36 Scheme of SDR digital transceiver
RF Section
RF Section transmits/receives RF signal from the antenna. To settle for the requirement of SDR, the work frequency band of TX&RX&Antenna must be wide and MCPA has high linearity.
IF Section
High-speed and wideband ADC&DAC is the key part of SDR, it performs analog-to-digital conversion (on receive path) and digital-to-analog conversion (on transmit path), respectively.
Baseband Section
Baseband section performs baseband operations and also implements the link layer protocol. Some fixed function parts, like filter and DUC&DDC, are made of FPGA, which can be re-program, and has more flexibility and higher speed than DSP, smoother parts need complex calculation, are made of DSP.
SDR Solution
In order to meet the requirement of operators‟ G/U deployment, Huawei presents multi-mode BTS
solution, which is applicable for multi-mode deployment and is able to evolve from EDGE to
HSPA to HSPA+ to LTE.
SDR technology is an important part of Huawei‟s multi-mode BTS solution and including
cabinet-based and distributed multi-mode BTS.
Figure 37 Huawei SDR Modules
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Cabinet-based multi-mode BTS: BTS3900 and BTS3900A (BBU3900+MRFU)
The cabinet-based multi-mode application has reduced footprint by sharing common G/U
platform and using SDR RF module. Cabinet-based multi-mode BTS is capable of evolution to
LTE.
MRFU
MRFU cover full spectrum: 900MHz or 1800MHz or 1900MHz. One MRFU maximum supports 6
GSM or 4 UMTS carriers, 4TRXs+2carriers or 5TRXs+1carrier for G/U dual mode. 80W output
power and 15MHz PA frequency bandwidth can meet the requirement of macro BTS and support
power sharing.
Figure 38 MRFU
Indoor BTS3900
Figure 39 Compact GSM/UMTS Multi-mode indoor BTS
BBU (Base Band Unit) can be shared by GSM and UMTS and inserted into the 2U space
reserved in the BTS cabinet. MRFU can support dual-mode simultaneously, like G/U, G/L, U/L,
and provide 80w power output. The stackable cabinet, easy for transportation and installation,
only need 1 cabinet footprint, 100% reuse site facilities: less consumption of power, battery,
feeder and antenna. The capacity of GSM&UMTS can be adjusted dynamically by software
control.
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Outdoor BTS3900A
Figure 40 Compact GSM/UMTS Multi-mode Out BTS
BBU can be shared by GSM and UMTS and inserted into the 2U space reserved in the outdoor
power supply cabinet. MRFU can support dual-mode simultaneously, like G/U, G/L, U/L, and
provide 80W power output. Both the indoor and outdoor BTS support stackable configuration,
which simplifies the transportation, installation and expansion. Thanks to the all-in-one design
architecture, this enables saving the investment on the site infrastructure and OPEX.
Distributed multi-mode BTS: DBS3900 (BBU3900 + RRU3908)
Figure 41 Multi-mode BBU
Distributed multi-mode BTS is application of module-based multi-mode. In this application, RF
module and baseband module can support GSM and UMTS respectively. The BBU and RRU are
connected with optical fiber, so there is no feeder loss, and RRU can be fixed near the antenna to
realize wide coverage.
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Figure 42 RRU3908
Distributed multi-mode DBS3900 will support G/U/LTE convergence by SDR as following:
RRU3908 cover full spectrum: 850MHz or 900MHZ or 1800MHz or 1900MHz.
One RRU3908 maximum support 6 GSM or 4 UMTS carriers, 4TRXs+2carriers or
5TRXs+1carrier for G/U dual mode.
Various clock supply: IP clock, or UMTS get clock signal from GSM E1/T1,save BITS
investment
RRU 60W output power can be shared between multi-carriers in the same mode to get
flexible configuration.
Smooth evolution to HSPA+ (64QAM, 2*2 MIMO by software update),hardware is ready for
LTE.
5.3 Highlight s of Huawei’s SingleRAN Solution
5.3.1 Highlight of Huawei‟s GSM Solution
5.3.1.1 TCO Saving Solution
Transmission Saving Solution
Abis Transmission Saving
1. Abis IP over E1/FE/GE
Huawei provide Abis IP over E1/FE/GE to reduce transmission cost. Abis IP over FE/GE adapts
to all IP development trend of future transport layer and protocol development. The Abis interface
incorporates the features such as high bandwidth and low cost deployment, and it does not have
any restrictions on the BSC capacity. The low IP network deployment cost, short construction
period, and easy maintenance effectively reduce the CAPEX and OPEX of operators. Operator
which owns transport network resources, Huawei proposes IP over E1 and TDM over E1. Thus,
telecom operators can use the existing TDM network to protect the investment and reduce the
transmission cost.
2. Abis MUX
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Figure 43 Abis MUX
Abis MUX is used to save the bandwidth and multiplex the packets. The BSC and the BTS serve
as transmitting end and receiving end of each other. When Abis MUX is applied, the transmitting
end multiplexes the UDP packets that meet the multiplexing condition. Multiple UDP packets are
multiplexed into one IP/UDP header at the transmitting end and then demultiplexed at the
receiving end to reconstruct the original data in the IP/UDP packets. Thus, the transmission
efficiency is improved and the bandwidth is saved.
By multiplexing and demultiplexing the IP/UDP packet, Abis MUX reduces the overhead of each
IP packet, increases the efficiency of the IP transmission, and saves the bandwidth.
3. BTS Local Switching Solution
With BTS Local Switching solution, if the calling MS and called MS are within the coverage of the
same BTS or BTS group, the BSC performs the loopback on the cabinet group of the convergent
BTS, only the signaling is sent to BSC when the calling and called parties are under the same site.
This feature helps save the local or long-distance transmission resources on the Abis and Ater
interfaces.
Figure 44 BTS Local Switch Solution
4. Abis Congestion Triggered HR Allocation
In heavy traffic hours, if the Abis transmission resources are not sufficient, the Abis
transmission may be congested earlier than the air interface. The TCHF-to-TCHH conversion
based on the air interface load and the mechanism of preferentially allocating TCHH cannot
guarantee the system capacity. Based on the congestion status on the Abis interface, the Abis
congestion triggered HR allocation function performs dynamic TCHF-TCHH conversion,
preferentially allocates TCHH, and carries out queuing and pre-emption to ease the Abis
interface congestion and to increase the system capacity. So this function can helps save the
Abis transmission resources and reduce the network construction cost.
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Power Consumption Saving
With leader solution, Huawei has introduced a new design chipset which can decrease the
Power consumption as compare to traditional chipset design. Being introduce new chipset the
static power consumption reaches up to less than 50%.
Figure 45 New IC Technology
Intelligent Power Management system
Figure 46 Power Optimization Based on Channel Type
Huawei intelligent power management system allows BTS to select best PA-bias dynamically for
GMSK and 8PSK codec which increases the PA efficiency by 10%.
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Figure 47 TRX Power Amplifier Intelligent Shutdown
Using intelligent shutdown of TRX by time function, operator can specify a period of low traffic
time. In this period, the BSC commands the BTS to shut down some TRXs in a cell. When the
period ends, the BSC commands the BTS to switch on the TRXs. Likewise, intelligent shutdown
of the idle TRX in time slot level and priority assignment of time slots in BCCH TRX decrease
power load in PA. Hence, typical power consumption of BTS3900 (TOC=20W, load factor=30%)
for S2/2/2 configuration is only 500W which is the leading value in the industry level.
By this way, the power management and self-protection of the system is enhanced. Thus raises
the reliability of the system and prolongs the life cycle of the product.
In a 900 MHz/1800 MHz dual-band network, Dynamic Cell Power Off feature is
generally used to save more power consumption.
In a specified period, if the traffic is low and a 900 MHz cell can carry all the traffic in the coverage
area of an 1800 MHz cell, then the 1800 MHz cell can be powered off to reduce the power
consumption of the BTS.
By powering off the idle network devices in low traffic hours, the consumption of resources can be
reduced. This also reduces the operational expenditure of the operators.
Figure 48 Dynamic Cell Power Off
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Active Backup Power Control
Figure 49 Active Backup Power Control
Once the external power of the BTS is disrupted, the BTS uses the backup battery to supply the
power. Huawei provide this function to gradually shut down the TRXs and decreases the transmit
power of the TRX to prolong the service time of the BTS.
This function decreases the power consumption of the BTS, prolongs the service time of the BTS,
and decreases the out-of-service cell rate when the external power supply of the BTS is disrupted.
And it also can increases the discharge time of the battery, saves the working time of the
generator, and thus saves the cost of the power supply.
PSU Smart Control
The PSU (Power Supply Unit Module) intelligent shutdown function shuts down the redundant
PSUs based on the BTS load on the condition that the required power consumption of the BTS is
met.
This function improves the efficiency of the power conversion, prolongs the working time and
lifetime of the PSU, reduces the power consumption, and saves the operating cost.
Enhanced BCCH Power Consumption Optimization
In traditional BTS, the transmit power of the main-BCCH carrier is fixed. Huawei Enhanced BCCH
Power Consumption Optimization function can reduce the transmit power of the non-main BCCH
timeslots on the main BCCH carrier to decrease the power consumption of the BTS.
5.3.1.2 Enhanced Capacity Solution
Soft Synchronized Network
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Figure 50 Network Synchronization
The Soft Synchronized Network is one of Huawei unique features. The software synchronized site
can synchronize the BTS TDMA frame without GPS engineering. This feature is especially useful
in two scenarios: high density traffic load area or limited frequency resource.
Huawei could support Um interface software synchronization intra BSC and inter BSC without
adding any additional hardware. As Figure 48 shows, before network synchronization, a center
BTS should be identified. Here BS1 becomes the Center BTS. In the first round, BTSs surrounding
BS1 will be synchronized orderly, such as1-2, 1-3, 1-4…1-7. In the second round, the already
synchronized BTS become the Center BTS, synchronization among BTSs will carried out
according to specific sequence, like 2-8, 2-9, 3-10, 3-11, 4-12…7-19. Synchronization will repeat
till all BTS are synchronized. For intra-BSC soft synchronization, the soft synch error is less than
1.5 bit, a pair of synch tuning time is less than 5sec, and a pair of synch info-collecting time is less
than 5min.
Synchronized network means that all the GSM BTSs are in same pace. It can improve the radio
link quality by enhancing the ICC performance to 5~10dB, while co-existing with other
technologies, tighter frequency reuse rate can be realized and network capacity can be increased.
IBCA
IBCA (Interference-Based Channel Allocation) is a dynamic frequency and channel allocation
algorithm based on the prediction of the achievable CIR (Channel Interference Relation) of each
candidate channel and established channel.
Figure 51 IBCA
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IBCA could be utilized under the condition where the spectrum resource is rare and dense
frequency reuse brings severe inter-cell interference which in stead of channel limits the network
capacity. IBCA bases on software synchronized network, no GPS needed, easy implementation. It
lessens the over interference level in the network and provides more effective frequency reuse
with ensured quality, thus the network capacity could be increased remarkably.
Tight BCCH Frequency Reuse
In order to improve spectrum efficiency, Huawei introduces the tight BCCH frequency reuse. The
multiplexing mode of the BCCH frequency is changed from 4 x 3 to 3 x 3, thus three frequencies
are added to the frequency hopping. After 1 x 1 frequency multiplexing is used, each cell can be
added with one TRX and the system capacity can be improved by around 25%. For operators, just
through enabling the function, the following benefits could be obtained.
Decreasing number of frequencies occupied by BCCH and improving spectrum frequency
Increasing available frequencies for TCH and frequencies for frequency hopping
Increasing frequencies for frequency hopping
Expanding the system capacity without adding new hardware
Saving the costs for adding sites and cells. The TCH channel on the BCCH frequency is
used by the MSs near the BTS. The subscribers can obtain improved speech quality when this
function is enabled.
The random access failures decrease and the access performance increases.
5.3.1.3 Enhanced Coverage Solution
Leading RF Performance
High TOC Output Power
Huawei GSM BTS series also adopt Multi-carrier Radio Frequency Unit (GRFU). Each GRFU
can serve as six TRXs. The max TOC power is 49.0dBm at GMSK mode or 47.2dBm at 8PSK
mode respectively without any degradation of capacity or additional antenna systems.
High Receiving Sensitivity
With the 3G RF design technology introduced, Huawei BTS has been improved in processing RF
and baseband signals, particularly the performance of the baseband demodulation algorithm. So
the static receive sensitivity of a single-channel reaches -113dBm, the uplink coverage of the
GSM network can be improved up to 20% compared to the industry level with the receive
sensitivity as -110dBm. Besides, 2-way receive sensitivity is -116dBm. Operators could further
enlarge the uplink coverage just through software configuration.
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Satellite Transmission
The satellite transmission mode is a supplementary for the common transmission. Huawei BSS
support satellite transmission over all interfaces on BSS part:
satellite transmission over Abis interface
satellite transmission over A interface
satellite transmission over Ater interface
satellite transmission over Pb interface
EDGE service over satellite transmission
Extended Coverage
CS: Extended Cell
In GSM specifications, limited by timing advance (TA) 63 bit, the standard maximum GSM cell
radius is 35 km. In regions such as vast land, seashore, where with scattered subscribers in low
traffic, and the infrastructure facilities such as transmission and power supply are hard to be
constructed or unavailable. The radius of cell shall be over 35 km.
Huawei extended cell technology breaks the limit of the 35 km and realizes the wide coverage.
Supported by BTS hardware, it can cover a range with radius of up to 120 km. It has been
implemented successfully in Qindao seashore coverage project since 2004; the maximum
coverage distance reached 120 Km.
PS:Enhanced downlink throughput in dual-timeslot extension cell
Figure 52 Enhanced downlink throughput in dual-timeslot extension cell
For the PS service, Huawei proposes dual-timeslot extension cell in order to enhance downlink
throughput. The cells with coverage over 35 kilometers, such as coast coverage, island coverage,
or wide coverage on land, support the PDCH allocation of four downlink timeslots and one uplink
timeslot can be performed for the MS with the multi-timeslot capability. The extension cell can
provide a data throughput four times of that provided by a traditional cell (single downlink timeslot
connection), and thus accelerates the download tasks of the MS, improves the user experience,
and helps the operators make more profit out of data services.
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5.3.1.4 Performance Enhancement Solution
AMR&WB AMR
Figure 53 AMR
AMR can select the traffic channel mode (FR or HR) and the coding mode according to the
channel quality and load. Therefore, AMR contributes a lot in better speech quality, improved
bearer capacity of the system in physical regions and stronger anti-interference capability. It could
balance the network quality and capacity, increasing about 40% network capacity.
Presently, Huawei BSS technologies support NB-AMR and WB-AMR (both FR and HR). Just
through software configuration, operators could realize both AMR FR and AMR HR functions
according to the specific network condition. Besides, Huawei BSS technology could dynamically
switch AMR FR/HR, leading to up to 40% capacity increase without degradation of service quality.
As the system could automatically adjust, the maintenance cost could also be decreased. WB
AMR provides clear and loud voice and high-quality speech compared with the narrow band AMR
with the sampling rate of 8 kHz and the speech frequency range between 200 Hz and 3400 Hz.
In Huawei BSS technology, the AMR wireless link timer is utilized to detect the quality of a
wireless link. By setting the wireless link timer of AMR voice service and that of non-AMR
voice service separately, the operator could prolong the conversation of AMR voice service,
reduce the call drop rate, and increase benefits and win a high subscribers‟ loyalty.
Enhanced EDGE Performance
When GSM/EDGE radio access network (GERAN) evolution introduced in the network, The rate
of PS services in the uplink and downlink is increased greatly. When four timeslots are used for
uplink data transmission, the theoretical rate of EGPRS is increased from 230 kbit/s to 300 kbit/s.
When ten timeslots are used on the downlink, the theoretical data rate of EGPRS is increased
from 592 kbit/s to 984 kbit/s.
In order to realize it, Huawei adopts following technologies to enhance the PS service.
MSRD:
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The receiver sensitivity of the MS is increased by about 3 dB and the downlink coverage distance
is increased. In conjunction with the dual-antenna interference cancellation (DAIC) technology, the
MSRD feature improves the anti-interference capability of the downlink, thus expanding the
downlink traffic capacity.
Dual Carriers in Downlink
With dual carriers in downlink, the GSM network can provide subscribers with data services similar
to those provided in a 3G network.
Uplink EGPRS2-A
With the 16QAM modulation, the theoretical rate of EGPRS is increased from 230 kbit/s to 300
kbit/s.
Downlink EGPRS2-A
With higher order modulation (16QAM and 32QAM), high symbol rate (1.2 times), and Turbo
codes,, When ten timeslots are used on the downlink, the theoretical data rate of EGPRS is
increased from 592 kbit/s to 984 kbit/s.
Latency Reduction
This feature reduces the packet transmission latency and thus improves the customer satisfaction.
Figure 54 EDGE evolution
Priority Control for Different Level Users
eMLPP+HR, providing different classes of services for the users with different priorities, ensures
VIP service quality.
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Figure 55 BSS eMLPP+HR Solution
The eMLPP services means to implement different policies for the calls of different priorities when
network resources are seized; The HR (Half Rate) voice services allow two users to share the
same TCH timeslot. Through channel reserved and preemption, it principally assures resources
for high-end subscribers or emergency calls. According to priority, this feature can allocate FR
channels and good speech quality for high-end users. Introduced HR technology, network
capacity can be double without any addition of TRXs. To decrease the congestion rate, the
network real time dynamically adjusts the channel type between FR and HR
Voice Quality Enhancement Technologies
High voice quality is a prerequisite for subscriber retention. In order to realize it, Huawei adopts
following technologies to enhance the voice quality.
AEC: Acoustic Echo CancelAEC: Acoustic Echo Cancel EMR: Enhanced Measurement ReportEMR: Enhanced Measurement Report
VQI : Voice Quality IndexVQI : Voice Quality Index
EPLC: Enhancement Packet Loss ConcealmentEPLC: Enhancement Packet Loss Concealment
TFO & TrFO inter-workingTFO & TrFO inter-working
ANC: Automatic Noise Compensation ANC: Automatic Noise Compensation
ALC: Automatic Level ControlALC: Automatic Level Control
ANR: Automatic Noise RestrainANR: Automatic Noise Restrain
AEC: Acoustic Echo CancelAEC: Acoustic Echo Cancel EMR: Enhanced Measurement ReportEMR: Enhanced Measurement Report
VQI : Voice Quality IndexVQI : Voice Quality Index
EPLC: Enhancement Packet Loss ConcealmentEPLC: Enhancement Packet Loss Concealment
TFO & TrFO inter-workingTFO & TrFO inter-working
ANC: Automatic Noise Compensation ANC: Automatic Noise Compensation
ALC: Automatic Level ControlALC: Automatic Level Control
ANR: Automatic Noise RestrainANR: Automatic Noise Restrain
Figure 56 Service Quality Enhancement Technologies
AEC (Acoustic Echo Cancel)
EMR(Enhanced Measurement Report)
ANR (Automatic Noise Restrain)
VQI (Voice Quality Index)
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ALC (Automatic Level Control)
TFO (Tandem Free Operation) & TrFO (Transcoder Free Operation)
ANC (Automatic Noise Compensation)
EPLC (Enhancement Packet Loss Concealment)
These above technologies could boost customer experience and customer loyalty, and rise
the ARPU for operators.
5.3.1.5 ALL IP BSS Network Solution
ALL IP BSS Solution Introduction
Figure 57 ALL IP BSS
Huawei is the first vendor in the industry to provide All IP BSS solution. Huawei BSC supports IP
over FE/GE, IP over TDM (E1/T1, cPOS).
Huawei BSS also can provide all IP interface, including Abis over IP, A over IP, and Gb over IP.
Based on ALL IP solution, the TrFO function can be supported to improve the voice quality and TC
resources can be saved. Meanwhile, the MSC in pool, the SGSN, in pool can be supported easily.
IP transmission offers sufficient bandwidth to the BTS, thus, new services can be developed
conveniently and efficiently. Operator can also have cheap rent fee, launch services quickly and
maintain network easily, Huawei IP BSS network can help operator reduce total cost.
Moreover, Huawei launched an advanced technology to ensure ALL IP BSS network, IP clock to
provide clock synchronization for several BTSs in the IP network and Abis MUX improves the
transmission efficiency. Huawei IP BSS also provides different QoS mechanisms in each layer to
guarantee the end-to-end QoS, and so on.
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Clock Over IP Support 1588V2
Figure 58 Clock Over IP Application
Clock over IP that complies with IEEE1588V2 provides clock synchronization for several BTSs in
the IP network. Compare with the GPS clock, it is a low-cost clock solution. The transmission cost
increases because the IP timing packets are sent continuously. The function provided by Huawei,
however, allows the operator to define the interval for sending IP timing packets. It can reduce the
transmission bandwidth as long as the BTS clock synchronization is guaranteed.
Ethernet OAM
With the introduction of IP GSM, the Ethernet as a type of transport bearer is widely used. As a
Layer 2 protocol, Ethernet O&M can report the status of the network at the data link layer. Thus,
the network is monitored and managed more effectively. The functions of Ethernet OAM consist of
fault detection, notification, verification, and identification. The faults involve the hardware faults
that can be detected by the physical layer, such as link failure, and the software faults that cannot
be detected by the physical layer, such as memory bridging unit damage. Ethernet O&M plays a
significant role in reducing CAPEX/OPEX and complying with the Service Level Agreement (SLA).
Figure 59 Ethernet OAM
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5.3.1.6 Network Reliability
MSC Pool
The MSC pool, one BSC can be connected to multiple MSCs simultaneously. With this feature, a
maximum of 32 MSCs form a resource pool to provide services for the subscribers under one
group of BSCs. In addition, the traffic on the BSC is evenly distributed to the MSCs in the pool
according to the NRI or load balancing principle.
The MSCs in an MSC pool share the traffic load and resources. Therefore, this feature provides
the following benefits:
MSC pool increases the network capacity and saves the equipment investment.
MSC pool realizes the redundancy backup and thus improves the network reliability because
the addition or deletion of an MSC does not affect the services.
MSC pool automatically adjusts the traffic load on an MSC and reduces the operation and
maintenance cost of operators.
The MSC pool is logically an MSC. Therefore, the number of handovers between MSCs is
reduced and the network performance is improved.
The following figure shows the typical networking of the MSC Pool feature:
Area 1
RAN node
Area 5
RAN node
Area 6
RAN node
Area 7
RAN node
Area 8
RAN node
Area 2
RAN node
Area 3
RAN node
Area 4
RAN node
PS pool- area 2 PS pool- area 1
CS pool- area 2
CS pool- area 1
MSC 3
MSC 2
MSC 1
MSC 6
MSC 5
MSC 4 MSC 7
Figure 60 MSC Pool
SGSN Pool
With SGSN Pool, one BSC can be connected to multiple SGSNs at the same time. This feature,
which is similar to the MSC Pool feature, enables a maximum of 32 SGSNs to form a resource
pool to provide services for the subscribers belonging to one group of BSCs. In addition, the traffic
on the BSC is evenly distributed to the SGSNs in the pool according to the network resource
identifier (NRI) or load balancing principle.
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The SGSNs in an SGSN pool share the traffic load and resources. This feature provides the
following benefits:
Increases the network capacity and saves the investment on equipment.
Implements redundancy backup and thus improves the network reliability because the
addition or deletion of an SGSN does not affect the services.
Reduces handovers between the SGSNs because the SGSNs in an SGSN pool are logically
one SGSN and thus improves the network performance.
TC POOL
In general, one GTCS belongs to only one BSC and is used to process the CS services of this
BSC. The GTCSs in different BSCs are not associated with each other. In this kind of network
topology, the TC resources cannot be multiplexed among multiple BSCs. In the scenario where
multiple BSCs with small capacity are grouped into a network, the TC resources are greatly
wasted.
The TC pool adapt to the mode that the GTCS is separated from the BSC cabinet and is
connected to the BSC through the Ater interface. The codec resources in the TC pool are shared
by the main BSC and sub-BSCs, which work in load sharing mode. In addition, a BSC can be
connected to only one TC pool. One TC pool supports a maximum of 16 BSCs.
The efficiency of the codec hardware can be increased because multiple BSCs share the same
resources in one TC pool. For the small-capacity BSC, 20% to 30% TC codec resources can be
saved.
Roomage is saved. For example, three small-capacity GTCSs require three cabinets. In TC pool
mode, three GTCSs require only one cabinet. In this manner, 40% to 60% area in the equipment
room can be saved.
The typical network topology is shown in the following figure.
E1/STM-1
TC(Pool)MSC2
BSC1 (main BSC)
BSC2(sub BSC)
BSC3(sub BSC)
MSC1
MSC3
BSC4(sub BSC)
E1/STM-1
E1/STM-1
E1/STM-1
E1/STM
-1
E1/STM-1
E1/STM-1
Ater A
Abis
Figure 61 TC Pool
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5.3.2 Highlight of Huawei‟s UMTS Solution
5.3.2.1 High Performance HSPA/HSPA+ Solution
With self-designed HSPA chipset, high performance HSPA can be achieved in Huawei UTRAN
products from day one, supporting full performance HSDPA with 15 codes /14.4 Mbps per user on
downlink and HSUPA with 5.76Mbps/user on uplink. For HSPA+ phase1, Huawei supports
21Mbps and 28Mbps per user on downlink with 64QAM and 2x2MIMO technique respectively.
In order to save evolution investment and keep the leading position of UMTS, Huawei is
recommending HSPA/HSPA+ deployment strategy as follows:
High performance HSPA/HSPA+ capability
To support high performance HSDPA and avoid hardware upgrade at the next stage, the Node B
should be ready to support full HSDPA performance from day one. Huawei supports this
philosophy by offering a Node B that supports 15 codes and peak bit rates at 14.4Mbit/s per cell.
Besides that, Huawei Node B supports all the 12 UE categories, avoiding system upgrade
investment along with the UE capability improvement.
Huawei HSUPA solution supports E-DCH TTI 10ms and 2ms, peak data rate up to 5.76Mbps.
Huawei has helped StarHub Singapore, eMobile Japan, Vodafone Spain, etc. to launch HSUPA
commercially with 1.92Mbps since 2007Q3.
With Huawei‟s advanced new generation Node B and RNC, Huawei can also provide high
performance HSPA+ phase1 solution, which has the ability to evolution to HSPA+ phase2
smoothly.
Coverage improvement
In HSDPA solution, Huawei supports HS-DPCCH preamble mode technology help the Node B to
distinguish between DTX and ACK/NACK without requiring a large ACK transmit power. In this
way, the uplink coverage gain is about 0.2dB to 0.9dB with different accompanying DPCH service.
DL 64QAM+MIMO improves user DL throughput and cell throughput
a) Introduction of DL 64QAM +MIMO
MIMO and 64QAM are introduced in 3GPP Release 7 and can only be used independently. In
3GPP Release 8, however, MIMO and 64QAM can be used in combination to increase the peak
throughput of a single user.
With 64QAM+MIMO, the peak throughput of a single user can reach 42Mbit/s, compared to
28Mbit/s with 16QAM+MIMO or 21Mbit/s with 64QAM only.
b) Benefits of Huawei MIMO solution
MIMO proved to bring high performance in spectral efficiency, cell capacity and user
throughput across the whole cell
MIMO deployment options can be a cost effective way to increase networks value
and end users perception
Major MIMO deployment issues could be solved
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Legay 1Tx RF cascade and new 2Tx RF solution
New algorithm has been proved for solving MIMO+HSDPA co-carrier
c) Benefits of MIMO+64QAM
Improve user DL throughput in good signal environment to 80% vs DL 64QAM
Figure 62 DL throughput comparison of DL MIMO+64QAM vs DL 64QAM
Improve cell throughput about 11.7% in Micro cell vs DL 64QAM
Figure 63 Cell throughput comparison of DL MIMO+64QAM vs DL 64QAM
For network where MIMO has been configured, combined application of 64 QAM and
MIMO will obtain relatively high gain in the micro cell.
For network where 64QAM has been configured, combined application of 64 QAM
and MIMO will obtain gain in both macro and micro cell and the gain is mainly from
the application of MIMO technique.
9.4% 11.7%
PA3, idea channel estimation, single user, type3 receiver
0
5000
10000
15000
20000
25000
30000
35000
40000
-5 0 5 10 15 20 25 30
Ior/Ioc (dB)
Throughput (kbps)
64QAM
MIMO dual
MIMO+64QAM dual
16QAM
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d) Leading position of DL MIMO+64QAM in industry
Huawei owns richest MIMO experience in 2009 and released MIMO RRU3908 in 2008.It shows
that Huawei is 2 year ahead industry for MIMO hardware ready.
In DL 64QAM and MIMO, Huawei is about one year leading ahead of other vendors both for
software and hardware ready.
DC-HSDPA Solution improves network performance
1) Introduction of DC-HSDPA solution
HSPA+ data can also be transmitted by the combination of two or more carriers and
this result in double or more times of data throughput. HSPA+ based on R8 uses
two carriers of consecutive frequencies in downlink and named as Dual Cell
HSDPA (DC-HSDPA). If both the network and the user equipment are capable of
Dual-Carrier HSDPA operation, the network will be able to configure the user
equipment not only with a (primary) serving cell but also with a secondary serving
cell originating from the same base station but on an adjacent carrier frequency.
Figure 64 DC-HSDPA working principle
2) Key benefits of DC-HSDPA solution
DC-HSDPA is an alternative of MIMO to improve the data throughput and users‟
experience. The carrier aggregation process enables the increase in capacity and user
throughput. The key benefits of DC-HSDPA are improved user experience, easy
deployment and low network cost.
a) Improve User Experience & Network Performance
DC-HSDPA provide higher throughput to the end-users even they are far from the
transceiver. The coverage performance of a DC user is higher than every other HSPA
user.
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Figure 65 DC-HSDPA service coverage comparison with other HSPA users
(Remark: from Huawei lab test)
b) Easy Deployment and Low Cost
For a deployed network, it is easy to upgrade it for the DC-HSDPA, no new antenna
configuration and no new transceivers required for DC-HSDPA. The cells only need
software configuration for DC-HSDPA if the network is already operating on the multi
frequency configurations in a same coverage area. For the areas where the cell is
covered by one carrier frequency only, there will be new requirement for another
carrier and it will cost some extra amount.
c) Decreases burst service and HTTP service relay remarkably
DC-HSDPA has best performance for the burst services like http, gaming or small
size download files. The burst services consume a small amount of resource and
users‟ transmission time is small, therefore; DC-HSDPA cells can easily share
their resources to all the subscribers.
d) Utilizes operators frequency resources and improves capacity and be compatible
with original terminals well.
3) Unique benefits of Huawei DC-HSDPA solution
a) Only software upgrade is needed for legacy market supporting DC-HSDPA
b) The network elements developed by Huawei are hardware ready for the
DC-HSDPA operations and only software up-gradation required. The SingleBTS
NodeBs and 6810/6900 series RNC types are capable to support DC-HSDPA
functionality through software up-gradation. The joint scheduling, channel
mapping and radio resource management are handled only by the software
change in the legacy elements.
c) Large capacity of baseband board, one board of 6 cells can support 2 carrier
DC-HSDPA.
d) First to provide Multi Carrier Transceivers.
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UL 16QAM increases system capacity of HSUPA cells
a) Introduction of UL 16QAM
HSPA+ uses HOM techniques in uplink to increase the number of bits per data symbol and
hence to increase the cell throughput capacity. In uplink, HSPA+ uses a 16QAM modulation
scheme instead of QPSK (Quadrature Phase Shift Keying), the number of bits per symbol
increases from 2bits to 4bits and hence the Uplink peak data rate can reach up to 11.5 Mb/s.
Figure 1-12 and Table1-3 gives the details descriptions of UL modulation schemes.
b) Benefits of UL16QAM
c) Raise the user peak rate and cell throughput
d) Obtain higher performance in Micro cell and indoor area than in Macro cell
e) Summary of UL 16QAM solution
f) Uplink 16QAM modulation scheme increases in uplink data throughput from 5.76Mps to
11.5Mbps. This is a 100% improvement over the previous 3GPP release of HSUPA.
g) UL 16QAM improves the UL data transmission performance and increases the system
capacity of HSUPA cells.
h) Leading position of Huawei UL 16QAM in industry
Huawei is around one year leading ahead of other vendors in UL16QAM.
HSPA+ Global Deployment
HSPA+ has quickly been embraced by many of the world‟s leading operators. More and more
operators had commercially deployed HSPA+ and more than 50 were engaged in vendor trials. It
is expected that by 2010 many more operators will have commercially deployed HSPA+.
GSA Survey on Global HSPA+ Commitments and Deployments on April 14 2010: Totally 101
HSPA+ networks, among which 51 commercial HSPA+ network, 50 HSPA+ networks in
deployment or planed. By Q1 2010, Huawei had already won more than 27 commercial HSPA+
contracts (market share> 50%) and the following operators had commercially launched HSPA+
networks.
Successful Cases
a) Starhub: Launched 1st HSPA+ Commercial Network in Asia Pacific
1st HSPA 7.2 Mb/s network in Southeast Asia in 2008.
1st Femto cell in the world in 2008.
1st HSPA+ 21 Mb/s with 64QAM technology nationwide 2100MHz network in Asia-pacific
area in 2009.
Single-user‟s desktop download speed up to 18.2 Mb/s
b) EMOBILE:Japan’s Leading Provider of High-Speed Mobile Data Services
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Figure 66 EMOBILE
EMOBILE chose Huawei to upgrade their network to HSPA+ 21 Mb/s with 64QAM
technology.The new 3G network provides EMOBILE customers with mobile data speeds
up to 21.6 Mb/s on the downlink.
EMOBILE is the fastest User Growth in 27 Months.
EMOBILE provides excellent MBB service and low tariff continually. Huawei‟s solution
helps E-Mobile to save 30% TCO as well as improve performance
With Huawei‟s SingleBTS, EMOBILE‟s current network can smoothly evolve to HSPA+ 42
Mb/s/84 Mb/s.
c) Vodafone: HSPA+ brings new opportunity to Vodafone Greece
Figure 67 Vodafone Greece
1st launched HSPA+ in Greece at July 8, 2009. And Stay ahead over competitors.
Huawei solution can support future evolution with low TCO. The network can upgrade to
64QAM Fast and smooth by software upgrading.
The best coverage in Greece.
Japan
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5.3.2.2 MBMS Solution
Overview
As one of the Leading Mobile MBMS vendors in the industry, Huawei has made some great
achievements in MBMS solution as the following:
Due to heavy investments in MBMS technology, Huawei holds 22% of the ETSI MBMS
patents.
1st vendor to perform live MBMS demo in Barcelona with 256Kbps worldwide.
Helping PCCW deploy first commercialized UMTS network with simplified MBMS
technology (CMB) in Hong Kong.
Huawei High-quality and More Competitive MBMS Solution
MBMS solution immediately launched by Huawei will have more enhanced features.
a) Supporting enhanced broadcast solution
Figure 68 Huawei MBMS Solution
Huawei MBMS broadcast solution is the unidirectional transmission of multimedia data (such as
text, audio, picture, video) from a single source entity to all users in the broadcast service area, it
includes P-T-P (point-to-point) mode and P-T-M (point-to-multi-point) mode. The enhanced
broadcast solution supports “counting/re-counting” function. Based on “Counting/re-counting”
result, RNC can select optimum transfer mode: PTM or PTP. In PTM mode, FACH/SCCPCH is
used to bear the MBMS services; in PTP mode, DCH or HSDPA is used to bear the MBMS
services. If in a cell there is no user interested in one specific MBMS service, RAN can decide to
cancel the service automatically.
b) Innovative Iub Transmission Sharing Solution Saving 66% Transmission
Resources
Figure 69 Iub Transmission Sharing
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Usually FACH channels in Iub interface are used to transport multimedia broadcast data
services from RNC to a few cells in a Node B. Without Iub transmission sharing, each cell must
have a FACH channel for transporting the data services from RNC so that more transmission
resources must be required in Iub interface.
By Huawei innovative Iub transmission sharing solution, a few cells in a Node B can share a
FACH channel if all the cells broadcast the same services. We can take 3x1 Node B for an
example, 66% transmission resources can be saved if 3 cells share a FACH channel. Obviously
operators can benefit from Iub transmission sharing solution.
c) Supporting MSCH
Huawei MBMS solution can support MSCH. Although MSCH is optional in 3GPP, Huawei
MBMS solution can support MSCH from day one. With the help of MSCH, MBMS terminal
power consumption can be reduced.
Continuous Efforts in MBMS and Bright Future
For a long time, Huawei has been dedicated in MBMS research in specifications and patents. Up
to now, 14 Huawei patents have been stated to ETSI and covered the total patents by 22%. With
some leading operators such as Vodafone, Huawei has been making efforts to promote the
development of MBMS in the industry. In-depth MBMS research and rich CMB commercialized
experiences have helped Huawei to take a leading position in MBMS solution.
5.3.2.3 UTRAN IP Transmission Solution
Overview
As IP technology is implemented more and more widely, IP becomes the most used transport
technology with the best cost efficiency. With the development of HSDPA and HSUPA, more
transport bandwidth will be needed. UTRAN IP transmission will be a good choice for operators.
Figure 70 UTRAN IP Transport Solution
Based on the current IP network condition, Huawei provides several UTRAN IP transmission
solutions. For Iu interface, Huawei provides Ethernet interface. As for Iub interface, Huawei
provides ATM access method for traditional ATM network whereas Ethernet interface for IP
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network. In order to use popular ADSL port, Huawei also provides ADSL access method. Likewise,
to guarantee the quality of voice and to lower cost, Huawei provides hybrid IP transmission.
IP over ATM Transmission Solution
Since ATM transport is the popular transport resource currently, IP over ATM is necessary. When
ATM Transport network carries Iub interface data, RNC and NodeB provide E1/T1 interface to
access ATM transport network. Huawei Iub interface IP protocol is compliant to 3GPP protocol,
UDP carries FP frame, and SCTP carries NBAP data. Huawei provides TCP to carry O&M data.
Huawei E1/T1 Iub interface supports ML-PPP/HDLC function in order to provide higher
bandwidth.
The highlight of IP over ATM:
Enhance the quality of IP service because ATM can provide the QOS guarantee.
Good ability of flow control and fault resilience, have good network reliability.
Suitable for multi-service, has a good network extension.
Figure 71 IP Transport based on ATM Transport Network
All IP Transmission Solution
In future, IP network will become more popular and will be used for Iub interface. RNC and NodeB
can then be connected to each other directly by metro Ethernet network through their FE
interfaces to access data communication network.
In general, NodeB cannot connect with RNC within the same metro Ethernet. NodeB needs to
access to metro Ethernet first, then access to IP network by edge router. However, RNC can
access directly to IP network.
For NodeB, the last mile access method is abundant, such as ADSL, SHDSL, MSTP, xPON, and
so on.
To solve the line synchronization for all IP transmission, Huawei provide clock over IP solution
instead of GPS to greatly reduce investment.
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Figure 72 IP Transmission based on IP Transport Network
Hybrid ATM/IP Transmission Solution
When the traditional UMTS network introduces HSDPA/HSUPA, The Traffic of RAN will be
increased greatly. If adopt traditional TDM transmission, the cost will be too huge to be accepted
by Operator. Due to the complexity of access network, If we adopt all IP transmission between
Node B and RNC, the QoS of real time service, such as Voice and Video Phone, cannot be
assured. In order to reach the balance of QoS and cost, Huawei introduces the IP Hybrid Base
Station Transmission Solution, which can solve the QoS of Network with low cost. Huawei
proposes the use of hybrid transmission solution on Iub interface whereby voice traffic will be
carried by TDM/ATM transport network and best effort traffic carried by IP network.
Figure 73 Hybrid IP Transmission Solution
Leading position of Huawei IP RAN solution
Huawei is more than one year ahead of other vendors in IP RAN.
1st vendor to support IP RAN solution, transmission cost saving
1st vendor to deploy commercial pure IP transmission, making full use of your transmission
resource
Only one vendor to realize Native IP RAN solution in the industry
1st vendor to provide clock over IP with clock server in commercial network, no need
external GPS or BITS to support synch.
No.1 in the benchmark-test of Vodafone at 10 consecutive quarters, perfect reliability
mechanism for stable performance
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Figure 74 Huawei‟s Leading IP RAN Solution
5.3.2.4 Co-site Solution
Overview
In order to speed up the construction and to cut down the CAPEX for setting up UMTS Network, it
is very important to share the existing facilities and the sites as far as practicable. Huawei is
experienced at 2G & 3G systems sharing the facilities and sharing the sites. Relying on this
experience, Huawei has summarized several general principles for 2G & 3G systems sharing the
facilities and the sites.
The UMTS network shall be of the excellent performance and 2G network performance has no
regression, even adopting 2G & 3G sharing sites solution.
Adoption of 2G & 3G sharing site solution shall insure the clear boundary between two Network
structures and systems, in order for easy maintenance and system management, and no
networks and no services cross-interfering.
The key objective for adopting 2G & 3G sharing site solution is to help the service provider
customer to cut down the CAPEX for constructing the new network. Any 2G & 3G sharing site
solution shall be obeying this economical rule.
Huawei’s Co site solution
The co site solution should fully consider the existing site conditions and the requirements of the
operator. The aspects of the co site solution shall include the space sharing, antenna system
sharing, transmission sharing, power sharing, etc. To ensure the reasonable reutilization of the
resource and the safety of the operation, the site survey and the detail site design shall be
conducted before the implementation. A general procedure for co site implementation is shown as
follows:
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C o S i te
D e sig n in g
S p a c e Sh a rin g
T ra n sm issio n
S h a rin g
P o w e r
E x p a n sio n
A ir C o n d i t io n e r
U p g ra d e
A u x i l ia ry
E q u ip m e n ts
M o d ific a t io n
S i te S u rv e y Si t e A d a p t io nE q u ip m e n ts
I & C
A n te n n a S y ste m
S h a rin g
Figure 75 Co Site Implementation Procedure
Antenna System Sharing
Due to the high cost of the installation and maintenance of the antenna system, the antenna
system sharing solution is always welcome to the operators. By the development of the antenna
technology, the sharing of the antenna and feeder system becomes more and more popular.
Huawei could plan and design the antenna system sharing solution based on the customer‟s
requirements and provide the necessary auxiliary equipments. Some typical antenna sharing
scenarios are shown as follows for sample:
Figure 76 Antenna Sharing Solution
Space Sharing
Depending on the space of the existing equipment room or shelter, Huawei will propose the
different product solutions accordingly:
If there is the enough space in the existing equipment room, Huawei will adopt indoor equipment.
During the on site survey and the engineering design period, Huawei will also evaluate the space
and the conditions and the life-span of existing shelters and consider the necessary alteration, in
order to install the new equipment and make the equipment operating normally.
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If there is no enough space in the existing room for installing new equipment, Huawei will propose
and adopt the Distributing Base Station (DBS) equipment or outdoor equipment, in accordance
with the site conditions. Huawei will evaluate the cost of those two solutions during on site survey
and engineering design and select the best solution for customer.
Figure 77 Space Sharing Solution
Transmission Sharing
To some operators, the cost of the transmission renting or maintenance is another huge
disbursement, especially for those suburban sites. So the transmission sharing solution is also
very important to the operators. Through flexible sharing of the transmission system, the TCO
could be obviously saved. Huawei Node Bs support IP RAN and other transmission sharing
modes, which will let the operator have abundance choices on transmission sharing. The
recommended sharing solution is fractional ATM mode, which could use part of the timeslots of
the E1 to carry the ATM message.
Figure 78 Transmission Sharing Solution of Fractional ATM
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5.3.2.5 RAN Sharing Solution
Overview
RAN sharing is an effective way to save CAPEX and OPEX., and approximate 30% ~ 40%
CAPEX and OPEX will be saved by RAN sharing. It can quicken the nationwide wide roll-out as
well. RAN sharing makes operators focus more on new and innovative services for end users with
less effort on roll-out and maintenances. RAN sharing brings better services, better quality of
experience and better coverage for end users.
Huawei can provide two kinds of RAN Sharing solution: Dedicted Carrier RS (MRNC) and Shared
Carrier RS (MOCN). In this proposal, Huawei introduces MOCN solution to SMART.
MOCN
In the MOCN solution, operators share resources of the entire UTRAN, including spectrum
resources. This solution is applicable to the following scenarios:
A 3G-licensed operator shares spectrum resources with other operators.
The operator who owns multiple spectrums uses these spectrums as a resource pool and
shares the pool with the operators who have no spectrums.
MOCN has the following characteristics:
The UTRAN of the shared area is constructed by one operator and shared by other
operators. These operators contribute their spectrum resources (if any) and share all
spectrum resources between each other (no matter whether an operator contributes
spectrum resources or not).
The shared RAN is connected to the CNs of multiple operators.
Each operator is allowed to deploy Iu Flex, and the CN nodes within an operator's network
form a CN pool.
The UEs in the same shared cell are routed from the RAN to the CNs of respective
operators.
RNC
Operator X
Operator B`s
CN node
Operator A
CN node
Operator C
CN node
Operator B`s
CN node
Operator B`s
CN node
No Iu-Flex No Iu-Flex
Iu-Flex
Iu Interface
Operator B`s CN nodes using Iu-Flex
Figure 79 MOCN
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The MOCN solution enables two to four operators to share RNCs and Node Bs and at the same
time to use their own CN. The operators work together to deploy CBS. With the application of this
solution, a cell can broadcast a Multiple PLMN ID LIST containing PLMN IDs of multiple operators.
The MOCN-enabled Supporting UE can choose a PLMN ID and send it to the RNC. The RNC
selects an appropriate route for this UE. If a Non-supporting UE exists in the shared cell, the UE
does not report any PLMN information to the RNC. Usually, at this time the RNC can determine a
route according to the PLMN ID derived from the IMSI or according to the NRI in the TMSI or
P-TMSI.
If the PLMN ID or NRI corresponds to one of the CNs that the RNC is connected to, the
RNC is directly routed to the corresponding CN node.
If the PLMN ID or NRI does not correspond to any of the CNs that the RNC is connected to,
the RNC tries to connect to each CN according to a certain principle. If the routing fails, the
RNC tries the next CN Node By following the Redirect process until the routing succeeds.
If the IMSI, TMSI, or P-TMSI is unavailable, the RNC keeps trying the CNs one by one according
to a certain principle.
The MOCN solution uses only one set of OSS equipment.
5.3.2.6 Smooth Evolution to HSPA+/LTE
The evolution paths for both distributed Node B and macro Node B is shown as follows:
Figure 80 Smooth Evolution to HSPA+/LTE
The Baseband Unit BBU3900 has 6 slots for base board, which supports the plug-and-play
function. The BBU is hardware ready for HSPA+ phase 1 (downlink 64QAM and MIMO 2 x 2)
and only need to add new baseband card to support HSPA+ phase 2 (uplink 16QAM) and
LTE respectively.
The RF Unit (RRU3804, RRU3908 and RF) is hardware ready for HSPA+, LTE, and only
need software upgrade to support HSPA+ and LTE at the same frequency band.
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A continuous investment reduces the TCO, improving the coverage and capacity and enhancing
the maintainability makes Huawei proposed network solution a cost-efficient solution. Huawei
multi-mode solution has prominent features such as distributed structure, large capacity, high
performance, low power consumption, and so on, which help operators save TCO at great height.
The multi-mode Solution consisted of the solutions are as follows:
TCO Saving
With the development of GSM/UMTS, operators are more and more focusing on the construction
and operation cost of a network. Huawei focused on reducing CAPEX and saving OPEX for
operators from different aspects as follows. In each aspect, Huawei has adopted many advanced
technologies to save cost.
Unit-equipment: one deployment for 10 years‟ viability
Unit-site: Co-Auxiliary facilities
Transmission Saving: Local Call Local Switching, Hub BTS, etc.
Power Consumption Saving: Direct Cooling in power, High efficiency PA, Power sharing, etc.
Civil Work Saving: Distributed BTS, etc.
Co-OAM: one maintenance team, optimize human resources
Smooth Evolution: SDR technology, UMTS900<E hardware reuse
Enhanced Coverage
Quickly set up a network by reducing the number of sites will not only win the competition but also
save the TCO. The leading operators have adopted the latest enhanced coverage technology that
can be used in both GSM & UMTS. This Enhanced Coverage Solution reduces 30% cell sites as
follows:
Leading RF Performance: Higher receive sensitivity.
Remote Radio Unit: 3db feeder loss avoided with fiber connection.
Transmit Diversity/Dynamic Transmit Diversity
4-Way Receive Diversity
Satellite Transmission
Extended Cell
Performance Enhancement
Along with the development of GSM/UMTS network, VMS attracts subscribers by excellent
service, flexible charging, and abundant handsets. The total revenue increases with the addition of
new subscribers. However, the ARPU decreases. In this situation, VMS is facing pressures of
expanding network capacity and improving service types and quality. Huawei introduces a series
of technologies to enhance network performance for VMS:
AMR
Wireless broadband service based on Edge+/HSPA/HSPA+
Frequency Hopping
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ICC/IBCA/Soft Synchronization
Dynamic MAIO
eMLPP +HR
Service Quality Enhancement Technologies
Smooth Evolution
Most of the operators have firmly believed that GSM/UMTS will evolve into LTE. That is a new
opportunity and challenge. With All-IP strategy, Huawei will build a future-oriented network for
operator and upgrade operator‟s network to LTE in the smoothest way. Huawei Smooth Evolution
Solution will save OPEX and reduce CAPEX by the ways such as reusing hardware and dynamic
capacity adjustment and so on.
GSM /GPRS Evolution into GERAN
GSM/EDGE/GERAN Evolution into LTE
UMTS/HSPA/HSPA+ Evolution in to LTE
Multi-mode BSC
5.3.3 High Transmission Efficiency /Improved Performance with 2G/3G Integrated
In multi-mode era, transmission cost counted as an important part of operator‟s TCO. Constructing
a cost-effective transmission network and being available for the need of the future evolution is a
challenge for all the operators. Huawei‟s co-transmission solution can solve this problem. It
includes two solutions based on different bearing network to fully reuse the exiting transmission
resource and protect customer investment.
Co-transmission Based on TDM network
Figure 81 Co-transmission Solution Based on TDM network
For some operators, they have an existing SDH network, and want to take back the investment as
soon as possible. Moreover, they have a difficulty in newly build an IP bearing network.
Therefore, Huawei provides this solution to fully use the existing TDM network. The GSM & UMTS
system can transmit the traffic in different TDM time slot independently on the SDH/PDH network
through the same E1/T1 line. UMTS BTS can adopt either ATM/IMA/Fractional ATM or IP/ML
PPP/PPP solutions. GSM can adopt TDM/ Abis over IP solutions. This makes the application
much more flexible.
Co-transmission Based on IP network
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Figure 82 Co-transmission Solution Based on IP network
For some operators who have an existing IP network or wish to construct an IP transmission
network, Huawei‟s co-transmission solution based on the IP network can fulfill their needs.
The GSM & UMTS system can transport the traffic on the same IP network through the same
E1/FE/GE line. GSM & UMTS can share the transmission resources dynamically, so there will be
a transmission convergent effect, and the transmission efficiency will be enhanced.
As a single network, the resources of 2G&3G should be shared in the total system. How to
manage the resources to get the efficient and improved network performance? Huawei has done
a lot of effort on researching this field, we think it will be a trend of multi-mode network, and our
unique Co-RRM and Co-TRM solutions will be benefit and help to achieve customer‟s business
plan.
Co-RRM
Co-RRM is especially useful for the applications where different RAT cover the same area.
Co-RRM maximizes the efficiency of different radio access network by selecting a suitable
network for camping or accessing a subscriber. Co-RRM can further lead to reduce power
consumption by dynamically allocating traffic between different radio access technologies and
shutting down some carriers in a particular RAT.
With separate network implementation cell load information is exchanged by core network
intervention and it will have the associated signaling delay and also delay in handover procedures,
one of the unique advantages with MBSC and Co-RRM feature is that core network intervention is
avoided and thus it helps in reducing handover and associated signaling delays as shown in 0,
and reduce service interruption time to less than 680 ms.
- Improved Performance with Co-RRM
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Figure 83 Co-RRM Solution
Co-TRM
Co-Transmission Resource Management (TRM) facilitates efficient access to 2G or 3G with
unique features such as Uni- Connection Admission Control (CAC), Uni-Flow control more
numbers of users can be effectively allocated to 2G/3G service. Co-TRM feature not only helps to
reduce maintenance trouble for the operators‟ but also helps to increase the efficiency of the
transmission resources.Morover, Co-TRM provide convergent solution and can be monitored and
maintained with Unified O&M.
5.4 Huawei Centralized OMC Solution
5.4.1 Overview of Unified OMC
2G/3G
CS Domain
2G/3G
PS Domain
LMTLMTLMTLMT
LMTLMT
LMTLMT
NMS
UTRAN Domain
RunAttentionFaultRemote
SP PresentStandby Power
Power
hp rp74xx
M2000 ServerAlarm Box GENEX OM Tools
BSS Network
NML
EML
NELDCN
EMS include:
iManager ® M2000
GENEX ® Serial Tools
LMT
M2000 Client
Open northbound interface
MML/BIN/SNMP
Figure 84 Huawei OMC Solution
Huawei OMC solution supports the centralized O&M of CS, PS core, BSS and UTRAN
system, through OM network. The OMC solution includes three parts:
iManager M2000, which is the centralized element management system (EMS) with
full centralized management functionalities on Huawei NEs, including alarm
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management, performance management, configuration management, software
management, security management etc.
GENEX serial OM tools, which is the Huawei‟s Radio Network Planning &
Optimization software applications, including GENEX UNet for network pre-planning
and planning, GENEX probe for drive test, GENEX Assistant for radio network test
data, GENEX Nastar for performance analysis.
Huawei LMT for each type of Network Element, which is the local maintenance
terminal installed software for specific NE‟s, capable of supporting full signal tracing
and trouble shooting functions besides the common O&M capability in NE level.
The M2000 and the LMT form two levels of an O&M system. Operators can manage and
maintain the authorized NEs via the M2000 Client, through the TCP/IP Ethernet network. The
major interface between M2000 and NEs is the highly efficient Man Machine Language (MML).
In case the connection fails or M2000 is unavailable, each NE will be managed and
maintained via the LMT respectively.
5.4.2 Huawei‟s Powerful iMananger M2000
iManager M2000 Mobile Element Management System can manage all the GSM&UMTS
network elements and the relative IP network equipments. In the future, the managed objects
(MO) of M2000 solution will include all IMS network elements. iManager M2000 has the
following characteristics:
Component based architecture
The CORBA component based architecture enables M2000 to expand its capacity smoothly
to meet network requirements. Besides that, the design flexibility enables it to be easily
extended with other components.
Implementing standard and open Northbound interfaces
The system supports standard 3GPP IRP CORBA solution sets, together with file interface,
database interface, alarm streaming interface, SNMP interface. These customizable open
northbound interfaces (Itf-N) well support customer to build a well-integrated OM system, with
an upper level NMS managing EMSs from multiple vendors.
Remote maintenance with security
By accessing M2000 system through PSTN remote dialup, a remote user can maintain its
UMTS network flexibly. All operations implemented by the remote user are monitored. When
the remote user quits, a maintenance report is generated automatically.
Software management
The system provides the function of transferring files between NE and M2000. M2000 can
download file to multiple NEs simultaneously, which hence improves file transfer performance
and reduces management work.
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The system can also manage all software‟s versions of managed NEs. NE version
management functions include version information management, version file management,
version activation, etc.
Dynamic upgrade
M2000 system upgrade has no impact on NEs. The function modules of M2000 can be
upgraded independently.
Customizing performance report
The template and content of performance report can be customized flexibly. Users can do
further processing on generated reports, including printing, querying, statistics, etc.
Alarm correlation processing
Alarm correlation analysis and processing are performed based on the expandable alarm
rules.
Status monitor
The status of device boards, CPU, database, memory, and M2000 itself can be monitored
dynamically.
Resource statistics
System resources such as IP addresses, ports, signaling points, device boards, M2000 server,
and so on can be gathered and refreshed automatically.
Interface message tracing and user message tracing
Specified signaling messages of various interfaces can be traced, which enables users to get
the current network status and locate faults.
5.4.3 Abundant Northbound Interfaces for OSS Integrated Solution
As an element management system (EMS), the iManager M2000 provides abundant and
flexible northbound interfaces to the upper-layer network management system (NMS).
These interfaces include CORBA interface, the FTP file interface, SNMP interface, etc. The
flexible northbound interfaces offered by Huawei can help the carriers to:
Conveniently and quickly construct the operation and maintenance system
Integrate the NMS and Huawei‟s EMS
Seamlessly embed Huawei‟s mobile communication equipment in their original O&M
system
5.4.4 CME for Graphical Network Configurations and Tuning
Aiming at the complexity of wireless network configurations, Huawei offers the
Configuration Management Express (CME) with graphic interface. The CME provides users
with fast and convenient wireless network configuration solutions in the different O&M
scenarios, saves the cost of construction. The typical scenarios are as following:
Initial construction configuration
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Transmission configuration
Adjustment of the wireless parameters
Cell relationship
The CME has the following attributes:
Offering friendly human-machine exchanging policy
Offering the navigation interface based on the network topology and protocol stack
Simplifying and visualizing the configurations by combining the configuration and
maintenance scenarios of RAN
Meanwhile, the CME has powerful configuration functions, including:
Configuration based on current data area and planned data area
Re-parent Configuration
Configuration wizard
Configuration data check, etc.
5.4.5 iSStar Offering Customized O&M Development Platform
The integrate script star (iSSTAR) of the M2000 system is a script development platform
independently developed by Huawei. It is capable of powerful script development. Based on
the python language, the is STAR has the following advantages:
Supporting the programmable logic control of the MML scripts
Offering compilation and batch execution functions
Providing abundant Huawei Foundation Class (HFC) library
Conveniently expanding the compilation function of scripts
By using the iSSTAR, the carriers can independently develop the scripts of different O&M
functions according to their requirements, scenarios, and working habits. For instance, the
scripts can include the routine check of equipment, real-time supervision of the network,
batch data modifications, etc.
The script compilation is convenient, time-saving, and matches different O&M scenarios. It
greatly improves efficiency and reduces costs.
5.4.6 Software Management and Remote Upgrade Solution to Save OPEX
The software management offered by Huawei can manage the NEs‟ software versions,
patches, licenses, and configuration data. It can also download and activate the software by
batches. The software management offers the GUI to manage the software versions and
patches. Through the tool of graphic Node-B software upgrade wizard, Huawei‟s software
management can download and activate 500 Node-B‟s software at most each time. In
addition, the download and activation of software can be scheduled as scheduling tasks.
The remote upgrade is an important issue of the software management. By using automatic
download and activation software by batches, the complicated grades can be implemented
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in easy way. Huawei‟s graphic BSC one-touch upgrade wizard greatly reduces the
complexity of upgrading operation, shortens the time of upgrading and service disruption,
and reduces the risks of upgrading.
The software management and remote upgrade solution has the following advantages:
Implementing the remote upgrade of the mobile network equipment
Saving the time for the operators
Improving working efficiency
Reducing the cost of operation and maintenance
5.5 Inter-working Solution with Existing GSM/GPRS/EDGE System
5.5.1 Inter-working Solution Overview
Spectral efficiency of UMTS is higher than GSM. Hence, operators with high GSM user
penetration rate will consider deploying UMTS network to optimize the total capacity of wireless
network (GSM plus UMTS) within a certain spectrum.
It needs seamless inter-working between existing GSM network and overlay UMTS network to
offer continuous services. In different phases of UMTS deployment, the user distribution of GSM
and UMTS/GSM dual mode is different and the coverage area of UMTS network increases
gradually from the initial phase. It is important to consider different inter-working strategies in
order to achieve operating efficiencies and savings.
Different concerns for operators in UMTS deployment will result in different inter-working
strategies between UMTS and existing GSM network. By considering operating efficiencies, it is
a need to maximize network capacity and to initiate as little as possible of inter-RAT handover. If
the inter-working solution has very little impact on existing GSM system, the investment on
existing GSM network can be reduced, resulting in total cost saving of network deployment.
Based on the above considerations, the proposal of an inter-working solution is recommended
as compared to different solutions.
5.5.2 Inter-working Solutions and Strategy
Camp solution and inter-RAT handover/cell reselection/cell change order solution are two
parts of inter-working solution. There is a need to consider these two solutions respectively.
Once UMTS is introduced to overlay GSM network, there are three possible solutions for
UMTS/GSM dual mode terminal camping. The table below is used to compare these three
solutions in terms of impact on network load, service experience for users and handover.
To fully utilize the capacity of UMTS network, improve the service quality and attract user
with UMTS based services, Huawei recommends „prefer UMTS‟ solution for network camp.
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Table 88 Comparison of Three Solutions
Solution Network Load Service Experience Handover
Prefer UMTS
Dual mode UEs camp on UMTS network. It decreases GSM network load and makes full use of UMTS network.
User can request UMTS based services immediately.
Softer/soft handover can be performed within UMTS network. Inter-RAT handover or cell reselection from UMTS to GSM is performed when there is no UMTS coverage.
Prefer GSM
Dual mode UEs camp on GSM network. It increases GSM network load and lessen the use of UMTS network.
Users can request GSM/GPRS/EDGE based services but can‟t request UMTS specific services like VP unless users do network reselection by hand.
Hard handover is performed within GSM network. If inter-RAT from GSM to UMTS is performed, it requires big upgrades in GSM network.
Random
Dual mode UEs in idle mode randomizes between GSM or UMTS. It is difficult to predict the load of each network hence causes a big problem in network optimization and adjustment.
Service experience is based on the camping network.
Handover type is based on the camping network.
For UMTS CS services, there are four possible solutions for inter-RAT handover between
UMTS and GSM. Based on the following analysis, Huawei recommends unidirectional
inter-RAT handover for CS service.
Unidirectional inter-RAT handover from UMTS: Only inter-RAT handover from GSM to
UMTS is performed to offer seamless service. It only needs software patch for GSM system
to support inter-handover from UMTS.
Bidirectional inter-RAT handover: Inter-RAT handover from/to UMTS to/from GSM is
performed to offer seamless service. It requires big changes on GSM BSS and MSC. It
means that operators need to increase investments in GSM network to support
bidirectional inter-RAT handover. It can‟t make total saving in network deployment and
operation.
Non inter-RAT handover: In initial phase, scale of UMTS network is small. Calls will be
dropped once UEs move out of UMTS area if inter-RAT handover is not performed. In
developing/mature phase of UMTS deployment, more and more users will camp on UMTS
network. So, the load of GSM will become less. It can‟t maximize the usage of total network
capacity if no inter-RAT handover to GSM is performed.
Unidirectional inter-RAT handover from GSM: Only inter-RAT handover from UMTS to
GSM is performed. It requires big change in existing GSM elements. And it will have call
drop once out of UMTS coverage (which will often happens in initial phase of UMTS
deployment.).
For UMTS PS service, cell reselection/cell change order procedure is used to keep call
connection once UEs are moving. It only requires GPRS/EDGE support three additional
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system information: SI 2ter; SI 3; SI 2quater. Therefore, Huawei recommends bidirectional
cell reselection/cell change order for PS service.
According to the above analysis, Huawei recommends „prefer to use UMTS, unidirectional
handover from UMTS for CS service and bidirectional cell reselection for PS service‟
solution for VMS‟s inter-working between UMTS and existing GSM network. In every
different phase of UMTS deployment, the coverage area of UMTS is different. There will be
impact from the adopting of handover methods to implement the inter-RAT handover.
Considering the small scale UMTS network in initial phase, Huawei recommends coverage
based on inter-RAT handover from UMTS to GSM to keep service continuity. As the UMTS
network develops, load balancing of UMTS and GSM becomes much more critical. Then,
Huawei recommends service and load based inter-RAT handover to maximize the total
network capacity.
The following sub-sections are used to describe the detailed solution of camp and
inter-RAT handover/cell reselection.
1) Camp solution
When an UE is switched on or in roaming, its primary work is to find and connect to a
network to obtain services. This means that this UE needs to camp on one network. If an
UE is switched on in an area covered by UMTS and GSM, Huawei recommends:
Network selection to UMTS network: This can be done by parameter setting (HPLMN with
access technology) in the USIM card. If different PLMNs are used in GSM and UMTS,
UMTS PLMN is set as HPLMN. Else if same PLMN is used for GSM and UMTS, UMTS is
set as higher priority access network. Huawei recommends same PLMN for GSM and
UMTS for it will not require VMS to sign additional roaming agreement for newly adopted
PLMN.
Cell reselection to GSM when there is only GSM coverage (out of UMTS coverage)
Cell reselection to UMTS when there is UMTS coverage
Huawei recommends cell reselection instead of PLMN reselection for UE in idle mode.
PLMN reselection will be performed at least 6 minutes after UE comes back to UMTS
coverage. During this period, UE cannot request for UMTS based services. Cell reselection
can be performed immediately just based on radio measurement.
GSM
UMTS UMTS
Cell reselection from UMTS to GSM
Cell reselection from GSM to UMTS
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Figure 85 Cell Reselection in Idle Mode
2) Inter-RAT handover/cell reselection/cell change order solution
Coverage based inter-RAT handover in initial phase
Figure 86 Coverage Based Inter-RAT Handover
In the initial phase of UMTS deployment, GSM network has better coverage than UMTS
network. Not only that, dual mode users are less than GSM only users. Huawei
recommends only coverage based inter-RAT handover is performed. UMTS can support
CS service, PS service, combination services (CS + PS). For different services, Huawei
recommends different handover strategies:
CS services only: Inter-RAT handover to GSM is performed when out of UMTS coverage.
Then, the call is kept in GSM until call is ended even UE moves into UMTS coverage again.
PS services only: Inter-RAT Cell reselection (when UE is not in CELL_DCH state) or
inter-RAT cell change order (when UE is in CELL_DCH state) to GPRS/EDGE is performed
when UE is out of UMTS coverage. When there is UMTS coverage, inter-RAT cell
reselection to UMTS is performed to offer higher data services.
CS service + PS service: For combined services, Huawei recommends to ensure CS
service continuity. The strategy is the same for CS service only. PS service connection will
be kept in the same network as CS service connection.
UE needs to perform cell reselection procedure to return to UMTS when UE is in idle mode
and moved into UMTS coverage.
Service based and load based inter-RAT handover; coverage based inter-RAT handover in
developing/mature phase.
Handover to
GSM
Staying in GSM
during the call
Call end, Cell
Reselection to UMTS
Service begin
Cell Reselection or
Cell Change Order to
GPRS/EDGE
Cell Reselection to
UMTS
CS service
UMTS & GSM cell
GSM/GPRS/EDGE cell
CS handover to
GSM
Staying in GSM
during the call
CS + PS
Cell Reselection or Cell
Change Order to
GPRS/EDGE
PS service
Camping on UMTS in
idle mode
Call end, Cell
Reselection to UMTS
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Figure 87 Service and Load Based Inter-RAT Handover
In developing/mature phase of UMTS deployment, UMTS network has better coverage.
Dual mode users are eventually more than GSM only users. Huawei recommends service
and load based inter-RAT handover. Considering the capability of GSM network, different
handover strategies for different services are required. For details refer to the above figure.
K1/ K2% is the load threshold that is used to initialize service and load based handover.
They can be set to the same or different value which is less than the threshold used to
initialize congestion control. Once cell load exceeds K1/K2%, RNC will initialize
corresponding action. R1/R2 data rate is set to a maximum data rate that
GSM/GPRS/EDGE can support. As per the specification, this functionality shall be
performed under the CN control (CN will set one proper IE in RAB assignment.). Huawei
RNC also supports this functionality by RNC configuration.
If there are combination services, RNC will first consider handover UE with single
connection to GSM and keep UE with combination services in UMTS network because
currently only UMTS network can support combination services.
When there is no UMTS coverage, coverage based on inter-RAT handover will be
performed. The strategy is similar to the one used in initial phase.
CS High
Rate Data
(> R1
kbps))
PS High
Rate BE
Services (>
R2 kbps
Conversational/
Streaming
Services except
CS Speech
PS Low
Rate BE
Services (<
R2 kbps)
CS Low
Rate Data
(<R1
kbps)
CS Speech
Percentage of
Cell load
K1%
K2%
K%
Handover to
GPRS/EDGE
No action Handover
to GSM
Handover
to GSM
No
handover
Handover to
GPRS/EDGE
Degrade and
handover to GSM
0%
RNC action: congestion control
RNC action:
RNC action:
Shall not be handed
over to GSM
Should not be handed over to GSM
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6. Huawei Experience & Credibility
6.1 Global References
In 2010, Huawei has won great success with SingleRAN solution, which includes Telenor Norway,
Net4Mobility in Sweden, Vodafone in Spain, SFR in France, Teliasonera MSR in Finland and LTE in
Norway, etc. Huawei has shipped 1.5 Million BTS units and Huawei‟s wireless product is serving
500+ operators and, 1.5 billion subscribers in over 160 countries.
With Huawei SingleRAN solution, 155+ 2G&3G network has been swapped worldwide with 31
swapped in EU. Till 2010Q4, Huawei has helped operators deploy more than 80 SingleRAN
networks of which 31 are commercially launched, 33 in deployment stage and 16 in trial stage.
According to GSA‟s survey on “Global HSPA+ Commitments and Deployments”, as of 24 January
2011, a total of 103 HSPA+ networks had been commercially launched, among which 48 networks
were deployed by Huawei (for a 46% share of market).
Besides by 2010, Huawei has been awarded with 281 GSM and 205 UMTS commercial
contracts by the mainstream mobile operators in the world, and has improves its GSM
shipments status as No.1 and maintains its UMTS shipments status as No. 2.
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6.2 IOT Experiences
Huawei is the member of NVIOT Forum, and Huawei IOT is based on NVIOT.
Huawei is the leader in establishing and developing interoperability testing between RAN and
CN equipment across the UMTS and GSM/GPRS.
Huawei is the leader in establishing and delivering interoperability testing between RAN and
terminals.
Huawei has extensive experience in IOT as shown in table below:
Figure 88 IOT Experiences
Huawei has realized numerous commercial UMTS/GSM handover and roaming with
main-streaming operators. For detailed information, please refer to the following table.
Table 89 Commercial Inter-working Experiences
GSM Vender NSS BSS Location
Ericsson √ √ Etisalat, U.A.E.
Telecom Malaysia, Malaysia etc.
Nokia √ √ Telecom Malaysia, Malaysia
Eurotel, Czech Republic etc.
Nortel √ √ SUNDAY, Hong Kong etc.
Alcatel √ √ Etisalat, U.A.E.
Telecom Malaysia, Malaysia etc.
Siemens √ √ Etisalat, U.A.E.
Emtel, Mauritius etc. CMCC, Beijing, China
Motorola √ Etisalat, U.A.E etc. CMCC, Beijing, China
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Huawei also supports open Iu interface and Huawei RAN elements have done many tests with
main-streaming vendors MSCs/SGSNs. Some of them are listed in the following table.
Table 90 IOT of Iu Interface
Interface HUAWEI device Other vendor’s device Vendor’s name Organizer
Iu RAN MSC R9
SGSN W4.0 ERICSSON CMCC
Iu RAN MSC NSS 16
SGSNPC 03 NORTEL CMCC
Iu RAN MSC V100R001
SGSN 1.7.0.0.52 MOTO CMCC
Iu RAN MSC R9.1
SGSN R4.0 ERICSSON MTNET
Iu RAN MSC M11
SGSN 1 1.2 NOKIA MTNET
Iu RAN MSC XA core MSC
SGSN Passport 15000 NORTEL MTNET
Iu RAN MSC UCR2.0
SGSN UCR2.0 SIEMENS MTNET
Iu RAN MSC U1X MD#1
SGSN U1X MD#3 ALCATEL MTNET
Iu RAN MSC V800R002
SGSN USP1.0 MOTO MTNET
6.3 Global Applications and Progress
6.3.1 GSM/UMTS Networks in Telefonica/O2, Germany
Telefonica/O2‟s Challenges
Aging equipments, high OPEX
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Hard to deploy new services
High churn rate due to poor performance
Degraded services from original providers
Project Profile
Build 2G/3G networks for Telefonica/O2 in Munich, Stotinka, Nuremburg etc.
To swap 3,000 Nortel BTSs and 1,700 Nokia 3G Node Bs, 1,800 new GSM
BTSs added
Benefits
~30% TCO saving within 2 years after swap
Power saving
Reduce leased line
DNBS save footprint and site rental
Easy maintenance & higher reliability
E2E HSPA+ solution
RAN, IP Microwave, Core network, Terminal
Highest Speed in Germany:
28Mbps Downlink /5.76Mbps Uplink
More data throughput gain with MIMO
260% ~280% increased from HSDPA
30%~50% increased from 64QAM
Multi-mode BTS3900
6.3.2 SingleRAN Strategic Fit for Vodafone D2
Project Introduction
July 2010, chosen as one of the two technology partners for nationwide LTE
upgrade & Single RAN modernization
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Secures 67% share of 1500 base stations for LTE upgrade in the 1st phase
Benefits for Vodafone D2
Best Practices for Cost Reduction
100% RRU sites, reducing site energies and rentals
All IP transport including provision of IP microwaves
Much simplified network topologies (fewer nodes, centralized
mgmt.)
World’s smallest & lightest 3MRRU saving deployment costs
Best Approaches to Radio Convergence
SingleRAN BTS easy to build 2G/3G/LTE multi-technology sites
One BTS solution for three technologies and five frequency bands
Best Network Performance and Long-term Partnership
LTE performance verified in field tests jointly carried out as early as
in 2009 (60Mbps cell throughput with 10MHz carriers)
Contributes to DD800 spectrum auction by providing joint research &
test results (of DTV interference) to German regulators
6.3.3 UMTS/HSPA Network in Vodafone, Spain
Project Introduction
Nov. 2005, became an Approved UMTS/HSPA Supplier
Jul. 2006, won Vodafone Spain Project
Market share: Increased to 68% including Barcelona
Sites: 7500+ (100% DNBS, Swap Nortel)
3G subscribers: over 3 million
Huawei‟s Values
Nearly 31.8% TCO saving for 5 consecutive years
Delivery: Maximum 453 sites per month
Better performance
CS call drop is reduced to 0.33%
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Handover success rate is 98%
Latest Progress
Vodafone group has started to cooperate with Huawei in more countries,
such as Hungary, Romania, Poland, Greece and so on
6.3.4 SingleRAN Well Matched for Orange Spain
Refarming 900M spectrum for UMTS & ready for HSPA+/LTE evolution
Project Introduction
Swapping 10,000+ 2G&3G base stations (5000+ sites) in Southern Spain
(OSP‟s strategic, high-value market)
Having secured 44% market share of 2G&3G BTS
A less-than-two-year project plan
Highlights of Huawei Proposal
Full-fledged & Unique 900M Refarming Solution
One RRU supporting RAN Sharing with another operator
One RRU support GSM900 & UMTS900 at the same time
Convergence-optimized SingleRAN Solution
Single BTS/BSC/OSS for GSM & UMTS concurrent operations
Save CAPEX and ease operation & Maintenance at all levels
Future-proof Solution, Smooth Evolution to HSPA+/LTE
Unique Dual-transmitter (2Tx) RRU solution
Hardware ready for HSPA+ 84Mbps and LTE MIMO
2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
PURCHASING 2G/3G INTERGRATED BTS
FOR MOBIFONE NETWORK 2010
Huawei Confidential Page 152 of 155
Best-in-class Tailor-made IMB Solution
Strategic cooperation with FT, 1st vendor to provide Internet
Multimedia Broadcast commercial solution (early 2011)
6.3.5 Telenor Keeps Leading with SingleRAN
Challenges
Profitability Risk due to rapid growing data traffic & decreasing revenue per
MB
High Cost for network upgrade & future evolution
Project Profile
6-year strategic cooperation covering 2G/3G/LTE
2G/3G modernization, U900 & LTE2.6G rollout
HSPA+ and LTE ready, SDR ensures flexible evolution
Benefits for Telenor
Best matched Telenor Norway‟s MBB strategy
Great TCO saving by SingleRAN solution
Win the competition based on the “Long Term Evolution” network
2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
PURCHASING 2G/3G INTERGRATED BTS
FOR MOBIFONE NETWORK 2010
Huawei Confidential Page 153 of 155
6.3.6 UMTS/HSPA Network in StarHub, Singapore
Project Introduction
Jan. 2007, won whole UMTS/HSPA network swap project
Market share : 100%
Sites : 1200+ (Swap Nokia)
3G subscribers: over 200k
Huawei‟s Values
Joint BP analysis: 25% CAPEX + OPEX saving
1st HSPA+ in Asia Pacific keeps leading brand in MBB market.
Hardware ready for LTE evolution.
“One Tunnel” solution simplified network structure.
IP RAN
iDBS Commercial。
Lower tariff and various services to consumers.
Smooth software upgrading saved TCO.
Fast engineering delivery (finished 800+ sites in < 3 months)
Latest Progress
Co-marketing with StarHub to develop more attractive 3G services
2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
PURCHASING 2G/3G INTERGRATED BTS
FOR MOBIFONE NETWORK 2010
Huawei Confidential Page 154 of 155
6.3.7 All-IP HSPA Network in eMobile, Japan
Challenges
Transform from fixed broadband service provider to mobile operator
How to reuse existing broadband resource
Extended UMTS band
Huawei‟s Values
Detailed business plan for Greenfield operator
Multi-band UMTS solution - 1.7 GHz for Japan
First commercial All-IP HSPA network in world
Industry-leading IDBS solution
Latest Progress
In Aug. 2007, awarded another 2200 DBNS and 30 iDBS contracts
2.3.1 SingleRAN Technical Proposal for Mobifone 2G3G Project-Center I,V.doc
PURCHASING 2G/3G INTERGRATED BTS
FOR MOBIFONE NETWORK 2010
Huawei Confidential Page 155 of 155
7. Conclusion
In this document, Huawei provides a comprehensive technical proposal of GSM/UMTS
network for VMS. Overall descriptions on network design and dimensioning are given,
following with equipment features and highlights of proposed solution. Detailed description
of the proposed equipment can be evaluated from the corresponding system description
documents.
In this proposal, Huawei offers SingleRAN solution to enable VMS to achieve full
convergence of multi-mode wireless networks, including base stations, base station
controllers, sites and operation as well as maintenance management. It provides a simple
and unified radio access network which can achieve GSM, UMTS and LTE functionalities
simultaneously and is software configurable according to different traffic models to have
more GSM or UMTS capacity. This is an optimal and long-term solution for VMS.
Huawei earns reputations of being a fast-growing, innovative, responsible and experienced
vendor in telecommunication field, especially in the leading position in many technology
aspects. Huawei is confident that the offered products can bring an advanced, tailored and
most cost-effective mobile network to VMS. Together with our professional technical
services, VMS can expect abundant benefits. We hope this offered package will lead to a
long-term cooperation between Huawei and VMS. As an innovative and reliable vendor in
the telecommunication industry, Huawei is dedicated to delivering a robust, future-oriented
and cost-effective GSM & UMTS system for our customer with the state-of-the-art
technology. A stable and long-term cooperation is the commitment that Huawei always
believes in.