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3G演进:HSPA与LTE(英文版 第二版)
出版时间:2010年版
丛编项: 图灵原版电子与电气工程系列
内容简介
《3G演进:HSPA与LTE(英文版.第2版)》是爱立信研究院研发人员的经验之谈,描述了3G数字蜂窝系统如何演进成为先进的宽带移动接入技术,重点介绍了3G移动通信标准化开发演进路线、无线接入技术和接入网络的演进。书中内容分为5部分,清晰地勾勒出了3G演进技术取舍的诸多细节。《3G演进:HSPA与LTE(英文版.第2版)》是移动通信行业技术人员的必备参考指南,也是高等院校通信专业师生不可多得的教学参考书。
目录
Part Ⅰ: Introduction
1 Background of 3G evolution 3
1.1 History and background of 3G 3
1.1.1 Before 3G 3
1.1.2 Early 3G discussions 5
1.1.3 Research on 3G 6
1.1.4 3G standardization starts 7
1.2 Standardization 7
1.2.1 The standardization process 7
1.2.2 3GPP 9
1.2.3 IMT-2000 activities in ITU 11
1.3 Spectrum for 3G and systems beyond 3G 13
2 The motives behind the 3G evolution 15
2.1 Driving forces 15
2.1.1 Technology advancements 16
2.1.2 Services 17
2.1.3 Cost and performance 20
2.2 3G evolution: Two Radio Access Network approaches and an evolved core network 21
2.2.1 Radio Access Network evolution 21
2.2.2 An evolved core network: system architecture evolution 24
Part Ⅱ: Technologies for 3G Evolution
3 High data rates in mobile communication 29
3.1 High data rates: Fundamental constraints 29
3.1.1 High data rates in noise-limited scenarios 31
3.1.2 Higher data rates in interference-limited scenarios 33
3.2 Higher data rates within a limited bandwidth: Higher-order modulation 34
3.2.1 Higher-order modulation in combination with channel coding 35
3.2.2 Variations in instantaneous transmit power 36
3.3 Wider bandwidth including multi-carrier transmission 37
3.3.1 Multi-carrier transmission 40
4 OFDM transmission 43
4.1 Basic principles of OFDM 43
4.2 OFDM demodulation 46
4.3 OFDM implementation using IFFT/FFT processing 46
4.4 Cyclic-prefix insertion 48
4.5 Frequency-domain model of OFDM transmission 51
4.6 Channel estimation and reference symbols 52
4.7 Frequency diversity with OFDM: Importance of channel coding 53
4.8 Selection of basic OFDM parameters 55
4.8.1 OFDM subcarrier spacing 55
4.8.2 Number of subcarriers 57
4.8.3 Cyclic-prefix length 58
4.9 Variations in instantaneous transmission power 58
4.10 OFDM as a user-multiplexing and multiple-access scheme 59
4.11 Multi-cell broadcast/multicast transmission and OFDM 61
5 Wider-band ‘single-carrier’ transmission 65
5.1 Equalization against radio-channel frequency selectivity 65
5.1.1 Time-domain linear equalization 66
5.1.2 Frequency-domain equalization 68
5.1.3 Other equalizer strategies 71
5.2 Uplink FDMA with flexible bandwidth assignment 71
5.3 DFT-spread OFDM 73
5.3.1 Basic principles 74
5.3.2 DFTS-OFDM receiver 76
5.3.3 User multiplexing with DFTS-OFDM 77
5.3.4 Distributed DFTS-OFDM 78
6 Multi-antenna techniques 81
6.1 Multi-antenna configurations 81
6.2 Benefits of multi-antenna techniques 82
6.3 Multiple receive antennas 83
6.4 Multiple transmit antennas 88
6.4.1 Transmit-antenna diversity 89
6.4.2 Transmitter-side beam-forming 93
6.5 Spatial multiplexing 96
6.5.1 Basic principles 97
6.5.2 Pre-coder-based spatial multiplexing 100
6.5.3 Non-linear receiver processing 102
7 Scheduling, link adaptation and hybrid ARQ 105
7.1 Link adaptation: Power and rate control 106
7.2 Channel-dependent scheduling 107
7.2.1 Downlink scheduling 108
7.2.2 Uplink scheduling 112
7.2.3 Link adaptation and channel-dependent scheduling in the frequency domain 115
7.2.4 Acquiring on channel-state information 116
7.2.5 Traffic behavior and scheduling 117
7.3 Advanced retransmission schemes 118
7.4 Hybrid ARQ with soft combining 120
Part Ⅲ: HSPA
8 WCDMA evolution: HSPA and MBMS 127
8.1 WCDMA: Brief overview 129
8.1.1 Overall architecture 129
8.1.2 Physical layer 132
8.1.3 Resource handling and packet-data session 137
9 High-Speed Downlink Packet Access 139
9.1 Overview 139
9.1.1 Shared-channel transmission 139
9.1.2 Channel-dependent scheduling 140
9.1.3 Rate control and higher-order modulation 142
9.1.4 Hybrid ARQ with soft combining 142
9.1.5 Architecture 143
9.2 Details of HSDPA 144
9.2.1 HS-DSCH: Inclusion of features in WCDMA Release 5 144
9.2.2 MAC-hs and physical-layer processing 147
9.2.3 Scheduling 149
9.2.4 Rate control 150
9.2.5 Hybrid ARQ with soft combining 154
9.2.6 Data flow 157
9.2.7 Resource control for HS-DSCH 159
9.2.8 Mobility 160
9.2.9 UE categories 162
9.3 Finer details of HSDPA 162
9.3.1 Hybrid ARQ revisited: Physical-layer processing 162
9.3.2 Interleaving and constellation rearrangement 167
9.3.3 Hybrid ARQ revisited: Protocol operation 168
9.3.4 In-sequence delivery 170
9.3.5 MAC-hs header 172
9.3.6 CQI and other means to assess the downlink quality 174
9.3.7 Downlink control signaling: HS-SCCH 177
9.3.8 Downlink control signaling: F-DPCH 180
9.3.9 Uplink control signaling: HS-DPCCH 180
10 Enhanced Uplink 185
10.1 Overview 185
10.1.1 Scheduling 186
10.1.2 Hybrid ARQ with soft combining 188
10.1.3 Architecture 189
10.2 Details of Enhanced Uplink 190
10.2.1 MAC-e and physical layer processing 193
10.2.2 Scheduling 195
10.2.3 E-TFC selection 202
10.2.4 Hybrid ARQ with soft combining 203
10.2.5 Physical channel allocation 208
10.2.6 Power control 210
10.2.7 Data flow 211
10.2.8 Resource control for E-DCH 212
10.2.9 Mobility 213
10.2.10 UE categories 213
10.3 Finer details of Enhanced Uplink 214
10.3.1 Scheduling - the small print 214
10.3.2 Further details on hybrid ARQ operation 223
10.3.3 Control signaling 230
11 MBMS: Multimedia Broadcast Multicast Services 239
11.1 Overview 242
11.1.1 Macro-diversity 243
11.1.2 Application-level coding 245
11.2 Details of MBMS 246
11.2.1 MTCH 247
11.2.2 MCCH and MICH 247
11.2.3 MSCH 249
12 HSPA Evolution 251
12.1 MIMO 251
12.1.1 HSDPA-MIMO data transmission 252
12.1.2 Rate control for HSDPA-MIMO 256
12.1.3 Hybrid-ARQ with soft combining for HSDPA-MIMO 256
12.1.4 Control signaling for HSDPA-MIMO 257
12.1.5 UE capabilities 259
12.2 Higher-order modulation. 259
12.3 Continuous packet connectivity 260
12.3.1 DTX
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