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WCDMA for UMTS [Hardback]

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  • Formāts: Hardback, 344 pages, height x width: 172x250 mm, weight: 690 g, ill.
  • Izdošanas datums: 20-Apr-2000
  • Izdevniecība: John Wiley & Sons Ltd
  • ISBN-10: 0471720518
  • ISBN-13: 9780471720515
Citas grāmatas par šo tēmu:
WCDMA for UMTSPalielināt
  • Formāts: Hardback, 344 pages, height x width: 172x250 mm, weight: 690 g, ill.
  • Izdošanas datums: 20-Apr-2000
  • Izdevniecība: John Wiley & Sons Ltd
  • ISBN-10: 0471720518
  • ISBN-13: 9780471720515
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780471720515.html
Keywords:
WCDMA (Wideband Code Division Multiple Access) is the air interface technology selected by ETSI (European Telecommunications Standard Institute) and the major European and Japanese mobile communications operators. This technology is optimized to allow very high-speed multimedia services such as full-motion video, internet access and videoconferencing. UMTS (Universal Mobile Telephony System) refers to the next generation of cellular technology which is also being standardized by ETSI. WCDMA is the air interface technology for the next generation mobile communications systems, which is in the process of being standardised by the 3rd Generation Partnership Project, consisting of ETSI, ARIB &TTC (Japan), TTA (Korea), T1P1 (USA) and CWTS (China).
Preface xiii Acknowledgements xv Abbreviations xvii Introduction 1(8) Harri Holma Antti Toskala Ukko Lappalainen WCDMA in Third Generation Systems 1(1) Air Interfaces and Spectrum Allocations for Third Generation Systems 2(2) Schedule for Third Generation Systems 4(1) Differences between WCDMA and Second Generation Air Interfaces 5(2) Core Networks 7(2) References 8(1) UMTS Services and Applications 9(16) Jouni Salonen Introduction 9(1) UMTS Bearer Service 10(1) UMTS QoS Classes 11(12) Conversational Class 12(7) Streaming Class 19(1) Interactive Class 20(2) Background Class 22(1) Concluding Remarks 23(2) References 23(2) Introduction to WCDMA 25(16) Peter Muszynski Harri Holma Introduction 25(1) Summary of Main Parameters in WCDMA 25(3) Spreading and Despreading 28(2) Multipath Radio Channels and Rake Reception 30(4) Power Control 34(4) Softer and Soft Handovers 38(3) References 40(1) Background and Standardisation of WCDMA 41(12) Antti Toskala Introduction 41(1) Background in Europe 41(4) Wideband CDMA 42(1) Wideband TDMA 43(1) Wideband TDMA/CDMA 43(1) OFDMA 44(1) ODMA 44(1) ETSI Selection 45(1) Background in Japan 45(1) Background in Korea 46(1) Background in the United States 46(1) W-CDMA N/A 46(1) UWC-136 46(1) cdma2000 47(1) TR46.1 47(1) WP-CDMA 47(1) Creation of 3GPP 47(2) Creation of 3GPP2 49(1) Harmonisation Phase 49(1) IMT2000 Process in ITU 50(1) Beyond 3GPP Release-99 51(2) References 52(1) Radio Access Network Architecture 53(20) Fabio Longoni Atte Lansisalmi System Architecture 53(4) UTRAN Architecture 57(2) The Radio Network Controller 57(2) The Node B (Base Station) 59(1) General Protocol Model for UTRAN Terrestrial Interfaces 59(2) General 59(1) Horizontal Layers 60(1) Vertical Planes 60(1) Iu, the UTRAN--CN Interface 61(5) Protocol Structure for Iu CS 61(1) Protocol Structure for Iu PS 62(2) RANAP Protocol 64(1) Iu User Plane Protocol 65(1) UTRAN Internal Interfaces 66(7) RNC--RNC Interface (Iur Interface) and the RNSAP Signalling 66(3) RNC--Node B Interface and the NBAP Signalling 69(2) References 71(2) Physical Layer 73(48) Antti Toskala Introduction 73(1) Transport Channels and their Mapping to the Physical Channels 74(4) Dedicated Transport Channel 75(1) Common Transport Channels 75(2) Mapping of Transport Channels onto the Physical Channels 77(1) Frame Structure of Transport Channels 78(1) Spreaading and Modulation 78(10) Scrambling 78(1) Channelisation Codes 79(1) Uplink Spreading and Modulation 80(5) Downlink Spreading and Modulation 85(2) Transmitter Characteristics 87(1) User Data Transmission 88(14) Uplink Dedicated Channel 89(2) Uplink Multiplexing 91(3) User Data Transmission with the Random Access Channel 94(1) Uplink Common Packet Channel 94(1) Downlink Dedicated Channel 95(2) Downlink Multiplexing 97(2) Downlink Shared Channel 99(1) Forward Access Channel for User Data Transmission 100(1) Channel Coding for User Data 101(1) Coding for TFCI information 102(1) Signalling 102(7) Common Pilot Channel (CPICH) 103(1) Synchronisation Channel (SCH) 103(1) Primary Common Control Physical Channel (Primary CCPCH) 104(1) Secondary Common Control Physical Channel (Secondary CCPCH) 105(1) Random Access Channel (RACH) for Signalling Transmission 106(1) Acquisition Indicator Channel (AICH) 107(1) Paging Indicator Channel (PICH) 107(1) Physical Channels for CPCH Access Procedure 108(1) Physical Layer Procedures 109(12) Fast Closed Loop Power Control Procedure 109(1) Open Loop Power Control 109(1) Paging Procedure 110(1) RACH Procedure 111(1) CPCH Operation 112(1) Cell Search Procedure 113(1) Transmit Diversity Procedure 114(1) Handover Measurements Procedure 115(2) Compressed Mode Measurement Procedure 117(2) Other Measurements 119(1) References 119(2) Radio Interface Protocols 121(32) Jukka Vialen Introduction 121(1) Protocol Architecture 121(2) The Medium Access Control Protocol 123(5) MAC Layer Architecture 123(1) MAC Functions 124(1) Logical Channels 125(1) Mapping between Logical Channels and Transport Channels 126(1) Example Data Flow through the MAC Layer 126(2) The Radio Link Control Protocol 128(4) RLC Layer Architecture 128(1) RLC Functions 129(1) Example Data Flow through the RLC Layer 130(2) The Packet Data Convergence Protocol 132(1) PDCP Layer Architecture 132(1) PDCP Functions 133(1) The Broadcast/Multicast Control Protocol 133(2) BMC Layer Architecture 134(1) BMC Functions 134(1) The Radio Resource Control Protocol 135(18) RRC Layer Logical Architecture 135(1) RRC Service States 136(2) RRC Functions and Signalling Procedures 138(13) References 151(2) Radio Network Planning 153(34) Harri Holma Zhi-Chun Honkasalo Seppo Hamalainen Jaana Laiho Kari Sipila Achim Wacker Introduction 153(1) Dimensioning 154(17) Radio Link Budgets and Coverge Efficiency 155(5) Load Factors and Spectral Efficiency 160(7) Soft Capacity 167(4) Capacity and Coverage Planning 171(7) Iterative Capacity and Coverage Prediction 171(1) Planning Tool 171(2) Case Study 173(4) Network Optimisation 177(1) GSM Co-planning 178(2) Multi-operator Interference 180(7) Introduction 180(1) Worst-Case Uplink Calculations 181(2) Downlink Blocking 183(1) Uplink Simulations 183(1) Simulation Results 184(1) Network Planning with Adjacent Channel Interference 184(2) References 186(1) Radio Resource Management 187(34) Janne Laakso Harri Holma Oscar Salonaho Interference-Based Radio Resource Management 187(1) Power Control 188(15) Fast Power Control 188(8) Outer Loop Power Control 196(7) Handovers 203(7) Intra-frequency Handovers 203(7) Inter-frequency and Inter-system Handovers 210(1) Measurement of Air Interface Load 210(4) Uplink Load 211(2) Downlink Load 213(1) Admission Control 214(3) Admission Control Principle 214(1) Wideband Power-Based Admission Control Strategy 215(2) Throughput-Based Admission Control Strategy 217(1) Load Control (Congestion Control) 217(4) References 218(3) Packet Access 221(22) Mika Raitola Harri Holma Packet Data Traffic 221(2) Overview of WCDMA Packet Access 223(1) Transport Channels for Packet Data 223(3) Common Channels 224(1) Dedicated Channels 224(1) Shared Channels 224(1) Common Packet Channel 225(1) Selection of Channel Type 225(1) Example Packet Scheduling Algorithms 226(3) Introduction 226(1) Time Division Scheduling 226(2) Code Division Scheduling 228(1) Transmission Power-Based Scheduling 229(1) Interaction between Packet Scheduler and Other RRM Algorithms 229(2) Packet Scheduler and Handover Control 230(1) Packet Scheduler and Load Control (Congestion Control) 230(1) Packet Scheduler and Admission Control 230(1) Packet Data Performance 231(12) Link-Level Performance 231(2) System-Level Performance 233(8) References 241(2) Physical Layer Performance 243(40) Harri Holma Markku Juntti Juha Ylitalo Introduction 243(1) Coverage 243(12) Uplink Coverage 244(8) Random Access Channel Coverage 252(1) Downlink Coverage 253(1) Coverage Improvements 254(1) Capacity 255(9) Downlink Orthogonal Codes 255(5) Downlink Transmit Diversity 260(3) Capacity Improvements 263(1) High Bit Rates 264(6) Inter-path Interference 265(2) Multipath Diversity Gain 267(1) Feasibility of High Bit Rates 268(2) Performance Enhancements 270(13) Antenna Solutions 270(6) Multi-user Detection 276(3) References 279(4) UTRA TDD Mode 283(20) Otto Lehtinen Antti Toskala Harri Holma Heli Vaataja Introduction 283(2) Time Division Duplex (TDD) 283(2) UTRA TDD Physical Layer 285(11) Transport and Physical Channels 286(1) Modulation and Spreading 286(1) Physical Channel Structures, Slot and Frame Format 287(5) UTRA TDD Physical Layer Procedures 292(4) UTRA TDD Interference Evaluation 296(5) TDD--TDD Interference 296(2) TDD and FDD Co-existence 298(3) Unlicensed TDD Operation 301(1) Conclusions on UTRA TDD Interference 301(1) Conclusions on UTRA TDD 301(2) Reference 302(1) Multi-Carrier CDMA in IMT-2000 303(14) Antti Toskala Introduction 303(1) Logical Channels 304(1) Physical Channels 305(1) Multi-Carrier Mode Spreading and Modulation 305(2) Uplink Spreading and Modulation 305(1) Downlink Spreading and Modulation 306(1) User Data Transmission 307(4) Uplink Data Transmission 308(1) Downlink Data Transmission 309(1) Channel Coding for User Data 310(1) Signalling 311(2) Pilot Channel 311(1) Synch Channel 311(1) Broadcast Channel 311(1) Quick Paging Channel 312(1) Common Power Control Channel 312(1) Common and Dedicated Control Channels 312(1) Random Access Channel (RACH) for Signalling Transmission 312(1) Physical Layer Procedures 313(4) Power Control Procedure 313(1) Cell Search Procedure 313(1) Random Access Procedure 314(1) Handover Measurements Procedure 315(1) References 315(2) Index 317