3G evolution HSPA and LTE for mobile broadband
Reflecting the recent completion of LTE's specification, the new edition of this bestseller has been fully updated to provide a complete picture of the LTE system. The latest LTE standards are included on the radio interface architecture, the physical layer, access procedures, MBMS, together wi...
| Otros Autores: | |
|---|---|
| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Amsterdam ; Boston ; London :
Academic
2008.
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| Edición: | 2nd ed |
| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009627475706719 |
Tabla de Contenidos:
- Front Cover; 3G Evolution: HSPA and LTE for Mobile Broadband; Copyright Page; Contents; List of Figures; List of Tables; Preface; Acknowledgements; List of Acronyms; Part I: Introduction; Chapter 1 Background of 3G evolution; 1.1 History and background of 3G; 1.1.1: Before 3G; 1.1.2: Early 3G discussions; 1.1.3: Research on 3G; 1.1.4: 3G standardization starts; 1.2 Standardization; 1.2.1: The standardization process; 1.2.2: 3GPP; 1.2.3: IMT-2000 activities in ITU; 1.3 Spectrum for 3G and systems beyond 3G; Chapter 2 The motives behind the 3G evolution; 2.1: Driving forces
- 2.1.1 Technology advancements2.1.2 Services; 2.1.3 Cost and performance; 2.2: 3G evolution: Two Radio Access Network approaches and an evolved core network; 2.2.1 Radio Access Network evolution; 2.2.2 An evolved core network: system architecture evolution; Part II: Technologies for 3G Evolution; Chapter 3 High data rates in mobile communication; 3.1 High data rates: Fundamental constraints; 3.1.1 High data rates in noise-limited scenarios; 3.1.2 Higher data rates in interference-limited scenarios; 3.2 Higher data rates within a limited bandwidth: Higher-order modulation
- 3.2.1 Higher-order modulation in combination with channel coding3.2.2 Variations in instantaneous transmit power; 3.3 Wider bandwidth including multi-carrier transmission; 3.3.1 Multi-carrier transmission; Chapter 4 OFDM transmission; 4.1 Basic principles of OFDM; 4.2 OFDM demodulation; 4.3 OFDM implementation using IFFT/FFT processing; 4.4 Cyclic-prefix insertion; 4.5 Frequency-domain model of OFDM transmission; 4.6 Channel estimation and reference symbols; 4.7 Frequency diversity with OFDM: Importance of channel coding; 4.8 Selection of basic OFDM parameters; 4.8.1 OFDM subcarrier spacing
- 4.8.2 Number of subcarriers4.8.3 Cyclic-prefix length; 4.9 Variations in instantaneous transmission power; 4.10 OFDM as a user-multiplexing and multiple-access scheme; 4.11 Multi-cell broadcast/multicast transmission and OFDM; Chapter 5 Wider-band 'single-carrier' transmission; 5.1 Equalization against radio-channel frequency selectivity; 5.1.1 Time-domain linear equalization; 5.1.2 Frequency-domain equalization; 5.1.3 Other equalizer strategies; 5.2 Uplink FDMA with flexible bandwidth assignment; 5.3 DFT-spread OFDM; 5.3.1 Basic principles; 5.3.2 DFTS-OFDM receiver
- 5.3.3 User multiplexing with DFTS-OFDM5.3.4 Distributed DFTS-OFDM; Chapter 6 Multi-antenna techniques; 6.1 Multi-antenna configurations; 6.2 Benefits of multi-antenna techniques; 6.3 Multiple receive antennas; 6.4 Multiple transmit antennas; 6.4.1 Transmit-antenna diversity; 6.4.2 Transmitter-side beam-forming; 6.5 Spatial multiplexing; 6.5.1 Basic principles; 6.5.2 Pre-coder-based spatial multiplexing; 6.5.3 Non-linear receiver processing; Chapter 7 Scheduling, link adaptation and hybrid ARQ; 7.1 Link adaptation: Power and rate control; 7.2 Channel-dependent scheduling
- 7.2.1 Downlink scheduling
