LTE, LTE-advanced, and WiMAX towards IMT-advanced networks
A concise introduction to IMT-Advanced Systems, including LTE-Advanced and WiMAX There exists a strong demand for fully extending emerging Internet services, including collaborative applications and social networking, to the mobile and wireless domain. Delivering such services can be possible only t...
| Autor principal: | |
|---|---|
| Otros Autores: | , |
| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Chichester, West Sussex :
Wiley
c2012.
|
| Edición: | 1st ed |
| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009627961706719 |
Tabla de Contenidos:
- LTE, LTE-Advanced and WiMAX; Contents; About the Authors; Preface; Acknowledgements; List of Abbreviations; 1 Introduction; 1.1 Evolution of Wireless Networks; 1.2 Why IMT-Advanced; 1.3 The ITU-R Requirements for IMT-Advanced Networks; 1.3.1 Cell Spectral Efficiency; 1.3.2 Peak Spectral Efficiency; 1.3.3 Bandwidth; 1.3.4 Cell Edge User Spectral Efficiency; 1.3.5 Latency; 1.3.6 Rates per Mobility Class; 1.3.7 Handover Interruption Time; 1.3.8 VoIP Capacity; 1.3.9 Spectrum; 1.4 IMT-Advanced Networks; 1.4.1 LTE-Advanced; 1.4.2 IEEE 802.16m; 1.5 Book Overview; References
- 2 Enabling Technologies for IMT-Advanced Networks2.1 Multicarrier Modulation and Multiple Access; 2.1.1 OFDM; 2.1.2 OFDMA; 2.1.3 SC-FDMA; 2.2 Multiuser Diversity and Scheduling; 2.3 Adaptive Coding and Modulation; 2.4 Frequency Reuse; 2.5 Wideband Transmissions; 2.6 Multiple Antenna Techniques; 2.7 Relaying; 2.8 Femtocells; 2.9 Coordinated Multi-Point (CoMP) Transmission; 2.9.1 Interference Cancellation; 2.9.2 Single Point Feedback/Single Point Reception; 2.9.3 Multichannel Feedback/Single Point Reception; 2.9.4 Multichannel Feedback/Multipoint Reception; 2.9.5 Inter-Cell MIMO
- 2.10 Power Management2.11 Inter-Technology Handovers; References; Part I WIMAX; 3 WiMAX Networks; 3.1 IEEE 802.16-2009; 3.1.1 IEEE 802.16-2009 Air Interfaces; 3.1.2 Protocol Reference Model; 3.2 IEEE 802.16m; 3.2.1 IEEE 802.16m Air Interface; 3.2.2 System Reference Model; 3.3 Summary of Functionalities; 3.3.1 Frame Structure; 3.3.2 Network Entry; 3.3.3 QoS and Bandwidth Reservation; 3.3.4 Mobility Management; 3.3.5 Security; 4 Frame Structure, Addressing and Identification; 4.1 Frame Structure in IEEE 802.16-2009; 4.1.1 TDD Frame Structure; 4.1.2 FDD/HD-FDD Frame Structure
- 4.2 Frame Structure in IEEE 802.16j4.2.1 Frame Structure in Transparent Relaying; 4.2.2 Frame Structure in Non-Transparent Relaying; 4.3 Frame Structure in IEEE 802.16m; 4.3.1 Basic Frame Structure; 4.3.2 Frame Structure Supporting IEEE 802.16-2009 Frames; 4.4 Addressing and Connections Identification; 4.4.1 Logical identifiers in IEEE 802.16-2009; 4.4.2 Logical identifiers in IEEE 802.16j-2009; 4.4.3 Logical identifiers in IEEE 802.16m; 5 Network Entry, Initialization and Ranging; 5.1 Network Entry in IEEE 802.16-2009; 5.1.1 Initial Ranging; 5.1.2 Periodic Ranging
- 5.1.3 Periodic Ranging in OFDM5.1.4 Periodic Ranging in OFDMA; 5.2 Network Entry in IEEE 802.16j-2009; 5.2.1 Initial Ranging; 5.2.2 Periodic Ranging; 5.3 Network Entry in IEEE 802.16m; 6 Quality of Service and Bandwidth Reservation; 6.1 QoS in IEEE 802.16-2009; 6.1.1 QoS Performance Measures; 6.1.2 Classification; 6.1.3 Signaling Bandwidth Requests and Grants; 6.1.4 Bandwidth Allocation and Traffic Handling; 6.2 Quality of Service in IEEE 802.16j; 6.2.1 Classification; 6.2.2 Signaling Bandwidth Requests and Grants; 6.2.3 Bandwidth Allocation and Traffic Handling; 6.3 QoS in IEEE 802.16m
- 6.3.1 QoS Parameters
