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Now in its fifth edition, the bestselling book on UMTS has been updated to cover 3GPP WCDMA and High Speed Packet Access (HSPA) from Release 99 to Release 9. Written by leading experts in the field, the book explains HSPA performance based on simulations and field experience, and illustrates the benefits of HSPA evolution (HSPA+) both from the operators and from the end user?s perspective. It continues to provide updated descriptions of the 3GPP standard including the physical layer, radio protocols on layers 1-3 and a system architecture description. The challenges and solutions regarding…mehr
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Now in its fifth edition, the bestselling book on UMTS has been updated to cover 3GPP WCDMA and High Speed Packet Access (HSPA) from Release 99 to Release 9. Written by leading experts in the field, the book explains HSPA performance based on simulations and field experience, and illustrates the benefits of HSPA evolution (HSPA+) both from the operators and from the end user?s perspective. It continues to provide updated descriptions of the 3GPP standard including the physical layer, radio protocols on layers 1-3 and a system architecture description. The challenges and solutions regarding terminal RF design are also discussed, including the benefits of HSPA+ power saving features. There is also the addition of a new chapter on femto cells as part of the updates to this fifth edition.
Key updates include:
HSPA evolution (HSPA+);
Multicarrier HSPA solutions;
HSPA femto cells (home base stations);
TD-SCDMA system description;
Terminal power consumption optimization.
Updated description of LTE
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Key updates include:
HSPA evolution (HSPA+);
Multicarrier HSPA solutions;
HSPA femto cells (home base stations);
TD-SCDMA system description;
Terminal power consumption optimization.
Updated description of LTE
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- 5. Aufl.
- Seitenzahl: 640
- Erscheinungstermin: 7. September 2010
- Englisch
- Abmessung: 256mm x 177mm x 40mm
- Gewicht: 1183g
- ISBN-13: 9780470686461
- ISBN-10: 0470686464
- Artikelnr.: 28707878
- Verlag: Wiley & Sons
- 5. Aufl.
- Seitenzahl: 640
- Erscheinungstermin: 7. September 2010
- Englisch
- Abmessung: 256mm x 177mm x 40mm
- Gewicht: 1183g
- ISBN-13: 9780470686461
- ISBN-10: 0470686464
- Artikelnr.: 28707878
Dr. Harri Holma, Principal Engineer at Nokia Siemens Networks, Finland. Antti Toskala, Head of 3GPP Radio Standardization, Nokia Siemens Networks, Finland. Harri Holma and Antti Toskala both work on cutting edge technologies for mobile communications today. They co-edited the books LTE for UMTS - OFDMA and SC-FDMA Based Radio Access, HSDPA/HSUPA for UMTS: High Speed Radio Access for Mobile Communications and WCDMA for UMTS, 4th edition.
Preface. Acknowledgements. 1 Introduction. 1.1 WCDMA Early Phase. 1.2 HSPA
Introduction and Data Growth. 1.3HSPA Deployments Globally. 1.4HSPA
Evolution. 1.5HSPA Network Product. 1.6 HSPA Future Outlook. References. 2
UMTS Services. 2.1 Introduction. 2.2 Voice. 2.3 Video Telephony. 2.4
Messaging. 2.5 Mobile Email. 2.6 Browsing. 2.7 Application and Content
Downloading. 2.8 Streaming. 2.9 Gaming. 2.10 Mobile Broadband for Laptop
and Netbook Connectivity. 2.11 Social Networking. 2.12 Mobile TV. 2.13
Location Based Services. 2.14 Machine-to-Machine Communications. 2.15
Quality of ServiceDifferentiation. 2.16 Maximum Air Interface Capacity.
2.17 Terminals. 2.18 Tariffing schemes. References. 3 Introduction to
WCDMA. 3.1 Introduction. 3.2 Summary of the Main Parameters in WCDMA. 3.3
Multipath Radio Channels and Rake Reception. 3.4 Power Control. 3.5 Softer
and Soft Handovers. References. 4 Background and Standardization of WCDMA.
4.1 Introduction. 4.2 Background in Europe. 4.3 Background in Japan. 4.4
Background in Korea. 4.5 Background in the United States. 4.6 Creation of
3GPP. 4.7 How does 3GPP operate? 4.8 Creation of 3GPP2. 4.9 Harmonisation
Phase. 4.10 IMT-2000 Process in ITU. 4.11 Beyond 3GPP Release 99 WCDMA.
4.12 Industry Convergence with LTE and LTE-Advanced. References. 5 Radio
Access Network Architecture. 5.1 System Architecture. 5.2 UTRAN
Architecture. 5.3 General Protocol Model for UTRAN Terrestrial Interfaces.
5.4 Iu, the UTRAN-CN Interface. 5.5 UTRAN Internal Interfaces. 5.6 UTRAN
Enhancements and Evolution. 5.7 UMTS CN Architecture and Evolution.
References. 6 Physical Layer. 6.1 Introduction. 6.2 Transport Channels and
their Mapping to the Physical Channels. 6.3 Spreading and Modulation. 6.4
User Data Transmission. 6.5 Signalling. 6.6 Physical Layer Procedures. 6.7
Terminal Radio Access Capabilities. 6.8 Conclusions. References. 7 Radio
Interface Protocols. 7.1 Introduction. 7.2 Protocol Architecture. 7.3 The
Medium Access Control Protocol. 7.4 The Radio Link Control Protocol. 7.5
The Packet Data Convergence Protocol. 7.6 The Broadcast/Multicast Control
Protocol. 7.7 Multimedia Broadcast Multicast Service. 7.8 The Radio
Resource Control Protocol. 7.9 Early UE Handling Principles. 7.10
Improvements for Call Setup Time Reduction. References. 8 Radio Network
Planning. 8.1 Introduction. 8.2 Dimensioning. 8.3 Capacity and Coverage
Planning and Optimisation. 8.4 GSM Co-planning. 8.5 Inter-operator
Interference. 8.6 WCDMA Frequency Variants. 8.7 UMTS Refarming to GSM900
Band. References. 9 Radio Resource Management. 9.1 Interference-Based Radio
Resource Management. 9.2 Power Control. 9.3 Handovers. 9.4 Measurement of
Air Interface Load. 9.5 Admission Control. 9.6 Load Control (Congestion
Control). References. 10 Packet Scheduling. 10.1 Transmission Control
Protocol (TCP). 10.2 Round Trip Time. 10.3 User-specific Packet Scheduling.
10.4 Cell-specific Packet Scheduling. 10.5 Packet Data System Performance.
10.6 Packet Data Application Performance. References. 11 Physical Layer
Performance. 11.1 Introduction. 11.2 Cell Coverage. 11.3 Downlink Cell
Capacity. 11.4 Capacity Trials. 11.5 3GPP Performance Requirements. 11.6
Performance Enhancements. References. 12 High-Speed Downlink Packet Access.
12.1 Release 99 WCDMA Downlink Packet Data Capabilities. 12.2 HSDPA
Concept. 12.3 HSDPA Impact on Radio Access Network Architecture. 12.4
Release 4 HSDPA Feasibility Study Phase. 12.5 HSDPA Physical Layer
Structure. 12.6 HSDPA Terminal Capability and Achievable Data Rates. 12.7
Mobility with HSDPA. 12.8 HSDPA Performance. 12.9 HSPA Link Budget. 12.10
HSDPA Iub Dimensioning. 12.11 HSPA Round-Trip Time. 12.12 Terminal Receiver
Aspects. 12.13 Evolution in Release 6. 12.14 Conclusions. References. 13
High-Speed Uplink Packet Access. 13.1 Release99 WCDMA Downlink Packet Data
Capabilities. 13.2 HSUPA Concept. 13.3 HSUPA Impact on Radio Access Network
Architecture. 13.4 HSUPA Feasibility Study Phase. 13.5 HSUPA Physical Layer
Structure. 13.6 E-DCH and Related Control Channels. 13.7 HSUPA Physical
Layer Operation Procedure. 13.8 HSUPA Terminal Capability. 13.9 HSUPA
Performance. 13.10 Conclusions. References. 14 Multimedia Broadcast
Multicast Service (MBMS). 14.1 MBMS Concept. 14.2 MBMS Impact to Network
Architecture. 14.3 HIGH LEVEL MBMS Procedures. 14.4 MBMS Radio Interface
Channel Structure. 14.5 MBMS Terminal Capability. 14.6 MBMS Performance.
14.7 MBMS Deployment and Use Cases. 14.8 Benchmarking of MBMS with DVB-H.
14.9 3GPP MBMS Evolution in Release 7. 14.10 Why Did MBMS Fail. 14.11
Integrated Mobile Broadcast (IMB) in Release 8. 14.12 Summary. References.
15 HSPA Evolution. 15.1 Introduction. 15.2 Discontinuous Transmission and
Reception (DTX/DRX). 15.3 Circuit Switched Voice on HSPA. 15.4 Enhanced
FACH and Enhanced RACH. 15.5 Latency. 15.6 Fast Dormancy. 15.7 Down
Downlink MIMO. 15.8 link 64QAM. 15.9 Transmit Diversity (TxAA). 15.10
Uplink 16QAM. 15.11 UE Categories. 15.12 Layer 2 Optimization. 15.13
Architecture Evolution. 15.14 Summary. References. 16 HSPA Multicarrier
Evolution. 16.1 Overview of Multicarrier Evolution. 16.2 Dual Dual Cell
HSUPA in Release 9. 16.3Cell HSDPA in Release 8. 16.4 Dual Cell HSDPA with
MIMO in Release 9. 16.5 Dual Band HSDPA in Release 9. 16.6 Three and Four
Carrier HSDPA in Release 10. 16.7 UE Categories. 16.8 Summary. 16.9
References. 17 UTRAN Long Term Evolution. 17.1 Background. 17.2 Multiple
Access and Architecture Decisions. 17.3 LTE Impact on Network Architecture.
17.4 LTE Multiple Access. 17.5 LTE Physical Layer Design and Parameters.
17.6 LTE Physical Layer Procedures. 17.7 LTE Protocols. 17.8 Performance.
17.9 LTE Device Categories. 17.10 LTE Advanced Outlook. 17.11 Summary.
References. 18 TD-SCDMA (new). 18.1 Introduction. 18.2 Differences in the
Network-Level Architecture. 18.3 TD-SCDMA Physical Layer. 18.4 TD-SCDMA
Data Rates. 18.5 TD-SCDMA Physical Layer Procedures. 18.6 TD-SCDMA
Interference and Co-existence considerations. 18.7 Concluding Remarks and
Future Outlook on TD-SCDMA. References. 19 Home Node B and Femto cells
(new). 19.1 Introduction. 19.2 Home Node B Specification work. 19.3
Technical Challenges of Uncoordinated Mass Deployment. 19.4 Home Node B
Architecture. 19.5 Closed Subscriber Group. 19.6 Home Node B Related
Mobility. 19.7 Home Node B Deployment and Interference Mitigation. 19.8
Home Node B Evolution. 19.9 Summary. References. 20 Terminal RF and
Baseband Design Challenges. 20.1 Introduction. 20.2 Transmitterchain system
design challenges. 20.3 Receiver chain design challenges. 20.4 Improving
talk-time with DTX/DRX. 20.5 Multi-Mode / band Challenges. 20.6
Conclusions.
Introduction and Data Growth. 1.3HSPA Deployments Globally. 1.4HSPA
Evolution. 1.5HSPA Network Product. 1.6 HSPA Future Outlook. References. 2
UMTS Services. 2.1 Introduction. 2.2 Voice. 2.3 Video Telephony. 2.4
Messaging. 2.5 Mobile Email. 2.6 Browsing. 2.7 Application and Content
Downloading. 2.8 Streaming. 2.9 Gaming. 2.10 Mobile Broadband for Laptop
and Netbook Connectivity. 2.11 Social Networking. 2.12 Mobile TV. 2.13
Location Based Services. 2.14 Machine-to-Machine Communications. 2.15
Quality of ServiceDifferentiation. 2.16 Maximum Air Interface Capacity.
2.17 Terminals. 2.18 Tariffing schemes. References. 3 Introduction to
WCDMA. 3.1 Introduction. 3.2 Summary of the Main Parameters in WCDMA. 3.3
Multipath Radio Channels and Rake Reception. 3.4 Power Control. 3.5 Softer
and Soft Handovers. References. 4 Background and Standardization of WCDMA.
4.1 Introduction. 4.2 Background in Europe. 4.3 Background in Japan. 4.4
Background in Korea. 4.5 Background in the United States. 4.6 Creation of
3GPP. 4.7 How does 3GPP operate? 4.8 Creation of 3GPP2. 4.9 Harmonisation
Phase. 4.10 IMT-2000 Process in ITU. 4.11 Beyond 3GPP Release 99 WCDMA.
4.12 Industry Convergence with LTE and LTE-Advanced. References. 5 Radio
Access Network Architecture. 5.1 System Architecture. 5.2 UTRAN
Architecture. 5.3 General Protocol Model for UTRAN Terrestrial Interfaces.
5.4 Iu, the UTRAN-CN Interface. 5.5 UTRAN Internal Interfaces. 5.6 UTRAN
Enhancements and Evolution. 5.7 UMTS CN Architecture and Evolution.
References. 6 Physical Layer. 6.1 Introduction. 6.2 Transport Channels and
their Mapping to the Physical Channels. 6.3 Spreading and Modulation. 6.4
User Data Transmission. 6.5 Signalling. 6.6 Physical Layer Procedures. 6.7
Terminal Radio Access Capabilities. 6.8 Conclusions. References. 7 Radio
Interface Protocols. 7.1 Introduction. 7.2 Protocol Architecture. 7.3 The
Medium Access Control Protocol. 7.4 The Radio Link Control Protocol. 7.5
The Packet Data Convergence Protocol. 7.6 The Broadcast/Multicast Control
Protocol. 7.7 Multimedia Broadcast Multicast Service. 7.8 The Radio
Resource Control Protocol. 7.9 Early UE Handling Principles. 7.10
Improvements for Call Setup Time Reduction. References. 8 Radio Network
Planning. 8.1 Introduction. 8.2 Dimensioning. 8.3 Capacity and Coverage
Planning and Optimisation. 8.4 GSM Co-planning. 8.5 Inter-operator
Interference. 8.6 WCDMA Frequency Variants. 8.7 UMTS Refarming to GSM900
Band. References. 9 Radio Resource Management. 9.1 Interference-Based Radio
Resource Management. 9.2 Power Control. 9.3 Handovers. 9.4 Measurement of
Air Interface Load. 9.5 Admission Control. 9.6 Load Control (Congestion
Control). References. 10 Packet Scheduling. 10.1 Transmission Control
Protocol (TCP). 10.2 Round Trip Time. 10.3 User-specific Packet Scheduling.
10.4 Cell-specific Packet Scheduling. 10.5 Packet Data System Performance.
10.6 Packet Data Application Performance. References. 11 Physical Layer
Performance. 11.1 Introduction. 11.2 Cell Coverage. 11.3 Downlink Cell
Capacity. 11.4 Capacity Trials. 11.5 3GPP Performance Requirements. 11.6
Performance Enhancements. References. 12 High-Speed Downlink Packet Access.
12.1 Release 99 WCDMA Downlink Packet Data Capabilities. 12.2 HSDPA
Concept. 12.3 HSDPA Impact on Radio Access Network Architecture. 12.4
Release 4 HSDPA Feasibility Study Phase. 12.5 HSDPA Physical Layer
Structure. 12.6 HSDPA Terminal Capability and Achievable Data Rates. 12.7
Mobility with HSDPA. 12.8 HSDPA Performance. 12.9 HSPA Link Budget. 12.10
HSDPA Iub Dimensioning. 12.11 HSPA Round-Trip Time. 12.12 Terminal Receiver
Aspects. 12.13 Evolution in Release 6. 12.14 Conclusions. References. 13
High-Speed Uplink Packet Access. 13.1 Release99 WCDMA Downlink Packet Data
Capabilities. 13.2 HSUPA Concept. 13.3 HSUPA Impact on Radio Access Network
Architecture. 13.4 HSUPA Feasibility Study Phase. 13.5 HSUPA Physical Layer
Structure. 13.6 E-DCH and Related Control Channels. 13.7 HSUPA Physical
Layer Operation Procedure. 13.8 HSUPA Terminal Capability. 13.9 HSUPA
Performance. 13.10 Conclusions. References. 14 Multimedia Broadcast
Multicast Service (MBMS). 14.1 MBMS Concept. 14.2 MBMS Impact to Network
Architecture. 14.3 HIGH LEVEL MBMS Procedures. 14.4 MBMS Radio Interface
Channel Structure. 14.5 MBMS Terminal Capability. 14.6 MBMS Performance.
14.7 MBMS Deployment and Use Cases. 14.8 Benchmarking of MBMS with DVB-H.
14.9 3GPP MBMS Evolution in Release 7. 14.10 Why Did MBMS Fail. 14.11
Integrated Mobile Broadcast (IMB) in Release 8. 14.12 Summary. References.
15 HSPA Evolution. 15.1 Introduction. 15.2 Discontinuous Transmission and
Reception (DTX/DRX). 15.3 Circuit Switched Voice on HSPA. 15.4 Enhanced
FACH and Enhanced RACH. 15.5 Latency. 15.6 Fast Dormancy. 15.7 Down
Downlink MIMO. 15.8 link 64QAM. 15.9 Transmit Diversity (TxAA). 15.10
Uplink 16QAM. 15.11 UE Categories. 15.12 Layer 2 Optimization. 15.13
Architecture Evolution. 15.14 Summary. References. 16 HSPA Multicarrier
Evolution. 16.1 Overview of Multicarrier Evolution. 16.2 Dual Dual Cell
HSUPA in Release 9. 16.3Cell HSDPA in Release 8. 16.4 Dual Cell HSDPA with
MIMO in Release 9. 16.5 Dual Band HSDPA in Release 9. 16.6 Three and Four
Carrier HSDPA in Release 10. 16.7 UE Categories. 16.8 Summary. 16.9
References. 17 UTRAN Long Term Evolution. 17.1 Background. 17.2 Multiple
Access and Architecture Decisions. 17.3 LTE Impact on Network Architecture.
17.4 LTE Multiple Access. 17.5 LTE Physical Layer Design and Parameters.
17.6 LTE Physical Layer Procedures. 17.7 LTE Protocols. 17.8 Performance.
17.9 LTE Device Categories. 17.10 LTE Advanced Outlook. 17.11 Summary.
References. 18 TD-SCDMA (new). 18.1 Introduction. 18.2 Differences in the
Network-Level Architecture. 18.3 TD-SCDMA Physical Layer. 18.4 TD-SCDMA
Data Rates. 18.5 TD-SCDMA Physical Layer Procedures. 18.6 TD-SCDMA
Interference and Co-existence considerations. 18.7 Concluding Remarks and
Future Outlook on TD-SCDMA. References. 19 Home Node B and Femto cells
(new). 19.1 Introduction. 19.2 Home Node B Specification work. 19.3
Technical Challenges of Uncoordinated Mass Deployment. 19.4 Home Node B
Architecture. 19.5 Closed Subscriber Group. 19.6 Home Node B Related
Mobility. 19.7 Home Node B Deployment and Interference Mitigation. 19.8
Home Node B Evolution. 19.9 Summary. References. 20 Terminal RF and
Baseband Design Challenges. 20.1 Introduction. 20.2 Transmitterchain system
design challenges. 20.3 Receiver chain design challenges. 20.4 Improving
talk-time with DTX/DRX. 20.5 Multi-Mode / band Challenges. 20.6
Conclusions.
Preface. Acknowledgements. 1 Introduction. 1.1 WCDMA Early Phase. 1.2 HSPA
Introduction and Data Growth. 1.3HSPA Deployments Globally. 1.4HSPA
Evolution. 1.5HSPA Network Product. 1.6 HSPA Future Outlook. References. 2
UMTS Services. 2.1 Introduction. 2.2 Voice. 2.3 Video Telephony. 2.4
Messaging. 2.5 Mobile Email. 2.6 Browsing. 2.7 Application and Content
Downloading. 2.8 Streaming. 2.9 Gaming. 2.10 Mobile Broadband for Laptop
and Netbook Connectivity. 2.11 Social Networking. 2.12 Mobile TV. 2.13
Location Based Services. 2.14 Machine-to-Machine Communications. 2.15
Quality of ServiceDifferentiation. 2.16 Maximum Air Interface Capacity.
2.17 Terminals. 2.18 Tariffing schemes. References. 3 Introduction to
WCDMA. 3.1 Introduction. 3.2 Summary of the Main Parameters in WCDMA. 3.3
Multipath Radio Channels and Rake Reception. 3.4 Power Control. 3.5 Softer
and Soft Handovers. References. 4 Background and Standardization of WCDMA.
4.1 Introduction. 4.2 Background in Europe. 4.3 Background in Japan. 4.4
Background in Korea. 4.5 Background in the United States. 4.6 Creation of
3GPP. 4.7 How does 3GPP operate? 4.8 Creation of 3GPP2. 4.9 Harmonisation
Phase. 4.10 IMT-2000 Process in ITU. 4.11 Beyond 3GPP Release 99 WCDMA.
4.12 Industry Convergence with LTE and LTE-Advanced. References. 5 Radio
Access Network Architecture. 5.1 System Architecture. 5.2 UTRAN
Architecture. 5.3 General Protocol Model for UTRAN Terrestrial Interfaces.
5.4 Iu, the UTRAN-CN Interface. 5.5 UTRAN Internal Interfaces. 5.6 UTRAN
Enhancements and Evolution. 5.7 UMTS CN Architecture and Evolution.
References. 6 Physical Layer. 6.1 Introduction. 6.2 Transport Channels and
their Mapping to the Physical Channels. 6.3 Spreading and Modulation. 6.4
User Data Transmission. 6.5 Signalling. 6.6 Physical Layer Procedures. 6.7
Terminal Radio Access Capabilities. 6.8 Conclusions. References. 7 Radio
Interface Protocols. 7.1 Introduction. 7.2 Protocol Architecture. 7.3 The
Medium Access Control Protocol. 7.4 The Radio Link Control Protocol. 7.5
The Packet Data Convergence Protocol. 7.6 The Broadcast/Multicast Control
Protocol. 7.7 Multimedia Broadcast Multicast Service. 7.8 The Radio
Resource Control Protocol. 7.9 Early UE Handling Principles. 7.10
Improvements for Call Setup Time Reduction. References. 8 Radio Network
Planning. 8.1 Introduction. 8.2 Dimensioning. 8.3 Capacity and Coverage
Planning and Optimisation. 8.4 GSM Co-planning. 8.5 Inter-operator
Interference. 8.6 WCDMA Frequency Variants. 8.7 UMTS Refarming to GSM900
Band. References. 9 Radio Resource Management. 9.1 Interference-Based Radio
Resource Management. 9.2 Power Control. 9.3 Handovers. 9.4 Measurement of
Air Interface Load. 9.5 Admission Control. 9.6 Load Control (Congestion
Control). References. 10 Packet Scheduling. 10.1 Transmission Control
Protocol (TCP). 10.2 Round Trip Time. 10.3 User-specific Packet Scheduling.
10.4 Cell-specific Packet Scheduling. 10.5 Packet Data System Performance.
10.6 Packet Data Application Performance. References. 11 Physical Layer
Performance. 11.1 Introduction. 11.2 Cell Coverage. 11.3 Downlink Cell
Capacity. 11.4 Capacity Trials. 11.5 3GPP Performance Requirements. 11.6
Performance Enhancements. References. 12 High-Speed Downlink Packet Access.
12.1 Release 99 WCDMA Downlink Packet Data Capabilities. 12.2 HSDPA
Concept. 12.3 HSDPA Impact on Radio Access Network Architecture. 12.4
Release 4 HSDPA Feasibility Study Phase. 12.5 HSDPA Physical Layer
Structure. 12.6 HSDPA Terminal Capability and Achievable Data Rates. 12.7
Mobility with HSDPA. 12.8 HSDPA Performance. 12.9 HSPA Link Budget. 12.10
HSDPA Iub Dimensioning. 12.11 HSPA Round-Trip Time. 12.12 Terminal Receiver
Aspects. 12.13 Evolution in Release 6. 12.14 Conclusions. References. 13
High-Speed Uplink Packet Access. 13.1 Release99 WCDMA Downlink Packet Data
Capabilities. 13.2 HSUPA Concept. 13.3 HSUPA Impact on Radio Access Network
Architecture. 13.4 HSUPA Feasibility Study Phase. 13.5 HSUPA Physical Layer
Structure. 13.6 E-DCH and Related Control Channels. 13.7 HSUPA Physical
Layer Operation Procedure. 13.8 HSUPA Terminal Capability. 13.9 HSUPA
Performance. 13.10 Conclusions. References. 14 Multimedia Broadcast
Multicast Service (MBMS). 14.1 MBMS Concept. 14.2 MBMS Impact to Network
Architecture. 14.3 HIGH LEVEL MBMS Procedures. 14.4 MBMS Radio Interface
Channel Structure. 14.5 MBMS Terminal Capability. 14.6 MBMS Performance.
14.7 MBMS Deployment and Use Cases. 14.8 Benchmarking of MBMS with DVB-H.
14.9 3GPP MBMS Evolution in Release 7. 14.10 Why Did MBMS Fail. 14.11
Integrated Mobile Broadcast (IMB) in Release 8. 14.12 Summary. References.
15 HSPA Evolution. 15.1 Introduction. 15.2 Discontinuous Transmission and
Reception (DTX/DRX). 15.3 Circuit Switched Voice on HSPA. 15.4 Enhanced
FACH and Enhanced RACH. 15.5 Latency. 15.6 Fast Dormancy. 15.7 Down
Downlink MIMO. 15.8 link 64QAM. 15.9 Transmit Diversity (TxAA). 15.10
Uplink 16QAM. 15.11 UE Categories. 15.12 Layer 2 Optimization. 15.13
Architecture Evolution. 15.14 Summary. References. 16 HSPA Multicarrier
Evolution. 16.1 Overview of Multicarrier Evolution. 16.2 Dual Dual Cell
HSUPA in Release 9. 16.3Cell HSDPA in Release 8. 16.4 Dual Cell HSDPA with
MIMO in Release 9. 16.5 Dual Band HSDPA in Release 9. 16.6 Three and Four
Carrier HSDPA in Release 10. 16.7 UE Categories. 16.8 Summary. 16.9
References. 17 UTRAN Long Term Evolution. 17.1 Background. 17.2 Multiple
Access and Architecture Decisions. 17.3 LTE Impact on Network Architecture.
17.4 LTE Multiple Access. 17.5 LTE Physical Layer Design and Parameters.
17.6 LTE Physical Layer Procedures. 17.7 LTE Protocols. 17.8 Performance.
17.9 LTE Device Categories. 17.10 LTE Advanced Outlook. 17.11 Summary.
References. 18 TD-SCDMA (new). 18.1 Introduction. 18.2 Differences in the
Network-Level Architecture. 18.3 TD-SCDMA Physical Layer. 18.4 TD-SCDMA
Data Rates. 18.5 TD-SCDMA Physical Layer Procedures. 18.6 TD-SCDMA
Interference and Co-existence considerations. 18.7 Concluding Remarks and
Future Outlook on TD-SCDMA. References. 19 Home Node B and Femto cells
(new). 19.1 Introduction. 19.2 Home Node B Specification work. 19.3
Technical Challenges of Uncoordinated Mass Deployment. 19.4 Home Node B
Architecture. 19.5 Closed Subscriber Group. 19.6 Home Node B Related
Mobility. 19.7 Home Node B Deployment and Interference Mitigation. 19.8
Home Node B Evolution. 19.9 Summary. References. 20 Terminal RF and
Baseband Design Challenges. 20.1 Introduction. 20.2 Transmitterchain system
design challenges. 20.3 Receiver chain design challenges. 20.4 Improving
talk-time with DTX/DRX. 20.5 Multi-Mode / band Challenges. 20.6
Conclusions.
Introduction and Data Growth. 1.3HSPA Deployments Globally. 1.4HSPA
Evolution. 1.5HSPA Network Product. 1.6 HSPA Future Outlook. References. 2
UMTS Services. 2.1 Introduction. 2.2 Voice. 2.3 Video Telephony. 2.4
Messaging. 2.5 Mobile Email. 2.6 Browsing. 2.7 Application and Content
Downloading. 2.8 Streaming. 2.9 Gaming. 2.10 Mobile Broadband for Laptop
and Netbook Connectivity. 2.11 Social Networking. 2.12 Mobile TV. 2.13
Location Based Services. 2.14 Machine-to-Machine Communications. 2.15
Quality of ServiceDifferentiation. 2.16 Maximum Air Interface Capacity.
2.17 Terminals. 2.18 Tariffing schemes. References. 3 Introduction to
WCDMA. 3.1 Introduction. 3.2 Summary of the Main Parameters in WCDMA. 3.3
Multipath Radio Channels and Rake Reception. 3.4 Power Control. 3.5 Softer
and Soft Handovers. References. 4 Background and Standardization of WCDMA.
4.1 Introduction. 4.2 Background in Europe. 4.3 Background in Japan. 4.4
Background in Korea. 4.5 Background in the United States. 4.6 Creation of
3GPP. 4.7 How does 3GPP operate? 4.8 Creation of 3GPP2. 4.9 Harmonisation
Phase. 4.10 IMT-2000 Process in ITU. 4.11 Beyond 3GPP Release 99 WCDMA.
4.12 Industry Convergence with LTE and LTE-Advanced. References. 5 Radio
Access Network Architecture. 5.1 System Architecture. 5.2 UTRAN
Architecture. 5.3 General Protocol Model for UTRAN Terrestrial Interfaces.
5.4 Iu, the UTRAN-CN Interface. 5.5 UTRAN Internal Interfaces. 5.6 UTRAN
Enhancements and Evolution. 5.7 UMTS CN Architecture and Evolution.
References. 6 Physical Layer. 6.1 Introduction. 6.2 Transport Channels and
their Mapping to the Physical Channels. 6.3 Spreading and Modulation. 6.4
User Data Transmission. 6.5 Signalling. 6.6 Physical Layer Procedures. 6.7
Terminal Radio Access Capabilities. 6.8 Conclusions. References. 7 Radio
Interface Protocols. 7.1 Introduction. 7.2 Protocol Architecture. 7.3 The
Medium Access Control Protocol. 7.4 The Radio Link Control Protocol. 7.5
The Packet Data Convergence Protocol. 7.6 The Broadcast/Multicast Control
Protocol. 7.7 Multimedia Broadcast Multicast Service. 7.8 The Radio
Resource Control Protocol. 7.9 Early UE Handling Principles. 7.10
Improvements for Call Setup Time Reduction. References. 8 Radio Network
Planning. 8.1 Introduction. 8.2 Dimensioning. 8.3 Capacity and Coverage
Planning and Optimisation. 8.4 GSM Co-planning. 8.5 Inter-operator
Interference. 8.6 WCDMA Frequency Variants. 8.7 UMTS Refarming to GSM900
Band. References. 9 Radio Resource Management. 9.1 Interference-Based Radio
Resource Management. 9.2 Power Control. 9.3 Handovers. 9.4 Measurement of
Air Interface Load. 9.5 Admission Control. 9.6 Load Control (Congestion
Control). References. 10 Packet Scheduling. 10.1 Transmission Control
Protocol (TCP). 10.2 Round Trip Time. 10.3 User-specific Packet Scheduling.
10.4 Cell-specific Packet Scheduling. 10.5 Packet Data System Performance.
10.6 Packet Data Application Performance. References. 11 Physical Layer
Performance. 11.1 Introduction. 11.2 Cell Coverage. 11.3 Downlink Cell
Capacity. 11.4 Capacity Trials. 11.5 3GPP Performance Requirements. 11.6
Performance Enhancements. References. 12 High-Speed Downlink Packet Access.
12.1 Release 99 WCDMA Downlink Packet Data Capabilities. 12.2 HSDPA
Concept. 12.3 HSDPA Impact on Radio Access Network Architecture. 12.4
Release 4 HSDPA Feasibility Study Phase. 12.5 HSDPA Physical Layer
Structure. 12.6 HSDPA Terminal Capability and Achievable Data Rates. 12.7
Mobility with HSDPA. 12.8 HSDPA Performance. 12.9 HSPA Link Budget. 12.10
HSDPA Iub Dimensioning. 12.11 HSPA Round-Trip Time. 12.12 Terminal Receiver
Aspects. 12.13 Evolution in Release 6. 12.14 Conclusions. References. 13
High-Speed Uplink Packet Access. 13.1 Release99 WCDMA Downlink Packet Data
Capabilities. 13.2 HSUPA Concept. 13.3 HSUPA Impact on Radio Access Network
Architecture. 13.4 HSUPA Feasibility Study Phase. 13.5 HSUPA Physical Layer
Structure. 13.6 E-DCH and Related Control Channels. 13.7 HSUPA Physical
Layer Operation Procedure. 13.8 HSUPA Terminal Capability. 13.9 HSUPA
Performance. 13.10 Conclusions. References. 14 Multimedia Broadcast
Multicast Service (MBMS). 14.1 MBMS Concept. 14.2 MBMS Impact to Network
Architecture. 14.3 HIGH LEVEL MBMS Procedures. 14.4 MBMS Radio Interface
Channel Structure. 14.5 MBMS Terminal Capability. 14.6 MBMS Performance.
14.7 MBMS Deployment and Use Cases. 14.8 Benchmarking of MBMS with DVB-H.
14.9 3GPP MBMS Evolution in Release 7. 14.10 Why Did MBMS Fail. 14.11
Integrated Mobile Broadcast (IMB) in Release 8. 14.12 Summary. References.
15 HSPA Evolution. 15.1 Introduction. 15.2 Discontinuous Transmission and
Reception (DTX/DRX). 15.3 Circuit Switched Voice on HSPA. 15.4 Enhanced
FACH and Enhanced RACH. 15.5 Latency. 15.6 Fast Dormancy. 15.7 Down
Downlink MIMO. 15.8 link 64QAM. 15.9 Transmit Diversity (TxAA). 15.10
Uplink 16QAM. 15.11 UE Categories. 15.12 Layer 2 Optimization. 15.13
Architecture Evolution. 15.14 Summary. References. 16 HSPA Multicarrier
Evolution. 16.1 Overview of Multicarrier Evolution. 16.2 Dual Dual Cell
HSUPA in Release 9. 16.3Cell HSDPA in Release 8. 16.4 Dual Cell HSDPA with
MIMO in Release 9. 16.5 Dual Band HSDPA in Release 9. 16.6 Three and Four
Carrier HSDPA in Release 10. 16.7 UE Categories. 16.8 Summary. 16.9
References. 17 UTRAN Long Term Evolution. 17.1 Background. 17.2 Multiple
Access and Architecture Decisions. 17.3 LTE Impact on Network Architecture.
17.4 LTE Multiple Access. 17.5 LTE Physical Layer Design and Parameters.
17.6 LTE Physical Layer Procedures. 17.7 LTE Protocols. 17.8 Performance.
17.9 LTE Device Categories. 17.10 LTE Advanced Outlook. 17.11 Summary.
References. 18 TD-SCDMA (new). 18.1 Introduction. 18.2 Differences in the
Network-Level Architecture. 18.3 TD-SCDMA Physical Layer. 18.4 TD-SCDMA
Data Rates. 18.5 TD-SCDMA Physical Layer Procedures. 18.6 TD-SCDMA
Interference and Co-existence considerations. 18.7 Concluding Remarks and
Future Outlook on TD-SCDMA. References. 19 Home Node B and Femto cells
(new). 19.1 Introduction. 19.2 Home Node B Specification work. 19.3
Technical Challenges of Uncoordinated Mass Deployment. 19.4 Home Node B
Architecture. 19.5 Closed Subscriber Group. 19.6 Home Node B Related
Mobility. 19.7 Home Node B Deployment and Interference Mitigation. 19.8
Home Node B Evolution. 19.9 Summary. References. 20 Terminal RF and
Baseband Design Challenges. 20.1 Introduction. 20.2 Transmitterchain system
design challenges. 20.3 Receiver chain design challenges. 20.4 Improving
talk-time with DTX/DRX. 20.5 Multi-Mode / band Challenges. 20.6
Conclusions.