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Written by experts actively involved in the 3GPP standards and product development, LTE for UMTS, Second Edition gives a complete and up-to-date overview of Long term Evolution (LTE) in a systematic and clear manner. Building upon on the success of the first edition, LTE for UMTS, Second Edition has been revised to now contain improved coverage of the Release 8 LTE details, including field performance results, transport network, self optimized networks and also covering the enhancements done in 3GPP Release 9. This new edition also provides an outlook to Release 10, including the overview of…mehr
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Written by experts actively involved in the 3GPP standards and product development, LTE for UMTS, Second Edition gives a complete and up-to-date overview of Long term Evolution (LTE) in a systematic and clear manner. Building upon on the success of the first edition, LTE for UMTS, Second Edition has been revised to now contain improved coverage of the Release 8 LTE details, including field performance results, transport network, self optimized networks and also covering the enhancements done in 3GPP Release 9. This new edition also provides an outlook to Release 10, including the overview of Release 10 LTE-Advanced technology components which enable reaching data rates beyond 1 Gbps.
Key updates for the second edition of LTE for UMTS are focused on the new topics from Release 9 & 10, and include:
- LTE-Advanced;
- Self optimized networks (SON);
- Transport network dimensioning;
- Measurement results.
Key updates for the second edition of LTE for UMTS are focused on the new topics from Release 9 & 10, and include:
- LTE-Advanced;
- Self optimized networks (SON);
- Transport network dimensioning;
- Measurement results.
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- Artikelnr. des Verlages: 14566000000
- 2. Aufl.
- Seitenzahl: 576
- Erscheinungstermin: 25. April 2011
- Englisch
- Abmessung: 251mm x 174mm x 32mm
- Gewicht: 984g
- ISBN-13: 9780470660003
- ISBN-10: 0470660007
- Artikelnr.: 30602289
- Verlag: Wiley & Sons
- Artikelnr. des Verlages: 14566000000
- 2. Aufl.
- Seitenzahl: 576
- Erscheinungstermin: 25. April 2011
- Englisch
- Abmessung: 251mm x 174mm x 32mm
- Gewicht: 984g
- ISBN-13: 9780470660003
- ISBN-10: 0470660007
- Artikelnr.: 30602289
Harri Holma and Antti Toskala, Nokia Siemens Networks, Finland
Preface. Acknowledgements. List of abbreviations. 1 Introduction (Harry
Holma and Antti Toskala). 1.1 Mobile Voice Subscriber Growth. 1.2 Mobile
Data Usage Growth. 1.3 Evolution of Wireline Technologies. 1.4 Motivation
and Targets for LTE. 1.5 Overview of LTE. 1.6 3GPP Family of Technologies.
1.7 Wireless Spectrum. 1.8 New Spectrum Identified by WRC-07. 1.9
LTE-Advanced. 2 LTE Standardization (Antti Toskala). 2.1 Introduction. 2.2
Overview of 3GPP Releases and Process. 2.3 LTE Targets. 2.4 LTE
Standardization Phases. 2.5 Evolution Beyond Release 8. 2.6 LTE-Advanced
for IMT-Advanced. 2.7 LTE Specifications and 3GPP Structure 3 System
Architecture Based on 3GPP SAE 23 (Atte Länsisalmi and Antti Toskala). 3.1
System Architecture Evolution in 3GPP. 3.2 Basic System Architecture
Configuration with only E-UTRAN Access Network. 3.3 System Architecture
with E-UTRAN and Legacy 3GPP Access Networks. 3.4 System Architecture with
E-UTRAN and Non-3GPP Access Networks. 3.5 Inter-working with cdma2000(r)
Access Networks. 3.6 IMS Architecture. 3.7 PCC and QoS. References. 4
Introduction to OFDMA and SC-FDMA and to MIMO in LTE (Antti Toskala and
Timo Lunttila). 4.1 Introduction. 4.2 LTE Multiple Access Background. 4.3
OFDMA Basics. 4.4 SC-FDMA Basics. 4.5 MIMO Basics. 4.6 Summary. References.
5 Physical Layer (Antti Toskala, Timo Lunttila, Esa Tiirola, Kari Hooli,
Mieszko Chmiel and Juha Korhonen). 5.1 Introduction. 5.2 Transport Channels
and their Mapping to the Physical Channels. 5.3 Modulation. 5.4 Uplink User
Data Transmission. 5.5 Downlink User Data Transmission. 5.6 Uplink Physical
Layer Signaling Transmission. 5.7 PRACH Structure. 5.8 Downlink Physical
Layer Signaling Transmission. 5.9 Physical Layer Procedures. 5.10 UE
Capability Classes and Supported Features. 5.11 Physical Layer
Measurements. 5.12 Physical Layer Parameter Configuration. 5.13 Summary.
References. 6 LTE Radio Protocols (Antti Toskala, Woonhee Hwang and Colin
Willcock). 6.1 Introduction. 6.2 Protocol Architecture. 6.3 The Medium
Access Control. 6.4 The Radio Link Control Layer. 6.5 Packet Data
Convergence Protocol. 6.6 Radio Resource Control (RRC). 6.7 X2 Interface
Protocols. 6.8 Understanding the RRC ASN.1 Protocol Definition. 6.9 Early
UE handling in LTE. 6.10 Summary. References. 7 Mobility (Chris Callender,
Harri Holma, Jarkko Koskela and Jussi Reunanen). 7.1 Introduction. 7.2
Mobility Management in Idle State. 7.3 Intra-LTE Handovers. 7.4
Inter-system Handovers. 7.5 Differences in E-UTRAN and UTRAN Mobility. 7.6
Summary. References. 8 Radio Resource Management (Harri Holma, Troels
Kolding, Daniela Laselva, Klaus Pedersen, Claudio Rosa and Ingo Viering).
8.1 Introduction. 8.2 Overview of RRM Algorithms. 8.3 Admission Control and
QoS Parameters. 8.4 Downlink Dynamic Scheduling and Link Adaptation. 8.5
Uplink Dynamic Scheduling and Link Adaptation. 8.6 Interference Management
and Power Settings. 8.7 Discontinuous Transmission and Reception (DTX/DRX).
8.8 RRC Connection Maintenance. 8.9 Summary. References. 9 Self Organizing
Networks (SON) (Krzysztof Kordybach, Seppo Hamalainen, Cinzia Sartori and
Ingo Viering). 9.1 Introduction. 9.2 SON Architecture. 9.3 SON Functions.
9.4 Self-configuration. 9.5 Self-Optimization and Self-Healing Use Cases.
9.6 3GPP Release 10 Use Cases. 9.7 Summary. References. 10 Performance
(Harri Holma, Pasi Kinnunen, István Z. Kovács, Kari Pajukoski, Klaus
Pedersen and Jussi Reunanen). 10.1 Introduction. 10.2 Layer 1 Peak Bit
Rates. 10.3 Terminal Categories. 10.4 Link Level Performance. 10.5 Link
Budgets. 10.6 Spectral Efficiency. 10.7 Latency. 10.8 LTE Refarming to GSM
Spectrum. 10.9 Dimensioning. 10.10 Capacity Management Examples from HSPA
Networks. 10.11 Summary. References. 11 LTE Measurements (Marilynn P.
Wylie-Green, Harri Holma, Jussi Reunanen and Antti Toskala). 11.1
Introduction. 11.2 Theoretical Peak Data Rates. 11.3 Laboratory
Measurements. 11.4 Field Measurement Setups. 11.5 Artificial Load
Generation. 11.6 Peak Data Rates in the Field. 11.7 Link Adaptation and
MIMO Utilization. 11.8 Handover Performance. 11.9 Data Rates in Drive
Tests. 11.10 Multi-User Packet Scheduling. 11.11 Latency. 11.12 Very Large
Cell Size. 11.13 Summary. References. 12 Transport (Torsten Musiol). 12.1
Introduction. 12.2 Protocol Stacks and Interfaces. 12.3 Transport Aspects
of Intra-LTE Handover. 12.4 Transport Performance Requirements. 12.5
Transport Network Architecture for LTE. 12.6 Quality of Service. 12.7
Transport Security. 12.8 Synchronization from Transport Network. 12.9 Base
Station Co-location. 12.10 Summary. References. 13 Voice over IP (VoIP)
(Harri Holma, Juha Kallio, Markku Kuusela, Petteri Lundén, Esa
Malkamäki,Jussi Ojala and Haiming Wang). 13.1 Introduction. 13.2 VoIP
Codecs. 13.3 VoIP Requirements. 13.4 Delay Budget. 13.5 Scheduling and
Control Channels. 13.6 LTE Voice Capacity. 13.7 Voice Capacity Evolution.
13.8 Uplink Coverage. 13.9 Circuit Switched Fallback for LTE. 13.10 Single
Radio Voice Call Continuity (SR-VCC). 13.11 Summary. References. 14
Performance Requirements (Andrea Ancora, Iwajlo Angelow, Dominique Brunel,
Chris Callender, Harri Holma, Peter Muszynski, Earl McCune and Laurent
Noël). 14.1 Introduction. 14.2 Frequency Bands and Channel Arrangements.
14.3 eNode-B RF Transmitter. 14.4 eNodeB RF Receiver. 14.5 eNodeB
Demodulation Performance. 14.6 User Equipment Design Principles and
Challenges. 14.7 UE RF Transmitter. 14.8 UE RF Receiver Requirements. 14.9
UE Demodulation Performance. 14.10 Requirements for Radio Resource
Management. 14.11 Summary. References. 15 LTE TDD Mode (Che Xiangguang,
Troels Kolding , Peter Skov, Wang Haiming and Antti Toskala). 15.1
Introduction. 15.2 LTE TDD Fundamentals. 15.3 TDD Control Design. 15.4
Semi-persistent Scheduling. 15.5 MIMO and Dedicated Reference Signals. 15.6
LTE TDD Performance. 15.7 Evolution of LTE TDD. 15.8 LTE TDD Summary.
References. 16 LTE-Advanced (Mieszko Chmiel, Mihai Enescu, Harri Holma,
Tommi Koivisto, Jari Lindholm, Timo Lunttila, Klaus Pedersen, Peter Skov,
Timo Roman, Antti Toskala and Yuyu Yan). 16.1 Introduction. 16.2
LTE-Advanced and IMT-Advanced. 16.3 Requirements. 16.4 3GPP LTE-Advanced
Study Phase. 16.5 Carrier Aggregation. 16.6 Downlink Multi-antenna
Enhancements. 16.7 Uplink Multi-Antenna Techniques. 16.8 Heterogeneous
Networks. 16.9 Relays. 16.10 Release 11 Outlook. 16.11 Conclusions.
References. 17 HSPA Evolution (Harri Holma, Karri Ranta-aho and Antti
Toskala). 17.1 Introduction. 17.2 Discontinuous Transmission and Reception
(DTX/DRX). 17.3 Circuit Switched Voice on HSPA. 17.4 Enhanced FACH and
RACH. 17.5 Downlink MIMO and 64QAM. 17.6 Dual Cell HSDPA and HSUPA. 17.7
Multicarrier and Multiband HSDPA. 17.8 Uplink 16QAM. 17.9 Terminal
Categories. 17.10 Layer 2 Optimization. 17.11 Single Frequency Network
(SFN) MBMS. 17.12 Architecture Evolution. 17.13 Summary. References. Index.
Holma and Antti Toskala). 1.1 Mobile Voice Subscriber Growth. 1.2 Mobile
Data Usage Growth. 1.3 Evolution of Wireline Technologies. 1.4 Motivation
and Targets for LTE. 1.5 Overview of LTE. 1.6 3GPP Family of Technologies.
1.7 Wireless Spectrum. 1.8 New Spectrum Identified by WRC-07. 1.9
LTE-Advanced. 2 LTE Standardization (Antti Toskala). 2.1 Introduction. 2.2
Overview of 3GPP Releases and Process. 2.3 LTE Targets. 2.4 LTE
Standardization Phases. 2.5 Evolution Beyond Release 8. 2.6 LTE-Advanced
for IMT-Advanced. 2.7 LTE Specifications and 3GPP Structure 3 System
Architecture Based on 3GPP SAE 23 (Atte Länsisalmi and Antti Toskala). 3.1
System Architecture Evolution in 3GPP. 3.2 Basic System Architecture
Configuration with only E-UTRAN Access Network. 3.3 System Architecture
with E-UTRAN and Legacy 3GPP Access Networks. 3.4 System Architecture with
E-UTRAN and Non-3GPP Access Networks. 3.5 Inter-working with cdma2000(r)
Access Networks. 3.6 IMS Architecture. 3.7 PCC and QoS. References. 4
Introduction to OFDMA and SC-FDMA and to MIMO in LTE (Antti Toskala and
Timo Lunttila). 4.1 Introduction. 4.2 LTE Multiple Access Background. 4.3
OFDMA Basics. 4.4 SC-FDMA Basics. 4.5 MIMO Basics. 4.6 Summary. References.
5 Physical Layer (Antti Toskala, Timo Lunttila, Esa Tiirola, Kari Hooli,
Mieszko Chmiel and Juha Korhonen). 5.1 Introduction. 5.2 Transport Channels
and their Mapping to the Physical Channels. 5.3 Modulation. 5.4 Uplink User
Data Transmission. 5.5 Downlink User Data Transmission. 5.6 Uplink Physical
Layer Signaling Transmission. 5.7 PRACH Structure. 5.8 Downlink Physical
Layer Signaling Transmission. 5.9 Physical Layer Procedures. 5.10 UE
Capability Classes and Supported Features. 5.11 Physical Layer
Measurements. 5.12 Physical Layer Parameter Configuration. 5.13 Summary.
References. 6 LTE Radio Protocols (Antti Toskala, Woonhee Hwang and Colin
Willcock). 6.1 Introduction. 6.2 Protocol Architecture. 6.3 The Medium
Access Control. 6.4 The Radio Link Control Layer. 6.5 Packet Data
Convergence Protocol. 6.6 Radio Resource Control (RRC). 6.7 X2 Interface
Protocols. 6.8 Understanding the RRC ASN.1 Protocol Definition. 6.9 Early
UE handling in LTE. 6.10 Summary. References. 7 Mobility (Chris Callender,
Harri Holma, Jarkko Koskela and Jussi Reunanen). 7.1 Introduction. 7.2
Mobility Management in Idle State. 7.3 Intra-LTE Handovers. 7.4
Inter-system Handovers. 7.5 Differences in E-UTRAN and UTRAN Mobility. 7.6
Summary. References. 8 Radio Resource Management (Harri Holma, Troels
Kolding, Daniela Laselva, Klaus Pedersen, Claudio Rosa and Ingo Viering).
8.1 Introduction. 8.2 Overview of RRM Algorithms. 8.3 Admission Control and
QoS Parameters. 8.4 Downlink Dynamic Scheduling and Link Adaptation. 8.5
Uplink Dynamic Scheduling and Link Adaptation. 8.6 Interference Management
and Power Settings. 8.7 Discontinuous Transmission and Reception (DTX/DRX).
8.8 RRC Connection Maintenance. 8.9 Summary. References. 9 Self Organizing
Networks (SON) (Krzysztof Kordybach, Seppo Hamalainen, Cinzia Sartori and
Ingo Viering). 9.1 Introduction. 9.2 SON Architecture. 9.3 SON Functions.
9.4 Self-configuration. 9.5 Self-Optimization and Self-Healing Use Cases.
9.6 3GPP Release 10 Use Cases. 9.7 Summary. References. 10 Performance
(Harri Holma, Pasi Kinnunen, István Z. Kovács, Kari Pajukoski, Klaus
Pedersen and Jussi Reunanen). 10.1 Introduction. 10.2 Layer 1 Peak Bit
Rates. 10.3 Terminal Categories. 10.4 Link Level Performance. 10.5 Link
Budgets. 10.6 Spectral Efficiency. 10.7 Latency. 10.8 LTE Refarming to GSM
Spectrum. 10.9 Dimensioning. 10.10 Capacity Management Examples from HSPA
Networks. 10.11 Summary. References. 11 LTE Measurements (Marilynn P.
Wylie-Green, Harri Holma, Jussi Reunanen and Antti Toskala). 11.1
Introduction. 11.2 Theoretical Peak Data Rates. 11.3 Laboratory
Measurements. 11.4 Field Measurement Setups. 11.5 Artificial Load
Generation. 11.6 Peak Data Rates in the Field. 11.7 Link Adaptation and
MIMO Utilization. 11.8 Handover Performance. 11.9 Data Rates in Drive
Tests. 11.10 Multi-User Packet Scheduling. 11.11 Latency. 11.12 Very Large
Cell Size. 11.13 Summary. References. 12 Transport (Torsten Musiol). 12.1
Introduction. 12.2 Protocol Stacks and Interfaces. 12.3 Transport Aspects
of Intra-LTE Handover. 12.4 Transport Performance Requirements. 12.5
Transport Network Architecture for LTE. 12.6 Quality of Service. 12.7
Transport Security. 12.8 Synchronization from Transport Network. 12.9 Base
Station Co-location. 12.10 Summary. References. 13 Voice over IP (VoIP)
(Harri Holma, Juha Kallio, Markku Kuusela, Petteri Lundén, Esa
Malkamäki,Jussi Ojala and Haiming Wang). 13.1 Introduction. 13.2 VoIP
Codecs. 13.3 VoIP Requirements. 13.4 Delay Budget. 13.5 Scheduling and
Control Channels. 13.6 LTE Voice Capacity. 13.7 Voice Capacity Evolution.
13.8 Uplink Coverage. 13.9 Circuit Switched Fallback for LTE. 13.10 Single
Radio Voice Call Continuity (SR-VCC). 13.11 Summary. References. 14
Performance Requirements (Andrea Ancora, Iwajlo Angelow, Dominique Brunel,
Chris Callender, Harri Holma, Peter Muszynski, Earl McCune and Laurent
Noël). 14.1 Introduction. 14.2 Frequency Bands and Channel Arrangements.
14.3 eNode-B RF Transmitter. 14.4 eNodeB RF Receiver. 14.5 eNodeB
Demodulation Performance. 14.6 User Equipment Design Principles and
Challenges. 14.7 UE RF Transmitter. 14.8 UE RF Receiver Requirements. 14.9
UE Demodulation Performance. 14.10 Requirements for Radio Resource
Management. 14.11 Summary. References. 15 LTE TDD Mode (Che Xiangguang,
Troels Kolding , Peter Skov, Wang Haiming and Antti Toskala). 15.1
Introduction. 15.2 LTE TDD Fundamentals. 15.3 TDD Control Design. 15.4
Semi-persistent Scheduling. 15.5 MIMO and Dedicated Reference Signals. 15.6
LTE TDD Performance. 15.7 Evolution of LTE TDD. 15.8 LTE TDD Summary.
References. 16 LTE-Advanced (Mieszko Chmiel, Mihai Enescu, Harri Holma,
Tommi Koivisto, Jari Lindholm, Timo Lunttila, Klaus Pedersen, Peter Skov,
Timo Roman, Antti Toskala and Yuyu Yan). 16.1 Introduction. 16.2
LTE-Advanced and IMT-Advanced. 16.3 Requirements. 16.4 3GPP LTE-Advanced
Study Phase. 16.5 Carrier Aggregation. 16.6 Downlink Multi-antenna
Enhancements. 16.7 Uplink Multi-Antenna Techniques. 16.8 Heterogeneous
Networks. 16.9 Relays. 16.10 Release 11 Outlook. 16.11 Conclusions.
References. 17 HSPA Evolution (Harri Holma, Karri Ranta-aho and Antti
Toskala). 17.1 Introduction. 17.2 Discontinuous Transmission and Reception
(DTX/DRX). 17.3 Circuit Switched Voice on HSPA. 17.4 Enhanced FACH and
RACH. 17.5 Downlink MIMO and 64QAM. 17.6 Dual Cell HSDPA and HSUPA. 17.7
Multicarrier and Multiband HSDPA. 17.8 Uplink 16QAM. 17.9 Terminal
Categories. 17.10 Layer 2 Optimization. 17.11 Single Frequency Network
(SFN) MBMS. 17.12 Architecture Evolution. 17.13 Summary. References. Index.
Preface. Acknowledgements. List of abbreviations. 1 Introduction (Harry
Holma and Antti Toskala). 1.1 Mobile Voice Subscriber Growth. 1.2 Mobile
Data Usage Growth. 1.3 Evolution of Wireline Technologies. 1.4 Motivation
and Targets for LTE. 1.5 Overview of LTE. 1.6 3GPP Family of Technologies.
1.7 Wireless Spectrum. 1.8 New Spectrum Identified by WRC-07. 1.9
LTE-Advanced. 2 LTE Standardization (Antti Toskala). 2.1 Introduction. 2.2
Overview of 3GPP Releases and Process. 2.3 LTE Targets. 2.4 LTE
Standardization Phases. 2.5 Evolution Beyond Release 8. 2.6 LTE-Advanced
for IMT-Advanced. 2.7 LTE Specifications and 3GPP Structure 3 System
Architecture Based on 3GPP SAE 23 (Atte Länsisalmi and Antti Toskala). 3.1
System Architecture Evolution in 3GPP. 3.2 Basic System Architecture
Configuration with only E-UTRAN Access Network. 3.3 System Architecture
with E-UTRAN and Legacy 3GPP Access Networks. 3.4 System Architecture with
E-UTRAN and Non-3GPP Access Networks. 3.5 Inter-working with cdma2000(r)
Access Networks. 3.6 IMS Architecture. 3.7 PCC and QoS. References. 4
Introduction to OFDMA and SC-FDMA and to MIMO in LTE (Antti Toskala and
Timo Lunttila). 4.1 Introduction. 4.2 LTE Multiple Access Background. 4.3
OFDMA Basics. 4.4 SC-FDMA Basics. 4.5 MIMO Basics. 4.6 Summary. References.
5 Physical Layer (Antti Toskala, Timo Lunttila, Esa Tiirola, Kari Hooli,
Mieszko Chmiel and Juha Korhonen). 5.1 Introduction. 5.2 Transport Channels
and their Mapping to the Physical Channels. 5.3 Modulation. 5.4 Uplink User
Data Transmission. 5.5 Downlink User Data Transmission. 5.6 Uplink Physical
Layer Signaling Transmission. 5.7 PRACH Structure. 5.8 Downlink Physical
Layer Signaling Transmission. 5.9 Physical Layer Procedures. 5.10 UE
Capability Classes and Supported Features. 5.11 Physical Layer
Measurements. 5.12 Physical Layer Parameter Configuration. 5.13 Summary.
References. 6 LTE Radio Protocols (Antti Toskala, Woonhee Hwang and Colin
Willcock). 6.1 Introduction. 6.2 Protocol Architecture. 6.3 The Medium
Access Control. 6.4 The Radio Link Control Layer. 6.5 Packet Data
Convergence Protocol. 6.6 Radio Resource Control (RRC). 6.7 X2 Interface
Protocols. 6.8 Understanding the RRC ASN.1 Protocol Definition. 6.9 Early
UE handling in LTE. 6.10 Summary. References. 7 Mobility (Chris Callender,
Harri Holma, Jarkko Koskela and Jussi Reunanen). 7.1 Introduction. 7.2
Mobility Management in Idle State. 7.3 Intra-LTE Handovers. 7.4
Inter-system Handovers. 7.5 Differences in E-UTRAN and UTRAN Mobility. 7.6
Summary. References. 8 Radio Resource Management (Harri Holma, Troels
Kolding, Daniela Laselva, Klaus Pedersen, Claudio Rosa and Ingo Viering).
8.1 Introduction. 8.2 Overview of RRM Algorithms. 8.3 Admission Control and
QoS Parameters. 8.4 Downlink Dynamic Scheduling and Link Adaptation. 8.5
Uplink Dynamic Scheduling and Link Adaptation. 8.6 Interference Management
and Power Settings. 8.7 Discontinuous Transmission and Reception (DTX/DRX).
8.8 RRC Connection Maintenance. 8.9 Summary. References. 9 Self Organizing
Networks (SON) (Krzysztof Kordybach, Seppo Hamalainen, Cinzia Sartori and
Ingo Viering). 9.1 Introduction. 9.2 SON Architecture. 9.3 SON Functions.
9.4 Self-configuration. 9.5 Self-Optimization and Self-Healing Use Cases.
9.6 3GPP Release 10 Use Cases. 9.7 Summary. References. 10 Performance
(Harri Holma, Pasi Kinnunen, István Z. Kovács, Kari Pajukoski, Klaus
Pedersen and Jussi Reunanen). 10.1 Introduction. 10.2 Layer 1 Peak Bit
Rates. 10.3 Terminal Categories. 10.4 Link Level Performance. 10.5 Link
Budgets. 10.6 Spectral Efficiency. 10.7 Latency. 10.8 LTE Refarming to GSM
Spectrum. 10.9 Dimensioning. 10.10 Capacity Management Examples from HSPA
Networks. 10.11 Summary. References. 11 LTE Measurements (Marilynn P.
Wylie-Green, Harri Holma, Jussi Reunanen and Antti Toskala). 11.1
Introduction. 11.2 Theoretical Peak Data Rates. 11.3 Laboratory
Measurements. 11.4 Field Measurement Setups. 11.5 Artificial Load
Generation. 11.6 Peak Data Rates in the Field. 11.7 Link Adaptation and
MIMO Utilization. 11.8 Handover Performance. 11.9 Data Rates in Drive
Tests. 11.10 Multi-User Packet Scheduling. 11.11 Latency. 11.12 Very Large
Cell Size. 11.13 Summary. References. 12 Transport (Torsten Musiol). 12.1
Introduction. 12.2 Protocol Stacks and Interfaces. 12.3 Transport Aspects
of Intra-LTE Handover. 12.4 Transport Performance Requirements. 12.5
Transport Network Architecture for LTE. 12.6 Quality of Service. 12.7
Transport Security. 12.8 Synchronization from Transport Network. 12.9 Base
Station Co-location. 12.10 Summary. References. 13 Voice over IP (VoIP)
(Harri Holma, Juha Kallio, Markku Kuusela, Petteri Lundén, Esa
Malkamäki,Jussi Ojala and Haiming Wang). 13.1 Introduction. 13.2 VoIP
Codecs. 13.3 VoIP Requirements. 13.4 Delay Budget. 13.5 Scheduling and
Control Channels. 13.6 LTE Voice Capacity. 13.7 Voice Capacity Evolution.
13.8 Uplink Coverage. 13.9 Circuit Switched Fallback for LTE. 13.10 Single
Radio Voice Call Continuity (SR-VCC). 13.11 Summary. References. 14
Performance Requirements (Andrea Ancora, Iwajlo Angelow, Dominique Brunel,
Chris Callender, Harri Holma, Peter Muszynski, Earl McCune and Laurent
Noël). 14.1 Introduction. 14.2 Frequency Bands and Channel Arrangements.
14.3 eNode-B RF Transmitter. 14.4 eNodeB RF Receiver. 14.5 eNodeB
Demodulation Performance. 14.6 User Equipment Design Principles and
Challenges. 14.7 UE RF Transmitter. 14.8 UE RF Receiver Requirements. 14.9
UE Demodulation Performance. 14.10 Requirements for Radio Resource
Management. 14.11 Summary. References. 15 LTE TDD Mode (Che Xiangguang,
Troels Kolding , Peter Skov, Wang Haiming and Antti Toskala). 15.1
Introduction. 15.2 LTE TDD Fundamentals. 15.3 TDD Control Design. 15.4
Semi-persistent Scheduling. 15.5 MIMO and Dedicated Reference Signals. 15.6
LTE TDD Performance. 15.7 Evolution of LTE TDD. 15.8 LTE TDD Summary.
References. 16 LTE-Advanced (Mieszko Chmiel, Mihai Enescu, Harri Holma,
Tommi Koivisto, Jari Lindholm, Timo Lunttila, Klaus Pedersen, Peter Skov,
Timo Roman, Antti Toskala and Yuyu Yan). 16.1 Introduction. 16.2
LTE-Advanced and IMT-Advanced. 16.3 Requirements. 16.4 3GPP LTE-Advanced
Study Phase. 16.5 Carrier Aggregation. 16.6 Downlink Multi-antenna
Enhancements. 16.7 Uplink Multi-Antenna Techniques. 16.8 Heterogeneous
Networks. 16.9 Relays. 16.10 Release 11 Outlook. 16.11 Conclusions.
References. 17 HSPA Evolution (Harri Holma, Karri Ranta-aho and Antti
Toskala). 17.1 Introduction. 17.2 Discontinuous Transmission and Reception
(DTX/DRX). 17.3 Circuit Switched Voice on HSPA. 17.4 Enhanced FACH and
RACH. 17.5 Downlink MIMO and 64QAM. 17.6 Dual Cell HSDPA and HSUPA. 17.7
Multicarrier and Multiband HSDPA. 17.8 Uplink 16QAM. 17.9 Terminal
Categories. 17.10 Layer 2 Optimization. 17.11 Single Frequency Network
(SFN) MBMS. 17.12 Architecture Evolution. 17.13 Summary. References. Index.
Holma and Antti Toskala). 1.1 Mobile Voice Subscriber Growth. 1.2 Mobile
Data Usage Growth. 1.3 Evolution of Wireline Technologies. 1.4 Motivation
and Targets for LTE. 1.5 Overview of LTE. 1.6 3GPP Family of Technologies.
1.7 Wireless Spectrum. 1.8 New Spectrum Identified by WRC-07. 1.9
LTE-Advanced. 2 LTE Standardization (Antti Toskala). 2.1 Introduction. 2.2
Overview of 3GPP Releases and Process. 2.3 LTE Targets. 2.4 LTE
Standardization Phases. 2.5 Evolution Beyond Release 8. 2.6 LTE-Advanced
for IMT-Advanced. 2.7 LTE Specifications and 3GPP Structure 3 System
Architecture Based on 3GPP SAE 23 (Atte Länsisalmi and Antti Toskala). 3.1
System Architecture Evolution in 3GPP. 3.2 Basic System Architecture
Configuration with only E-UTRAN Access Network. 3.3 System Architecture
with E-UTRAN and Legacy 3GPP Access Networks. 3.4 System Architecture with
E-UTRAN and Non-3GPP Access Networks. 3.5 Inter-working with cdma2000(r)
Access Networks. 3.6 IMS Architecture. 3.7 PCC and QoS. References. 4
Introduction to OFDMA and SC-FDMA and to MIMO in LTE (Antti Toskala and
Timo Lunttila). 4.1 Introduction. 4.2 LTE Multiple Access Background. 4.3
OFDMA Basics. 4.4 SC-FDMA Basics. 4.5 MIMO Basics. 4.6 Summary. References.
5 Physical Layer (Antti Toskala, Timo Lunttila, Esa Tiirola, Kari Hooli,
Mieszko Chmiel and Juha Korhonen). 5.1 Introduction. 5.2 Transport Channels
and their Mapping to the Physical Channels. 5.3 Modulation. 5.4 Uplink User
Data Transmission. 5.5 Downlink User Data Transmission. 5.6 Uplink Physical
Layer Signaling Transmission. 5.7 PRACH Structure. 5.8 Downlink Physical
Layer Signaling Transmission. 5.9 Physical Layer Procedures. 5.10 UE
Capability Classes and Supported Features. 5.11 Physical Layer
Measurements. 5.12 Physical Layer Parameter Configuration. 5.13 Summary.
References. 6 LTE Radio Protocols (Antti Toskala, Woonhee Hwang and Colin
Willcock). 6.1 Introduction. 6.2 Protocol Architecture. 6.3 The Medium
Access Control. 6.4 The Radio Link Control Layer. 6.5 Packet Data
Convergence Protocol. 6.6 Radio Resource Control (RRC). 6.7 X2 Interface
Protocols. 6.8 Understanding the RRC ASN.1 Protocol Definition. 6.9 Early
UE handling in LTE. 6.10 Summary. References. 7 Mobility (Chris Callender,
Harri Holma, Jarkko Koskela and Jussi Reunanen). 7.1 Introduction. 7.2
Mobility Management in Idle State. 7.3 Intra-LTE Handovers. 7.4
Inter-system Handovers. 7.5 Differences in E-UTRAN and UTRAN Mobility. 7.6
Summary. References. 8 Radio Resource Management (Harri Holma, Troels
Kolding, Daniela Laselva, Klaus Pedersen, Claudio Rosa and Ingo Viering).
8.1 Introduction. 8.2 Overview of RRM Algorithms. 8.3 Admission Control and
QoS Parameters. 8.4 Downlink Dynamic Scheduling and Link Adaptation. 8.5
Uplink Dynamic Scheduling and Link Adaptation. 8.6 Interference Management
and Power Settings. 8.7 Discontinuous Transmission and Reception (DTX/DRX).
8.8 RRC Connection Maintenance. 8.9 Summary. References. 9 Self Organizing
Networks (SON) (Krzysztof Kordybach, Seppo Hamalainen, Cinzia Sartori and
Ingo Viering). 9.1 Introduction. 9.2 SON Architecture. 9.3 SON Functions.
9.4 Self-configuration. 9.5 Self-Optimization and Self-Healing Use Cases.
9.6 3GPP Release 10 Use Cases. 9.7 Summary. References. 10 Performance
(Harri Holma, Pasi Kinnunen, István Z. Kovács, Kari Pajukoski, Klaus
Pedersen and Jussi Reunanen). 10.1 Introduction. 10.2 Layer 1 Peak Bit
Rates. 10.3 Terminal Categories. 10.4 Link Level Performance. 10.5 Link
Budgets. 10.6 Spectral Efficiency. 10.7 Latency. 10.8 LTE Refarming to GSM
Spectrum. 10.9 Dimensioning. 10.10 Capacity Management Examples from HSPA
Networks. 10.11 Summary. References. 11 LTE Measurements (Marilynn P.
Wylie-Green, Harri Holma, Jussi Reunanen and Antti Toskala). 11.1
Introduction. 11.2 Theoretical Peak Data Rates. 11.3 Laboratory
Measurements. 11.4 Field Measurement Setups. 11.5 Artificial Load
Generation. 11.6 Peak Data Rates in the Field. 11.7 Link Adaptation and
MIMO Utilization. 11.8 Handover Performance. 11.9 Data Rates in Drive
Tests. 11.10 Multi-User Packet Scheduling. 11.11 Latency. 11.12 Very Large
Cell Size. 11.13 Summary. References. 12 Transport (Torsten Musiol). 12.1
Introduction. 12.2 Protocol Stacks and Interfaces. 12.3 Transport Aspects
of Intra-LTE Handover. 12.4 Transport Performance Requirements. 12.5
Transport Network Architecture for LTE. 12.6 Quality of Service. 12.7
Transport Security. 12.8 Synchronization from Transport Network. 12.9 Base
Station Co-location. 12.10 Summary. References. 13 Voice over IP (VoIP)
(Harri Holma, Juha Kallio, Markku Kuusela, Petteri Lundén, Esa
Malkamäki,Jussi Ojala and Haiming Wang). 13.1 Introduction. 13.2 VoIP
Codecs. 13.3 VoIP Requirements. 13.4 Delay Budget. 13.5 Scheduling and
Control Channels. 13.6 LTE Voice Capacity. 13.7 Voice Capacity Evolution.
13.8 Uplink Coverage. 13.9 Circuit Switched Fallback for LTE. 13.10 Single
Radio Voice Call Continuity (SR-VCC). 13.11 Summary. References. 14
Performance Requirements (Andrea Ancora, Iwajlo Angelow, Dominique Brunel,
Chris Callender, Harri Holma, Peter Muszynski, Earl McCune and Laurent
Noël). 14.1 Introduction. 14.2 Frequency Bands and Channel Arrangements.
14.3 eNode-B RF Transmitter. 14.4 eNodeB RF Receiver. 14.5 eNodeB
Demodulation Performance. 14.6 User Equipment Design Principles and
Challenges. 14.7 UE RF Transmitter. 14.8 UE RF Receiver Requirements. 14.9
UE Demodulation Performance. 14.10 Requirements for Radio Resource
Management. 14.11 Summary. References. 15 LTE TDD Mode (Che Xiangguang,
Troels Kolding , Peter Skov, Wang Haiming and Antti Toskala). 15.1
Introduction. 15.2 LTE TDD Fundamentals. 15.3 TDD Control Design. 15.4
Semi-persistent Scheduling. 15.5 MIMO and Dedicated Reference Signals. 15.6
LTE TDD Performance. 15.7 Evolution of LTE TDD. 15.8 LTE TDD Summary.
References. 16 LTE-Advanced (Mieszko Chmiel, Mihai Enescu, Harri Holma,
Tommi Koivisto, Jari Lindholm, Timo Lunttila, Klaus Pedersen, Peter Skov,
Timo Roman, Antti Toskala and Yuyu Yan). 16.1 Introduction. 16.2
LTE-Advanced and IMT-Advanced. 16.3 Requirements. 16.4 3GPP LTE-Advanced
Study Phase. 16.5 Carrier Aggregation. 16.6 Downlink Multi-antenna
Enhancements. 16.7 Uplink Multi-Antenna Techniques. 16.8 Heterogeneous
Networks. 16.9 Relays. 16.10 Release 11 Outlook. 16.11 Conclusions.
References. 17 HSPA Evolution (Harri Holma, Karri Ranta-aho and Antti
Toskala). 17.1 Introduction. 17.2 Discontinuous Transmission and Reception
(DTX/DRX). 17.3 Circuit Switched Voice on HSPA. 17.4 Enhanced FACH and
RACH. 17.5 Downlink MIMO and 64QAM. 17.6 Dual Cell HSDPA and HSUPA. 17.7
Multicarrier and Multiband HSDPA. 17.8 Uplink 16QAM. 17.9 Terminal
Categories. 17.10 Layer 2 Optimization. 17.11 Single Frequency Network
(SFN) MBMS. 17.12 Architecture Evolution. 17.13 Summary. References. Index.
"Written by experts actively involved in the 3GPP standards and product development, LTE for UMTS, Second Edition gives a complete and up-to-date overview of Long Term Evolution (LTE) in a systematic and clear manner. Building upon on the success of the first edition, LTE for UMTS, Second Edition has been revised to now contain improved coverage of the Release 8 LTE details, including field performance results, transport network, self optimized networks and also covering the enhancements done in 3GPP Release 9." (FierceTelecom, 17 August 2011)