Summary

Following on from the success of the first edition, this edition will be revised in light of new developments in near-capacity turbo-transceivers. It will include 5 new chapters on: Multilevel Coding Theory; MLC Design Using EXIT Analysis; Space Time Sphere Packing Aided MLC/ BICM Design; MLC/ BICM Schemes for Wireless Internet and Near-Capacity Irregular BICM-ID Design. The book is divided into the following 4 parts:Part 1 - explains the necessary background for novices. It aims to be both an easy reading text book and a deep research monograph. Part 2 - provides detailed coverage of turbo conventional and turbo block coding considering the known decoding algorithms and their performance over Gaussian as well as narrowband and wideband fading channels. Part 3 comprehensively discusses both space-time block and space-time trellis coding.Part 4 - provides an overview of turbo equalisations, also referred to as turbo demodulation.

Author Biography

Lajos Hanzo received his Doctorate in 1983 from the Technical University of Budapest. In 2010 he was awarded the university's highest honour, namely the Honorary Doctorate "Doctor Honaris Causa". During his 34-year career in telecommunications he has held various research and academic posts in Hungary, Germany and the UK. Since 1986 he has been a member of academic staff in the School of Electronics and Computer Science, University of Southampton, UK, where he currently holds the Chair in Telecommunications and he is head of the Communications Research Area. He is also a Chaired Professor at Tsinghua University, Beijing, China. Lajos Hanzo has co-authored 20 John Wiley/IEEE Press books on mobile radio communications, and published over 1000 research papers and book chapters at IEEE Xplore. He has also organised and chaired major IEEE conferences, such as WCNC'2006, WCNC'2009, VTC'2011, presented Tutorial/overview lectures at international conferences.

Tong Hooi Liew received his PhD degree in 2001 from the University of Southampton, UK. Following a one year spell as postdoctoral research fellow, he joined Ubinetcs in Cambridge, UK in algorithm design for 3G mobile station. He then joined TTP Group as a consultant working in mobile TV. Currently he is working as a consultant for Aeroflex in both physical layer and Layer 2 in various wireless technologies like 3G HSPA, HSPA+, LTE and advanced LTE wireless systems. He has over 40 publications in books, book chapters, journal and conference papers. His research interests are associated with coding and modulation for wireless channels, space-time coding and adaptive transceivers.

Ronald Yee Siong Tee received his PhD degree from the University of Southampton in 2008. He was previously involved in research collaboration with Nokia UK in signal processing and handwriting recognition in 2000. From 2001 to 2002 he worked at Nortel Networks Switzerland in the area of data and optical network. In 2003, he was with a local Singapore IT company, where he headed the telecommunication business. Dr. Tee is the recipient of several academic awards, including the Overseas Research Scheme, the ASEAN scholarship, and the Malaysian Government studentships. He is currently with Ernst & Young London, working in forensic technology and electronic disclosure.

Bee Leong Yeap received his PhD in 2000 from the University of Southampton, having been fully funded by the University's Communications Group and the Overseas Research Studentship. He continued his research as a postdoctoral research fellow in Southampton until 2004, working on EU projects such as TRUST and SCOUT. In 2004, he joined RadioScape Plc, London to develop commercial DAB, DRM and DMB receivers. Subsequently from 2008, he has been with Motorola Ltd, Ashburton designing Point-to-Point Wireless Ethernet bridges, which are used to provide connectivity and backhaul for network carriers, Educational Broadcast Service and Federal agencies. To date, he has published two John Wiley/IEEE Press books and over 30 research papers. His research interests include MIMO systems, turbo coding, LDPC, turbo equalisation, space-time coding and adaptive modulation.

Soon Xin Ng received the Ph.D. degree in wireless communications from the University of Southampton, UK, in December 2002. From 2003 to 2006, he was a postdoctoral research fellow working on collaborative European research projects known as SCOUT, NEWCOM and PHOENIX. Since August 2006, he has been a member of academic staff in the School of Electronics and Computer Science, University of Southampton. He is involved in the OPTIMIX European project as well as the IU-ATC and UC4G projects. His research interests include adaptive coded modulation, coded modulation, channel coding, space-time coding, joint source and channel coding, iterative detection, OFDM, MIMO, cooperative communications and distributed coding. He has published over 120 papers and co-authored two John Wiley/IEEE Press books in this field. He is a senior member of the IEEE and a fellow of the Higher Education Academy in the UK.

About the Authors	p. xv
Other Related Wiley and IEEE Press Books	p. xvii
Acknowledgments	p. xix
Historical Perspective, Motivation and Outline
A Historical Perspective on Channel Coding
Motivation of the Book
Organisation of the Book
Novel Contributions of the Book
Convolutional Channel Coding
Brief Channel Coding History
Convolutional Encoding
State and Trellis Transitions
The Viterbi Algorithm
Summary and Conclusions
Soft Decoding and Performance of BCH Codes
Introduction
BCH codes
Trellis Decoding
Soft input Algebraic Decoding
Summary and Conclusions
Turbo Convolutional and Turbo Block Coding
Turbo Convolutional Coding
Introduction
Turbo Encoder
Turbo Decoder
TurboâÇôcoded BPSK Performance over Gaussian Channels
Turbo Coding Performance over Rayleigh Channels
Summary and Conclusions
Turbo BCH Coding
Introduction
Turbo Encoder
Turbo Decoder
Turbo Decoding Example
MAP Algorithm for Extended BCH codes
Simulation Results
Summary and Conclusions
SpaceâÇôTime Block and SpaceâÇôTime Trellis Coding
SpaceâÇôTime Block Codes
Classification of Smart Antennas
Introduction to SpaceâÇôtime Coding
Background
SpaceâÇôtime Block Codes
ChannelâÇôcoded SpaceâÇôtime Block Codes
Summary and Conclusions
SpaceâÇôTime Trellis Codes
Introduction
SpaceâÇôtime Trellis Codes
SpaceâÇôtimeâÇôcoded Transmission over Wideband Channels
Simulation Results
SpaceâÇôtimeâÇôcoded Adaptive Modulation for OFDM
Summary and Conclusions
TurboâÇôcoded Adaptive QAM versus SpaceâÇôtime Trellis Coding
Introduction
System Overview
Simulation Parameters
Simulation Results
Summary and Conclusions
Turbo Equalisation
TurboâÇôcoded PartialâÇôresponse Modulation
Motivation
The Mobile Radio Channel
Continuous Phase Modulation Theory
Digital Frequency Modulation Systems
State Representation
Spectral Performance
Construction of TrellisâÇôbased Equaliser States
SoftâÇôoutput GMSK Equaliser and Turbo Coding
Summary and Conclusions
Turbo Equalisation for PartialâÇôResponse Systems
Motivation
Principle of Turbo Equalisation Using Single/Multiple Decoder(s)
SoftâÇôin/SoftâÇôout Equaliser for Turbo Equalisation
SoftâÇôin/SoftâÇôout Decoder for Turbo Equalisation
Turbo Equalisation Example
Summary of Turbo Equalisation
Performance of Coded GMSK Systems using Turbo Equalisation
Discussion of Results
Summary and Conclusions
Comparative Study of Turbo Equalisers
Motivation
System overview
Simulation Parameters
Results and Discussion
NonâÇôiterative Joint Channel Equalisation and Decoding
Summary and Conclusions
ReducedâÇôcomplexity Turbo Equaliser	p. 369
Motivation
Complexity of the Multilevel FullâÇôresponse Turbo Equaliser
System Model
InâÇôphase/QuadratureâÇôphase Equaliser Principle
Overview of the ReducedâÇôcomplexity Turbo Equaliser
Complexity of the InâÇôphase/QuadratureâÇôphase Turbo Equaliser
System Parameters
System Performance
Summary and Conclusions
Turbo Equalisation for SpaceâÇôtime TrellisâÇôcoded Systems
Introduction
System Overview
Principle of InâÇôphase/QuadratureâÇôphase Turbo Equalisation
Complexity Analysis
Results and Discussion
Summary and Conclusions
Coded and SpaceâÇôTimeâÇôCoded AdaptiveModulation: TCM, TTCM, BICM, BICMâÇôID and MLC
Coded Modulation Theory and Performance 413
Introduction
TrellisâÇôCoded Modulation
The SymbolâÇôbased MAP Algorithm
Turbo TrellisâÇôcoded Modulation
BitâÇôinterleaved Coded Modulation
BitâÇôInterleaved Coded Modulation Using Iterative Decoding
Coded Modulation Performance
Summary and Conclusions
Multilevel Coding Theory
Introduction
Multilevel Coding
BitâÇôInterleaved Coded Modulation
BitâÇôInterleaved Coded Modulation Using Iterative Decoding
Conclusion
MLC Design Using EXIT Analysis 503
Introduction
Comparative Study of Coded Modulation Schemes
EXIT Chart Analysis
PrecoderâÇôAided MLC
Chapter Conclusions
Space Time Sphere Packing AidedMLC/BICMDesign
Introduction
Space Time Block Code
Orthogonal G2 Design Using Sphere Packing
Iterative Demapping for Sphere Packing
STBCâÇôSPâÇôMLC
STBCâÇôSPâÇôBICM
Chapter Conclusions
MLC/BICMSchemes for theWireless Internet	p. 569
Introduction
Multilevel Generalised LowâÇôDensity ParityâÇôCheck Codes
An Iterative Stopping Criterion for MLCâÇôGLDPCs
Coding for the Wireless Internet
LTâÇôBICMâÇôID Using LLR Packet Reliability Estimation
Chapter Conclusions
NearâÇôCapacity Irregular BICMâÇôID Design
Introduction
Irregular BitâÇôInterleaved Coded Modulation Schemes
EXIT Chart Analysis
Irregular Components
Simulation Results
Chapter Conclusions
Summary and Conclusions	p. 625
Summary of the Book
Future Work
Concluding Remarks
Bibliography	p. 645
Subject Index	p. 665
Table of Contents provided by Publisher. All Rights Reserved.

Supplemental Materials

What is included with this book?

The New copy of this book will include any supplemental materials advertised. Please check the title of the book to determine if it should include any access cards, study guides, lab manuals, CDs, etc.

The Used, Rental and eBook copies of this book are not guaranteed to include any supplemental materials. Typically, only the book itself is included. This is true even if the title states it includes any access cards, study guides, lab manuals, CDs, etc.