Turbo Coding, Turbo Equalisation and Space-Time Coding: EXIT-Chart-Aided Near-Capacity Designs for Wireless Channels, 2nd Edition
May 2011, Wiley-IEEE Press
The horizon of the content is then extended to incorporate topics which have found their way into diverse standard systems. These include space-time block and trellis codes, as well as other Multiple-Input Multiple-Output (MIMO) schemes and near-instantaneously Adaptive Quadrature Amplitude Modulation (AQAM). The book also elaborates on turbo equalisation by providing a detailed portrayal of recent advances in partial response modulation schemes using diverse channel codes.
A radically new aspect for this second edition is the discussion of multi-level coding and sphere-packing schemes, Extrinsic Information Transfer (EXIT) charts, as well as an introduction to the family of Generalized Low Density Parity Check codes.
This new edition includes recent advances in near-capacity turbo-transceivers as well as new sections on multi-level coding schemes and of Generalized Low Density Parity Check codes
- Comparatively studies diverse channel coded and turbo detected systems to give all-inclusive information for researchers, engineers and students
- Details EXIT-chart based irregular transceiver designs
- Uses rich performance comparisons as well as diverse near-capacity design examples
Other Related Wiley–IEEE Press Books.
1 Historical Perspective, Motivation and Outline.
1.1 A Historical Perspective on Channel Coding.
1.2 Motivation for this Book.
1.3 Organisation of the Book.
1.4 NovelContributions of the Book.
2 Convolutional Channel Coding.
2.1 Brief Channel Coding History.
2.2 Convolutional Encoding.
2.3 State and Trellis Transitions.
2.4 The Viterbi Algorithm.
2.5 Summary and Conclusions.
3 Soft Decoding and Performance of BCH Codes.
3.2 BCH codes.
3.3 Trellis Decoding.
3.4 Soft-input Algebraic Decoding.
3.5 Summary and Conclusions.
Part I Turbo Convolutional and Turbo Block Coding.
4 Turbo Convolutional Coding (J. P. Woodard and L. Hanzo).
4.2 Turbo Encoder.
4.3 Turbo Decoder.
4.4 Turbo-coded BPSK Performance over Gaussian Channels.
4.5 Turbo Coding Performance over Rayleigh Channels.
4.6 Summary and Conclusions.
5 Turbo BCH Coding.
5.2 Turbo Encoder.
5.3 Turbo Decoder.
5.4 Turbo Decoding Example.
5.5 MAP Algorithm for Extended BCH Codes.
5.6 Simulation Results.
5.7 Summary and Conclusions.
Part II Space–time Block and Space–time Trellis Coding.
6 Space–time Block Codes.
6.1 Classification of Smart Antennas.
6.2 Introduction to Space–time Coding.
6.4 Space–time Block Codes.
6.5 Channel-coded Space–time Block Codes.
6.6 Performance Results.
6.7 Summary and Conclusions.
7 Space–time Trellis Codes.
7.2 Space–time Trellis Codes.
7.3 Space–time-coded Transmission over Wideband Channels.
7.4 Simulation Results.
7.5 Space–time-coded Adaptive Modulation for OFDM.
7.6 Summary and Conclusions.
8 Turbo-coded Adaptive Modulation versus Space–time Trellis Codes for Transmission over Dispersive Channels.
8.2 System Overview.
8.3 Simulation Parameters.
8.4 Simulation Results.
8.5 Summary and Conclusions.
Part III Turbo Equalisation.
9 Turbo-coded Partial-response Modulation.
9.2 The Mobile Radio Channel.
9.3 Continuous Phase Modulation Theory.
9.4 Digital Frequency Modulation Systems.
9.5 State Representation.
9.6 Spectral Performance.
9.7 Construction of Trellis-based Equaliser States.
9.8 Soft-output GMSK Equaliser and Turbo Coding.
9.9 Summary and Conclusions.
10 Turbo Equalisation for Partial-response Systems.
10.2 Principle of Turbo Equalisation Using Single/Multiple Decoder(s).
10.3 Soft-in/Soft-out Equaliser for Turbo Equalisation.
10.4 Soft-in/Soft-out Decoder for Turbo Equalisation.
10.5 Turbo Equalisation Example.
10.6 Summary of Turbo Equalisation.
10.7 Performance of Coded GMSK Systems Using Turbo Equalisation.
10.8 Discussion of Results.
10.9 Summary and Conclusions.
11 Comparative Study of Turbo Equalisers.
11.3 Simulation Parameters.
11.4 Results and Discussion.
11.5 Non-iterative Joint Channel Equalisation and Decoding.
11.6 Summary and Conclusions.
12 Reduced-complexity Turbo Equaliser.
12.2 Complexity of the Multilevel Full-response Turbo Equaliser.
12.3 System Model.
12.4 In-phase/Quadrature-phase Equaliser Principle.
12.5 Overview of the Reduced-complexity Turbo Equaliser.
12.6 Complexity of the In-phase/Quadrature-phase Turbo Equaliser.
12.7 System Parameters.
12.8 System Performance.
12.9 Summary and Conclusions.
13 Turbo Equalisation for Space–time Trellis-coded Systems.
13.2 System Overview.
13.3 Principle of In-phase/Quadrature-phase Turbo Equalisation.
13.4 Complexity Analysis.
13.5 Results and Discussion.
13.6 Summary and Conclusions.
Part IV Coded and Space–time-Coded Adaptive Modulation: TCM, TTCM, BICM, BICM-ID and MLC.
14 Coded Modulation Theory and Performance.
14.2 Trellis-coded Modulation.
14.3 The Symbol-based MAP Algorithm.
14.4 Turbo Trellis-coded Modulation.
14.5 Bit-interleaved Coded Modulation.
14.6 Bit-interleaved Coded Modulation Using Iterative Decoding.
14.7 Coded Modulation Performance.
14.8 Near-capacity Turbo Trellis-coded Modulation Design Based on EXIT Charts and Union Bounds.
14.9 Summary and Conclusions.
15 Multilevel Coding Theory.
15.2 Multilevel Coding.
15.3 Bit-interleaved Coded Modulation.
15.4 Bit-interleaved Coded Modulation Using Iterative Decoding.
16 MLC Design Using EXIT Analysis.
16.2 Comparative Study of Coded Modulation Schemes.
16.3 EXIT-chart Analysis.
16.4 Precoder-aided MLC.
16.5 Chapter Conclusions.
17 Sphere Packing-aided Space–time MLC/BICMDesign.
17.2 Space–time Block Code.
17.3 Orthogonal G2 Design Using Sphere Packing.
17.4 Iterative Demapping for Sphere Packing.
17.7 Chapter Conclusions.
18 MLC/BICMSchemes for theWireless Internet.
18.2 Multilevel Generalised Low-density Parity-check Codes.
18.3 An Iterative Stopping Criterion for MLC-GLDPCs.
18.4 Coding for theWireless Internet.
18.5 LT-BICM-ID Using LLR Packet Reliability Estimation.
18.6 Chapter Conclusions.
19 Near-capacity Irregular BICM-ID Design.
19.2 Irregular Bit-interleaved Coded Modulation Schemes.
19.3 EXIT-chart Analysis.
19.4 Irregular Components.
19.5 Simulation Results.
19.6 Chapter Conclusions.
20 Summary and Conclusions.
20.1 Summary of the Book.
20.2 Future Work.
20.3 Concluding Remarks.
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.