Since the publication of Wireless Video Communications five years ago, the area of video compression and wireless transceivers has evolved even further. This new edition addresses a range of recent developments in these areas, giving cognizance to the associated transmission aspects and issues of error resilience.
Video Compression and Communications has been updated and condensed yet remains all-encompassing, giving a comprehensive overview of the subject. Covering compression issues, coding delay, implementational complexity and bitrate, the book also looks at the historical perspective to video communication.
New edition of successful and informative text, Wireless Video Communications Substantial new material has been added on areas such as H.264, MPEG4 coding and transceivers Clear presentation and broad scope make it essential for anyone interested in wireless communications Systematically converts the lessons of Shannon's information theory into design principles applicable to practical wireless systems.
This book is ideal for postgraduates and researchers in communication systems but will also be a valuable reference to undergraduates, development and systems engineers of video compression applications as well as industrialists, managers and visual communications practitioners.
About the Authors xvii Other Wiley and IEEE Press Books on Related Topics xix Preface xxi Acknowledgments xxiii 1 Introduction 1 1.1 A Brief Introduction to Compression Theory 1 1.2 Introduction to Video Formats 2 1.3 Evolution of Video Compression Standards 5 1.4 Video Communications 15 1.5 Organization of the Monograph 17 I Video Codecs for HSDPA-style Adaptive Videophones 19 2 Fractal Image Codecs 21 2.1 Fractal Principles 21 2.2 One-dimensional Fractal Coding 23 2.3 Error Sensitivity and Complexity 32 2.4 Summary and Conclusions 33 3 Low Bitrate DCT Codecs and HSDPA-style Videophone Transceivers 35 3.1 Video Codec Outline 35 3.2 The Principle of Motion Compensation 37 3.3 Transform Coding 51 3.4 The Codec Outline 58 3.5 Initial Intra-frame Coding 60 3.6 Gain-controlled Motion Compensation 60 3.7 TheMCER Active/Passive Concept 61 3.8 Partial Forced Update of the Reconstructed FrameBuffers 62 3.9 The Gain/Cost-controlled Inter-frame Codec 64 3.10 The Bit-allocation Strategy 66 3.11 Results 67 3.12 DCT Codec Performance under Erroneous Conditions 70 3.13 DCT-based Low-rate Video Transceivers 72 3.14 System Performance 80 3.15 Summary and Conclusions 89 4 Very Low Bitrate VQ Codecs and HSDPA-style Videophone Transceivers 93 4.1 Introduction 93 4.2 The Codebook Design 93 4.3 The Vector Quantizer Design 95 4.4 Performance under Erroneous Conditions 105 4.5 VQ-based Low-rate Video Transceivers 107 4.6 System Performance 113 4.7 Joint Iterative Decoding of Trellis-based Vector-quantized Video and TCM 118 4.8 Summary and Conclusions 136 5 Low Bitrate Quad-tree-based Codecs and HSDPA-style Videophone Transceivers 139 5.1 Introduction 139 5.2 Quad-tree Decomposition 139 5.3 Quad-tree Intensity Match 142 5.4 Model-based Parametric Enhancement 148 5.5 The Enhanced QTCodec 153 5.6 Performance and Considerations under Erroneous Conditions 154 5.7 QT-codec-based Video Transceivers 158 5.8 QT-based Video-transceiver Performance 162 5.9 Summary of QT-based Video Transceivers 165 5.10 Summary of Low-rate Video Codecs and Transceivers 166 II High-resolution Video Coding 171 6 Low-complexity Techniques 173 6.1 Differential Pulse Code Modulation 173 6.2 Block Truncation Coding 177 6.3 Subband Coding 183 6.4 Summary and Conclusions 202 7 High-resolution DCT Coding 205 7.1 Introduction 205 7.2 Intra-frame Quantizer Training 205 7.3 Motion Compensation for High-quality Images 209 7.4 Inter-frame DCT Coding 215 7.5 The Proposed Codec 224 7.6 Summary and Conclusions 235 III H.261, H.263, H.264, MPEG2 and MPEG4 for HSDPA-style Wireless Video Telephony and DVB 237 8 H.261 for HSDPA-style Wireless Video Telephony 239 8.1 Introduction 239 8.2 TheH.261VideoCoding Standard 239 8.3 Effect of Transmission Errors on theH.261Codec 253 8.4 A Reconfigurable Wireless Videophone System 272 8.5 H.261-basedWireless Videophone System Performance 283 8.6 Summary and Conclusions 293 9 Comparative Study of the H.261 and H.263 Codecs 295 9.1 Introduction 295 9.2 TheH.263CodingAlgorithms 297 9.3 Performance Results 318 9.4 Summary and Conclusions 335 10 H.263 for HSDPA-style Wireless Video Telephony 339 10.1 Introduction 339 10.2 H.263inaMobileEnvironment 339 10.3 Design of an Error-resilient Reconfigurable Videophone System 343 10.4 H.263-based Video System Performance 352 10.5 Transmission Feedback 367 10.6 Summary and Conclusions 376 11 MPEG-4 Video Compression 379 11.1 Introduction 379 11.2 OverviewofMPEG-4 380 11.3 MPEG-4: Content-based Interactivity 387 11.4 Scalability of Video Objects 396 11.5 Video Quality Measures 398 11.6 Effect of Coding Parameters 400 11.7 Summary and Conclusion 404 12 Comparative Study of the MPEG-4 and H.264 Codecs 407 12.1 Introduction 407 12.2 TheITU-TH.264Project 407 12.3 H.264VideoCodingTechniques 408 12.4 H.264SpecificCodingAlgorithm 410 12.5 Comparative Study of theMPEG-4 and H.264 Codecs 425 12.6 Performance Results 428 13 MPEG-4 Bitstream and Bit-sensitivity Study 437 13.1 Motivation 437 13.2 Structure of Coded Visual Data 437 13.3 Visual Bitstream Syntax 440 13.4 Introduction to Error-resilient Video Encoding 441 13.5 Error-resilient Video Coding in MPEG-4 441 13.6 Error-resilience Tools in MPEG-4 443 13.7 MPEG-4Bit-sensitivityStudy 448 13.8 Chapter Conclusions 457 14 HSDPA-like and Turbo-style Adaptive Single- and Multi-carrier Video Systems 459 14.1 Turbo-equalized H.263-based Videophony for GSM/GPRS 459 14.2 HSDPA-style Burst-by-burst Adaptive CDMA Videophony: Turbo-coded Burst-by-burst Adaptive Joint Detection CDMA and H.263-based Videophony 472 14.3 Subband-adaptive Turbo-coded OFDM-based Interactive Videotelephony 485 14.4 Burst-by-burst Adaptive Decision Feedback Equalized TCM, TTCM, and BICM for H.263-assistedWireless Videotelephony 506 14.5 Turbo-detected MPEG-4 Video Using Multi-level Coding, TCM and STTC 526 14.6 Near-capacity Irregular Variable Length Codes 543 14.7 Digital Terrestrial Video Broadcasting for Mobile Receivers 558 14.8 Satellite-based Video Broadcasting 601 14.9 Summary and Conclusions 622 14.10WirelessVideoSystemDesignPrinciples 623 Glossary 625 Bibliography 635 Index 659 Author Index 667
Laios Hanzo, Universitv of Southamoton, UK Lajos Hanzo is currently chair of Telecommunications at University of Southampton in the department of Electronics and Computer Science. He has held various research and academic posts in Hungary, Germany and the UK over his 30-year career in communications. The author of over 600 research papers and co-author of over 30 books Hanzo is also an IEEE Distinguished Lecturer of the Communications Society and the Vehicular Technology Society and Governor of the IEEE VT Society. Dr. Peter J. Cherriman, University of Southampton, UK Peter Cherriman is currently at the University of Southampton. He is also working on projects for the Mobile Virtual Centre of Excellence, U.K. His current areas of research include robust video coding, microcellular radio systems, power control, dynamic channel allocation, and multiple access protocols. Dr. Jurgen Streit, University of Southampton, UK Jurgen Streit is also at the University of Southampton, working with the Mobile Multimedia Communications Research Group. He is also a software consultant.
