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006 m o d
007 cr |n|||||||||
008 171024s2008 maua ob 001 eng d
010 _z 2008052216 (print)
015 _zGBA900986 (print)
016 _z014864482 (print)
020 _a9780470745168
_qelectronic
020 _z9780470773079
_qcloth
020 _z0470773073
_qcloth
024 7 _a10.1002/9780470745168
_2doi
035 _a(CaBNVSL)mat08039799
035 _a(IDAMS)0b00006485f0db65
040 _aCaBNVSL
_beng
_erda
_cCaBNVSL
_dCaBNVSL
050 4 _aTK5105.15
_b.A13 2009eb
082 0 0 _a621.384
_222
245 0 0 _a4G wireless video communications /
_cHaohong Wang ... [et al.].
264 1 _aChichester, U.K. :
_bWiley,
_c2009.
264 2 _a[Piscataqay, New Jersey] :
_bIEEE Xplore,
_c[2009]
300 _a1 PDF (xxvi, 394 pages) :
_billustrations.
336 _atext
_2rdacontent
337 _aelectronic
_2isbdmedia
338 _aonline resource
_2rdacarrier
490 1 _aWireless communications and mobile computing
504 _aIncludes bibliographical references and index.
505 0 _a-- Forward xiii -- Preface xv -- About the Authors xxi -- About the Series Editors xxv -- 1 Introduction 1 -- 1.1 Why 4G? 1 -- 1.2 4G Status and Key Technologies 3 -- 1.2.1 3GPP LTE 3 -- 1.2.2 Mobile WiMAX 4 -- 1.3 Video Over Wireless 5 -- 1.3.1 Video Compression Basics 5 -- 1.3.2 Video Coding Standards 9 -- 1.3.3 Error Resilience 10 -- 1.3.4 Network Integration 12 -- 1.3.5 Cross-Layer Design for Wireless Video Delivery 14 -- 1.4 Challenges and Opportunities for 4G Wireless Video 15 -- References 17 -- 2 Wireless Communications and Networking 19 -- 2.1 Characteristics and Modeling of Wireless Channels 19 -- 2.1.1 Degradation in Radio Propagation 19 -- 2.1.2 Rayleigh Fading Channel 20 -- 2.2 Adaptive Modulation and Coding 23 -- 2.2.1 Basics of Modulation Schemes 23 -- 2.2.2 System Model of AMC 25 -- 2.2.3 Channel Quality Estimation and Prediction 26 -- 2.2.4 Modulation and Coding Parameter Adaptation 28 -- 2.2.5 Estimation Error and Delay in AMC 30 -- 2.2.6 Selection of Adaptation Interval 30 -- 2.3 Orthogonal Frequency Division Multiplexing 31 -- 2.3.1 Background 31 -- 2.3.2 System Model and Implementation 31 -- 2.3.3 Pros and Cons 33 -- 2.4 Multiple-Input Multiple-Output Systems 34 -- 2.4.1 MIMO System Model 34 -- 2.4.2 MIMO Capacity Gain: Multiplexing 35 -- 2.4.3 MIMO Diversity Gain: Beamforming 35 -- 2.4.4 Diversity-Multiplexing Trade-offs 35 -- 2.4.5 Space-Time Coding 36 -- 2.5 Cross-Layer Design of AMC and HARQ 37 -- 2.5.1 Background 38 -- 2.5.2 System Modeling 39 -- 2.5.3 Cross-Layer Design 41 -- 2.5.4 Performance Analysis 44 -- 2.5.5 Performance 45 -- 2.6 Wireless Networking 47 -- 2.6.1 Layering Network Architectures 48 -- 2.6.2 Network Service Models 50 -- 2.6.3 Multiplexing Methods 51 -- 2.6.4 Connection Management in IP-Based Data Networks 53 -- 2.6.5 QoS Handoff 54 -- 2.7 Summary 55 -- References 56 -- 3 Video Coding and Communications 59 -- 3.1 Digital Video Compression / Why and How Much? 59 -- 3.2 Basics 60 -- 3.2.1 Video Formats 60 -- 3.3 Information Theory 64.
505 8 _a3.3.1 Entropy and Mutual Information 65 -- 3.3.2 Encoding of an Information Source 66 -- 3.3.3 Variable Length Coding 68 -- 3.3.4 Quantization 71 -- 3.4 Encoder Architectures 73 -- 3.4.1 DPCM 73 -- 3.4.2 Hybrid Transform-DPCM Architecture 77 -- 3.4.3 A Typical Hybrid Transform DPCM-based Video Codec 79 -- 3.4.4 Motion Compensation 82 -- 3.4.5 DCT and Quantization 83 -- 3.4.6 Procedures Performed at the Decoder 84 -- 3.5 Wavelet-Based Video Compression 86 -- 3.5.1 Motion-Compensated Temporal Wavelet Transform Using Lifting 90 -- References 94 -- 4 4G Wireless Communications and Networking 97 -- 4.1 IMT-Advanced and 4G 97 -- 4.2 LTE 99 -- 4.2.1 Introduction 101 -- 4.2.2 Protocol Architecture 102 -- 4.2.3 LTE Layer 2 107 -- 4.2.4 The Evolution of Architecture 110 -- 4.2.5 LTE Standardization 110 -- 4.3 WIMAX-IEEE 802.16m 112 -- 4.3.1 Network Architecture 113 -- 4.3.2 System Reference Model 114 -- 4.3.3 Protocol Structure 114 -- 4.3.4 Other Functions Supported by IEEE 802.16m for Further Study 125 -- 4.4 3GPP2 UMB 125 -- 4.4.1 Architecture Reference Model 126 -- 4.4.2 Layering Architecture and Protocols 127 -- Acknowledgements 133 -- References 133 -- 5 Advanced Video Coding (AVC)/H.264 Standard 135 -- 5.1 Digital Video Compression Standards 135 -- 5.2 AVC/H.264 Coding Algorithm 138 -- 5.2.1 Temporal Prediction 139 -- 5.2.2 Spatial Prediction 147 -- 5.2.3 The Transform 148 -- 5.2.4 Quantization and Scaling 151 -- 5.2.5 Scanning 151 -- 5.2.6 Variable Length Lossless Codecs 152 -- 5.2.7 Deblocking Filter 155 -- 5.2.8 Hierarchy in the Coded Video 156 -- 5.2.9 Buffers 158 -- 5.2.10 Encapsulation/Packetization 159 -- 5.2.11 Profiles 160 -- 5.2.12 Levels 163 -- 5.2.13 Parameter Sets 167 -- 5.2.14 Supplemental Enhancement Information (SEI) 167 -- 5.2.15 Subjective Tests 168 -- References 168 -- 6 Content Analysis for Communications 171 -- 6.1 Introduction 171 -- 6.2 Content Analysis 173 -- 6.2.1 Low-Level Feature Extraction 174 -- 6.2.2 Image Segmentation 179 -- 6.2.3 Video Object Segmentation 185.
505 8 _a6.2.4 Video Structure Understanding 200 -- 6.2.5 Analysis Methods in Compressed Domain 208 -- 6.3 Content-Based Video Representation 209 -- 6.4 Content-Based Video Coding and Communications 212 -- 6.4.1 Object-Based Video Coding 212 -- 6.4.2 Error Resilience for Object-Based Video 215 -- 6.5 Content Description and Management 217 -- 6.5.1 MPEG-7 217 -- 6.5.2 MPEG-21 219 -- References 219 -- 7 Video Error Resilience and Error Concealment 223 -- 7.1 Introduction 223 -- 7.2 Error Resilience 224 -- 7.2.1 Resynchronization Markers 224 -- 7.2.2 Reversible Variable Length Coding (RVLC) 225 -- 7.2.3 Error-Resilient Entropy Coding (EREC) 226 -- 7.2.4 Independent Segment Decoding 228 -- 7.2.5 Insertion of Intra Blocks or Frames 228 -- 7.2.6 Scalable Coding 229 -- 7.2.7 Multiple Description Coding 230 -- 7.3 Channel Coding 232 -- 7.4 Error Concealment 234 -- 7.4.1 Intra Error Concealment Techniques 234 -- 7.4.2 Inter Error Concealment Techniques 234 -- 7.5 Error Resilience Features of H.264/AVC 236 -- 7.5.1 Picture Segmentation 236 -- 7.5.2 Intra Placement 236 -- 7.5.3 Reference Picture Selection 237 -- 7.5.4 Data Partitioning 237 -- 7.5.5 Parameter Sets 237 -- 7.5.6 Flexible Macroblock Ordering 238 -- 7.5.7 Redundant Slices (RSs) 239 -- References 239 -- 8 Cross-Layer Optimized Video Delivery over 4G Wireless Networks 241 -- 8.1 Why Cross-Layer Design? 241 -- 8.2 Quality-Driven Cross-Layer Framework 242 -- 8.3 Application Layer 244 -- 8.4 Rate Control at the Transport Layer 244 -- 8.4.1 Background 244 -- 8.4.2 System Model 246 -- 8.4.3 Network Setting 246 -- 8.4.4 Problem Formulation 248 -- 8.4.5 Problem Solution 248 -- 8.4.6 Performance Evaluation 249 -- 8.5 Routing at the Network Layer 252 -- 8.5.1 Background 252 -- 8.5.2 System Model 254 -- 8.5.3 Routing Metric 255 -- 8.5.4 Problem Formulation 257 -- 8.5.5 Problem Solution 258 -- 8.5.6 Implementation Considerations 262 -- 8.5.7 Performance Evaluation 263 -- 8.6 Content-Aware Real-Time Video Streaming 265 -- 8.6.1 Background 265.
505 8 _a8.6.2 Background 265 -- 8.6.3 Problem Formulation 266 -- 8.6.4 Routing Based on Priority Queuing 267 -- 8.6.5 Problem Solution 269 -- 8.6.6 Performance Evaluation 270 -- 8.7 Cross-Layer Optimization for Video Summary Transmission 272 -- 8.7.1 Background 272 -- 8.7.2 Problem Formulation 274 -- 8.7.3 System Model 276 -- 8.7.4 Link Adaptation for Good Content Coverage 278 -- 8.7.5 Problem Solution 280 -- 8.7.6 Performance Evaluation 283 -- 8.8 Conclusions 287 -- References 287 -- 9 Content-based Video Communications 291 -- 9.1 Network-Adaptive Video Object Encoding 291 -- 9.2 Joint Source Coding and Unequal Error Protection 294 -- 9.2.1 Problem Formulation 295 -- 9.2.2 Solution and Implementation Details 299 -- 9.2.3 Application on Energy-Efficient Wireless Network 301 -- 9.2.4 Application on Differentiated Services Networks 303 -- 9.3 Joint Source-Channel Coding with Utilization of Data Hiding 305 -- 9.3.1 Hiding Shape in Texture 308 -- 9.3.2 Joint Source-Channel Coding 309 -- 9.3.3 Joint Source-Channel Coding and Data Hiding 311 -- 9.3.4 Experimental Results 315 -- References 322 -- 10 AVC/H.264 Application / Digital TV 325 -- 10.1 Introduction 325 -- 10.1.1 Encoder Flexibility 326 -- 10.2 Random Access 326 -- 10.2.1 GOP Bazaar 327 -- 10.2.2 Buffers, Before and After 332 -- 10.3 Bitstream Splicing 335 -- 10.4 Trick Modes 337 -- 10.4.1 Fast Forward 338 -- 10.4.2 Reverse 338 -- 10.4.3 Pause 338 -- 10.5 Carriage of AVC/H.264 Over MPEG-2 Systems 338 -- 10.5.1 Packetization 339 -- 10.5.2 Audio Video Synchronization 344 -- 10.5.3 Transmitter and Receiver Clock Synchronization 344 -- 10.5.4 System Target Decoder and Timing Model 344 -- References 345 -- 11 Interactive Video Communications 347 -- 11.1 Video Conferencing and Telephony 347 -- 11.1.1 IP and Broadband Video Telephony 347 -- 11.1.2 Wireless Video Telephony 348 -- 11.1.3 3G-324M Protocol 348 -- 11.2 Region-of-Interest Video Communications 351 -- 11.2.1 ROI based Bit Allocation 351 -- 11.2.2 Content Adaptive Background Skipping 356.
505 8 _aReferences 366 -- 12 Wireless Video Streaming 369 -- 12.1 Introduction 369 -- 12.2 Streaming System Architecture 370 -- 12.2.1 Video Compression 370 -- 12.2.2 Application Layer QoS Control 372 -- 12.2.3 Protocols 374 -- 12.2.4 Video/Audio Synchronization 376 -- 12.3 Delay-Constrained Retransmission 377 -- 12.3.1 Receiver-Based Control 378 -- 12.3.2 Sender-Based Control 378 -- 12.3.3 Hybrid Control 379 -- 12.3.4 Rate-Distortion Optimal Retransmission 379 -- 12.4 Considerations for Wireless Video Streaming 382 -- 12.4.1 Cross-Layer Optimization and Physical Layer Consideration 383 -- 12.5 P2P Video Streaming 384 -- References 385 -- Index 389.
506 _aRestricted to subscribers or individual electronic text purchasers.
520 _aA comprehensive presentation of the video communication techniques and systems, this book examines 4G wireless systems which are set to revolutionise ubiquitous multimedia communication. 4G Wireless Video Communications covers the fundamental theory and looks at systems' descriptions with a focus on digital video. It addresses the key topics associated with multimedia communication on 4G networks, including advanced video coding standards, error resilience and error concealment techniques, as well as advanced content-analysis and adaptation techniques for video communications, cross-layer design and optimization frameworks and methods. It also provides a high-level overview of the digital video compression standard MPEG-4 AVC/H.264 that is expected to play a key role in 4G networks. Material is presented logically allowing readers to turn directly to specific points of interest. The first half of the book covers fundamental theory and systems, while the second half moves onto advanced techniques and applications. This book is a timely reflection of the latest advances in video communications for 4G wireless systems. * One of the first books to study the latest video communications developments for emerging 4G wireless systems * Considers challenges and techniques in video delivery over 4G wireless systems * Examines system architecture, key techniques and related standards of advanced wireless multimedia applications * Written from both the perspective of industry and academia.
530 _aAlso available in print.
538 _aMode of access: World Wide Web
588 _aDescription based on PDF viewed 10/24/2017.
650 0 _aMultimedia communications.
_96134
650 0 _aWireless communication systems.
_93474
650 0 _aVideo telephone.
_930088
655 0 _aElectronic books.
_93294
700 1 _aWang, Haohong,
_d1973-
_930244
710 2 _aIEEE Xplore (Online Service),
_edistributor.
_930245
710 2 _aWiley,
_epublisher.
_930246
776 0 8 _iPrint version:
_z9780470773079
830 0 _aWireless communications and mobile computing
_930247
856 4 2 _3Abstract with links to resource
_uhttps://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=8039799
942 _cEBK
999 _c74783
_d74783