LEADER 20439nam 2200793 450 001 9910144581803321 005 20221206094424.0 010 $a1-281-13536-4 010 $a9786611135362 010 $a0-470-51992-4 010 $a0-470-51991-6 024 7 $a10.1002/9780470519929 035 $a(CKB)1000000000376947 035 $a(EBL)326418 035 $a(SSID)ssj0000267382 035 $a(PQKBManifestationID)11239425 035 $a(PQKBTitleCode)TC0000267382 035 $a(PQKBWorkID)10333554 035 $a(PQKB)11381529 035 $a(MiAaPQ)EBC326418 035 $a(CaBNVSL)mat05361040 035 $a(IDAMS)0b00006481178868 035 $a(IEEE)5361040 035 $a(PPN)254673759 035 $a(OCoLC)181368622 035 $a(EXLCZ)991000000000376947 100 $a20071116h20152007 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 10$aVideo compression and communications $efrom basics to H.261, H.263, H.264, MPEG2, MPEG4 for DVB and HSDPA-style adaptive turbo-transceivers /$fL. Hanzo, P.J. Cherriman and J. Streit 205 $a2nd ed. 210 1$aHoboken, New Jersey :$cIEEE Press,$dc2007. 210 2$a[Piscataqay, New Jersey] :$cIEEE Xplore,$d[2008] 215 $a1 online resource (703 p.) 300 $aDescription based upon print version of record. 311 $a0-470-51849-9 320 $aIncludes bibliographical references (p. [635]-658) and indexes. 327 $aAbout the Authors -- Other Wiley and IEEE Press Books on Related Topics -- Preface -- Acknowledgments -- 1 Introduction -- 1.1 A Brief Introduction to Compression Theory -- 1.2 Introduction to Video Formats -- 1.3 Evolution of Video Compression Standards -- 1.3.1 The International Telecommunications Union's H.120 Standard -- 1.3.2 Joint Photographic Expert Group -- 1.3.3 The ITU H.261 Standard -- 1.3.4 The Motion Pictures Expert Group -- 1.3.5 The MPEG-2 Standard -- 1.3.6 The ITU H.263 Standard -- 1.3.7 The ITU H.263+/H.263++ Standards -- 1.3.8 The MPEG-4 Standard -- 1.3.9 The H.26L/H.264 Standard -- 1.4 Video Communications -- 1.5 Organisation of the Monograph -- I Video Codecs for HSDPA-Style Adaptive Videophones -- 2 Fractal Image Codecs -- 2.1 Fractal Principles -- 2.2 One-Dimensional Fractal Coding -- 2.2.1 Fractal Codec Design -- 2.2.2 Fractal Codec Performance -- 2.3 Error Sensitivity and Complexity -- 2.4 Summary and Conclusions -- 3 Low Bit-Rate DCT Codecs and HSDPA-Style Videophones -- 3.1 Video Codec Outline -- 3.2 The Principle of Motion Compensation -- 3.2.1 Distance Measures -- 3.2.2 Motion Search Algorithms -- 3.2.2.1 Full or Exhaustive Motion Search -- 3.2.2.2 Gradient-Based Motion Estimation -- 3.2.2.3 Hierarchical or Tree Search -- 3.2.2.4 Subsampling Search -- 3.2.2.5 Post-Processing of Motion Vectors -- 3.2.2.6 Gain-Cost-Controlled Motion Compensation -- 3.2.3 Other Motion Estimation Techniques -- 3.2.3.1 Pel-Recursive Displacement Estimation -- 3.2.3.2 Grid Interpolation Techniques -- 3.2.3.3 MC Using Higher Order Transformations -- 3.2.3.4 MC in the Transform Domain -- 3.2.4 Conclusion -- 3.3 Transform Coding -- 3.3.1 One-Dimensional Transform Coding -- 3.3.2 Two-Dimensional Transform Coding -- 3.3.3 Quantizer Training for Single-Class DCT -- 3.3.4 Quantizer Training for Multiclass DCT -- 3.4 The Codec Outline -- 3.5 Initial Intra-Frame Coding -- 3.6 Gain-Controlled Motion Compensation -- 3.7 The MCER Active/Passive Concept -- 3.8 Partial Forced Update of the Reconstructed Frame Buffers. 327 $a3.9 The Gain/Cost-Controlled Inter-Frame Codec -- 3.9.1 Complexity Considerations and Reduction Techniques -- 3.10 The Bit-Allocation Strategy -- 3.11 Results -- 3.12 DCT Codec Performance under Erroneous Conditions -- 3.12.1 Bit Sensitivity -- 3.12.2 Bit Sensitivity of Codec I and II -- 3.13 DCT-Based Low-Rate Video Transceivers -- 3.13.1 Choice of Modem -- 3.13.2 Source-Matched Transceiver -- 3.13.2.1 System 1 -- 3.13.2.1.1 System Concept -- 3.13.2.1.2 Sensitivity-Matched Modulation -- 3.13.2.1.3 Source Sensitivity -- 3.13.2.1.4 Forward Error Correction -- 3.13.2.1.5 Transmission Format -- 3.13.2.2 System 2 -- 3.13.2.2.1 Automatic Repeat Request -- 3.13.2.3 Systems 3-5 -- 3.14 System Performance -- 3.14.1 Performance of System 1 -- 3.14.2 Performance of System 2 -- 3.14.2.1 FER Performance -- 3.14.2.2 Slot Occupancy Performance -- 3.14.2.3 PSNR Performance -- 3.14.3 Performance of Systems 3-5 -- 3.15 Summary and Conclusions -- 4 Low Bit-Rate VQ Codecs and HSDPA-Style Videophones -- 4.1 Introduction -- 4.2 The Codebook Design -- 4.3 The Vector Quantizer Design -- 4.3.1 Mean and Shape Gain Vector Quantization -- 4.3.2 Adaptive Vector Quantization -- 4.3.3 Classified Vector Quantization -- 4.3.4 Algorithmic Complexity -- 4.4 Performance under Erroneous Conditions -- 4.4.1 Bit-Allocation Strategy -- 4.4.2 Bit Sensitivity -- 4.5 VQ-Based Low-Rate Video Transceivers -- 4.5.1 Choice of Modulation -- 4.5.2 Forward Error Correction -- 4.5.3 Architecture of System 1 -- 4.5.4 Architecture of System 2 -- 4.5.5 Architecture of Systems 3-6 -- 4.6 System Performance -- 4.6.1 Simulation Environment -- 4.6.2 Performance of Systems 1 and 3 -- 4.6.3 Performance of Systems 4 and 5 -- 4.6.4 Performance of Systems 2 and 6 -- 4.7 Joint Iterative Decoding of Trellis-Based VQ-Video and TCM -- 4.7.1 Introduction -- 4.7.2 System Overview -- 4.7.3 Compression -- 4.7.4 Vector quantization decomposition -- 4.7.5 Serial concatenation and iterative decoding -- 4.7.6 Transmission Frame Structure. 327 $a4.7.7 Frame difference decomposition -- 4.7.8 VQ codebook -- 4.7.9 VQ-induced code constraints -- 4.7.10 VQ trellis structure -- 4.7.11 VQ Encoding -- 4.7.12 VQ Decoding -- 4.7.13 Results -- 4.8 Summary and Conclusions -- 5 Low Bit-Rate Quad-Tree-Based Codecs and HSDPA-Style Videophones. -- 5.1 Introduction -- 5.2 Quad-Tree Decomposition -- 5.3 Quad-Tree Intensity Match -- 5.3.1 Zero-Order Intensity Match -- 5.3.2 First-Order Intensity Match -- 5.3.3 Decomposition Algorithmic Issues -- 5.4 Model-Based Parametric Enhancement -- 5.4.1 Eye and Mouth Detection -- 5.4.2 Parametric Codebook Training -- 5.4.3 Parametric Encoding -- 5.5 The Enhanced QT Codec -- 5.6 Performance under Erroneous Conditions -- 5.6.1 Bit Allocation -- 5.6.2 Bit Sensitivity -- 5.7 QT-Codec-Based Video Transceivers -- 5.7.1 Channel Coding and Modulation -- 5.7.2 QT-Based Transceiver Architectures -- 5.8 QT-Based Video-Transceiver Performance -- 5.9 Summary of QT-Based Video Transceivers -- 5.10 Summary of Low-Rate Codecs/Transceivers -- II High-Resolution Video Coding -- 6 Low-Complexity Techniques -- 6.1 Differential Pulse Code Modulation -- 6.1.1 Basic Differential Pulse Code Modulation -- 6.1.2 Intra/Inter-Frame Differential Pulse Code Modulation -- 6.1.3 Adaptive Differential Pulse Code Modulation -- 6.2 Block Truncation Coding -- 6.2.1 The Block Truncation Algorithm -- 6.2.2 Block Truncation Codec Implementations -- 6.2.3 Intra-Frame Block Truncation Coding -- 6.2.4 Inter-Frame Block Truncation Coding -- 6.3 Subband Coding -- 6.3.1 Perfect Reconstruction Quadrature Mirror Filtering -- 6.3.1.1 Analysis Filtering -- 6.3.1.2 Synthesis Filtering -- 6.3.1.3 Practical QMF Design Constraints -- 6.3.2 Practical Quadrature Mirror Filters -- 6.3.3 Run-Length-Based Intra-Frame Subband Coding. -- 6.3.4 Max-Lloyd-Based Subband Coding -- 6.4 Summary and Conclusions -- 7 High-Resolution DCT Coding -- 7.1 Introduction -- 7.2 Intra-Frame Quantizer Training -- 7.3 Motion Compensation for High-Quality Images. 327 $a7.4 Inter-Frame DCT Coding -- 7.4.1 Properties of the DCT transformed MCER -- 7.4.2 Joint Motion Compensation and Residual Encoding -- 7.5 The Proposed Codec -- 7.5.1 Motion Compensation -- 7.5.2 The Inter/Intra-DCT Codec -- 7.5.3 Frame Alignment -- 7.5.4 Bit-Allocation -- 7.5.5 The Codec Performance -- 7.5.6 Error Sensitivity and Complexity -- 7.6 Summary and Conclusions -- III H.261, H.263, H.264, MPEG2 and MPEG 4 forHSDPA-Style Wireless Video Telephony and DVB -- 8 H.261 for HSDPA-Style Wireless Video Telephony -- 8.1 Introduction -- 8.2 The H.261 Video Coding Standard -- 8.2.1 Overview -- 8.2.2 Source Encoder -- 8.2.3 Coding Control -- 8.2.4 Video Multiplex Coder -- 8.2.4.1 Picture Layer -- 8.2.4.2 Group of Blocks Layer -- 8.2.4.3 Macroblock Layer -- 8.2.4.4 Block Layer -- 8.2.5 Simulated Coding Statistics -- 8.2.5.1 Fixed-Quantizer Coding -- 8.2.5.2 Variable Quantizer Coding -- 8.3 Effect of Transmission Errors on the H.261 Codec -- 8.3.1 Error Mechanisms -- 8.3.2 Error Control Mechanisms -- 8.3.2.1 Background -- 8.3.2.2 Intra-Frame Coding -- 8.3.2.3 Automatic Repeat Request -- 8.3.2.4 Reconfigurable Modulations Schemes -- 8.3.2.5 Combined Source/Channel Coding -- 8.3.3 Error Recovery -- 8.3.4 Effects of Errors -- 8.3.4.1 Qualitative Effect of Errors on H.261 Parameters -- 8.3.4.2 Quantitative Effect of Errors on a H.261 Data Stream -- 8.3.4.2.1 Errors in an Intra-Coded Frame -- 8.3.4.2.2 Errors in an Inter-Coded Frame -- 8.3.4.2.3 Errors in Quantizer Indices -- 8.3.4.2.4 Errors in an Inter-Coded Frame withMotion Vectors -- 8.3.4.2.5 Errors in an Inter-Coded Frame at Low Rate -- 8.4 A Reconfigurable Wireless Videophone System -- 8.4.1 Introduction -- 8.4.2 Objectives -- 8.4.3 Bit-Rate Reduction of the H.261 Codec -- 8.4.4 Investigation of Macroblock Size -- 8.4.5 Error Correction Coding -- 8.4.6 Packetization Algorithm -- 8.4.6.1 Encoding History List -- 8.4.6.2 Macroblock Compounding -- 8.4.6.3 End of Frame Effect -- 8.4.6.4 Packet Transmission Feedback -- 8.4.6.5 Packet Truncation and Compounding Algorithms. 327 $a8.5 H.261-Based Wireless Videophone System Performance -- 8.5.2 System Performance -- 8.6 Summary and Conclusions -- 9 Comparison of the H.261 and H.263 Codecs -- 9.1 Introduction -- 9.2 The H.263 Coding Algorithms -- 9.2.1 Source Encoder -- 9.2.1.1 Prediction -- 9.2.1.2 Motion Compensation and Transform Coding -- 9.2.1.3 Quantization -- 9.2.2 Video Multiplex Coder -- 9.2.2.1 Picture Layer -- 9.2.2.2 Group of Blocks Layer -- 9.2.2.3 H.261 Macroblock Layer -- 9.2.2.4 H.263 Macroblock Layer -- 9.2.2.5 Block Layer -- 9.2.3 Motion Compensation -- 9.2.3.1 H.263 Motion Vector Predictor -- 9.2.3.2 H.263 Subpixel Interpolation -- 9.2.4 H.263 Negotiable Options -- 9.2.4.1 Unrestricted Motion Vector Mode -- 9.2.4.2 Syntax-Based Arithmetic Coding Mode -- 9.2.4.2.1 Arithmetic coding [1] -- 9.2.4.3 Advanced Prediction Mode -- 9.2.4.3.1 Four Motion Vectors per Macroblock -- 9.2.4.3.2 Overlapped Motion Compensation for Luminance -- 9.2.4.4 P-B Frames Mode -- 9.3 Performance Results -- 9.3.1 Introduction -- 9.3.2 H.261 Performance -- 9.3.3 H.261/H.263 Performance Comparison -- 9.3.4 H.263 Codec Performance -- 9.3.4.1 Gray-Scale versus Color Comparison -- 9.3.4.2 Comparison of QCIF Resolution Color Video -- 9.3.4.3 Coding Performance at Various Resolutions -- 9.4 Summary and Conclusions -- 10 H.263 for HSDPA-Style Wireless Video Telephony -- 10.1 Introduction -- 10.2 H.263 in a Mobile Environment -- 10.2.1 Problems of Using H.263 in a Mobile Environment -- 10.2.2 Possible Solutions for Using H.263 in a Mobile Environment. -- 10.2.2.1 Coding Video Sequences Using Exclusively Intra-Coded Frames -- 10.2.2.2 Automatic Repeat Requests -- 10.2.2.3 Multimode Modulation Schemes -- 10.2.2.4 Combined Source/Channel Coding -- 10.3 Design of an Error-Resilient Reconfigurable Videophone System -- 10.3.1 Introduction -- 10.3.2 Controling the Bit Rate -- 10.3.3 Employing FEC Codes in the Videophone System -- 10.3.4 Transmission Packet Structure -- 10.3.5 Coding Parameter History List -- 10.3.6 The Packetization Algorithm. 327 $a10.3.6.1 Operational Scenarios of the Packetizing Algorithm -- 10.4 H.263-Based Video System Performance -- 10.4.1 System Environment -- 10.4.2 Performance Results -- 10.4.2.1 Error-Free Transmission Results -- 10.4.2.2 Effect of Packet Dropping on Image Quality -- 10.4.2.3 Image Quality versus Channel Quality without ARQ -- 10.4.2.4 Image Quality versus Channel Quality with ARQ -- 10.4.3 Comparison of H.263 and H.261-Based Systems -- 10.4.3.1 Performance with Antenna Diversity -- 10.4.3.2 Performance over DECT Channels -- 10.5 Transmission Feedback -- 10.5.1 ARQ Issues -- 10.5.2 Implementation of Transmission Feedback -- 10.5.2.1 Majority Logic Coding -- 10.6 Summary and Conclusions -- 11 MPEG-4 Video Compression -- 11.1 Introduction -- 11.2 Overview of MPEG-4 -- 11.2.1 MPEG-4 Profiles -- 11.2.2 MPEG-4 Features -- 11.2.3 MPEG-4 Object Based Orientation -- 11.3 MPEG-4 : Content-Based Interactivity -- 11.3.1 Video Object Plane Based Encoding -- 11.3.2 Motion and Texture Encoding -- 11.3.3 Shape Coding -- 11.3.3.1 VOP Shape Encoding -- 11.3.3.2 Gray Scale Shape Coding -- 11.4 Scalability of Video Objects -- 11.5 Video Quality Measures -- 11.5.1 Subjective Video Quality Evaluation -- 11.5.2 Objective Video Quality -- 11.6 Effect of Coding Parameters. -- 11.7 Summary and Conclusion -- 12 Comparative Study of the MPEG-4 and H.264 Codecs -- 12.1 Introduction -- 12.2 The ITU-T H.264 Project -- 12.3 H.264 Video Coding Techniques -- 12.3.1 H.264 Encoder -- 12.3.2 H.264 Decoder -- 12.4 H.264 Specific Coding Algorithm -- 12.4.1 Intra-frame Prediction -- 12.4.2 Inter-frame Prediction -- 12.4.2.1 Block Sizes -- 12.4.2.2 Motion Estimation Accuracy -- 12.4.2.3 Multiple Reference Frame Selection for Motion Compensation -- 12.4.2.4 De-blocking Filter -- 12.4.3 Integer Transform -- 12.4.3.1 Development of the 4 4-pixel Integer DCT -- 12.4.3.2 Quantisation -- 12.4.3.3 The Combined Transform, Quantisation, Rescaling and Inverse Transform Process -- 12.4.3.4 Integer Transform Example. 327 $a12.4.4 Entropy Coding -- 12.4.4.1 Universal Variable Length Coding -- 12.4.4.2 Context-Based Adaptive Binary Arithmetic Coding -- 12.4.4.3 H.264 Conclusion -- 12.5 Comparative Study of the MPEG-4 and H.264 Codecs -- 12.5.1 Introduction -- 12.5.2 Intra-frame Coding and Prediction -- 12.5.3 Inter-frame Prediction and Motion Compensation -- 12.5.4 Transform Coding and Quantisation -- 12.5.5 Entropy Coding -- 12.5.6 De-blocking Filter -- 12.6 Performance Results -- 12.6.1 Introduction -- 12.6.2 MPEG-4 Performance -- 12.6.3 H.264 Performance -- 12.6.4 Comparative Study -- 12.6.5 Summary and Conclusions -- 13 MPEG-4 Bitstream and Bit-Sensitivity Study -- 13.1 Motivation -- 13.2 Structure of Coded Visual Data -- 13.3 Visual Bitstream Syntax -- 13.3.1 Start Codes -- 13.4 Introduction to Error-Resilient Video Encoding -- 13.5 Error-Resilient Video Coding in MPEG-4 -- 13.6 Error Resilience Tools in MPEG-4 -- 13.6.1 Resynchronisation -- 13.6.2 Data Partitioning -- 13.6.3 Reversible Variable-Length Codes -- 13.6.4 Header Extension Code -- 13.7 MPEG-4 Bit-Sensitivity Study -- 13.7.1 Objectives -- 13.7.2 Introduction -- 13.7.3 Simulated Coding Statistics -- 13.7.4 Effects of Errors -- 13.8 Chapter Conclusions -- 14 HSDPA-Like and Turbo-Style Adaptive Single- and Multi-Carrier Video Systems -- 14.1 Turbo-equalised H.263-based videophony for GSM/GPRS -- 14.1.1 Motivation and Background -- 14.1.2 System Parameters -- 14.1.3 Turbo Equalization -- 14.1.4 Turbo-equalization Performance -- 14.1.4.1 Video Performance -- 14.1.4.2 Bit Error Statistics -- 14.1.5 Summary and Conclusions -- 14.2 HSDPA-Style Burst-by-burst Adaptive CDMA Videophony -- 14.2.1 Motivation and Video Transceiver Overview -- 14.2.2 Multimode Video System Performance -- 14.2.3 Burst-by-Burst Adaptive Videophone System -- 14.2.4 Summary and Conclusions -- 14.3 Adaptive Turbo-Coded OFDM-Based Videotelephony. -- 14.3.1 Motivation and Background -- 14.3.2 AOFDM Modem Mode Adaptation and Signaling -- 14.3.3 AOFDM Subband BER Estimation. 327 $a14.3.4 Video Compression and Transmission Aspects -- 14.3.5 Comparison of Subband-Adaptive OFDM and Fixed Mode -- OFDM Transceivers -- 14.3.6 Subband-Adaptive OFDM Transceivers Having Different Target Bit Rates -- 14.3.7 Time-Variant Target Bit Rate OFDM Transceivers -- 14.3.8 Summary and Conclusions -- 14.4 HSDPA-Style Adaptive TCM, TTCM and BICM for H.263 Video Telephony -- 14.4.1 Introduction -- 14.4.2 System Overview -- 14.4.2.1 System Parameters and Channel Model -- 14.4.3 Employing Fixed Modulation Modes -- 14.4.4 Employing Adaptive Modulation -- 14.4.4.1 Performance of TTCM AQAM -- 14.4.4.2 Performance of AQAMUsing TTCM, TCC, TCMand BICM -- 14.4.4.3 The Effect of Various AQAM Thresholds -- 14.4.5 TTCM AQAM in CDMA system -- 14.4.5.1 Performance of TTCM AQAM in CDMA system -- 14.4.6 Conclusions -- 14.5 Turbo-Detected MPEG-4 Video Using Multi-Level Coding, TCM and STTC -- 14.5.1 Motivation and Background -- 14.5.2 The Turbo Transceiver -- 14.5.2.1 Turbo Decoding -- 14.5.2.2 Turbo Benchmark Scheme -- 14.5.3 MIMO Channel Capacity -- 14.5.4 Convergence Analysis -- 14.5.5 Simulation results -- 14.5.6 Conclusions -- 14.6 Near-Capacity Irregular Variable Length Codes -- 14.6.1 Introduction -- 14.6.2 Overview of Proposed Schemes -- 14.6.2.1 Joint source and channel coding -- 14.6.2.2 Iterative decoding -- 14.6.3 Parameter Design for the Proposed Schemes -- 14.6.3.1 Scheme hypothesis and parameters -- 14.6.3.2 EXIT chart analysis and optimization -- 14.6.4 Results -- 14.6.4.1 Asymptotic performance following iterative decoding convergence -- 14.6.4.2 Performance during iterative decoding -- 14.6.4.3 Complexity analysis -- 14.6.5 Conclusions -- 14.7 Digital Terrestrial Video Broadcasting for Mobile Receivers -- 14.7.1 Background and Motivation -- 14.7.2 MPEG-2 Bit Error Sensitivity -- 14.7.3 DVB Terrestrial Scheme -- 14.7.4 Terrestrial Broadcast Channel Model -- 14.7.5 Data Partitioning Scheme -- 14.7.6 Performance of the Data Partitioning Scheme -- 14.7.7 Nonhierarchical OFDM DVBP Performance. 327 $a14.7.8 Hierarchical OFDM DVB Performance -- 14.7.9 Summary and Conclusions -- 14.8 Satellite-Based Video Broadcasting -- 14.8.1 Background and Motivation -- 14.8.2 DVB Satellite Scheme -- 14.8.3 Satellite Channel Model -- 14.8.4 The Blind Equalizers -- 14.8.5 Performance of the DVB Satellite Scheme -- 14.8.5.1 Transmission over the Symbol-Spaced Two-Path Channel -- 14.8.5.2 Transmission over the Two-Symbol Delay Two-Path Channel -- 14.8.5.3 Performance Summary of the DVB-S System -- 14.8.6 Summary and Conclusions -- 14.9 Summary and Conclusions -- 14.10Wireless Video System Design Principles. -- Glossary -- Bibliography -- Subject Index -- Author Index. 330 $aSince 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. 606 $aVideo compression 606 $aDigital video 606 $aMobile communication systems 615 0$aVideo compression. 615 0$aDigital video. 615 0$aMobile communication systems. 676 $a006.6/96 676 $a621.38833 700 $aHanzo$b Lajos$f1952-$028461 701 $aCherriman$b Peter J.$f1972-$0845515 701 $aStreit$b Ju?rgen$f1968-$0845516 701 $aHanzo$b Lajos$f1952-$028461 801 0$bCaBNVSL 801 1$bCaBNVSL 801 2$bCaBNVSL 906 $aBOOK 912 $a9910144581803321 996 $aVideo compression and communications$91887683 997 $aUNINA LEADER 01026nam0 22002413i 450 001 996504668803316 005 20230125120350.0 010 $a978-88-916-5886-9 100 $a20221105d2022----||||0itac50 ba 101 $aita 102 $aIT 200 1 $aConcorso funzionario esperto in gestione e controllo dei fondi europei$eFondi strutturali e PNRR$eManuale di preparazione TEORIA e TEST online$eFondi comunitari e gestione concorrente, Programmazione, gestione e controllo dei fondi strutturali, Programmazione e attuazione del PNRR$fGiorgio Centurelli 210 1 $aSantarcangelo di Romagna$cMaggioli$d2022 215 $a209 p.$d24 cm 606 0 $aPiano nazionale di ripresa e resilienza (PNRR)$xAttuazione$xManuali per concorsi$2BNCF 676 $a352.342140945 801 0$aIT$bcba$bcba$gREICAT 912 $a996504668803316 951 $aXXI.6. 786$b94441 G.$cXXI.6.$d552704 959 $aBK 969 $aGIU 996 $aConcorso funzionario esperto in gestione e controllo dei fondi europei$93004243 997 $aUNISA LEADER 05255nam 2200625Ia 450 001 9910831085403321 005 20230721033243.0 010 $a1-281-93939-0 010 $a9786611939397 010 $a0-470-69687-7 010 $a0-470-69688-5 035 $a(CKB)1000000000552962 035 $a(EBL)366784 035 $a(OCoLC)437234398 035 $a(SSID)ssj0000225840 035 $a(PQKBManifestationID)11202225 035 $a(PQKBTitleCode)TC0000225840 035 $a(PQKBWorkID)10234196 035 $a(PQKB)11672332 035 $a(MiAaPQ)EBC366784 035 $a(EXLCZ)991000000000552962 100 $a20080604d2008 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 10$aPractical lipid management$b[electronic resource] $econcepts and controversies /$fPeter P. Toth, Kevin C. Maki 210 $aChichester, West Sussex, UK ;$aHoboken, NJ $cWiley-Blackwell$d2008 215 $a1 online resource (264 p.) 300 $aDescription based upon print version of record. 311 $a0-470-05690-8 320 $aIncludes bibliographical references and index. 327 $aPractical Lipid Management; Contents; Foreword; Preface; Acknowledgements; Chapter 1 Epidemiology of Lipids, Lipid Management and Risk for Coronary Heart Disease: An Overview; 1.1 Early History of Cardiovascular Epidemiology; 1.2 Lipid Risk Factors are Central to Efforts at CHD Prevention; 1.3 LDL-C and CHD Risk; 1.4 LDL-C Lowering and CHD Risk Reduction; 1.5 Other Atherogenic Lipoproteins: Atherogenic Remnants; 1.6 HDL-C and CHD Risk; 1.7 Trends in Lipids and Lipid Management in the USA 327 $a1.8 The National Cholesterol Education Program Evaluation Project Using Novel E-Technology (NEPTUNE) II SurveyControversy: Should a Measure of Atherogenic Lipoprotein Particle Number be used in Risk Assessment And/Or to Evaluate the Response to Lipid Therapy?; Chapter 2 Vascular Biology and Atherogenesis; 2.1 Introduction; 2.2 Arterial Structure; 2.3 Endothelial Cell Function and Dysfunction; 2.4 The Role of Monocytes and Lymphocytes; 2.5 Atheromatous Plaques; Chapter 3 Detection, Evaluation, and Treatment Goals for Lipid Disorders in Adults 327 $a3.1 Matching Aggressiveness of Treatment to Absolute Risk3.2 Screening for Dyslipidemias; 3.3 Risk Stratification; 3.4 Steps in the Risk Stratification Process - Major Risk Categories; 3.5 Tips for Calculating the Framingham Risk Score; 3.6 Subcategories for Consideration of More Aggressive Optional Treatment Goals; 3.7 Very High Risk Patients, Optional LDL-C Goal <70 mg dl-1; 3.8 Moderately High Risk Patients, OPTIONAL LDL-C Goal <100 mg dl-1; 3.9 Treatment Goals for Patients with Elevated Triglycerides; 3.10 Triglycerides and HDL-C as Targets for Therapy 327 $aControversy: Should Treatment Guidelines Include Targets for the Total/HDL Cholesterol Ratio?Chapter 4 Therapeutic Lifestyle Changes in the Management of Lipid Disorders and the Metabolic Syndrome; 4.1 Nature and Nurture in the Development of CHD Risk Factors; 4.2 Lifestyle Factors as Determinants of CHD Risk in Populations; 4.3 Within Country Variations in Lifestyle and CHD Risk; 4.4 The Metabolic Syndrome; 4.5 Therapeutic Lifestyle Changes; 4.6 The TLC Diet; 4.7 Dietary Adjuncts: Viscous Fibers and Plant Sterol/Stanol Products; 4.8 Physical Activity and Weight Reduction 327 $a4.9 Smoking Cessation4.10 Importance of Allied Health Professionals; Chapter 5 Management of Elevated Low-Density Lipoprotein Cholesterol; 5.1 Relationship between LDL-C and Risk for Cardiovascular Events; 5.2 Clinical Trial Support for Very Aggressive LDL-C Reduction for Those at Highest Risk; 5.3 Genetic Disorders Associated with Elevated LDL-C; 5.4 Atherogenic Impact of LDL-C; 5.5 Management of Elevated LDL-C; 5.6 Summary; Controversy: How Low Should We Go?; Controversy: Risks and Bene.ts of High-Dose Statin Therapy Versus Combination Lipid Drug Therapy 327 $aControversy: Do the Benefits of Low-Density Lipoprotein Cholesterol Reduction Depend Strictly on "How Low You Go" or also on "How You Get There"? 330 $aLipid management is a key part of medical practice, affecting the prevention and treatment of several diseases, including diabetes, cardiovascular disease and stroke. A practical text on the clinical management of dyslipidemias, Practical Lipid Management balances conceptual development and pathophysiology with a straightforward approach to the identification and treatment of abnormalities in lipid metabolism. The book explores the role of novel risk markers in clinical practice, summarizes the current guidelines for lipid management, and offers a critical and systematic approach to i 606 $aHyperlipidemia$xTreatment 606 $aCoronary heart disease$xPrevention 615 0$aHyperlipidemia$xTreatment. 615 0$aCoronary heart disease$xPrevention. 676 $a616.3/997 676 $a616.3997 700 $aToth$b Peter P$01343554 701 $aMaki$b Kevin C$01668866 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910831085403321 996 $aPractical lipid management$94029765 997 $aUNINA