Coding for MIMO Communication Systems is a comprehensive introduction and overview to the various emerging coding techniques developed for MIMO communication systems. The basics of wireless communications and fundamental issues of MIMO channel capacity are introduced and the space-time block and trellis coding techniques are covered in detail. Other signaling schemes for MIMO channels are also considered, including spatial multiplexing, concatenated coding and iterative decoding for MIMO systems, and space-time coding for non-coherent MIMO channels. Practical issues including channel…mehr
Coding for MIMO Communication Systems is a comprehensive introduction and overview to the various emerging coding techniques developed for MIMO communication systems. The basics of wireless communications and fundamental issues of MIMO channel capacity are introduced and the space-time block and trellis coding techniques are covered in detail. Other signaling schemes for MIMO channels are also considered, including spatial multiplexing, concatenated coding and iterative decoding for MIMO systems, and space-time coding for non-coherent MIMO channels. Practical issues including channel correlation, channel estimation and antenna selection are also explored, with problems at the end of each chapter to clarify many important topics.
_ A comprehensive book on coding for MIMO techniques covering main strategies _ Theories and practical issues on MIMO communications are examined in detail _ Easy to follow and accessible for both beginners and experienced practitioners in the field _ References at the end of each chapter for further reading _ Can be used with ease as a research book, or a textbook on a graduate or advanced undergraduate level course
This book is aimed at advanced undergraduate and postgraduate students, researchers and practitioners in industry, as well as individuals working for government, military, science and technology institutions who would like to learn more about coding for MIMO communication systems.
Tolga M. Duman received the B.S. degree from Bilkent University, Ankara, Turkey, in 1993, M.S. and Ph.D. degrees from Northeastern University, Boston, in 1995 and 1998, respectively, all in electrical engineering. Since August 1998, he has been with the electrical Engineering Department of Arizona State University, first as an Assistant Professor (1998-2004), and currently as an Associate Professor. He spent the 2004-05 academic year as a visiting associate professor at Bilkent University in Turkey. Dr. Duman's current research interests are in digital communications, wireless and mobile communications, MIMO systems, channel coding, underwater acoustic communications, and applications of coding to wireless and recording channels. Dr. Duman is a recipient of the National Science Foundation CAREER Award and IEEE Third Millennium medal. He is a senior member of IEEE, and an editor for IEEE Transactions on Wireless Communications and IEEE Transactions on communications. Ali Ghrayeb received the Ph.D. degree in electrical engineering from the University of Arizona, Tucson, AZ, in May 2000. He is currently an Associate Professor in the Department of Electrical and Computer Engineering, Concordia University, Montreal, Canada. He holds a Concordia Research Chair in High-Speed Wireless Communications. His research interests are in wireless and mobile communications, wireless networks, and coding and signal processing for data transmission and storage. He has co-instructed technical tutorials and short courses on coding for MIMO Systems and on Synchronization for WCDMA Systems at several major IEEE conferences. He serves as an Associate Editor for IEEE Transactions on Vehicular Technology and Wiley Wireless Communications and Mobile Computing Journal.
Inhaltsangabe
Contents Preface 1 Overview 1.1 Need for MIMO Systems 1.2 MIMO Communications in Wireless Standards 1.3 Organization of the Book 1.4 Other Topics in MIMO Systems 2 Fading Channels and Diversity Techniques 2.1 Wireless Channels 2.2 Error/Outage Probabilities over Fading Channels 2.3 Diversity Techniques 2.4 Channel Coding as a Means of Time Diversity 2.5 Multiple Antennas in Wireless Communications 2.6 Chapter Summary and Further Reading 3 Capacity and Information Rates of MIMO Channels 3.1 Capacity and Information Rates of Noisy Channels 3.2 Capacity and Information Rates of AWGN and Fading Channels 3.3 Capacity of MIMO Channels 3.4 Constrained Signaling for MIMO Communications 3.5 Discussion: Why Use MIMO Systems? 3.6 Chapter Summary and Further Reading 4 Space-Time Block Codes 4.1 Transmit Diversity with Two Antennas: The Alamouti Scheme 4.2 Orthogonal Space-Time Block Codes 4.3 Quasi-Orthogonal Space-Time Block Codes 4.4 Linear Dispersion Codes 4.5 Chapter Summary and Further Reading 5 Space-Time Trellis Codes 5.1 A Simple Space-Time Trellis Code 5.2 General Space-Time Trellis Codes 5.3 Basic Space-Time Code Design Principles 5.4 Representation for Space-Time Trellis Codes for PSK Constellations 5.5 Performance Analysis for Space-Time Trellis Codes 5.6 Comparison of Space-Time Block and Trellis Codes 5.7 Chapter Summary and Further Reading 6 Layered Space-Time Codes 6.1 Basic Bell Labs Layered Space-Time (BLAST) Architectures 6.2 Diagonal BLAST (DBLAST) 6.3 Multilayered Space-Time Coding 6.4 Threaded Space-Time Codes 6.5 Other Detection Algorithms for Spatial Multiplexing Systems 6.6 Diversity/Multiplexing Gain Trade-off 6.7 Chapter Summary and Further Reading 7 Concatenated Codes and Iterative Decoding 7.1 Development of Concatenated Codes 7.2 Concatenated Codes for AWGN Channels 7.3 Concatenated Codes for MIMO Channels 7.4 Turbo Coded Modulation for MIMO Channels 7.5 Concatenated Space-Time Block Coding 7.6 Chapter Summary and Further Reading 8 Unitary and Differential Space-Time Codes 8.1 Capacity of Noncoherent MIMO Channels 8.2 Unitary Space-Time Codes 8.3 Differential Space-Time Codes 8.4 Turbo Coded Unitary Space-Time Codes 8.5 Trellis Coded Unitary Space-Time Codes 8.6 Turbo Coded Differential Space-Time Codes 8.7 Chapter Summary and Further Reading 9 Space-Time Coding for Frequency Selective Fading Channels 9.1 MIMO Frequency Selective Channels 9.2 Capacity and Information Rates of MIMO Frequency Selective Fading Channels 9.3 Space-Time Coding for MIMO FS Channels 9.4 Channel Detection for MIMO FS Channels 9.5 MIMO OFDM Systems 9.6 Chapter Summary and Further Reading 10 Practical Issues in MIMO Communications 10.1 Channel State Information Estimation 10.2 Spatial Channel Correlation for MIMO Systems 10.3 Temporal Channel Correlation 10.4 MIMO Communication System Design Issues 10.5 Chapter Summary and Further Reading 11 Antenna Selection for MIMO Systems 11.1 Capacity-based Antenna Selection 11.2 Energy-based Antenna Selection 11.3 Antenna Selection for Space-Time Trellis Codes 11.4 Antenna Selection for Space-Time Block Codes 11.5 Antenna Selection for Combined Channel Coding and Orthogonal STBCs 11.6 Antenna Selection for Frequency Selective Channels 11.7 Antenna Selection with Nonidealities 11.8 Chapter Summary and Further Reading Bibliography
Contents Preface 1 Overview 1.1 Need for MIMO Systems 1.2 MIMO Communications in Wireless Standards 1.3 Organization of the Book 1.4 Other Topics in MIMO Systems 2 Fading Channels and Diversity Techniques 2.1 Wireless Channels 2.2 Error/Outage Probabilities over Fading Channels 2.3 Diversity Techniques 2.4 Channel Coding as a Means of Time Diversity 2.5 Multiple Antennas in Wireless Communications 2.6 Chapter Summary and Further Reading 3 Capacity and Information Rates of MIMO Channels 3.1 Capacity and Information Rates of Noisy Channels 3.2 Capacity and Information Rates of AWGN and Fading Channels 3.3 Capacity of MIMO Channels 3.4 Constrained Signaling for MIMO Communications 3.5 Discussion: Why Use MIMO Systems? 3.6 Chapter Summary and Further Reading 4 Space-Time Block Codes 4.1 Transmit Diversity with Two Antennas: The Alamouti Scheme 4.2 Orthogonal Space-Time Block Codes 4.3 Quasi-Orthogonal Space-Time Block Codes 4.4 Linear Dispersion Codes 4.5 Chapter Summary and Further Reading 5 Space-Time Trellis Codes 5.1 A Simple Space-Time Trellis Code 5.2 General Space-Time Trellis Codes 5.3 Basic Space-Time Code Design Principles 5.4 Representation for Space-Time Trellis Codes for PSK Constellations 5.5 Performance Analysis for Space-Time Trellis Codes 5.6 Comparison of Space-Time Block and Trellis Codes 5.7 Chapter Summary and Further Reading 6 Layered Space-Time Codes 6.1 Basic Bell Labs Layered Space-Time (BLAST) Architectures 6.2 Diagonal BLAST (DBLAST) 6.3 Multilayered Space-Time Coding 6.4 Threaded Space-Time Codes 6.5 Other Detection Algorithms for Spatial Multiplexing Systems 6.6 Diversity/Multiplexing Gain Trade-off 6.7 Chapter Summary and Further Reading 7 Concatenated Codes and Iterative Decoding 7.1 Development of Concatenated Codes 7.2 Concatenated Codes for AWGN Channels 7.3 Concatenated Codes for MIMO Channels 7.4 Turbo Coded Modulation for MIMO Channels 7.5 Concatenated Space-Time Block Coding 7.6 Chapter Summary and Further Reading 8 Unitary and Differential Space-Time Codes 8.1 Capacity of Noncoherent MIMO Channels 8.2 Unitary Space-Time Codes 8.3 Differential Space-Time Codes 8.4 Turbo Coded Unitary Space-Time Codes 8.5 Trellis Coded Unitary Space-Time Codes 8.6 Turbo Coded Differential Space-Time Codes 8.7 Chapter Summary and Further Reading 9 Space-Time Coding for Frequency Selective Fading Channels 9.1 MIMO Frequency Selective Channels 9.2 Capacity and Information Rates of MIMO Frequency Selective Fading Channels 9.3 Space-Time Coding for MIMO FS Channels 9.4 Channel Detection for MIMO FS Channels 9.5 MIMO OFDM Systems 9.6 Chapter Summary and Further Reading 10 Practical Issues in MIMO Communications 10.1 Channel State Information Estimation 10.2 Spatial Channel Correlation for MIMO Systems 10.3 Temporal Channel Correlation 10.4 MIMO Communication System Design Issues 10.5 Chapter Summary and Further Reading 11 Antenna Selection for MIMO Systems 11.1 Capacity-based Antenna Selection 11.2 Energy-based Antenna Selection 11.3 Antenna Selection for Space-Time Trellis Codes 11.4 Antenna Selection for Space-Time Block Codes 11.5 Antenna Selection for Combined Channel Coding and Orthogonal STBCs 11.6 Antenna Selection for Frequency Selective Channels 11.7 Antenna Selection with Nonidealities 11.8 Chapter Summary and Further Reading Bibliography
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