London ; ; Imperial College Press ; ; Hackensack, NJ, : Distributed by World Scientific, c2007

1-281-86764-0

9786611867645

1-86094-869-3

1 online resource (208 p.)

Communications and signal processing ; ; v. 2

GuanYong Liang

TjhungTjeng Thiang

621.3822

Space time codes

MIMO systems

Electronic books.

Inglese

Description based upon print version of record.

Includes bibliographical references (p. 184-190) and index.

Contents; Foreword; 1 . Introduction of MIMO Channel and Space-Time Block Code; 1.1 MIMO Channel for Wireless Communications; 1.2 Transmit Diversity with Space-Time Block Code; 1.3 Notations and Abbreviations; 1.4 Signal Model of MIMO Channel and STBC; 1.4.1 Signal model of MIMO channel; 1.4.2 Signal model of STBC; 1.5 Design Criteria and Performance Measure of STBC; 2 . Orthogonal and Quasi-Orthogonal Space-Time Block Code; 2.1 Orthogonal Space-Time Block Code; 2.1.1 Benefits of 0-STBC; 2.1.2 Background of amicable orthogonal design; 2.1.3 Construction of 0-STBC and its rate limitation

2.2 Quasi-Orthogonal Space-Time Block Code2.2.1 Approaching capacity with low decoding complexity; 2.2.2 Performance optimization of QO-STBC; 2.2.2.1 Full-diversity QO-STBC with constellation rotation; 2.2.2.2 Full-diversity QO-STBC without constellation rotation; 2.2.3 Remark; 3 . Insights of QO-STBC; 3.1 Algebraic Structure of QO-STBC; 3.1.1 Decoding complexity of a QO-STBC; 3.1.2 Maximal symbol-wise diversity of a QO-STBC; 3.2 Generalized Decoding Framework of QO-STBC; 3.3 Impact of Constellation Rotation on the Decoding Complexity

of QO-STBC

3.3.1 Simplified QO-STBC model with real symbols only3.3.2 Decoding complexity of QO-STBC with CR; 3.4 Group-Constrained Linear Transformation; 3.4.1 Definition of GCLT; 3.4.2 Optimization of GCLT parameters; 3.4.2.1 GCLT of J4; 3.4.2.2 GCLT of J8; 3.4.2.3 GCLTof TBH8; 3.4.3 Performance comparison; 3.4.3.1 ML decoding complexity; 3.4.3.2 Decoding performance; 3.5 Chapter Summary; 4 . Quasi-Orthogonal Space-Time Block Code with Minimum Decoding Complexity; 4.1 Algebraic Structure of MDC-QOSTBC; 4.2 Square MDC-QOSTBC Design; 4.2.1 Definition of preferred AOD pair

4.2.2 Relationship between MDC-QOSTBC and AOD through preferred AOD pair4.2.3 Lower bound on the code rate for square design; 4.2.4 Construction of preferred AOD pair; 4.2.4.1 Quaternion; 4.2.4.2 Systematic construction of preferred AOD pair; 4.2.4.3 Examples of MDC-QOSTBC constructed)om preferred AOD pair; 4.3 Construction of MDC-QOSTBC from 0-STBC; 4.3.1 Construction method; 4.3.2 Performance optimization; 4.3.2.1 Diversity product of MDC-QOSTBC; 4.3.2.2 Optimum CR angle for square- and rectangular-QAM; 4.3.2.3 Optimum CR angle for PSK; 4.3.3 Non-square MDC-QOSTBC design

4.3.3.1 MDC-QOSTBC for odd number of transmit antennas4.3.3.2 Maximum code rate of square MDC-QOSTBC; 4.3.3.3 Maximum code rate of non-square MDC-QOSTBC; 4.4 Performance Results; 4.5 Chapter Summary; 5 . Differential QO-STBC; 5.1 DSTM Codeword Model and Design Criteria; 5.2 Unitary DSTM Based on QO-STBC; 5.2.1 Literature review; 5.2.2 Signal model of unitary DSTM scheme; 5.2.3 Double-symbol-decodable unitary DSTM; 5.2.3.1 STBC Unitary DSTM Based on Double-Symbol-Decodable QO-; 5.2.3.2 Design of constellation set; 5.2.4 Performance comparison; 5.2.5 Section summary

5.3 Quasi-Unitary DSTM Based on MDC-QOSTBC

<i>Quasi-Orthogonal Space-Time Block Code</i> presents an up-to-date, comprehensive and in-depth discussion of an important emerging class of space-time codes, called the Quasi-Orthogonal STBC (QO-STBC). Used in Multiple-Input Multiple-Output (MIMO) communication systems, they provide transmit diversity with higher code rates than the well-known orthogonal STBC (O-STBC), yet at lower decoding complexity than non-orthogonal STBC. This book will help readers gain a broad understanding of the fundamental principles as well as the state-of-the-art work in QO-STBC, thus enabling them to appreciate