Georgios B. Giannakis, Zhiqiang Liu, Xiaoli Ma, Sheng Zhou
Space-Time Coding for Broadband Wireless Communications (eBook, PDF)
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Georgios B. Giannakis, Zhiqiang Liu, Xiaoli Ma, Sheng Zhou
Space-Time Coding for Broadband Wireless Communications (eBook, PDF)
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This is the first book on space-time coding for wireless communications, one of the most promising techniques for ensuring bandwidth efficiency. The text describes theoretical principles as well as engineering applications; discusses key criteria in the design of practical space-time codes; and covers single-carrier and multi-carrier transmission for both single- and multi-user communications.
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This is the first book on space-time coding for wireless communications, one of the most promising techniques for ensuring bandwidth efficiency. The text describes theoretical principles as well as engineering applications; discusses key criteria in the design of practical space-time codes; and covers single-carrier and multi-carrier transmission for both single- and multi-user communications.
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Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 488
- Erscheinungstermin: 30. August 2007
- Englisch
- ISBN-13: 9780471462873
- Artikelnr.: 37302083
- Verlag: John Wiley & Sons
- Seitenzahl: 488
- Erscheinungstermin: 30. August 2007
- Englisch
- ISBN-13: 9780471462873
- Artikelnr.: 37302083
GEORGIOS B. GIANNAKIS, PhD, is ADC Endowed Chair Professor in Wireless Telecommunications with the Department of Electrical and Computer Engineering at the University of Minnesota. He is a Fellow of the IEEE, a (co-)recipient of six IEEE best paper awards (including the IEEE Communication Society's 2004 Guglielmo Marconi Prize Paper), and a recipient of the IEEE Signal Processing Society's Technical Achievement Award. His interests and expertise span the areas of wireless communications, wireless networks, sensor networks, and statistical signal processing. ZHIQIANG LIU, PhD, is Assistant Professor with the Department of Electrical and Computer Engineering at the University of Iowa. His research interests include space-time coding and processing, wireless communications theory, synchronization, channel estimation, and sensor networks. XIAOLI MA, PhD, is Assistant Professor with the School of Electrical and Computer Engineering at the Georgia Institute of Technology. Her research interests include signal processing for communications and networking, signal estimation algorithms, wireless communications theory, and sensor networks. SHENGLI ZHOU, PhD, is Assistant Professor with the Department of Electrical and Computer Engineering at the University of Connecticut. His research interests include wireless communications and signal processing, underwater acoustic communications and networking, and wireless positioning and synchronization.
Preface. Acronyms. 1. Motivation and Context. 1.1 Evolution of Wireless
Communication Systems. 1.2 Wireless Propagation Effects. 1.3 Parameters and
Classification of Wireless Channels. 1.4 Providing, Enabling and Collecting
Diversity. 1.5 Chapter-by-Chapter Organization. 2. Fundamentals of ST
Wireless Communications. 2.1 Generic ST System Model. 2.2 ST Coding viz
Channel Coding. 2.3 Capacity of ST Channels. 2.4 Error Performance of ST
Coding. 2.5 Design Criteria for ST Codes. 2.6 Diversity and Rate: Finite
SNR viz Asymptotics. 2.7 Classification of ST Codes. 2.8 Closing Comments.
3. Coherent ST Codes for Flat Fading Channels. 3.1 Delay Diversity ST
Codes. 3.2 ST Trellis Codes. 3.3 Orthogonal ST Block Codes. 3.4
Quasi-Orthogonal ST Block Codes. 3.5 ST Linear Complex Field Codes. 3.6
Linking OSTBC, QO-STBC and STLCFC Designs. 3.7 Closing Comments. 4. Layered
ST Codes. 4.1 BLAST Designs. 4.2 ST Codes Trading Diversity for Rate. 4.3
Full-Diversity Full-Rate ST Codes. 4.4 Numerical Examples. 4.5 Closing
Comments. 5. Sphere Decoding and (Near-) Optimal MIMO Demodulation. 5.1
Sphere Decoding Algorithm. 5.2 Average Complexity of SDA in Practice. 5.3
SDA Improvements. 5.4 Reduced-Complexity IRS-SDA. 5.5 Soft Decision Sphere
Decoding. 5.6 Closing Comments. 6. Non-Coherent and Differential ST Codes
for Flat Fading Channels. 6.1 Non-Coherent ST Codes. 6.2 Differential ST
Codes. 6.3 Closing Comments. 7. ST Codes for Frequency-Selective Fading
Channels: Single-Carrier Systems. 7.1 System Model and Performance Limits.
7.2 ST Trellis Codes. 7.3 ST Block Codes. 7.4 Closing Comments. 8. ST Codes
for Frequency-Selective Fading Channels: Multi-Carrier Systems. 8.1 The
General MIMO OFDM Framework. 8.2 ST and SF Coded MIMO OFDM. 8.3 STF Coded
OFDM. 8.4 Digital Phase Sweeping and Block Circular Delay. 8.5
Full-Diversity Full-Rate MIMO OFDM. 8.6 Closing Comments. 9. ST Codes for
Time-Varying Channels. 9.1 Time-Varying Channels. 9.2 Space-Time-Doppler
Block Codes. 9.3 Space-Time-Doppler FDFR Codes. 9.4 Space-Time-Doppler
Trellis Codes. 9.5 Numerical Examples. 9.6 Space-Time-Doppler Differential
Codes. 9.7 ST Codes for Doubly-Selective Channels. 9.8 Closing Comments.
10. Joint Galois-Field and Linear Complex-Field ST Codes. 10.1 GF-LCF ST
Codes. 10.2 GF-LCF ST Layered Codes. 10.3 GF-LCF Coded MIMO OFDM. 10.4
Closing Comments. 11. MIMO Channel Estimation and Synchronization. 11.1
Preamble-Based Channel Estimation. 11.2 Optimal Training-Based Channel
Estimation. 11.3 (Semi-)Blind Channel Estimation. 11.4 Joint Symbol
Detection and Channel Estimation. 11.5 Carrier Synchronization. 11.6
Closing Comments. 12. ST Codes with Partial Channel Knowledge: Statistical
CSI. 12.1 Partial CSI Models. 12.2 ST Spreading. 12.3 Combining OSTBC with
Beamforming. 12.4 Numerical Examples. 12.5 Adaptive Modulation for Rate
Improvement. 12.6 Optimizing Average Capacity. 12.7 Closing Comments. 13.
ST Codes With Partial Channel Knowledge: Finite-Rate CSI. 13.1 General
Problem Formulation. 13.2 Finite-Rate Beamforming. 13.3 Finite-Rate
Precoded Spatial Multiplexing. 13.4 Finite-Rate Precoded OSTBC. 13.5
Capacity Optimization with Finite-Rate Feedback. 13.6 Combining Adaptive
Modulation with Beamforming. 13.7 Finite-rate Feedback in MIMO OFDM. 13.8
Closing Comments. 14. ST Codes in the Presence of Interference. 14.1 ST
Spreading. 14.2 Combining STS with OSTBC. 14.3 Optimal Training with
Interference. 14.4 Numerical Examples. 14.5 Closing Comments. 15. ST Codes
for Orthogonal Multiple Access. 15.1 System Model. 15.2 Single-Carrier
Systems: STBC-CIBS-CDMA. 15.3 Multi-Carrier Systems: STF-OFDMA. 15.4
Closing Comments. References. Index.
Communication Systems. 1.2 Wireless Propagation Effects. 1.3 Parameters and
Classification of Wireless Channels. 1.4 Providing, Enabling and Collecting
Diversity. 1.5 Chapter-by-Chapter Organization. 2. Fundamentals of ST
Wireless Communications. 2.1 Generic ST System Model. 2.2 ST Coding viz
Channel Coding. 2.3 Capacity of ST Channels. 2.4 Error Performance of ST
Coding. 2.5 Design Criteria for ST Codes. 2.6 Diversity and Rate: Finite
SNR viz Asymptotics. 2.7 Classification of ST Codes. 2.8 Closing Comments.
3. Coherent ST Codes for Flat Fading Channels. 3.1 Delay Diversity ST
Codes. 3.2 ST Trellis Codes. 3.3 Orthogonal ST Block Codes. 3.4
Quasi-Orthogonal ST Block Codes. 3.5 ST Linear Complex Field Codes. 3.6
Linking OSTBC, QO-STBC and STLCFC Designs. 3.7 Closing Comments. 4. Layered
ST Codes. 4.1 BLAST Designs. 4.2 ST Codes Trading Diversity for Rate. 4.3
Full-Diversity Full-Rate ST Codes. 4.4 Numerical Examples. 4.5 Closing
Comments. 5. Sphere Decoding and (Near-) Optimal MIMO Demodulation. 5.1
Sphere Decoding Algorithm. 5.2 Average Complexity of SDA in Practice. 5.3
SDA Improvements. 5.4 Reduced-Complexity IRS-SDA. 5.5 Soft Decision Sphere
Decoding. 5.6 Closing Comments. 6. Non-Coherent and Differential ST Codes
for Flat Fading Channels. 6.1 Non-Coherent ST Codes. 6.2 Differential ST
Codes. 6.3 Closing Comments. 7. ST Codes for Frequency-Selective Fading
Channels: Single-Carrier Systems. 7.1 System Model and Performance Limits.
7.2 ST Trellis Codes. 7.3 ST Block Codes. 7.4 Closing Comments. 8. ST Codes
for Frequency-Selective Fading Channels: Multi-Carrier Systems. 8.1 The
General MIMO OFDM Framework. 8.2 ST and SF Coded MIMO OFDM. 8.3 STF Coded
OFDM. 8.4 Digital Phase Sweeping and Block Circular Delay. 8.5
Full-Diversity Full-Rate MIMO OFDM. 8.6 Closing Comments. 9. ST Codes for
Time-Varying Channels. 9.1 Time-Varying Channels. 9.2 Space-Time-Doppler
Block Codes. 9.3 Space-Time-Doppler FDFR Codes. 9.4 Space-Time-Doppler
Trellis Codes. 9.5 Numerical Examples. 9.6 Space-Time-Doppler Differential
Codes. 9.7 ST Codes for Doubly-Selective Channels. 9.8 Closing Comments.
10. Joint Galois-Field and Linear Complex-Field ST Codes. 10.1 GF-LCF ST
Codes. 10.2 GF-LCF ST Layered Codes. 10.3 GF-LCF Coded MIMO OFDM. 10.4
Closing Comments. 11. MIMO Channel Estimation and Synchronization. 11.1
Preamble-Based Channel Estimation. 11.2 Optimal Training-Based Channel
Estimation. 11.3 (Semi-)Blind Channel Estimation. 11.4 Joint Symbol
Detection and Channel Estimation. 11.5 Carrier Synchronization. 11.6
Closing Comments. 12. ST Codes with Partial Channel Knowledge: Statistical
CSI. 12.1 Partial CSI Models. 12.2 ST Spreading. 12.3 Combining OSTBC with
Beamforming. 12.4 Numerical Examples. 12.5 Adaptive Modulation for Rate
Improvement. 12.6 Optimizing Average Capacity. 12.7 Closing Comments. 13.
ST Codes With Partial Channel Knowledge: Finite-Rate CSI. 13.1 General
Problem Formulation. 13.2 Finite-Rate Beamforming. 13.3 Finite-Rate
Precoded Spatial Multiplexing. 13.4 Finite-Rate Precoded OSTBC. 13.5
Capacity Optimization with Finite-Rate Feedback. 13.6 Combining Adaptive
Modulation with Beamforming. 13.7 Finite-rate Feedback in MIMO OFDM. 13.8
Closing Comments. 14. ST Codes in the Presence of Interference. 14.1 ST
Spreading. 14.2 Combining STS with OSTBC. 14.3 Optimal Training with
Interference. 14.4 Numerical Examples. 14.5 Closing Comments. 15. ST Codes
for Orthogonal Multiple Access. 15.1 System Model. 15.2 Single-Carrier
Systems: STBC-CIBS-CDMA. 15.3 Multi-Carrier Systems: STF-OFDMA. 15.4
Closing Comments. References. Index.
Preface. Acronyms. 1. Motivation and Context. 1.1 Evolution of Wireless
Communication Systems. 1.2 Wireless Propagation Effects. 1.3 Parameters and
Classification of Wireless Channels. 1.4 Providing, Enabling and Collecting
Diversity. 1.5 Chapter-by-Chapter Organization. 2. Fundamentals of ST
Wireless Communications. 2.1 Generic ST System Model. 2.2 ST Coding viz
Channel Coding. 2.3 Capacity of ST Channels. 2.4 Error Performance of ST
Coding. 2.5 Design Criteria for ST Codes. 2.6 Diversity and Rate: Finite
SNR viz Asymptotics. 2.7 Classification of ST Codes. 2.8 Closing Comments.
3. Coherent ST Codes for Flat Fading Channels. 3.1 Delay Diversity ST
Codes. 3.2 ST Trellis Codes. 3.3 Orthogonal ST Block Codes. 3.4
Quasi-Orthogonal ST Block Codes. 3.5 ST Linear Complex Field Codes. 3.6
Linking OSTBC, QO-STBC and STLCFC Designs. 3.7 Closing Comments. 4. Layered
ST Codes. 4.1 BLAST Designs. 4.2 ST Codes Trading Diversity for Rate. 4.3
Full-Diversity Full-Rate ST Codes. 4.4 Numerical Examples. 4.5 Closing
Comments. 5. Sphere Decoding and (Near-) Optimal MIMO Demodulation. 5.1
Sphere Decoding Algorithm. 5.2 Average Complexity of SDA in Practice. 5.3
SDA Improvements. 5.4 Reduced-Complexity IRS-SDA. 5.5 Soft Decision Sphere
Decoding. 5.6 Closing Comments. 6. Non-Coherent and Differential ST Codes
for Flat Fading Channels. 6.1 Non-Coherent ST Codes. 6.2 Differential ST
Codes. 6.3 Closing Comments. 7. ST Codes for Frequency-Selective Fading
Channels: Single-Carrier Systems. 7.1 System Model and Performance Limits.
7.2 ST Trellis Codes. 7.3 ST Block Codes. 7.4 Closing Comments. 8. ST Codes
for Frequency-Selective Fading Channels: Multi-Carrier Systems. 8.1 The
General MIMO OFDM Framework. 8.2 ST and SF Coded MIMO OFDM. 8.3 STF Coded
OFDM. 8.4 Digital Phase Sweeping and Block Circular Delay. 8.5
Full-Diversity Full-Rate MIMO OFDM. 8.6 Closing Comments. 9. ST Codes for
Time-Varying Channels. 9.1 Time-Varying Channels. 9.2 Space-Time-Doppler
Block Codes. 9.3 Space-Time-Doppler FDFR Codes. 9.4 Space-Time-Doppler
Trellis Codes. 9.5 Numerical Examples. 9.6 Space-Time-Doppler Differential
Codes. 9.7 ST Codes for Doubly-Selective Channels. 9.8 Closing Comments.
10. Joint Galois-Field and Linear Complex-Field ST Codes. 10.1 GF-LCF ST
Codes. 10.2 GF-LCF ST Layered Codes. 10.3 GF-LCF Coded MIMO OFDM. 10.4
Closing Comments. 11. MIMO Channel Estimation and Synchronization. 11.1
Preamble-Based Channel Estimation. 11.2 Optimal Training-Based Channel
Estimation. 11.3 (Semi-)Blind Channel Estimation. 11.4 Joint Symbol
Detection and Channel Estimation. 11.5 Carrier Synchronization. 11.6
Closing Comments. 12. ST Codes with Partial Channel Knowledge: Statistical
CSI. 12.1 Partial CSI Models. 12.2 ST Spreading. 12.3 Combining OSTBC with
Beamforming. 12.4 Numerical Examples. 12.5 Adaptive Modulation for Rate
Improvement. 12.6 Optimizing Average Capacity. 12.7 Closing Comments. 13.
ST Codes With Partial Channel Knowledge: Finite-Rate CSI. 13.1 General
Problem Formulation. 13.2 Finite-Rate Beamforming. 13.3 Finite-Rate
Precoded Spatial Multiplexing. 13.4 Finite-Rate Precoded OSTBC. 13.5
Capacity Optimization with Finite-Rate Feedback. 13.6 Combining Adaptive
Modulation with Beamforming. 13.7 Finite-rate Feedback in MIMO OFDM. 13.8
Closing Comments. 14. ST Codes in the Presence of Interference. 14.1 ST
Spreading. 14.2 Combining STS with OSTBC. 14.3 Optimal Training with
Interference. 14.4 Numerical Examples. 14.5 Closing Comments. 15. ST Codes
for Orthogonal Multiple Access. 15.1 System Model. 15.2 Single-Carrier
Systems: STBC-CIBS-CDMA. 15.3 Multi-Carrier Systems: STF-OFDMA. 15.4
Closing Comments. References. Index.
Communication Systems. 1.2 Wireless Propagation Effects. 1.3 Parameters and
Classification of Wireless Channels. 1.4 Providing, Enabling and Collecting
Diversity. 1.5 Chapter-by-Chapter Organization. 2. Fundamentals of ST
Wireless Communications. 2.1 Generic ST System Model. 2.2 ST Coding viz
Channel Coding. 2.3 Capacity of ST Channels. 2.4 Error Performance of ST
Coding. 2.5 Design Criteria for ST Codes. 2.6 Diversity and Rate: Finite
SNR viz Asymptotics. 2.7 Classification of ST Codes. 2.8 Closing Comments.
3. Coherent ST Codes for Flat Fading Channels. 3.1 Delay Diversity ST
Codes. 3.2 ST Trellis Codes. 3.3 Orthogonal ST Block Codes. 3.4
Quasi-Orthogonal ST Block Codes. 3.5 ST Linear Complex Field Codes. 3.6
Linking OSTBC, QO-STBC and STLCFC Designs. 3.7 Closing Comments. 4. Layered
ST Codes. 4.1 BLAST Designs. 4.2 ST Codes Trading Diversity for Rate. 4.3
Full-Diversity Full-Rate ST Codes. 4.4 Numerical Examples. 4.5 Closing
Comments. 5. Sphere Decoding and (Near-) Optimal MIMO Demodulation. 5.1
Sphere Decoding Algorithm. 5.2 Average Complexity of SDA in Practice. 5.3
SDA Improvements. 5.4 Reduced-Complexity IRS-SDA. 5.5 Soft Decision Sphere
Decoding. 5.6 Closing Comments. 6. Non-Coherent and Differential ST Codes
for Flat Fading Channels. 6.1 Non-Coherent ST Codes. 6.2 Differential ST
Codes. 6.3 Closing Comments. 7. ST Codes for Frequency-Selective Fading
Channels: Single-Carrier Systems. 7.1 System Model and Performance Limits.
7.2 ST Trellis Codes. 7.3 ST Block Codes. 7.4 Closing Comments. 8. ST Codes
for Frequency-Selective Fading Channels: Multi-Carrier Systems. 8.1 The
General MIMO OFDM Framework. 8.2 ST and SF Coded MIMO OFDM. 8.3 STF Coded
OFDM. 8.4 Digital Phase Sweeping and Block Circular Delay. 8.5
Full-Diversity Full-Rate MIMO OFDM. 8.6 Closing Comments. 9. ST Codes for
Time-Varying Channels. 9.1 Time-Varying Channels. 9.2 Space-Time-Doppler
Block Codes. 9.3 Space-Time-Doppler FDFR Codes. 9.4 Space-Time-Doppler
Trellis Codes. 9.5 Numerical Examples. 9.6 Space-Time-Doppler Differential
Codes. 9.7 ST Codes for Doubly-Selective Channels. 9.8 Closing Comments.
10. Joint Galois-Field and Linear Complex-Field ST Codes. 10.1 GF-LCF ST
Codes. 10.2 GF-LCF ST Layered Codes. 10.3 GF-LCF Coded MIMO OFDM. 10.4
Closing Comments. 11. MIMO Channel Estimation and Synchronization. 11.1
Preamble-Based Channel Estimation. 11.2 Optimal Training-Based Channel
Estimation. 11.3 (Semi-)Blind Channel Estimation. 11.4 Joint Symbol
Detection and Channel Estimation. 11.5 Carrier Synchronization. 11.6
Closing Comments. 12. ST Codes with Partial Channel Knowledge: Statistical
CSI. 12.1 Partial CSI Models. 12.2 ST Spreading. 12.3 Combining OSTBC with
Beamforming. 12.4 Numerical Examples. 12.5 Adaptive Modulation for Rate
Improvement. 12.6 Optimizing Average Capacity. 12.7 Closing Comments. 13.
ST Codes With Partial Channel Knowledge: Finite-Rate CSI. 13.1 General
Problem Formulation. 13.2 Finite-Rate Beamforming. 13.3 Finite-Rate
Precoded Spatial Multiplexing. 13.4 Finite-Rate Precoded OSTBC. 13.5
Capacity Optimization with Finite-Rate Feedback. 13.6 Combining Adaptive
Modulation with Beamforming. 13.7 Finite-rate Feedback in MIMO OFDM. 13.8
Closing Comments. 14. ST Codes in the Presence of Interference. 14.1 ST
Spreading. 14.2 Combining STS with OSTBC. 14.3 Optimal Training with
Interference. 14.4 Numerical Examples. 14.5 Closing Comments. 15. ST Codes
for Orthogonal Multiple Access. 15.1 System Model. 15.2 Single-Carrier
Systems: STBC-CIBS-CDMA. 15.3 Multi-Carrier Systems: STF-OFDMA. 15.4
Closing Comments. References. Index.