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Multicarrier Communications [Hardback]

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(University of Southampton)
  • Formāts: Hardback, 696 pages, height x width x depth: 252x201x41 mm, weight: 1297 g
  • Izdošanas datums: 09-Jan-2009
  • Izdevniecība: John Wiley & Sons Inc
  • ISBN-10: 0470722002
  • ISBN-13: 9780470722008
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Multicarrier CommunicationsPalielināt
  • Formāts: Hardback, 696 pages, height x width x depth: 252x201x41 mm, weight: 1297 g
  • Izdošanas datums: 09-Jan-2009
  • Izdevniecība: John Wiley & Sons Inc
  • ISBN-10: 0470722002
  • ISBN-13: 9780470722008
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780470722008.html
Keywords:
Benefiting from both time-domain and frequency-domain signal processing techniques, multicarrier systems have the potential for achieving high spectral-efficiency, high-flexibility and low-complexity wireless communications. Multicarrier techniques therefore constitute the promising techniques for implementation of future generations of wideband, broadband and ultra-wideband systems.

Multicarrier Communications offers comprehensive and in-depth evaluation of numerous topics in the area, covering the fundamental principles of spread-spectrum and multicarrier CDMA as well as more advanced topics such as multiuser detection (MUD), multiuser transmitter preprocessing (MUTP), MIMO and space-time processing. It examines OFDM and various multicarrier CDMA within an unified framework and provides analytical approaches and formulas for error-performance evaluation of numerous multicarrier systems.

  • Examines MUD and MUTP in parallel to illustrate the strong duality between receiver optimization and transmitter optimization
  • Comprehensively establishes the theory of noncoherent MUD and noncoherent interference suppression
  • Details the body of knowledge on MIMO theory and space-time multicarrier communications
  • Contains tables, diagrams and figures to illustrate the performance results.

Practicing electrical engineers and researchers in wireless communications will find Multicarrier Communications an invaluable guide. It will also be of interest to senior undergraduate and graduate students on wireless communications courses.

Preface xv
Introduction
1(20)
Spread Spectrum
1(5)
Orthogonal Frequency-Division Multiplexing
6(2)
Multiple Access
8(3)
Duplex
11(3)
Time-Division Duplex (TDD)
11(1)
Frequency-Division Duplex (FDD)
12(1)
Multicarrier-Division Duplex (MDD)
13(1)
Code-Division Duplex (CDD)
14(1)
Diversity in Wireless Communications
14(4)
Organization of the Book
18(3)
Principles of Code-Division Multiple-Access Communications
21(76)
Direct-Sequence Spread Spectrum
22(12)
Transmitted Signals
23(2)
Detection of DS-SS Signals
25(1)
Correlation Receiver
25(2)
Matched-Filter Receiver
27(3)
Anti-Jamming Property of DS-SS Systems
30(3)
Direct-Sequence Code-Division Multiple Access
33(1)
Multicarrier Spread-Spectrum Communications
34(6)
Transmitted Signals
34(2)
Detection of MC Spread-Spectrum Signals
36(2)
Multicarrier Code-Division Multiple Access
38(2)
Frequency-Hopped Spread-Spectrum Communications
40(14)
M-ary Frequency-Shift Keying
40(2)
M-ary Frequency-Shift Keying Aided Slow Frequency-Hopping
42(2)
M-ary Frequency-Shift Keying Aided Fast Frequency-Hopping
44(3)
Detection of FH/MFSK Signals
47(4)
Frequency-Hopping Multiple-Access
51(1)
Slow Frequency-Hopping Multiple-Access
51(2)
Fast Frequency-Hopping Multiple-Access
53(1)
Time-Hopping Spread-Spectrum Communications
54(19)
Slow Time-Hopping M-ary Pulse-Position Modulation
56(4)
Fast Time-Hopping M-ary Pulse-Position Modulation
60(1)
Detection of Slow Time-Hopping Signals
61(3)
Detection of Fast Time-Hopping Signals
64(3)
Time-Hopping Multiple-Access
67(1)
Slow Time-Hopping Multiple-Access
68(2)
Fast Time-Hopping Multiple-Access
70(3)
Hybrid Direct-Sequence/Frequency-Hopping Multiple-Access
73(13)
Hybrid DS/SFH Signals
74(1)
DS/SFH Using BPSK Modulation
74(1)
Detection of BPSK Modulated DS/SFH Signals
75(3)
Hybrid DS/FFH Signals
78(1)
DS/FFH Using MFSK Modulation
79(1)
Detection of DS/FFH Signals Using MFSK
80(2)
DS/FFH Using M-ary Orthogonal Modulation
82(1)
Detection of DS/FFH Signals Using M-ary Orthogonal Modulation
83(3)
Hybrid Direct-Sequence/Time-Hopping Multiple-Access
86(10)
Hybrid DS/STH Signals
87(1)
DS/STH Using MPPM
87(1)
Detection of DS/STH Signals Using MPPM
87(3)
Hybrid DS/FTH Signals
90(1)
DS/FTH Using MPPM
90(1)
Detection of DS/FTH Signal Using MPPM
90(2)
DS/FTH Using M-ary Orthogonal Modulation
92(1)
Detection of DS/FTH Signals Using M-ary Orthogonal Modulation
93(3)
Summary and Discussion
96(1)
Principles of Multicarrier Communications
97(56)
Introduction
97(2)
Orthogonal Frequency-Division Multiplexing
99(9)
Modulator
99(1)
Modulation Parameters
100(1)
Demodulator
101(2)
Implementation of Multicarrier Modulation/Demodulation
103(5)
Frequency-Domain Spread Multicarrier CDMA
108(7)
Transmitted Signal
108(1)
Modulation Parameters
109(2)
Correlation Receiver
111(4)
Single-Carrier Frequency-Division Multiple Access
115(7)
Orthogonal Multicarrier DS-CDMA
122(6)
Transmitted Signal
122(1)
Modulation Parameters
123(2)
Correlation Receiver
125(3)
Multitone DS-CDMA
128(6)
Transmitted Signal
128(2)
Modulation Parameters
130(1)
Correlation Receiver
131(3)
Generalized Multicarrier DS-CDMA
134(6)
Transmitted Signal
136(1)
Modulation Parameters
137(1)
Correlation Receiver
138(2)
Time-Hopping Multicarrier CDMA
140(5)
Transmitted Signal
140(1)
Modulation Parameters
141(2)
Receiver Model
143(2)
Time-Frequency-Domain Spread Multicarrier DS-CDMA
145(5)
Transmitted Signal
146(1)
Receiver Model
146(4)
Summary and Discussion
150(3)
Performance of Multicarrier Systems over Gaussian Channels
153(50)
Introduction
153(1)
Performance of Orthogonal Frequency-Division Multiplexing
154(4)
Performance of Single-User Frequency-Domain Spread Multicarrier CDMA
158(1)
Performance of Single-User Multicarrier DS-CDMA
159(10)
Performance of Single-User Time-Hopping Multicarrier CDMA
169(8)
Power Spectral Density of TH/MC-CDMA Signals
169(4)
Error Probability of TH/MC-CDMA Systems
173(4)
Performance of Time-Frequency-Domain Spread Multicarrier DS-CDMA Supporting Multiusers
177(18)
Transmitted signal
178(1)
Power Spectral Density
179(2)
Representation of the Received Signal
181(4)
Single-User Detection and Analysis
185(5)
Bit-Error Rate (BER) Performance Analysis
190(2)
Bit-Error Rate (BER) Performance Results
192(3)
Equivalence Between Single-Carrier DS-CDMA and Multicarrier CDMA
195(3)
Summary and Discussion
198(5)
Appendix 4.A Standard Gaussian Approximation
199(4)
Performance of Multicarrier Systems over Frequency-Selective Fading Channels
203(72)
Introduction
203(2)
Frequency-Selective Fading in Multicarrier Systems
205(6)
Intersymbol Interference Suppression: Cyclic-Prefixing and Zero-Padding
211(4)
Generation of Fading Statistics for Multicarrier Signals
215(1)
Performance of Orthogonal Frequency-Division Multiplexing
216(2)
Performance of Single-User Frequency-Domain Spread Multicarrier CDMA
218(7)
Representation of the Received Signals
218(1)
MRC-Assisted Detection and Performance Analysis
219(3)
Performance Results
222(3)
Performance of Single-Carrier Frequency-Division Multiple Access
225(3)
Frequency-Domain Equalization in Single-Carrier DS-CDMA
228(6)
Performance of Single-User Multicarrier DS-CDMA
234(11)
Representation of the Received Signals
234(4)
MRC-Assisted Detection and Performance Analysis
238(3)
Interbit and Intercarrier Interference in MC DS-CDMA: An Example
241(4)
Performance of Single-User Time-Hopping Multicarrier CDMA
245(6)
Decision Variables and Their Statistics
245(3)
Error Probability Analysis
248(2)
Performance Results
250(1)
Performance of Time-Frequency-Domain Spread Multicarrier DS-CDMA Supporting Multiusers
251(15)
Representation of the Received Signal
253(2)
Single-User Detection and Analysis
255(2)
Statistics Analysis
257(3)
Bit-Error Rate (BER) Analysis
260(1)
Standard Gaussian Approximation
260(2)
Simplified Improved Gaussian Approximation
262(2)
Performance Results
264(2)
Summary and Discussion
266(9)
Appendix 5.A n0∞ Q(√2γ) f(γ) dγ
269(1)
Appendix 5.B E[ exp( - ΣNj=1 (γi/sin2 θ))] in Correlated Nakagami-m Fading
270(2)
Appendix 5.C Derivation of the Variance of ψ
272(3)
Coherent Multiuser Detection
275(130)
Introduction
275(2)
Multiuser Detection in Frequency-Domain Spread Multicarrier CDMA
277(66)
Decorrelating
280(5)
Minimum Variance Distortionless Response (MVDR)
285(2)
Minimum Mean-Square Error (MMSE)
287(5)
Maximum Signal-to-Interference-plus-Noise Ratio (MSINR)
292(2)
Minimum Power Distortionless Response (MPDR)
294(2)
Multiuser Detection in Subspaces
296(2)
Signal Subspace
298(2)
Principal Components (PCs)
300(1)
Cross-Spectral Metric (CSM)
301(2)
Taylor Polynomial Approximation (TPA)
303(3)
Decision Feedback Multiuser Detection
306(2)
Matched-Filtering Decision-Feedback
308(6)
Zero-Forcing Decision-Feedback
314(3)
Minimum Mean-Square Error Decision-Feedback
317(1)
Maximum A Posteriori Probability Multiuser Detection
318(11)
Maximum Likelihood Decision Multiuser Detection
329(2)
Minimum Error-Probability Linear Multiuser Detection
331(12)
Multiuser Detection in Multicarrier DS-CDMA
343(19)
Zero-Forcing Multiuser Detection
346(7)
Minimum Mean-Square Error Multiuser Detection
353(5)
Maximum Likelihood Decision Multiuser Detection
358(4)
Multiuser Detection in Time-Frequency-Domain Spread Multicarrier DS-CDMA
362(19)
Time-Frequency-Domain Zero-Forcing Multiuser Detection
365(6)
Time-Frequency-Domain MMSE Multiuser Detection
371(6)
Hybrid Time-Frequency-Domain ZF-MMSE Multiuser Detection
377(3)
Maximum-Likelihood Decision Multiuser Detection
380(1)
Summary and Discussion
381(24)
Appendix
6. A Derivatives with Respect to Complex Vector/Matrix
383(3)
Appendix 6.B Matrix Inversion
386(2)
Appendix 6.C Suboptimal Algorithms for Maximum Likelihood Decision Multiuser Detection
388(1)
Search Algorithms
388(1)
QRD-M Tree-Search Algorithm
389(1)
Greedy Search Algorithm
390(1)
Sphere-Decoding-Based Search
391(1)
Coordinate Descent Search Algorithm
392(1)
Evolutionary Programming Algorithm
393(1)
Genetic Algorithm
394(2)
Ant-Colony-Inspired Search
396(2)
Non-Search Algorithms
398(1)
Expectation Maximization
398(2)
Probabilistic Data Associated Algorithm
400(3)
Semidefinite Programming Relaxation
403(2)
Noncoherent Multiuser Detection
405(70)
Representation of Discrete Time-Hopping Multicarrier CDMA Signals
406(5)
Noncoherent Single-User Detection
411(4)
Optimum Prior Noncoherent Multiuser Detection
415(3)
Prior Noncoherent Decorrelating Multiuser Detection
418(5)
Prior Noncoherent MMSE Multiuser Detection
423(6)
Optimum Posterior Noncoherent Multiuser Detection
429(10)
Optimum Posterior Noncoherent Multiuser Detection in Noiseless Rayleigh Fading Channels
433(3)
Optimum Posterior Noncoherent Multiuser Detection in Noisy Rayleigh Fading Channels
436(3)
Suboptimum Posterior Noncoherent Multiuser Detection in Rayleigh Fading Channels
439(4)
Posterior Noncoherent Interference Cancellation
443(24)
Conventional Single-User Posterior Noncoherent Detection
443(7)
Minimum-Distance Decoding Based Interference Cancellation
450(5)
Iterative Posterior Interference Cancellation
455(6)
Posterior Multistage Interference Cancellation
461(6)
Summary and Discussion
467(8)
Appendix 7.A Noncoherent Diversity Combining Schemes for M-ary Orthogonal Signalling
469(3)
Appendix 7.B Derivation of PNC(i)
472(3)
Multiuser Transmitter Preprocessing
475(104)
Principles of Transmitter Preprocessing: An Example
476(3)
Transmitter Preprocessing in Frequency-Domain Spread MC-CDMA
479(51)
Transmitted Signal
479(2)
Representation of the Received Signal
481(2)
Transmitter Matched-Filtering Single-User Preprocessor
483(5)
Zero-Forcing Multiuser Transmitter Preprocessor
488(7)
Minimum Mean-Square Error (MMSE) Multiuser Transmitter Preprocessing
495(4)
Maximum Signal-to-Interference-Plus-Noise Ratio (MSINR) Multiuser Transmitter Preprocessing
499(2)
Minimum Variance Distortionless Response (MVDR) Multiuser Transmitter Preprocessing
501(3)
Minimum Power Distortionless Response (MPDR) Multiuser Transmitter Preprocessing
504(2)
Eigenspace-Based Multiuser Transmitter Preprocessing
506(4)
Minimum Bit-Error Rate (MBER) Multiuser Transmitter Preprocessing
510(5)
Maximum Mutual Information (MMI) Multiuser Transmitter Preprocessing
515(8)
Transmitter Multiuser Interference Cancellation
523(7)
Transmitter Preprocessing in Frequency-Domain Spread MC DS-CDMA Systems
530(27)
Transmitted Signal
531(4)
Representation of the Received Signal
535(5)
Minimum Mean-Square Error Multiuser Transmitter Preprocessing
540(2)
Matched Filtering
542(3)
Zero-Forcing
545(1)
Minimum Mean-Square Error
546(5)
Maximum Mutual Information Multiuser Transmitter Preprocessing
551(4)
Transmission Power Allocation
555(1)
Joint Power Normalization
555(1)
Individual Power Normalization
556(1)
Maximal SNR Assisted Normalization for ZF-MUTP
556(1)
Relationship Between Linear Multiuser Transmission and Linear Multiuser Detection
557(4)
Extraction of Channel Knowledge for Transmitter Preprocessing in Multicarrier CDMA Systems
561(17)
Time-Division Duplex (TDD)
562(1)
Frequency-Division Duplex (FDD)
563(1)
Multicarrier-Division Duplex (MDD)
564(1)
Principles of MDD: Gaussian Channels
565(3)
MDD Systems in Frequency-Selective Fading Channels
568(4)
Channel Estimation/Prediction in MDD Systems
572(6)
Summary and Discussion
578(1)
Multiantenna Multicarrier CDMA
579(76)
Multiple-Input Multiple-Output Communications
580(15)
Multiple-Input Multiple-Output System Model
580(1)
Capacity of Multiple-Input Multiple-Output Channels
581(14)
Spatial Diversity
595(17)
Receive Diversity
595(1)
Transmit Diversity
596(1)
Switched Transmit Diversity
596(1)
TMRC-Assisted Transmit Diversity
597(1)
Orthogonal Transmit Diversity
597(1)
Transmit Diversity Based on Space-Time Coding
598(10)
Transmit Diversity Based on Space-Time Spreading
608(3)
MIMO Diversity
611(1)
Spatial-Division Multiple Access
612(2)
Performance of Multicarrier CDMA Using Space-Time Coding
614(11)
Transmission Scheme
614(2)
Receiver Scheme
616(3)
Analysis of Probability of Error
619(4)
Performance Results
623(2)
Time-Frequency-Domain Space-Time Spread Multicarrier DS-CDMA
625(8)
Transmission Scheme
626(2)
Receiver Scheme
628(3)
Analysis of Probability of Error
631(2)
Space-Time MC DS-CDMA over Fast Time-Varying Fading Channels
633(20)
System Model
635(1)
Transmitter Model
635(2)
Receiver Model
637(4)
Detection Schemes
641(3)
Analysis of Single-User Bit-Error-Rate
644(3)
Performance Results
647(4)
Conclusions
651(2)
Summary and Discussion
653(2)
Bibliography 655(18)
Index 673
Dr. Lie-Liang Yang, Reader, PhD, School of Electronics and Computer Science, University of Southampton, UK Since December 1997, Dr Yang has been with the Communications Research Group at the School of Electronics and Computer Science of the University of Southampton, where he has been an academic staff member since 2002. His research has covered a wide range of areas in information theory, digital communications, mobile communications, wireless networking, signal processing for wireless communications, as well as wideband, broadband and ultrawide bandwidth (UWB) code-division multiple-access (CDMA). He has published over 190 research papers, which include about 70 journal papers and more than 120 conference papers, mainly in IEEE journals and IEEE conference proceedings. He has co-authored one book, which was jointly published by John Wiley & Sons and IEEE Press, and also published many book chapters in the field of wireless communications. He has presented invited lectures in a number of universities in both UK and China, and also provided tutorial lectures at conferences.