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More About This Title Wireless Communications - Principles, Theory andMethodology
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Understand the mechanics of wireless communication
Wireless Communications: Principles, Theory and Methodology offers a detailed introduction to the technology. Comprehensive and well-rounded coverage includes signaling, transmission, and detection, including the mathematical and physics principles that underlie the technology's mechanics. Problems with modern wireless communication are discussed in the context of applied skills, and the various approaches to solving these issues offer students the opportunity to test their understanding in a practical manner. With in-depth explanations and a practical approach to complex material, this book provides students with a clear understanding of wireless communication technology.
- English
English
Keith Q.T. Zhang, electronics engineer, educator. Achievements include research in wireless communications. Member of Institute of Electrical and Electronics Engineers (associate editor letters 2000-2008). B. England, Tsinghua University, Beijing, 1970. Doctor of Philosophy, McMaster University, Hamilton, Ontario, Canada, 1985. Senior member technical staff Spar Aerospace Ltd, Satellite Communications Division, Montreal, 1991—1993. Professor Ryerson, Toronto, Canada, 1993—2002, City University, Hong Kong, since 2000.
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English
Preface xvii
Acknowledgments xix
1 Introduction 1
1.1 Resources for wireless communications 3
1.2 Shannon’s theory 3
1.3 Three challenges 4
1.4 Digital modulation versus coding 5
1.5 Philosophy to combat interference 6
1.6 Evolution of processing strategy 7
1.7 Philosophy to exploit two-dimensional random fields 7
1.8 Cellular: Concept, Evolution, and 5G 8
1.9 The structure of this book 10
1.10 Repeatedly used abbreviations and math symbols 10
Problems 12
References 12
2 Mathematical Background 14
2.1 Introduction 14
2.2 Congruence mapping and signal spaces 14
2.3 Estimation methods 19
2.3.1 Maximum likelihood estimation (MLE) 20
2.3.2 Maximum a posteriori estimation 21
2.4 Commonly used distributions in wireless 21
2.4.1 Chi-square distributions 21
2.4.2 Gamma distribution 25
2.4.3 Nakagami distribution 26
2.4.4 Wishart distribution 26
2.5 The calculus of variations 28
2.6 Two inequalities for optimization 29
2.6.1 Inequality for Rayleigh quotient 29
2.6.2 Hadamard inequality 29
2.7 Q-function 30
2.8 The CHF method and its skilful applications 32
2.8.1 Gil-Pelaez’s lemma 32
2.8.2 Random variables in denominators 32
2.8.3 Parseval’s theorem 33
2.9 Matrix operations and differentiation 33
2.9.1 Decomposition of a special determinant 33
2.9.2 Higher order derivations 33
2.9.3 Kronecker product 34
2.10 Additional reading 34
Problems 34
References 35
3 Channel Characterization 37
3.1 Introduction 37
3.2 Large-scale propagation loss 38
3.2.1 Free-space propagation 39
3.2.2 Average large-scale path loss in mobile 40
3.2.3 Okumura’s model 40
3.2.4 Hata’s model 42
3.2.5 JTC air model 42
3.3 Lognormal shadowing 43
3.4 Multipath characterization for local behavior 44
3.4.1 An equivalent bandwidth 44
3.4.2 Temporal evolution of path coefficients 49
3.4.3 Statistical description of local fluctuation 50
3.4.4 Complex Gaussian distribution 50
3.4.5 Nakagami fading 51
3.4.6 Clarke–Jakes model 52
3.5 Composite model to incorporate multipath and shadowing 53
3.6 Example to illustrate the use of various models 54
3.6.1 Static design 54
3.6.2 Dynamic design 55
3.6.3 Large-scale design 56
3.7 Generation of correlated fading channels 56
3.7.1 Rayleigh fading with given covariance structure 56
3.7.2 Correlated Nakagami fading 57
3.7.3 Complex correlated Nakagami channels 62
3.7.4 Correlated lognormal shadowing 62
3.7.5 Fitting a lognormal sum 64
3.8 Summary 65
3.9 Additional reading 66
Problems 66
References 68
4 Digital Modulation 70
4.1 Introduction 70
4.2 Signals and signal space 71
4.3 Optimal MAP and ML receivers 72
4.4 Detection of two arbitrary waveforms 74
4.5 MPSK 77
4.5.1 BPSK 77
4.5.2 QPSK 79
4.5.3 MPSK 81
4.6 M-ary QAM 85
4.7 Noncoherent scheme–differential MPSK 88
4.7.1 Differential BPSK 88
4.7.2 Differential MPSK 89
4.7.3 Connection to MPSK 89
4.8 MFSK 90
4.8.1 BFSK with coherent detection 90
4.9 Noncoherent MFSK 92
4.10 Bit error probability versus symbol error probability 93
4.10.1 Orthogonal MFSK 93
4.10.2 Square M-QAM 93
4.10.3 Gray-mapped MPSK 94
4.11 Spectral efficiency 96
4.12 Summary of symbol error probability for various schemes 97
4.13 Additional reading 98
Problems 98
References 102
5 Minimum Shift Keying 103
5.1 Introduction 103
5.2 MSK 104
5.3 de Buda’s approach 105
5.3.1 The basic idea and key equations 105
5.4 Properties of MSK signals 106
5.5 Understanding MSK 108
5.5.1 MSK as FSK 108
5.5.2 MSK as offset PSK 109
5.6 Signal space 109
5.7 MSK power spectrum 110
5.8 Alternative scheme–differential encoder 113
5.9 Transceivers for MSK signals 115
5.10 Gaussian-shaped MSK 116
5.11 Massey’s approach to MSK 117
5.11.1 Modulation 117
5.11.2 Receiver structures and error performance 117
5.12 Summary 119
Problems 119
References 120
6 Channel Coding 121
6.1 Introduction and philosophical discussion 121
6.2 Preliminary of Galois fields 123
6.2.1 Fields 123
6.2.2 Galois fields 124
6.2.3 The primitive element of GF(q) 124
6.2.4 Construction of GF(q) 124
6.3 Linear block codes 126
6.3.1 Syndrome test 129
6.3.2 Error-correcting capability 132
6.4 Cyclic codes 134
6.4.1 The order of elements: a concept in GF(q) 134
6.4.2 Cyclic codes 136
6.4.3 Generator, parity check, and syndrome polynomial 137
6.4.4 Systematic form 138
6.4.5 Syndrome and decoding 140
6.5 Golay code 141
6.6 BCH codes 141
6.6.1 Generating BCH codes 142
6.6.2 Decoding BCH codes 143
6.7 Convolutional codes 146
6.7.1 Examples 146
6.7.2 Code generation 147
6.7.3 Markovian property 148
6.7.4 Decoding with hard-decision Viterbi algorithm 150
6.7.5 Transfer function 152
6.7.6 Choice of convolutional codes 155
6.7.7 Philosophy behind decoding strategies 156
6.7.8 Error performance of convolutional decoding 160
6.8 Trellis-coded modulation 162
6.9 Summary 166
Problems 166
References 170
7 Diversity Techniques 171
7.1 Introduction 171
7.2 Idea behind diversity 173
7.3 Structures of various diversity combiners 174
7.3.1 MRC 174
7.3.2 EGC 175
7.3.3 SC 176
7.4 PDFs of output SNR 176
7.4.1 MRC 176
7.4.2 EGC 178
7.4.3 SC 178
7.5 Average SNR comparison for various schemes 179
7.5.1 MRC 179
7.5.2 EGC 180
7.5.3 SC 181
7.6 Methods for error performance analysis 182
7.6.1 The chain rule 182
7.6.2 The CHF method 183
7.7 Error probability of MRC 183
7.7.1 Error performance in nondiversity Rayleigh fading 183
7.7.2 MRC in i.i.d. Rayleigh fading 185
7.7.3 MRC in correlated Rayleigh fading 187
7.7.4 Pe for generic channels 188
7.8 Error probability of EGC 189
7.8.1 Closed-form solution to order-3 EGC 189
7.8.2 General EGC error performance 191
7.8.3 Diversity order of EGC 192
7.9 Average error performance of SC in Rayleigh fading 193
7.9.1 Pure SC 193
7.9.2 Generalized SC 195
7.10 Performance of diversity MDPSK systems 196
7.10.1 Nondiversity MDPSK in Rayleigh fading 196
7.10.2 Remarks on use of the chain rule 199
7.10.3 Linear prediction to fit the chain rule 199
7.10.4 Alternative approach for diversity MDPSK 200
7.11 Noncoherent MFSK with diversity reception 201
7.12 Summary 203
Problems 204
References 206
8 Processing Strategies for Wireless Systems 209
8.1 Communication problem 209
8.2 Traditional strategy 210
8.3 Paradigm of orthogonality 211
8.4 Turbo processing principle 211
Problems 213
References 213
9 Channel Equalization 214
9.1 Introduction 214
9.2 Pulse shaping for ISI-free transmission 215
9.3 ISI and equalization strategies 216
9.4 Zero-forcing equalizer 217
9.4.1 Orthogonal projection 217
9.4.2 ZFE 219
9.4.3 Equivalent discrete ZFE receiver 221
9.5 MMSE linear equalizer 225
9.6 Decision-feedback equalizer (DFE) 227
9.7 SNR comparison and error performance 229
9.8 An example 230
9.9 Spectral factorization 233
9.10 Summary 234
Problems 234
References 236
10 Channel Decomposition Techniques 238
10.1 Introduction 238
10.2 Channel matrix of ISI channels 239
10.3 Idea of channel decomposition 239
10.4 QR-decomposition-based Tomlinson–Harashima equalizer 240
10.5 The GMD equalizer 242
10.6 OFDM for time-invariant channel 243
10.6.1 Channel SVD 243
10.6.2 OFDM: a multicarrier modulation technique 244
10.6.3 PAPR and statistical behavior of OFDM 246
10.6.4 Combating PAPR 247
10.7 Cyclic prefix and circulant channel matrix 248
10.8 OFDM receiver 251
10.9 Channel estimation 251
10.10 Coded OFDM 252
10.11 Additional reading 252
Problems 252
References 254
11 Turbo Codes and Turbo Principle 257
11.1 Introduction and philosophical discussion 257
11.1.1 Generation of random-like long codes 258
11.1.2 The turbo principle 259
11.2 Two-device mechanism for iteration 259
11.3 Turbo codes 261
11.3.1 A turbo encoder 261
11.3.2 RSC versus NRC 261
11.3.3 Turbo codes with two constituent RSC encoders 264
11.4 BCJR algorithm 266
11.5 Turbo decoding 270
11.6 Illustration of turbo-code performance 270
11.7 Extrinsic information transfer (EXIT) charts 272
11.8 Convergence and fixed points 276
11.9 Statistics of LLRs 277
11.9.1 Mean and variance of LLRs 277
11.9.2 Mean and variance of hard decision 277
11.10 Turbo equalization 278
11.11 Turbo CDMA 281
11.12 Turbo IDMA 283
11.13 Summary 283
Problems 284
References 287
12 Multiple-Access Channels 289
12.1 Introduction 289
12.2 Typical MA schemes 291
12.3 User space of multiple-access 292
12.3.1 User spaces for TDMA 293
12.3.2 User space for CDMA 294
12.3.3 User space for MC-CDMA 294
12.3.4 MC-DS-CDMA 295
12.3.5 User space for OFDMA 296
12.3.6 Unified framework for orthogonal multiaccess schemes 297
12.4 Capacity of multiple-access channels 298
12.4.1 Flat fading 299
12.4.2 Frequency-selective fading 300
12.5 Achievable MI by various MA schemes 301
12.5.1 AWGN channel 301
12.5.2 Flat-fading MA channels 304
12.6 CDMA-IS-95 306
12.6.1 Forward link 306
12.6.2 Reverse link 308
12.7 Processing gain of spreading spectrum 310
12.8 IS-95 downlink receiver and performance 310
12.9 IS-95 uplink receiver and performance 317
12.10 3GPP-LTE uplink 318
12.11 m-Sequences 321
12.11.1 PN sequences of a shorter period 322
12.11.2 Conditions for m-sequence generators 322
12.11.3 Properties of m-sequence 323
12.11.4 Ways to generate PN sequences 324
12.12 Walsh sequences 327
12.13 CAZAC sequences for LTE-A 327
12.14 Nonorthogonal MA schemes 329
12.15 Summary 330
Problems 330
References 334
13 Wireless MIMO Systems 337
13.1 Introduction 337
13.2 Signal model and mutual information 338
13.3 Capacity with CSIT 339
13.4 Ergodic capacity without CSIT 340
13.4.1 i.i.d. MIMO Rayleigh channels 341
13.4.2 Ergodic capacity for correlated MIMO channels 341
13.5 Capacity: asymptotic results 344
13.5.1 Asymptotic capacity with large MIMO 344
13.5.2 Large SNR approximation 345
13.6 Optimal transceivers with CSIT 346
13.6.1 Optimal eigenbeam transceiver 347
13.6.2 Distributions of the largest eigenvalue 348
13.6.3 Average symbol-error probability 350
13.6.4 Average mutual information of MIMO-MRC 350
13.6.5 Average symbol-error probability 351
13.7 Receivers without CSIT 352
13.8 Optimal receiver 352
13.9 Zero-forcing MIMO receiver 353
13.10 MMSE receiver 355
13.11 VBLAST 357
13.11.1 Alternative VBLAST based on QR decomposition 358
13.12 Space–time block codes 359
13.13 Alamouti codes 359
13.13.1 One receive antenna 359
13.13.2 Two receive antennas 360
13.14 General space–time codes 362
13.14.1 Exact pairwise error probability 363
13.15 Information lossless space–time codes 365
13.16 Multiplexing gain versus diversity gain 365
13.16.1 Two frameworks 366
13.16.2 Derivation of the DMT 367
13.16.3 Available DFs for diversity 368
13.17 Summary 370
Problems 370
References 374
14 Cooperative Communications 377
14.1 A historical review 377
14.2 Relaying 378
14.3 Cooperative communications 379
14.3.1 Cooperation protocols 380
14.3.2 Diversity analysis 382
14.3.3 Resource allocation 384
14.4 Multiple-relay cooperation 385
14.4.1 Multi-relay over frequency-selective channels 386
14.4.2 Optimal matrix structure 389
14.4.3 Power allocation 390
14.5 Two-way relaying 395
14.5.1 Average power constraints 397
14.5.2 Instantaneous power constraint 399
14.6 Multi-cell MIMO 400
14.7 Summary 401
Problems 401
References 402
15 Cognitive Radio 405
15.1 Introduction 405
15.2 Spectrum sensing for spectrum holes 406
15.3 Matched filter versus energy detector 407
15.3.1 Matched-filter detection 407
15.3.2 Energy detection 408
15.4 Detection of random primary signals 410
15.4.1 Energy-based detection 411
15.4.2 Maximum likelihood ratio test 412
15.4.3 Eigenvalue ratio test 413
15.5 Detection without exact knowledge of σ2n 414
15.5.1 LRT with σ2n 414
15.5.2 LRT without noise-level reference 415
15.6 Cooperative spectrum sensing 416
15.7 Standardization of CR networks 418
15.8 Experimentation and commercialization of CR systems 418
Problems 419
References 420
Index 423