RF Power Amplifiers for wireless communication:Contents
Preface to the Second Edition xi
CHAPTER 1
Introduction 1
1.1 Introduction 1
1.2 Linear RF Amplifier Theory 2
1.3 Weakly Nonlinear Effects: Power and Volterra Series 5
1.4 Strongly Nonlinear Effects 6
1.5 Nonlinear Device Models for CAD 9
1.6 Conjugate Match 11
1.7 RF Power Device Technology 14
References 15
CHAPTER 2
Linear Power Amplifier Design 17
2.1 Class A Amplifiers and Linear Amplifiers 17
2.2 Gain Match and Power Match 19
2.3 Introduction to Load-Pull Measurements 20
2.4 Loadline Theory 21
2.5 Package Effects and Refinements to Load-Pull Theory 27
2.6 Drawing the Load-Pull Contours on CAD Programs 31
2.7 Class A Design Example 31
2.8 Conclusions 36
References 37
CHAPTER 3
Conventional High Efficiency Amplifier Modes 39
3.1 Introduction 39
3.2 Reduced Conduction Angle—Waveform Analysis 40
3.3 Output Termination 43
3.4 Reduced Conduction Angle Mode Analysis—FET Model 47
Case 1: Class A 48
Case 2: Class AB 49
Case 3: Class B 51
Case 4: Class C 53
3.5 Reduced Conduction Angle Mode Analysis—BJT Model 55
3.6 Effect of I-V “Knee” 59
3.7 Input Drive Requirements 61
3.8 Conclusions 65
References 65
CHAPTER 4
Class AB PAs at GHz Frequencies 67
4.1 Introduction 67
4.2 Class AB Using a Capacitive Harmonic Termination—The Class J PA 68
4.2.1 Theory 68
4.2.2 Practicalities 73
4.3 Nonlinear Device Characteristics 77
4.4 Nonlinear Capacitance Effects in RF Power Devices 81
4.4.1 Introduction 81
4.4.2 Nonlinear Capacitors—Characterization and Analysis 81
4.4.3 Input Varactor Effects on Class AB PAs 84
4.5 Conclusions 89
References 89
CHAPTER 5
Practical Design of Linear RF Power Amplifiers 91
5.1 Low-Pass Matching Networks 92
5.2 Transmission Line Matching 100
5.3 Shorting the Harmonics 102
5.4 A Generic MESFET 105
5.5 A 2W Class B Design for 850 MHz 107
5.6 The Pi Section Power Matching Network 112
5.7 Pi Section Analysis for PA Design 115
5.8 Class J Design Example 122
5.9 HBT Design Example 124
5.10 Conclusions 129
References 131
CHAPTER 6
Overdriven PAs and the Class F Mode 133
6.1 Introduction 133
6.2 Overdriven Class A Amplifier 134
6.3 Overdriven Class AB Amplifier 139
6.4 Class F: Introduction and Theory 143
6.5 Class F in Practice 149
6.6 The Clipping Model for the Class F Mode—Class FD 155
6.7 PA_Waves 163
6.8 Class F Simulations 164
6.9 Conclusions 171
References 172
CHAPTER 7
Switching Mode Amplifiers for RF Applications 173
7.1 Introduction 173
7.2 A Simple Switching Amplifier 174
7.3 A Tuned Switching Amplifier 178
7.4 The Class D Switching Amplifier 180
7.4 Class E—Introduction 182
7.5 Class E—Simplified Analysis 183
7.6 Class E—Design Example 192
7.7 Conclusions 198
References 199
CHAPTER 8
Switching PA Modes at GHz Frequencies 201
8.1 Introduction 201
8.2 Ignoring the Obvious: Breaking the 100% Barrier 202
8.3 Waveform Engineering 205
8.4 PA_Waves 216
8.5 Implementation and Simulation 225
8.6 Conclusions 227
References 229
CHAPTER 9
Nonlinear Effects in RF Power Amplifiers 231
9.1 Introduction 231
9.2 Two-Carrier Power Series Analysis 233
9.3 Two-Carrier Envelope Analysis 240
9.4 Envelope Analysis with Variable PAR 246
9.5 AM to PM Effects 250
9.6 PA Memory Effects 256
9.7 Digital Modulation Systems 261
9.7.1 Introduction to Digital Modulation 261
9.7.2 QPSK Modulation Systems 262
9.7.3 CDMA and WCDMA 268
9.7.4 OFDM Modulation, 802.11/16 Standards 275
9.8 30 Watt LDMOS Test Amplifier Measurements 278
9.9 Conclusions 282
References 283
CHAPTER 10
Efficiency Enhancement Techniques 285
Introduction 285
10.1 Efficiency Enhancement 286
10.2 The Doherty Amplifier 290
10.3 Realization of the Doherty Amplifier 298
10.4 Outphasing Techniques 303
10.5 Envelope Elimination and Restoration (EER) 309
10.6 Envelope Tracking 311
10.7 Power Converters for EER and ET 314
10.8 Pulse Width Modulation (PWM) 318
10.9 Other Efficiency Enhancement Techniques 323
10.9.1 The Sequential Power Amplifier 323
10.9.2 Pulse Position Modulation 325
10.9.3 RF to DC Conversion 326
10.9.4 RF Switching Techniques 328
10.9.5 Smart Antennas 329
10.10 Case Studies in Efficiency Enhancement 330
10.11 Conclusions 333
References 334
CHAPTER 11
Power Amplifier Bias Circuit Design 337
11.1 Introduction 337
11.2 Stability of RF Power Transistors 338
11.3 Bias Supply Modulation Effects 343
11.4 Bias Network Design 350
11.5 Bias Insertion Networks 353
11.6 Prime Power Supply Issues 354
11.7 Bias Control Circuits 355
11.8 Conclusions 356
References 357
CHAPTER 12
Load-Pull Techniques 359
12.1 Tuner Design for Fundamental Load-Pull 359
12.2 Harmonic Load-Pull 362
12.3 Active Harmonic Load-Pull 365
12.4 Variations, Results, Conclusions 367
References 369
CHAPTER 13
Power Amplifier Architecture 371
Introduction 371
13.1 Push-Pull Amplifiers 372
13.2 Balanced Amplifiers 380
13.3 Power Combining 387
13.4 Multistage PA Design 391
13.5 Conclusions 394
References 395
CHAPTER 14
Power Amplifier Linearization Techniques 397
Introduction 397
14.1 Introduction to PA Linearization 399
14.2 Predistortion 401
14.2.1 Introduction to Predistortion Theory 401
14.2.2 Digital Predistortion (DPD) 404
14.2.3 Analog Predistortion 407
14.2.4 Predistortion—Conclusions 410
14.3 Feedforward Techniques 410
14.3.1 Feedforward, Introduction 410
14.3.2 Feedforward—Gain Compression 411
14.3.3 Feedforward—Effect of the Output Coupler 414
14.3.4 Feedforward—Adaptive Controls 417
14.3.5 Feedforward—Practical Issues, Conclusions 418
14.4 Feedback Techniques 419
14.4.1 Introduction, Direct Feedback Techniques 419
14.4.2 Indirect Feedback Techniques—Introduction 420
14.4.3 The Cartesian Loop 421
14.4.4 The Polar Loop 423
14.5 Other Linearization Methods 424
14.6 Conclusions 425
References 426
APPENDIX A
PA_Waves 429
APPENDIX B
Spectral Analysis Using Excel IQ Spreadsheets 433
Bibliography 435
Introductory Texts on RF and Microwave Techniques 435
Wireless Communications 435
Digital Modulation 435
Nonlinear Techniques and Modeling 435
Power Amplifier Techniques 435
Recommended Reading 436
这个已经发布过了
呵呵,是啊这个第二版应该是以前就有过了