Artech.House.-.Nonlinear.Microwave.and.RF.Circuits.(2nd)

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【文件名】:0932@52RD_Artech.House.-.Nonlinear.Microwave.and.RF.Circuits.(2nd).rar
【格　式】:rar
【大　小】:3631K
【简　介】:
【目　录】:
Chapter 1 Introduction, Fundamental Concepts, and Definitions 1
1.1 Linearity and Nonlinearity 1
1.2 Frequency Generation 4
1.3 Nonlinear Phenomena 13
1.3.1 Harmonic Generation 13
1.3.2 Intermodulation Distortion 14
1.3.3 Saturation and Desensitization 14
1.3.4 Cross Modulation 15
1.3.5 AM-to-PM Conversion 15
1.3.6 Spurious Responses 16
1.3.7 Adjacent Channel Interference 16
1.4 Approaches to Analysis
Chapter 2 Solid-State Device Modeling for Quasistatic Analysis 29
2.1 Nonlinear Device Models 29
2.2 Nonlinear Lumped Circuit Elements and
Controlled Sources 31
2.2.1 The Substitution Theorem 33
2.2.2 Large-Signal Nonlinear Resistive Elements 34
2.2.3 Small-Signal Nonlinear Resistive Elements 35
2.2.4 Large-Signal Nonlinear Capacitance 38
2.2.5 Small-Signal Nonlinear Capacitance 39
2.2.6 Relationship Between I/V, Q/V and G/V, C/V
Expansions 41
2.2.7 Multiply Controlled Nonlinear Capacitors 43
2.2.8 Nonlinear Inductance 47
2.3 Numerical and Human Requirements for Device
Models 48
2.3.1 Continuous Derivatives in
Chapter 3 Harmonic-Balance Analysis and Related Methods 119
3.1 Why Use Harmonic-Balance Analysis? 119
3.2 An Heuristic Introduction to
Harmonic-Balance Analysis 120
3.3 Single-Tone Harmonic-Balance Analysis 124
3.3.1 Circuit Partitioning 124
3.3.2 The Nonlinear Subcircuit 129
3.3.3 The Linear Subcircuit 135
3.3.4 Solution Algorithms 137
3.3.5 Newton Solution of the Harmonic-
Balance Equation 140
3.3.6 Selecting the Number of Harmonics
and Time Samples 149
3.3.7 Matrix Methods for Solving (3.37) 151
3.3.8 Norm Reduction 155
3.3.9 Optimizing Convergence and Efficiency 156
3.4 Large-Signal/Small-Signal Analysis Using
Conversion Matrices 164
3.4.1 Conversion Matrix Formulation
Chapter 4 Volterra-Series and Power-Series Analysis 215
4.1 Power-Series Analysis 216
4.1.1 Power-Series Model and Multitone
Response 216
4.1.2 Frequency Generation 224
4.1.3 Intercept Point and Power Relations 225
4.1.4 Intermodulation Measurement 231
4.1.5 Interconnections of Weakly Nonlinear
Components 232
4.2 Volterra-Series Analysis 235
4.2.1 Introduction to the V
Chapter 5 Balanced and Multiple-Device Circuits 277
5.1 Balanced Circuits Using Microwave Hybrids 278
5.1.1 Properties of Ideal Hybrids 278
5.1.2 Practical Hybrids 280
5.1.3 Properties of Hybrid-Coupled Components 288
5.2 Direct Interconnection of Microwave Components 300
5.2.1 Harmonic Properties of Two-Terminal
Device Interconnections 301
References 315
Chapter 6 Diode Mixers 317
6.1 Mixer Diodes
Chapter 7 Diode Frequency Multipliers 355
7.1 Varactor Frequency Multipliers 356
7.1.1 Noise Considerations 356
7.1.2 Power Relations and Efficiency
Limitations 357
7.1.3 Design of Varactor Frequency Multipliers 361
7.1.4 Design Example of a Varactor Multiplier 364
7.1.5 Final Details
Chapter 8 Small-Signal Amplifiers 395
8.1 Review of Linear Amplifier Theory 395
8.1.1 Stability Considerations in Linear
Amplifier Design 395
8.1.2 Amplifier Design 400
8.1.3 Characteristics of FETs and Bipolars
in Small-Signal Amplifiers 405
8.1.4 Broadband Amplifiers 406
8.1.5 Negative Image Modeling 407
8.2 Nonlinear Analysis 409
8.2.1 Nonlinearities in FETs 410
8.2.2 Nonlinearities in Bipolar Devices 413
8.2.3 Nonlinear Phenomena in Small-Signal
Amplifiers 415
8.2.4 Calculating the Nonlinear Transfer
Functions 421
8.3 Linearity Optimization 421
8.3.1 Linearity Criteria 421
8.3.2 MESFETs and HEMTs 423
8.3.3 HBTs and BJTs 428
References 430
Chapter 9 Power Amplifiers 431
9.1 FET and Bipolar Devices

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where is the book?