射频微电子（影印版）

Preface

1 Introduction to RF and Wireless Technology

1.1 Complexity Comparison
1.2 Design Bottleneck
1.3 Applications
1.4 Analog and Digital Systems
1.5 Choice of Technology

2 Basic Concepts in RF Design

2.1 Nonlinearity and Time Variance
2.1.1 Effects of Nonlinearity
2.1.2 Cascaded Nonlinear Stages
2.2 Intersymbol Interference
2.3 Random Processes and Noise
2.3.1 Random Processes
2.3.2 Noise
2.4 Seneitivity and Dynamic Range
2.5 Passive Impedance Transformation
References

3 Modulation and Detection

3.1 General Considerations
3.2 Analog Modulation
3.2.1 Amplitude Modulation
3.2.2 Phase and Frequency Modulation
3.3 Digital Modulation
3.3.1 Basic Concepts
3.3.2 Binary Modulation
3.3.3 Quadrature Modulation
3.4 Power Efficiency of Modulation Schemes
3.4.1 Constant-and Varisble-Envelope Signals
3.4.2 Spectral Regrowth
3.5 Noncoherent Detection
References

4 Multiple Acces Techniques and Wireless Standards

4.1 Mobile RF Communications
4.2 Multiple Access Techniques
4.2.1 Time-and Frequency-Division Duplexing
4.2.2 Frequency-Division Multiple Access
4.2.3 Time-Division Multiple Access
4.2.4 Code-Division Multiple Access
4.3 Wireless Standards
4.3.1 Advanced Mobile Phone Service
4.3.2 North American Digital Standard
4.3.3 Golbal System for Mobile Communication
4.3.4 Qualcomm CDMA
4.3.5 Digital European Cordless Telephone
References

5 Transceiver Architectures

5.1 General Considerations
5.2 Receiver Architectures
5.2.1 Heterodyne Receivers
5.2.2 Homodyne Receivers
5.2.3 Image-Reject Receivers
5.2.4 Digital-IF Receivers
5.2.5 Subgsampling Receivers
5.3 Transmitter Architectures
5.3.1 Direct-Conversion Transmitters
5.3.2 Two-Step Transmitters
5.4 Transceiver Performance Tests
5.5 Case Studies
5.5.1 Motorola's FM Receiver
5.5.2 Philips' Pager Receiver
5.5.3 Philips' DECT Transceiver
5.5.4 Lunent Technologies' GSM Transceiver
5.5.5 Philips'GSM Transceiver
References

6 Low-Noise Amplifiers and Mixers

6.1 Low-Noise Amplifiers
6.1.1 General Considerations
6.1.2 Input Matching
6.1.3 Bipolar LNAs
6.1.4 CMOS LNAs
6.2 Downconversio Mixers
6.2.1 General Considerations
6.2.2 Bipolar Mixers
6.2.3 CMOS Mixers
6.2.4 Noise in Mixers
6.3 Cascaded Stages Revisited
References

7 Oscillators

7.1 General Considerations
7.2 Basic LC Oscillator Topologies
7.3 Voltage-Controlled Oscillators
7.4 Phase Noise
7.4.1 Effect of Phase Noise in RF Communications
7.4.2 Q of an Oscillator
7.4.3 Phase Noise Mechanisms
7.4.4 Noise-Power Trade-off
7.4.5 Effect of Frequency Division and Multiplicationj on Phase Noise
7.4.6 Oscillator Pulling and Pushing
7.5 Bipolar and CMOS LC Oscillators
7.5.1 Negative-Gm Oscillators
7.5.2 Interpolative Oscillators
7.6 Monolithic Inductors
7.7 Resonatorless VCOs
7.8 Quadrature Signal Generation
7.8.1 RC-CR Netword
7.8.2 Havents' Technique
7.8.3 Frequency Division
7.9 Single-Sideband Generation
References

8 Frequency Synthesizers

8.1 General Considerations
8.2 Phase-Locked Loops
8.2.1 Basic Concepts
8.2.2 Basic PLL
8.2.3 Charge-Pump PLLs
8.2.4 Type I and Type II PLLs
8.2.5 Noise in PLLs
8.2.6 Phase Noise at Input
8.2.7 Phase Noise of VCO
8.2.8 Frequency Multiplication
8.3 RF Synthesizer Architectures
8.3.1 Integer-N Architecture
8.3.2 Fractional-N Architecture
8.3.3 Dual-Loop Architectures
8.3.4 Direct Digital Synthesis
8.4 Frequency Dividers
8.4.1 Divide-by-Two Circuits
8.4.2 Dual-Modulus Dividers
References

9 Power Amplifiers

9.1 General Considerations
9.1.1 Linear and Nonlinear PAs
9.2 Classification of Power  Amplifiers
9.2.1 Class A and B PAs
9.2.2 Class C PAs
9.3 High-Efficiency Power Amplifiers
9.4 Large-Signal Impedance Matching
9.5 Linearization Techniques
9.5.1 Feedforward
9.5.2 Feedback
9.5.3 Envelope Elimination and Restoration
9.5.4 LINC
9.6Design Examples
References