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射频微电子(英文版)第二版

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资源简介
射频微电子(英文版)第二版
作者:(美)毕查德,(美)拉扎维 著
出版时间:2012年版
内容简介
  《国外电子与通信教材系列:射频微电子(第2版)(英文版)》侧重系统级描述,综合了无线通信电路系统描述、器件特性及单元电路分析,讨论最新架构、电路和器件。第1和第2章首先介绍射频电子学基本概念和术语;第3章和第4章讨论通信系统层的建模、检测、多路存取等技术及无线标准;第5章讨论无线前端收发器的结构和集成电路的实现,第6章到第9章详细讨论了低噪声放大器和混频器、振荡器、频率综合器和功放器电路原理和分析方法。
目录
CHAPTER 1 INTRODUCTION TO RF AND WIRELESS TECHNOLOGY
 1.1 A Wireless World
 1.2 RF Design Is Challenging
 1.3 The Big Picture
 References
CHAPTER 2 BASIC CONCEPTS IN RF DESIGN
 2.1 General Considerations
 2.1.1 Units in RF Design
 2.1.2 Time Variance
 2.1.3 Nonlinearity
 2.2 Effects of Nonlinearity
 2.2.1 Harmonic Distortion
 2.2.2 Gain Compression
 2.2.3 Cross Modulation
 2.2.4 Intermodulation
 2.2.5 Cascaded Nonlinear Stages
 2.2.6 AM/PM Conversion
 2.3 Noise
 2.3.1 Noise as a Random Process
 2.3.2 Noise Spectrum
 2.3.3 Effect of Transfer Function on Noise
 2.3.4 Device Noise
 2.3.5 Representation of Noise in Circuits
 2.4 Sensitivity and Dynamic Range
 2.4.1 Sensitivity
 2.4.2 Dynamic Range
 2.5 Passive Impedance Transformation
 2.5.1 Quality Factor
 2.5.2 Series-to-Parallel Conversion
 2.5.3 Basic Matching Networks
 2.5.4 Loss in Matching Networks
 2.6 Scattering Parameters
 2.7 Analysis of Nonlinear Dynamic Systems
 2.7.1 Basic Considerations
 2.8 Volterra Series
 2.8.1 Method of Nonlinear Currents
 References
 Problems
CHAPTER 3 COMMUNICATION CONCEPTS
 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 Intersymbol Interference
 3.3.2 Signal Constellations
 3.3.3 Quadrature Modulation
 3.3.4 GMSK and GFSK Modulation
 3.3.5 Quadrature Amplitude Modulation
 3.3.6 Orthogonal Frequency Division Multiplexing
 3.4 Spectral Regrowth
 3.5 Mobile RF Communications
 3.6 Multiple Access Techniques
 3.6.1 Time and Frequency Division Duplexing
 3.6.2 Frequency-Division Multiple Access
 3.6.3 Time-Division Multiple Access
 3.6.4 Code-Division Multiple Access
 3.7 Wireless Standards
 3.7.1 GSM
 3.7.2 IS-95 CDMA
 3.7.3 Wideband CDMA
 3.7.4 Bluetooth
 3.7.5 IEEE802.11a/b/g
 3.8 Appendix I: Differential Phase Shift Keying
 References
 Problems
CHAPTER 4 TRANSCEIVER ARCHITECTURES
 4.1 General Considerations
 4.2 Receiver Architectures
 4.2.1 Basic Heterodyne Receivers
 4.2.2 Modern Heterodyne Receivers
 4.2.3 Direct-Conversion Receivers
 4.2.4 Image-Reject Receivers
 4.2.5 Low-IF Receivers
 4.3 Transmitter Architectures
 4.3.1 General Considerations
 4.3.2 Direct-Conversion Transmitters
 4.3.3 Modern Direct-Conversion Transmitters
 4.3.4 Heterodyne Transmitters
 4.3.5 Other TX Architectures
 4.4 OOK Transceivers
 References
 Problems
CHAPTER 5 LOW-NOISE AMPLIFIERS
 5.1 General Considerations
 5.2 Problem of Input Matching
 5.3 LNA Topologies
 5.3.1 Common-Source Stage with Inductive Load
 5.3.2 Common-Source Stage with Resistive Feedback
 5.3.3 Common-Gate Stage
 5.3.4 Cascode CS Stage with Inductive Degeneration
 5.3.5 Variants of Common-Gate LNA
 5.3.6 Noise-Cancelling LNAs
 5.3.7 Reactance-Cancelling LNAs
 5.4 Gain Switching
 5.5 Band Switching
 5.6 High-IP2 LNAs
 5.6.1 Differential LNAs
 5.6.2 Other Methods of IP2 Improvement
 5.7 Nonlinearity Calculations
 5.7.1 Degenerated CS Stage
 5.7.2 Undegenerated CS Stage
 5.7.3 Differential and Quasi-Differential Pairs
 5.7.4 Degenerated Differential Pair
 References
 Problems
CHAPTER 6 MIXERS
 6.1 General Considerations
 6.1.1 Performance Parameters
 6.1.2 Mixer Noise Figures
 6.1.3 Single-Balanced and Double-Balanced Mixers
 6.2 Passive Downconversion Mixers
 6.2.1 Gain
 6.2.2 LO Self-Mixing
 6.2.3 Noise
 6.2.4 Input Impedance
 6.2.5 Current-Driven Passive Mixers
 6.3 Active Downconversion Mixers
 6.3.1 Conversion Gain
 6.3.2 Noise in Active Mixers
 6.3.3 Linearity
 6.4 Improved Mixer Topologies
 6.4.1 Active Mixers with Current-Source Helpers
 6.4.2 Active Mixers with Enhanced Transconductance
 6.4.3 Active Mixers with High IP2
 6.4.4 Active Mixers with Low Flicker Noise
 6.5 Upconversion Mixers
 6.5.1 Performance Requirements
 6.5.2 Upconversion Mixer Topologies
 References
 Problems
CHAPTER 7 PASSIVE DEVICES
 7.1 General Considerations
 7.2 Inductors
 7.2.1 Basic Structure
 7.2.2 Inductor Geometries
 7.2.3 Inductance Equations
 7.2.4 Parasitic Capacitances
 7.2.5 Loss Mechanisms
 7.2.6 Inductor Modeling
 7.2.7 Alternative Inductor Structures
 7.3 Transformers
 7.3.1 Transformer Structures
 7.3.2 Effect of Coupling Capacitance
 7.3.3 Transformer Modeling
 7.4 Transmission Lines
 7.4.1 T-Line Structures
 7.5 Varactors
 7.6 Constant Capacitors
 7.6.1 MOS Capacitors
 7.6.2 Metal-Plate Capacitors
 References
 Problems
CHAPTER 8 OSCILLATORS
 8.1 Performance Parameters
 8.2 Basic Principles
 8.2.1 Feedback View of Oscillators
 8.2.2 One-Port View of Oscillators
 8.3 Cross-Coupled Oscillator
 8.4 Three-Point Oscillators
 8.5 Voltage-Controlled Oscillators
 8.5.1 Tuning Range Limitations
 8.5.2 Effect of Varactor Q
 8.6 LC VCOs with Wide Tuning Range
 8.6.1 VCOs with Continuous Tuning
 8.6.2 Amplitude Variation with Frequency Tuning
 8.6.3 Discrete Tuning
 8.7 Phase Noise
 8.7.1 Basic Concepts
 8.7.2 Effect of Phase Noise
 8.7.3 Analysis of Phase Noise: Approach I
 8.7.4 Analysis of Phase Noise: Approach II
 8.7.5 Noise of Bias Current Source
 8.7.6 Figures of Merit of VCOs
 8.8 Design Procedure
 8.8.1 Low-Noise VCOs
 8.9 LO Interface
 8.10 Mathematical Model of VCOs
 8.11 Quadrature Oscillators
 8.11.1 Basic Concepts
 8.11.2 Properties of Coupled Oscillators
 8.11.3 Improved Quadrature Oscillators
 8.12 Appendix I: Simulation of Quadrature Oscillators
 References
 Problems
CHAPTER 9 PHASE-LOCKED LOOPS
 9.1 Basic Concepts
 9.1.1 Phase Detector
 9.2 Type-I PLLs
 9.2.1 Alignment of a VCO’s Phase
 9.2.2 Simple PLL
 9.2.3 Analysis of Simple PLL
 9.2.4 Loop Dynamics
 9.2.5 Frequency Multiplication
 9.2.6 Drawbacks of Simple PLL
 9.3 Type-II PLLs
 9.3.1 Phase/Frequency Detectors
 9.3.2 Charge Pumps
 9.3.3 Charge-Pump PLLs
 9.3.4 Transient Response
 9.3.5 Limitations of Continuous-Time Approximation
 9.3.6 Frequency-Multiplying CPPLL
 9.3.7 Higher-Order Loops
 9.4 PFD/CP Nonidealities
 9.4.1 Up and Down Skew and Width Mismatch
 9.4.2 Voltage Compliance
 9.4.3 Charge Injection and Clock Feedthrough
 9.4.4 Random Mismatch between Up and Down Currents
 9.4.5 Channel-Length Modulation
 9.4.6 Circuit Techniques
 9.5 Phase Noise in PLLs
 9.5.1 VCO Phase Noise
 9.5.2 Reference Phase Noise
 9.6 Loop Bandwidth
 9.7 Design Procedure
 9.8 Appendix I: Phase Margin of Type-II PLLs
 References
 Problems
CHAPTER 10 INTEGER-N FREQUENCY SYNTHESIZERS
 10.1 General Considerations
 10.2 Basic Integer-N Synthesizer
 10.3 Settling Behavior
 10.4 Spur Reduction Techniques
 10.5 PLL-Based Modulation
 10.5.1 In-Loop Modulation
 10.5.2 Modulation by Offset PLLs
 10.6 Divider Design
 10.6.1 Pulse Swallow Divider
 10.6.2 Dual-Modulus Dividers
 10.6.3 Choice of Prescaler Modulus
 10.6.4 Divider Logic Styles
 10.6.5 Miller Divider
 10.6.6 Injection-Locked Dividers
 10.6.7 Divider Delay and Phase Noise
 References
 Problems
CHAPTER 11 FRACTIONAL-N SYNTHESIZERS
 11.1 Basic Concepts
 11.2 Randomization and Noise Shaping
 11.2.1 Modulus Randomization
 11.2.2 Basic Noise Shaping
 11.2.3 Higher-Order Noise Shaping
 11.2.4 Problem of Out-of-Band Noise
 11.2.5 Effect of Charge Pump Mismatch
 11.3 Quantization Noise Reduction Techniques
 11.3.1 DAC Feedforward
 11.3.2 Fractional Divider
 11.3.3 Reference Doubling
 11.3.4 Multiphase Frequency Division
 11.4 Appendix I: Spectrum of Quantization Noise
 References
 Problems
CHAPTER 12 POWER AMPLIFIERS
 12.1 General Considerations
 12.1.1 Effect of High Currents
 12.1.2 Efficiency
 12.1.3 Linearity
 12.1.4 Single-Ended and Differential PAs
 12.2 Classification of Power Amplifiers
 12.2.1 Class A Power Amplifiers
 12.2.2 Class B Power Amplifiers
 12.2.3 Class C Power Amplifiers
 12.3 High-Efficiency Power Amplifiers
 12.3.1 Class A Stage with Harmonic Enhancement
 12.3.2 Class E Stage
 12.3.3 Class F Power Amplifiers
 12.4 Cascode Output Stages
 12.5 Large-Signal Impedance Matching
 12.6 Basic Linearization Techniques
 12.6.1 Feedforward
 12.6.2 Cartesian Feedback
 12.6.3 Predistortion
 12.6.4 Envelope Feedback
 12.7 Polar Modulation
 12.7.1 Basic Idea
 12.7.2 Polar Modulation Issues
 12.7.3 Improved Polar Modulation
 12.8 Outphasing
 12.8.1 Basic Idea
 12.8.2 Outphasing Issues
 12.9 Doherty Power Amplifier
 12.10 Design Examples
 12.10.1 Cascode PA Examples
 12.10.2 Positive-Feedback PAs
 12.10.3 PAs with Power Combining
 12.10.4 Polar Modulation PAs
 12.10.5 Outphasing PA Example
 References
 Problems
CHAPTER 13 TRANSCEIVER DESIGN EXAMPLE
 13.1 System-Level Considerations
 13.1.1 Receiver
 13.1.2 Transmitter
 13.1.3 Frequency Synthesizer
 13.1.4 Frequency Planning
 13.2 Receiver Design
 13.2.1 LNA Design
 13.2.2 Mixer Design
 13.2.3 AGC
 13.3 TX Design
 13.3.1 PA Design
 13.3.2 Upconverter
 13.4 Synthesizer Design
 13.4.1 VCO Design
 13.4.2 Divider Design
 13.4.3 Loop Design
 References
 Problems
 INDEX
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