射頻微電子（影印版）

定　價(jià)：￥35.00

作　者：	（美）Behzad Razavi著
出版社：	清華大學(xué)出版社
叢編項(xiàng)：	國(guó)外大學(xué)優(yōu)秀教材微電子類系列
標(biāo)　簽：	暫缺

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ISBN：	9787302075226	出版時(shí)間：	2003-12-01	包裝：	平裝
開本：	23cm	頁(yè)數(shù)：	335	字?jǐn)?shù)：

內(nèi)容簡(jiǎn)介

　　Behzad Razavi所著的RF Microelectronics一書既可供高年級(jí)大學(xué)生或研究生作教科書用，又可滿足集成電路設(shè)計(jì)工作者進(jìn)一步提高自身知識(shí)和設(shè)計(jì)技能之目的。相對(duì)其他RF CMOS電路的書籍而言，本書的特點(diǎn)是系統(tǒng)級(jí)的介紹較為詳細(xì)。即它將無(wú)線通信電路系統(tǒng)的描述、器件特性及單元電路分析融合在一起，使讀者有一個(gè)完整的概念。本書共分9章。第1和第2章首先介紹了在射頻電子學(xué)經(jīng)常遇到的概念和術(shù)語(yǔ)，并給出了評(píng)價(jià)射頻電路性能的主要指標(biāo)；第3章定義和描述了模擬信號(hào)和數(shù)字信號(hào)的調(diào)幅、調(diào)相和調(diào)頻調(diào)制方法；第4章專門介紹3種在無(wú)線通信系統(tǒng)中通用的多路存取技術(shù)：FDMA，TDMA和CDMA，及幾種常用的無(wú)線通信標(biāo)準(zhǔn)，如GSM和Qualcomm 公司的CDMA；第5章是本書的重點(diǎn)，討論了無(wú)線前端收發(fā)器的結(jié)構(gòu)和集成電路的實(shí)現(xiàn)；第6章至第9章詳細(xì)討論了低噪聲放大器和混頻器、振蕩器、頻率綜合器和功放器電路原理和分析方法。

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圖書目錄

Preface
1  Introduction to RF and Wireless Technology
1.1  Complexity Comparison  2
1.2  Design Bottleneck 4
1.3  Applications 6
1.4  Analog and Digital Systems 7
1.5  Choice of Technology  9
References  10
2  Basic Concepts in RF Design
2.1  Nonlinearity and Time Variance  11
2.1.1  Effects of Nonlinearity 14
2.1.2  Cascaded Nonlinear Stages 22
2.2  Intersymbol Interference 25
2.3  Random Processes and Noise  28
2.3.1  Random Processes  29
2.3.2  Noise 37
2.4  Sensitivity and Dynamic Range  48
2.5   Passive Impedance Transformation 50
References 53
3  Modulation and Detection
3.1   General Considerations 54
3.2  Analog Modulation 57
3.2.1  Amplitude Modulation 57
3.2.2  Phase and Frequency Modulation  58
3.3  Digital Modulation 63
3.3.1  Basic Concepts 64
3.3.2  Binary Modulation 74
3.3.3  Quadrature Modulation 81
3.4  Power Efficiency of Modulation Schemes 90
3.4.1  Constant- and Variable-Envelope Signals  90
3.4.2  Spectral Regrowth 91
3.5   Noncoherent Detection  93
References  96
4 Multiple Access Techniques and Wireless Standards
4.1  Mobile RF Communications 98
4.2  Multiple Access Techniques  103
4.2.1  Tune- and Frequency-Division Duplexing 103
4.2.2  Frequency-Division Multiple Access  105
4.2.3  Tune-Division Multiple Access  105
4.2.4  Code-Division Multiple Access 107
4.3   Wireless Standards  110
4.3.1  Advanced Mobile Phone Service  111
4.3.2  North American Digital Standard  112
4.3.3  Global System for Mobile Communication  113
4.3.4  Qualcomm CDMA 114
4.3.5  Digital European Cordless Telephone  116
References 117
5  Transceiver Architectures
5.1  General Considerations 118
5.2  Receiver Architectures  122
5.2.1  Heterodyne Receivers  122
5.2.2  Homodyne Receivers  129
5.2.3  Image-Reject Receivers  138
5.2.4  Digital-IF Receivers 146
5.2.5  Subsampling Receivers  147
5.3  Transmitter Architectures 149
5.3.1  Direct-Conversion Transmitters  152
5.3.2  Two-Step Transmitters 154
5.4  Transceiver Performance Tests  155
5.5  Case Studies 157
5.5.1  Motorola's FM Receiver  157
5.5.2  Philips' Pager Receiver  158
5.5.3  Philips' DECT Transceiver  159
5.5.4  Lucent Technologies' GSM Transceiver 161
5.5.5  Philips' GSM Transceiver  162
References  163
6  Low-Noise Amplifiers and Mixers
6.1  Low-Noise Amplifiers  166
6.1.1  General Considerations  166
6.1.2  Input Matching 170
6.1.3  Bipolar LNAs  173
6.1.4  CMOS LNAs  178
6.2  Downconversion Mixers  180
6.2.1  General Considerations  180
6.2.2  Bipolar Mixers  188
6.2.3  CMOS Mixers  192
6.2.4  Noise in Mixers  194
6.3  Cascaded Stages Revisited 200
References  204
7  Oscillators
7.1  General Considerations  206
7.2  Basic LC Oscillator Topologies 209
7.3  Voltage-Controlled Oscillators 212
7.4  Phase Noise  214
7.4.1  Effect of Phase Noise in RF Communications 215
7.4.2  Q of an Oscillator 217
7.4.3  Phase Noise Mechanisms  220
7.4.4  Noise-Power Trade-off 224
7.4.5  Effect of Frequency Division and Multiplication on Phase Noise 224
7.4.6  Oscillator Pulling and Pushing 225
7.5  Bipolar and CMOS LC Oscillators 227
7.5.1  Negative-Gm Oscillators  227
7.5.2  Interpolative Oscillators 231
7.6  Monolithic Inductors 233
7.7  Resonatorless VCOs  235
7.8  Quadrature Signal Generation  236
7.8.1  RC-CR Network 236
7.8.2  Havens' Technique 239
7.8.3  Frequency Division 243
7.9  Single-Sideband Generation  243
References  244
8  Frequency Synthesizers
8.1  General Considerations  247
8.2  Phase-Locked Loops  249
8.2.1  Basic Concepts 249
8.2.2  Basic PLL 252
8.2.3  Charge-Pump PLLs  258
8.2.4  Type I and Type II PLLs 265
8.2.5  Noise in PLLs 266
8.2.6  Phase Noise at Input 266
8.2.7  Phase Noise of VCO 267
8.2.8  Frequency Multiplication 269
8.3  RF Synthesizer Architectures  269
8.3.1  Integer-N Architecture 270
8.3.2  Fractional-N Architecture  277
8.3.3  Dual-Loop Architectures 284
8.3.4  Direct Digital Synthesis 285
8.4  Frequency Dividers  290
8.4.1  Divide-by-Two Circuits  290
8.4.2  Dual-Modulus Dividers 293
References 296
9  Power Amplifiers
9.1  General Considerations 298
9.1.1  Linear and Nonlinear PAs  301
9.2  Classification of Power Amplifiers  301
9.2.1  Class A and B PAs 302
9.2.2  Class C PAs 305
9.3  High-Efficiency Power Amplifiers  306
9.4  Large-Signal Impedance Matching 310
9.5  Linearization Techniques  313
9.5.1  Feedforward  314
9.5.2  Feedback 315
9.5.3  Envelope Elimination and Restoration  317
9.5.4  LINC  318
9.6  Design Examples  320
References 323