模拟CMOS集成电路设计英文版PDF电子书下载

1Introduction to Analog Design 1

1.1 Why Analog? 1

1.2 Why Integrated? 6

1.3 Why CMOS? 6

1.4 Why This Book? 7

1.5 General Concepts 7

1.5.1 Levels of Abstraction 7

1.5.2 Robust Analog Design 7

2Basic MOS Device Physics 9

2.1 General Considerations 10

2.1.1 MOSFET as a Switch 10

2.1.2 MOSFET Structure 10

2.1.3 MOS Symbols 12

2.2 MOS I/V Characteristics 13

2.2.1 Threshold Voltage 13

2.2.2 Derivation of I/V Characteristics 15

2.3 Second-Order Effects 23

2.4 MOS Device Models 28

2.4.1 MOS Device Layout 28

2.4.2 MOS Device Capacitances 29

2.4.3 MOS Small-Signal Model 33

2.4.4 MOS SPICE models 36

2.4.5 NMOS versus PMOS Devices 37

2.4.6 Long-Channel versus Short-Channel Devices 38

3 Single-Stage Amplifiers 47

3.1 Basic Concepts 47

3.2 Common-Source Stage 48

3.2.1 Common-Source Stage with Resistive Load 48

3.2.2 CS Stage with Diode-Connected Load 53

3.2.3 CS Stage with Current-Source Load 58

3.2.4 CS Stage with Triode Load 59

3.2.5 CS Stage with Source Degeneration 60

3.3 Source Follower 67

3.4 Common-Gate Stage 76

3.5 Cascode Stage 83

3.5.1 Folded Cascode 90

3.6 Choice of Device Models 92

4 Differential Amplifiers 100

4.1 Single-Ended and Differential Operation 100

4.2 Basic Differential Pair 103

4.2.1 Qualitative Analysis 104

4.2.2 Quantitative Analysis 107

4.3 Common-Mode Response 118

4.4 Differential Pair with MOS Loads 124

4.5 Gilbert Cell 126

5 Passive and Active Current Mirrors 135

5.1 Basic Current Mirrors 135

5.2 Cascode Current Mirrors 139

5.3 Active Current Mirrors 145

5.3.1 Large-Signal Analysis 149

5.3.2 Small-Signal Analysis 151

5.3.3 Common-Mode Properties 154

6 Frequency Response of Amplifiers 166

6.1 General Considerations 166

6.1.1 Miller Effect 166

6.1.2 Association of Poles with Nodes 169

6.2 Common-Source Stage 172

6.3 Source Followers 178

6.4 Common-Gate Stage 183

6.5 Cascode Stage 185

6.6 Differential Pair 187

Appendix A:Dual of Miller's Theorem 193

7 Noise 201

7.1 Statistical Characteristics of Noise 201

7.1.1 Noise Spectrum 203

7.1.2 Amplitude Distribution 206

7.1.3 Correlated and Uncorrelated Sources 207

7.2 Types of Noise 209

7.2.1 Thermal Noise 209

7.2.2 Flicker Noise 215

7.3 Representation of Noise in Circuits 218

7.4 Noise in Single-Stage Amplifiers 224

7.4.1 Common-Source Stage 225

7.4.2 Common-Gate Stage 228

7.4.3 Source Followers 231

7.4.4 Cascode Stage 232

7.5 Noise in Differential Pairs 233

7.6 Noise Bandwidth 239

8 Feedback 246

8.1 General Considerations 246

8.1.1 Properties of Feedback Circuits 247

8.1.2 Types of Amplifiers 254

8.2 Feedback Topologies 258

8.2.1 Voltage-Voltage Feedback 258

8.2.2 Current-Voltage Feedback 263

8.2.3 Voltage-Current Feedback 266

8.2.4 Current-Current Feedback 269

8.3 Effect of Loading 270

8.3.1 Two-Port Network Models 270

8.3.2 Loading in Voltage-Voltage Feedback 272

8.3.3 Loading in Current-Voltage Feedback 275

8.3.4 Loading in Voltage-Current Feedback 278

8.3.5 Loading in Current-Current Feedback 281

8.3.6 Summary of Loading Effects 283

8.4 Effect of Feedback on Noise 284

9 Operational Amplifiers 291

9.1 General Considerations 291

9.1.1 Performance Parameters 291

9.2 One-Stage Op Amps 296

9.3 Two-Stage Op Amps 307

9.4 Gain Boosting 309

9.5 Comparison 313

9.6 Common-Mode Feedback 314

9.7 Input Range Limitations 325

9.8 Slew Rate 326

9.9 Power Supply Rejection 334

9.10 Noise in Op Amps 336

10 Stability and Frequency Compensation 345

10.1 General Considerations 345

10.2 Multipole Systems 349

10.3 Phase Margin 351

10.4 Frequency Compensation 355

10.5 Compensation of Two-Stage Op Amps 361

10.5.1 Slewing in Two-Stage Op Amps 368

10.6 Other Compensation Techniques 369

11 Bandgap References 377

11.1 General Considerations 377

11.2 Supply-Independent Biasing 377

11.3 Temperature-Independent References 381

11.3.1 Negative-TC Voltage 381

11.3.2 Positive-TC Voltage 382

11.3.3 Bandgap Reference 384

11.4 PTAT Current Generation 390

11.5 Constant-Gm Biasing 392

11.6 Speed and Noise Issues 393

11.7 Case Study 397

12 Introduction to Switched-Capacitor Circuits 405

12.1 General Considerations 405

12.2 Sampling Switches 410

12.2.1 MOSFETS as Switches 410

12.2.2 Speed Considerations 414

12.2.3 Precision Considerations 417

12.2.4 Charge Injection Cancellation 421

12.3 Switched-Capacitor Amplifiers 423

12.3.1 Unity-Gain Sampler/Buffer 424

12.3.2 Noninverting Amplifier 432

12.3.3 Precision Multiply-by-Two Circuit 438

12.4 Switched-Capacitor Integrator 439

12.5 Switched-Capacitor Common-Mode Feedback 442

13 Nonlinearity and Mismatch 448

13.1 Nonlinearity 448

13.1.1 General Considerations 448

13.1.2 Nonlinearity of Differential Circuits 452

13.1.3 Effect of Negative Feedback on Nonlinearity 454

13.1.4 Capacitor Nonlinearity 457

13.1.5 Linearization Techniques 458

13.2 Mismatch 463

13.2.1 Offset Cancellation Techniques 471

13.2.2 Reduction of Noise by Offset Cancellation 476

13.2.3 Alternative Definition of CMRR 478

14 Oscillators 482

14.1 General Considerations 482

14.2 Ring Oscillators 484

14.3 LC Oscillators 495

14.3.1 Crossed-Coupled Oscillator 499

14.3.2 Colpitts Oscillator 502

14.3.3 One-Port Oscillators 505

14.4 Voltage-Controlled Oscillators 510

14.4.1 Tuning in Ring Oscillators 512

14.4.2 Tuning in LC Oscillators 521

14.5 Mathematical Model of VCOs 525

15 Phase-Locked Loops 532

15.1 Simple PLL 532

15.1.1 Phase Detector 532

15.1.2 Basic PLLTopology 533

15.1.3 Dynamics of Simple PLL 542

15.2 Charge-Pump PLLs 549

15.2.1 Problem of Lock Acquisition 549

15.2.2 Phase/Frequency Detector and Charge Pump 550

15.2.3 Basic Charge-Pump PLL 556

15.3 Nonideal Effects in PLLs 562

15.3.1 PFD/CP Nonidealities 562

15.3.2 Jitter in PLLs 567

15.4 Delay-Locked Loops 569

15.5 Applications 572

15.5.1 Frequency Multiplication and Synthesis 572

15.5.2 Skew Reduction 574

15.5.3 Jitter Reduction 576

16 Short-Channel Effects and Device Models 579

16.1 Scaling Theory 579

16.2 Short-Channel Effects 583

16.2.1 Threshold Voltage Variation 583

16.2.2 Mobility Degradation with Vertical Field 585

16.2.3 Velocity Saturation 587

16.2.4 Hot Carrier Effects 589

16.2.5 Output Impedance Variation with Drain-Source Voltage 589

16.3 MOS Device Models 591

16.3.1 Level 1 Model 592

16.3.2 Level 2 Model 593

16.3.3 Level 3 Model 595

16.3.4 BSIM Series 596

16.3.5 Other Models 597

16.3.6 Charge and Capacitance Modeling 598

16.3.7 Temperature Dependence 599

16.4 Process Corners 599

16.5 Analog Design in a Digital World 600

17 CMOS Processing Technology 604

17.1 General Considerations 604

17.2 Wafer Processing 605

17.3 Photolithography 606

17.4 Oxidation 608

17.5 Ion Implantation 608

17.6 Deposition and Etching 611

17.7 Device Fabrication 611

17.7.1 Active Devices 611

17.7.2 Passive Devices 616

17.7.3 Interconnects 624

17.8 Latch-Up 627

18 Layout and Packaging 631

18.1 General Layout Considerations 631

18.1.1 Design Rules 632

18.1.2 Antenna Effect 634

18.2 Analog Layout Techniques 635

18.2.1 Multifinger Transistors 635

18.2.2 Symmetry 637

18.2.3 Reference Distribution 642

18.2.4 Passive Devices 644

18.2.5 Interconnects 653

18.3 Substrate Coupling 660

Index 677