powerpoint or word format. This new edition has been thoroughly revised and updated by Tony Chan Carusone, a University of Toronto colleague of Drs. sample-and-holds and voltage references. Using the menu at the top, select a chapter. ISBN: 0-471-14448-7, 706 Pages, Cloth, 1997, In Canada, call 1-800-567-4797 For reference use, this book is intended to rapidly increase a practicing Using the menu at the top, select a resource. DAVID JOHNS and KEN MARTIN , Univ. Comprehensive coverage of A/D and D/A converters including oversampling Welcome to the Web site for Analog Integrated Circuit Design, 2nd Edition by Tony Chan Carusone, David A. Johns, Kenneth W. Martin. All right reserved. An intuitive approach and emphasis on practical design and analysis make it the reference for both students and practicing analog designers alike. For classroom use, the chapters have intentially been made mostly When first published in 1996, this text by David Johns and Kenneth Martin quickly became a leading textbook for the advanced course on Analog IC Design. Coverage has been added on several types of circuits that have increased in importance in the past decade, such as generalized integer-N phase locked loops and their phase noise analysis, voltage regulators, and 1.5b-per-stage pipelined A/D converters. Emphasizes CMOS analog circuit design rather than bipolar design. as a reference for practicing engineers. Modern coverage of phase-locked-loops including the popular charge-pump DAVID JOHNS and KEN MARTIN, Univ. Two new chapters have been added to make the book more accessible to beginners in the field: frequency response of analog ICs; and basic theory of feedback amplifiers. Since 2001, he has been with the Department of Electrical and Computer Engineering at the University of Toronto where he is currently an Associate Professor. Would you like to change to the United States site? He has served as a guest editor for both the IEEE Journal of Solid-State Circuits and the IEEE Transactons on Circuits and Systems I: Regular Papers, and served on the editorial board of the IEEE Transactons on Circuits and Systems II: Express Briefs from 2006 untl 2009 when he was Editor-in-Chief. and Ph.D. degrees at the University of Toronto in 1997 and 2002 respectvely, during which tme he received the Governor-General's Silver Medal. of Toronto ISBN: 0-471-14448-7, 706 Pages, Cloth, 1997 . Tony was a co-author of the best student papers at both the 2007 and 2008 Custom Integrated Circuits Conference and the best paper at the 2005 Compound Semiconductor Integrated Circuits Symposium. have been highlighted and modern design examples are included throughout. This book is intended for use as a senior or graduate level textbook and Johns and Martin. To Order Individual or Sample Copies: In Canada, call 1-800-567-4797 In the USA, call 1-800-225-5945 . Analog Integrated Circuit Design, 2nd Edition. Click here to download instructor slides in pdf form (extract the 816 Pages. Request permission to reuse content from this site, 1.1.4 Large-Signal Junction Capacitance 9, 1.1.6 Junction Capacitance of Forward-Biased Diode 11, 1.1.7 Small-Signal Model of a Forward-Biased Diode 12, 1.2.6 Low-Frequency Small-Signal Modelling in the Active Region 25, 1.2.7 High-Frequency Small-Signal Modelling in the Active Region 30, 1.2.8 Small-Signal Modelling in the Triode and Cutoff Regions 33, 1.2.9 Analog Figures of Merit and Trade-offs 36, 1.4.3 Summary of Subthreshold and Mobility Degradation Equations 47, 1.5.3 Advanced SPICE Models of MOS Transistors 51, 1.7.3 MOS Threshold Voltage and the Body Effect 64, 2.1.2 Photolithography and Well Definition 74, 2.1.4 Chemical Vapor Deposition and Defining the Active Regions 78, 2.1.6 Gate-Oxide and Threshold-Voltage Adjustments 81, 2.1.8 Implanting the Junctions, Depositing SiO2, and Opening Contact Holes 82, 2.1.9 Annealing, Depositing and Patterning Metal, and Overglass Deposition 84, 2.3.1 Systematic Variations Including Proximity Effects 96, CHAPTER 3 BASIC CURRENT MIRRORS AND SINGLE-STAGE AMPLIFIERS 117, 3.3 Source-Follower or Common-Drain Amplifier 122, 3.5 Source-Degenerated Current Mirrors 127, 3.8 MOS Differential Pair and Gain Stage 135, CHAPTER 4 FREQUENCY RESPONSE OF ELECTRONIC CIRCUITS 144, 4.1 Frequency Response of Linear Systems 144, 4.1.3 Second-Order Low-Pass Transfer Functions with Real Poles 154, 4.1.5 Second-Order Low-Pass Transfer Functions with Complex Poles 163, 4.2 Frequency Response of Elementary Transistor Circuits 165, 4.2.1 High-Frequency MOS Small-Signal Model 165, 4.2.3 Miller Theorem and Miller Effect 169, 4.2.4 Zero-Value Time-Constant Analysis 173, 4.5.2 Symmetric Differential Amplifier 194, 4.5.3 Single-Ended Differential Amplifier 195, 4.5.4 Differential Pair with Active Load 196, 5.2 Dynamic Response of Feedback Amplifiers 208, 5.3 First- and Second-Order Feedback Systems 213, 5.4.3 Transimpedance (Inverting) Amplifiers 231, CHAPTER 6 BASIC OPAMP DESIGN AND COMPENSATION 242, 6.1.4 n-Channel or p-Channel Input Stage 252, 6.2.1 Dominant-Pole Compensation and Lead Compensation 254, 6.2.2 Compensating the Two-Stage Opamp 255, 6.2.3 Making Compensation Independent of Process and Temperature 259, 6.3.2 Enhanced Output-Impedance Current Mirrors and Gain Boosting 263, 6.3.3 Wide-Swing Current Mirror with Enhanced Output Impedance 266, 6.7.1 Fully Differential Folded-Cascode Opamp 283, 6.7.2 Alternative Fully Differential Opamps 284, CHAPTER 7 BIASING, REFERENCES, AND REGULATORS 302, 7.1 Analog Integrated Circuit Biasing 302, 7.2 Establishing Constant Transconductance 307, 7.2.1 Basic Constant-Transconductance Circuit 307, 7.2.2 Improved Constant-Transconductance Circuits 309, 7.3 Establishing Constant Voltages and Currents 310, 7.3.1 Bandgap Voltage Reference Basics 310, 7.3.2 Circuits for Bandgap References 314, CHAPTER 8 BIPOLAR DEVICES AND CIRCUITS 331, 8.4.2 Modern SiGe BiCMOS HBT Processing 347, 8.5 Bipolar Current Mirrors and Gain Stages 349, 8.6.1 Bipolar Transistor Exponential Relationship 356, 8.6.2 Base Charge Storage of an Active BJT 359, CHAPTER 9 NOISE AND LINEARITY ANALYSIS AND MODELLING 363, 9.3 Noise Models for Circuit Elements 377, 9.4.4 Fiber-Optic Transimpedance Amplifier Example 395, 9.5.1 Total Harmonic Distortion (THD) 398, 9.5.2 Third-Order Intercept Point (IP3) 400, 9.5.3 Spurious-Free Dynamic Range (SFDR) 402, 9.5.4 Signal-to-Noise and Distortion Ratio (SNDR) 404, 10.3.1 Making Charge-Injection Signal Independent 421, 10.3.2 Minimizing Errors Due to Charge-Injection 421, 10.3.3 Speed of Multi-Stage Comparators 424, 10.5 Examples of CMOS and BiCMOS Comparators 431, 10.5.1 Input-Transistor Charge Trapping 435, CHAPTER 11 SAMPLE-AND-HOLD AND TRANSLINEAR CIRCUITS 444, 11.1 Performance of Sample-and-Hold Circuits 444, 11.4 Bipolar and BiCMOS Sample-and-Holds 456, 12.1 Introduction to Continuous-Time Filters 469, 12.2.2 Fully Differential Integrators 474, 12.3 Transconductors Using Fixed Resistors 479, 12.4 CMOS Transconductors Using Triode Transistors 484, 12.4.1 Transconductors Using a Fixed-Bias Triode Transistor 484, 12.4.2 Transconductors Using Varying Bias-Triode Transistors 486, 12.4.3 Transconductors Using Constant Drain-Source Voltages 491, 12.5 CMOS Transconductors Using Active Transistors 493, 12.5.2 Constant Sum of Gate-Source Voltages 494, 12.5.3 Source-Connected Differential Pair 495, 12.5.5 Differential-Pair with Floating Voltage Sources 497, 12.5.6 Bias-Offset Cross-Coupled Differential Pairs 499, 12.6.2 Transconductors Using Multiple Differential Pairs 501, 12.7.2 Fixed-Resistor Transconductor with a Translinear Multiplier 507, 12.7.3 Fixed Active MOS Transconductor with a Translinear Multiplier 508, 12.8.2 MOSFET-C Two-Transistor Integrators 512, 12.9.5 Tuning Methods Based on Adaptive Filtering 523, 12.10 Introduction to Complex Filters 525, 12.10.4 Frequency-Translated Analog Filters 528, 13.2 Laplace Transforms of Discrete-Time Signals 537, 13.2.1 Spectra of Discrete-Time Signals 540, 13.5.1 Frequency Response of Discrete-Time Filters 545, 13.5.2 Stability of Discrete-Time Filters 548, CHAPTER 14 SWITCHED-CAPACITOR CIRCUITS 557, 14.2.1 Resistor Equivalence of a Switched Capacitor 560, 14.2.2 Parasitic-Sensitive Integrator 560, 14.2.3 Parasitic-Insensitive Integrators 565, 14.3 Noise in Switched-Capacitor Circuits 570, 14.7 Switched-Capacitor Gain Circuits 588, 14.7.1 Parallel Resistor-Capacitor Circuit 588, 14.8 Correlated Double-Sampling Techniques 593, 14.9 Other Switched-Capacitor Circuits 594, CHAPTER 15 DATA CONVERTER FUNDAMENTALS 606, CHAPTER 16 NYQUIST-RATE D/A CONVERTERS 623, 16.1.2 Folded Resistor-String Converters 625, 16.1.3 Multiple Resistor-String Converters 625, 16.2.1 Binary-Weighted Resistor Converters 629, 16.2.2 Reduced-Resistance-Ratio Ladders 630, 16.2.4 Charge-Redistribution Switched-Capacitor Converters 632, 16.3.1 Thermometer-Code Current-Mode D/A Converters 636, 16.3.2 Single-Supply Positive-Output Converters 637, 16.3.3 Dynamically Matched Current Sources 638, 16.4.1 Resistor-Capacitor Hybrid Converters 640, CHAPTER 17 NYQUIST-RATE A/D CONVERTERS 646, 17.2 Successive-Approximation Converters 650, 17.2.1 DAC-Based Successive Approximation 652, 17.2.4 Speed Estimate for Charge-Redistribution Converters 658, 17.2.5 Error Correction in Successive-Approximation Converters 659, 17.2.6 Multi-Bit Successive-Approximation 662, 17.3 Algorithmic (or Cyclic) A/D Converter 662, 17.3.1 Ratio-Independent Algorithmic Converter 662, 17.4.1 One-Bit-Per-Stage Pipelined Converter 667, 17.4.2 1.5 Bit Per Stage Pipelined Converter 669, 17.4.4 Generalized k-Bit-Per-Stage Pipelined Converters 673, 17.5.1 Issues in Designing Flash A/D Converters 675, 17.6.1 Two-Step Converter with Digital Error Correction 679, 18.1 Oversampling without Noise Shaping 696, 18.1.4 The Advantage of 1-Bit D/A Converters 701, 18.2.1 Noise-Shaped Delta-Sigma Modulator 703, 18.2.3 Switched-Capacitor Realization of a First-Order A/D Converter 706, 18.2.5 Noise Transfer-Function Curves 708, 18.2.6 Quantization Noise Power of 1-Bit Modulators 709, 18.3.1 System Architecture of Delta-Sigma A/D Converters 711, 18.3.2 System Architecture of Delta-Sigma D/A Converters 713, 18.5.2 Multi-Stage Noise Shaping (MASH) Architecture 719, 18.6 Bandpass Oversampling Converters 721, 18.7.2 Linearity of Two-Level Converters 723, 18.8 Multi-Bit Oversampling Converters 727, 18.8.2 Dynamically Matched Current Source D/S Converters 728, 18.8.3 Digital Calibration A/D Converter 728, 18.8.4 A/D with Both Multi-Bit and Single-Bit Feedback 729, 19.1 Basic Phase-Locked Loop Architecture 738, 19.2 Linearized Small-Signal Analysis 748, 19.2.2 Limitations of the Second-Order Small-Signal Model 751, 19.3.4 Other Spectral Representations of Jitter 762, 19.3.5 Probability Density Function of Jitter 764, 19.5.1 Input Phase Noise and Divider Phase Noise 777.