Table of Contents

PrefaceAcknowledgments1. Introduction 1.1 The Organization of Electronics 1.2 An Analysis of Circuit Analyses 1.3 The Nature of Design Reference2. Basic Amplifier Circuits 2.1 Active Device Models 2.2 Basic Amplifier Configurations 2.3 Basic Amplifier Analysis Procedure 2.4 Common-Base and Common-Collector Amplifier Analyses 2.5 Dynamic Input and Output Resistances 2.6 Bipolar-Junction Transistor Output Resistance 2.7 The Effect of a Base-Emitter Shunt Resistance 2.8 The Cascade Amplifier 2.9 The Cascode Amplifier 2.10 The Darlington (or Compound) Amplifier 2.11 The Differential (Emitter-Coupled) Amplifier 2.12 Current Mirrors 2.13 Matched Transistor Buffers and Complementary Combinations 2.14 Closure References3. Feedback Circuits 3.1 Basic Feedback Topology 3.2 Identification of Forward and Feedback Paths 3.3 Operational Amplifier Configurations 3.4 Feedback Effects on Input and Output Resistance 3.5 Noise Rejection by Feedback 3.6 Reduction of Nonlinearity with Feedback 3.7 Miller's Theorem 3.8 An Inverting Feedback Voltage Amplifier 3.9 Input and Output Loading 3.10 A Noninverting Feedback Amplifier 3.11 A Noninverting Voltage Feedback Amplifier with Output Block 3.12 Field-Effect Transistor Buffer Amplifier 3.13 Closure References4. Multiple-Path Amplifiers 4.1 The Reduction Theorem 4.2 μ Transform of Bipolar-Junction Transistor and Field-Effect Transistor T Models 4.3 Common-Gate Amplifier with ro 4.4 Common-Source Amplifier with ro 4.5 Common-Drain Amplifier with ro 4.6 Field-Effect Transistor Cascode Amplifier with ro 4.7 Common-Base Amplifier with ro 4.8 Common-Collector and Common-Emitter Amplifiers with ro 4.9 Some Circuit Transformations 4.10 Feedback Analysis of Multipath Transistor Amplifiers 4.11 Feedback Analysis of the Common-Base Amplifier 4.12 Feedback Analysis of the Common-Emitter Amplifier 4.13 Feedback Analysis of the Common-Collector Amplifier 4.14 Inverting Op-Amp with Output Resistance 4.15 Feedback Analysis of the Shunt-Feedback Amplifier 4.16 Shunt-Feedback Amplifier Analysis: Substitution Theorem 4.17 An Idealized Shunt-Feedback Amplifier 4.18 Feedback Circuit Resistances 4.19 The Asymptotic Gain Method 4.20 The Cascode and Differential Shunt-Feedback Amplifiers 4.21 The Emitter-Coupled Feedback Amplifier 4.22 Closure References5. Transient and Frequency Response 5.1 Reactive Circuit Elements 5.2 First-Order Time-Domain Transient Response 5.3 Complex Poles and the Complex-Frequency Domain 5.4 Second-Order Time-Domain Response: RLC Circuit 5.5 Forced Response and Transfer Functions in the s-Domain 5.6 The Laplace Transform 5.7 Time-Domain Response to a Unit Step Function 5.8 Circuit Characterization in the Time Domain 5.9 The 5-Plane Frequency Response of Transfer Functions 5.10 Graphical Representation of Frequency Response 5.11 Loci of Quadratic Poles 5.12 Optimization of Time-Domain and Frequency-Domain Response 5.13 Reactance Chart Transfer Functions of Passive Circuits 5.14 Closure References6. Dynamic Response Compensation 6.1 Passive Compensation: Voltage Divider 6.2 Op-Amp Transfer Functions from Reactance Charts 6.3 Feedback Circuit Response Representation 6.4 Feedback Circuit Stability 6.5 Compensation Techniques 6.6 Compensator Design: Compensating with Zeros in H 6.7 Compensator Design: Reducing dc Loop Gain 6.8 Compensator Design: Pole Separation and Parameter Variation 6.9 Two-Pole Compensation 6.10 Output Load Isolation 6.11 Complex Pole Compensation 6.12 Compensation by the Direct (Truxal's) Method 6.13 Power Supply Bypassing 6.14 Closure Reference 7. Frequency-Related Impedance Transformations 7.