Preface 1. Introduction to Spice 1.1. Computer Simulation of Electronic Circuits 1.2. An Outline of Spice 1.2.1.

Types of Analysis Performed by Spice 1.2.2. Input to Spice 1.2.3. Output from Spice 1.3.

Output Post-Processing Using Probe 1.4. Examples 1.4.1. Example 1: DC Node Voltages of a Linear Network 1.4.2.

Example 2: Transient Response of a 3-Stage Linear Amplifier 1.4.3. Example 3: Setting Circuit Initial Conditions During a Transient Analysis 1.4.4. Example 4: Frequency Response of a Linear Amplifier 1.5.

Spice Tips 1.6. Bibliography 1.7. Problems 2. Operational Amplifiers 2.1. Modeling an Ideal Op Amp with Spice 2.

2. Analyzing the Behavior of Ideal Op Amp Circuits 2.2.1. Inverting Amplifier 2.2.2. The Miller Integrator 2.

2.3. A Damped Miller Integrator 2.2.4. The Unity-Gain Buffer 2.2.5.

Instrumentation Amplifier 2.3. Nonideal Op Amp Performance 2.3.1. Small-Signal Frequency Response of Op Amp Circuits 2.3.2.

Modeling the Large-Signal Behavior of Op Amps 2.4. The Effects of Op Amp Large-Signal Nonidealities on Closed-Loop Behavior 2.4.1. DC Transfer Characteristic of an Inverting Amplifier 2.4.2.

Slew-Rate Limiting 2.4.3. Other Op Amp Nonidealities 2.5. Spice Tips 2.6. Bibliography 2.

7. Problems 3. Diodes 3.1. Describing Diodes to Spice 3.1.1. Diode Element Description 3.

1.2. Diode Model Description 3.2. Spice as a Curve Tracer 3.2.1. Extracting the Small-Signal Diode Parameters 3.

2.2. Temperature Effects 3.3. Zener Diode Modeling 3.4. A Half-Wave Rectifier Circuit 3.5.

Limiting and Clamping Circuits 3.6. Spice Tips 3.7. Problems 4. Bipolar Junction Transistors (BJTs) 4.1. Describing BJTs to Spice 4.

1.1. BJT Element Description 4.1.2. BJT Model Description 4.1.3.

Verifying NPN Transistor Circuit Operation 4.2. Using Spice as a Curve Tracer 4.3. Spice Analysis as a Curve Tracer 4.3.1. Transistor Modes of Operation 4.

3.2. Computing DC Bias of a PNP Transistor Circuit 4.4. BJT Transistor Amplifiers 4.4.1. BJT Small-Signal Model 4.

4.2. Single-Stage Voltage-Amplifier Circuits 4.5. DC Bias Sensitivity Analysis 4.6. The Common-Emitter Amplifier 4.7.

Spice Tips 4.8. Bibliography 4.9. Problems 5. Field-Effect Transistors (FETs) 5.1. Describing MOSFETs to Spice 5.

1.1. MOSFET Element Description 5.1.2. MOSFET Model Description 5.1.3.

An Enhancement-Mode N-Channel MOSFET Circuit 5.1.4. Observing the MOSFET Current - Voltage Characteristics 5.2. Spice Analysis of MOSFET Circuits at DC 5.2.1.

An Enhancement-Mode P-Channel MOSFET Circuit 5.2.2. A Depletion-Mode P-Channel MOSFET Circuit 5.2.3. A Depletion-Mode N-Channel MOSFET Circuit 5.3.

Describing JFETs to Spice 5.3.1. JFET Element Description 5.3.2. JFET Model Description 5.3.

3. An N-Channel JFET Example 5.3.4. A P-Channel JFET Example 5.4. FET Amplifier Circuis 5.4.

1. Effect of Bias Point on Amplifier Conditions 5.4.2. Small-Signal Model of the FET 5.4.3. A Basic FET Amplifier Circuit 5.

5. Investigating Bias Stability with Spice 5.6. Integrated-Circuit MOS Amplifiers 5.6.1. Enhancement-Load Amplifiers Including the Body Effect 5.6.

2. CMOS Amplifier 5.7. MOSFET Switches 5.8. Describing MESFETs to PSpice 5.8.1.

MESFET Element Description 5.8.2. MESFET Model Description 5.8.3. Small-Signal MESFET Model 5.8.

4. A MESFET Biasing Example 5.9. Spice Tips 5.10. Bibliography 5.11. Problems 6.

Differential and Multistage Amplifiers 6.1. Input Excitation for the Differential Pair 6.2. Small-Signal Analysis of the Differential Amplifier: Symmetric Conditions 6.3. Small-Signal Analysis of the Differential Amplifier: Asymmetric Conditions 6.4.

Current-Source Biasing in Integrated Circuits 6.5. A BJT Multistage Amplifier Circuit 6.6. Spice Tips 6.7. Bibliography 6.8.

Problems 7. Frequency Response 7.1. Investigating Transfer Function Behavior Using PSpice 7.2. Modeling Dynamic Effects in Semiconductor Devices 7.3. The Low-Frequency Response of the Common-Source Amplifier 7.

4. High-Frequency Response Comparison of the Common-Emitter and Cascode Amplfiers 7.5. High-Frequency Response of the Common Emitter and Cascode Amplifiers 7.6. Spice Tips 7.7. Problems 8.

Feedback 8.1. The General Feedback Structure 8.2. Determining Loop Gain with Spice 8.3. Stability Analysis Using Spice 8.4.

Investigating the Range of Amplifier Stability 8.5. The Effect of Phase Margin on Transient Response 8.6. Frequency Compensation 8.7. Spice Tips 8.8.

Bibliography 8.9. Problems 9. Output Stages and Power Amplifiers 9.1. Emitter-Follower Output Stage 9.2. Class B Output Stage 9.

3. Spice Tips 9.4. Problems 10. Analog Integrated Circuits 10.1. A Detailed Analysis of the 741 Op Amp Circuit 10.2.

A CMOS Op Amp 10.3. Spice Tips 10.4. Bibliography 10.5. Problems 11. Filters and Tuned Amplifiers 11.

1. The Butterworth and Chebyshev Transfer Functions 11.2. Second-Order Active Filters Based on Inductor Replacement 11.3. Second-Order Active Filters Based on the Two-Integrator-Loop Topology 11.4. Tuned Amplifiers 11.

5. Spice Tips 11.6. Bibliography 11.7. Problems 12. Signal Generators and Waveform - Shaping Circuits 12.1.

Op Amp-RC Sinusoidal Oscillators 12.1.1. The Wien-Bridge Oscillator 12.1.2. An Active-Filter-Tuned Oscillator 12.2.

Multivibrator Circuits 12.3. Precision Rectifier Circuits 12.4. Spice Tips 12.5. Bibliography 12.6.

Problems 13. MOS Digital Circuits 13.1. NMOS Inverter with Enhancement Load 13.2. NMOS Inverter with Depletion Load 13.3. The CMOS Inverter 13.

4. A Gallium-Arsenide Inverter Circuit 13.5. Spice Tips 13.6. Problems 14. Bipolar Digital Circuits 14.1.

Transistor-Transistor Logic (TTL) 14.2. Emitter-Coupled Logic (ECL) 14.3. BiCMOS Digital Circuits 14.4. Bibliography 14.5.

Problems Appendix A. A.1. Diode Model A.2. BJT Model A.3. JET Model A.

4. MOSFET Model A.5. MESFET Model A.6. Bibliography Appendix B. Index.