DETAILED TABLE OF CONTENTSEach chapter begins with an Introduction and ends with a Summary and Problems.PrefacePART I: DEVICES AND BASIC CIRCUITS1. Introduction to Electronics1.1. Signals1.2. Frequency Spectrum of Signals1.3.

Analog and Digital Signals1.4. Amplifiers1.4.1. Signal Amplification1.4.2.

Amplifier Circuit Symbol1.4.3. Voltage Gain1.4.4. Power Gain and Current Gain1.4.

5. Expressing Gain in Decibels1.4.6. The Amplifier Power Supplies1.4.7. Amplifier Saturation1.

4.8. Nonlinear Transfer Characteristics and Biasing1.4.9. Symbol Convention1.5. Circuit Models for Amplifiers1.

5.1. Voltage Amplifiers1.5.2. Cascaded Amplifiers1.5.3.

Other Amplifier Types1.5.4. Relationships Between the Four Amplifier Models1.6. Frequency Response of Amplifiers1.6.1.

Measuring the Amplifier Frequency Response1.6.2. Amplifier Bandwidth1.6.3. Evaluating the Frequency Response of Amplifiers1.6.

4. Single-Time-Constant Networks1.6.5. Classification of Amplifiers Based on Frequency Response1.7. Digital Logic Inverters1.7.

1. Function of the Inverter1.7.2. The Voltage Transfer Characteristic (VTC)1.7.3. Noise Margins1.

7.4. The Ideal VTC1.7.5. Inverter Implementation1.7.6.

Power Dissipation1.7.7. Propagation Delay1.8. Circuit Simulation Using SPICE2. Operational Amplifiers2.1.

The Ideal Op Amp2.1.1. The Op-Amp Terminals2.1.2. Function and Characteristics of the Ideal Op Amp2.1.

3. Differential and Common-Mode Signals2.2. The Inverting Configuration2.2.1. The Closed-Loop Gain2.2.

2. Effect of Finite Open-Loop Gain2.2.3. Input and Output Resistances2.2.4. An Important Application--The Weighted Summer2.

3. The Noninverting Configuration2.3.1. The Closed-Loop Gain2.3.2. Characteristics of the Noninverting Configuration2.

3.3. Effect of Finite Open-Loop Gain2.3.4. The Voltage Follower2.4. Difference Amplifiers2.

4.1. A Single Op-Amp Difference Amplifier2.4.2. A Superior Circuit--The Instrumentation Amplifier2.5. Effect of Finite Open-Loop Gain and Bandwidth on Circuit Performance2.

5.1. Frequency Dependence of the Open-Loop Gain2.5.2. Frequency Response of Closed-Loop Amplifiers2.6. Large-Signal Operation of Op Amps2.

6.1. Output Voltage Saturation2.6.2. Output Current Limits2.6.3.

Slew Rate2.6.4. Full-Power Bandwidth2.7. DC Imperfections2.7.1.

Offset Voltage2.7.2. Input Bias and Offset Currents2.8. Integrators and Differentiators2.8.1.

The Inverting Configuration with General Impedances2.8.2. The Inverting Integrator2.8.3. The Op-Amp Differentiator2.9.

The SPICE Op-Amp Model and Simulation Examples2.9.1. Linear Macromodel2.9.2. Nonlinear Macromodel3. Diodes3.

1. The Ideal Diode3.1.1. Current-Voltage Characteristic3.1.2. A Simple Application: The Rectifier3.

1.3. Another Application: Diode Logic Gates3.2. Terminal Characteristics of Junction Diodes3.2.1. The Forward-Bias Region3.

2.2. The Reverse-Bias Region3.2.3. The Breakdown Region3.3. Modeling the Diode Forward Characteristic3.

3.1. The Exponential Model3.3.2. Graphical Analysis Using the Exponential Model3.3.3.

Iterative Analysis Using the Exponential Model3.3.4. The Need for Rapid Analysis3.3.5. The Piecewise-Linear Model3.3.

6. The Constant-Voltage-Drop Model3.3.7. The Ideal-Diode Model3.3.8. The Small-Signal Model3.

3.9. Use of the Diode Forward Drop in Voltage Regulation3.3.10. Summary3.4. Operation in the Reverse Breakdown Region--Zener Diodes3.

4.1. Specifying and Modeling the Zener Diode3.4.2. Use of the Zener as a Shunt Regulator3.4.3.

Temperature Effects3.4.4. A Final Remark3.5. Rectifier Circuits3.5.1.

The Half-Wave Rectifier3.5.2. The Full-Wave Rectifier3.5.3. The Bridge Rectifier3.5.

4. The Rectifier with a Filter Capacitor--The Peak Rectifier3.5.5. Precision Half-Wave Rectifier--The Super Diode3.6. Limiting and Clamping Circuits3.6.

1. Limiter Circuits3.6.2. The Clamped Capacitor or DC Restorer3.6.3. The Voltage Doubler3.

7. Physical Operation of Diodes3.7.1. Basic Semiconductor Concepts3.7.2. The pn Junction Under Open-Circuit Conditions3.

7.3. The pn Junction Under Reverse-Bias Conditions3.7.4. The pn Ju.