Preface1. Introduction to ElectronicsIntroduction1.1. Signals1.2. Frequency Spectrum of Signals1.3. Analog and Digital Signals1.

4. Amplifiers1.5. Circuit Models for Amplifiers1.6. Frequency Response of Amplifiers1.7. The Digital Logic InverterSummaryBibliographyProblemsPart I: Devices and Basic Circuits2.

Operational AmplifiersIntroduction2.1. The Op-Amp Terminals2.2. The Ideal Op Amp2.3. Analysis of Circuits Containing Ideal Op Amps -- The Inverting Configuration2.4.

Other Applications of the Inverting Configuration2.5. The Noninverting Configuration2.6. Examples of Op-Amp Circuits2.7. Effect of Finite Open-Loop Gain and Bandwidth on Circuit Performance2.8.

Large-Signal Operation of Op Amps2.9. DC ImperfectionsSummaryBibliographyProblems3. DiodesIntroduction3.1. The Ideal Diode3.2. Terminal Characteristics of Junction Diodes3.

3. Physical Operation of Diodes3.4. Analysis of Diode Circuits3.5. The Small-Signal Model and Its Application3.6. Operation in the Reverse Breakdown Region -- Zener Diodes3.

7. Recitifier Circuits3.8. Limiting and Clamping Circuits3.9. Special Diode Types3.10. The SPICE Diode Model and Simulation ExamplesSummaryBibliographyProblems4.

Bipolar Junction Transistors (BJTs)4.1. Physical Structure and Modes of Operation4.2. Operation of the npn Transistor in the Active Mode4.3. The pnp Transistor4.4.

Circuit Symbols and Conventions4.5. Graphical Representation of Transistor Characteristics4.6. Analysis of Transistor Circuits at DC4.7. The Transistor as an Amplifier4.8.

Small-Signal Equivalent Circuit Models4.9. Graphical Analysis4.10. Biasing the BJT for Discrete-Circuit Design4.11. Basic Single-Stage BJT Amplifier Configuration4.12.

The Transistor as a Switch -- Cutoff and Saturation4.13. A General Large-Signal Model for the BJT: The Ebers-Moll (EM) Model4.14. The Basic BJT Logic Inverter4.15. Complete Static Characteristics, Internal Capacitances, and Second-Order Effects4.16.

The SPICE BJT Model and Simulation ExamplesSummaryBibliographyProblems5. Field-Effect Transistors (FETs)Introduction5.1. Structure and Physical Operation of the Enhancement-Type MOSFET5.2. Current-Voltage Characteristics of the Enhancement MOSFET5.3. The Deletion-Type MOSFET5.

4. MOSFET Circuits at DC5.5. The MOSFET as an Amplifier5.6. Biasing in MOS Amplifier Circuits5.7. Basic Configurations of Single-Stage IC MOS Amplifiers5.

8. The CMOS Digital Logic Inverter5.9. The MOSFET as an Analog Swiitch5.10. The MOSFET Internal Capacitances and High-Frequency Model5.11. The Junction Field-Effect Transistor5.

12. Gallium Arsenide (GaAs) Devices - The MESFET5.13. The SPICE MOSFET Model and Simulation ExamplesSummaryBibliographyProblemsPart II: Analog Circuits6. Differential and Multistage AmplifiersIntroduction6.1. The BJT Differential Pair6.2.

Small-Signal Operation of the BJT Differential Amplifier6.3. Other Nonideal Characteristics of the Differential Amplifier6.4. Biasing in BJT Integrated Circuits6.5. The BJT Differential Amplifier with Active Load6.6.

MOS Differential Amplifiers6.7. BiCMOS Amplifiers6.8. GaAs Amplifiers6.9. Multistage Amplifiers6.10.

SPICE Simulation ExampleSummaryBibliographyProblems7. Frequency ResponseIntroduction7.1. s-Domain Analysis: Poles, Zeros, and Bode Plots7.2. The Amplifier Transfer Function7.3. Low-Frequency Response of the Common-Source and Common-Emitter Amplifiers7.

4. High-Frequency Response of the Common-Source and Common-Emitter Amplifiers7.5. The Common-Base, Common-Gate, and Cascode Configurations7.6. Frequency Response of the Emitter and Source Followers7.7. The Common-Collector Common Emitter Cascade7.

8. Frequency Response of the Differential Amplifier7.9. SPICE Simulation ExamplesSummaryBibliographyProblems8. Feedback8.1. The General Feedback Structure8.2.

Some Properties of Negative Feedback8.3. The Four Basic Feedback Topologies8.4. The Series-Shunt Feedback Amplifier8.5. The Series-Series Feedback Amplifier8.6.

The Shunt-Shunt and the Shunt-Series Feedback Amplifiers8.7. Determining the Loop Gain8.8. The Stability Problem8.9. Effect of Feedback on the Amplifier Poles8.10.

Stability Study Using Bode Plots8.11. Frequency Compensation8.12. SPICE Simulation ExamplesSummaryBibliographyProblems9. Output Stages and Power AmplifiersIntroduction9.1. Classification of Output Stages9.

2. Class A Output Stage9.3. Class B Output Stage9.4. Class AB Output Stage9.5. Biasing the Class AB Circuit9.

6. Power BJTs9.7. Variations on the Class AB Configuration9.8. IC Power Amplifiers9.9. MOS Power Transistors9.

10. SPICE Simulation ExampleSummaryBibliographyProblems10. Analog Integrated CircuitsIntroduction10.1. The 741 Op-Amp Circuit10.2. DC Analysis of the 74110.3.

Small-Signal Analysis of the 741 Input Stage10.4. Small-Signal Analysis of the 741 Second Stage10.5. Analysis of the 741 Output Stage10.6. Gain and Frequency Response of the 74110.7.

CMOS Op Amps10.8. Alternative Configurations for CMOS and BiCMOS Op Amps10.9. Data Converters -- An Introduction10.10. D/A Converter Circuits10.11.

A/D Converter Circuits10.12. SPICE Simulation ExampleSummaryBibliographyProblems11. Filters and Tuned AmplifiersIntroduction11.1. Filter Transmission, Types, and Specification11.2. The Filter Transfer Function11.

3. Butterworth and Chebyshev Filters11.4. First-Order and Second-Order Filter Functions11.5. The Second-Order LCR Resonator11.6. Second-Order Active Filters Based on Inductor Replacement11.

7. Second-Order Active Filters Based on the Two-Integrator Loop Topology11.8. Single-Amplifier Biquadratic Active Filters11.9. Sensitivity11.10. Switched-Capacitor Filters11.

11. Tuned Amplifiers11.12. SPICE SImulation ExamplesSummaryBibliography12. Signal Generators and Waveform-Shaping CircuitsIntroduction12.1. Basic Principles of Sinusoidal Oscillators12.2.

Op Amp-RC Oscillator Circuits12.3. LC and Crystal Oscillators12.4. Bistable Multivibrators12.5. Generation of Square and Triangular Waveforms Using Astable Multivibrators12.6.

Generation of a Standardized Pulse -- The Monostable Multivibrator12.7. Integrated-Circuit Timers12.8. Nonlinear Waveform-Shaping Circuits12.9. Precision Rectifier Circuits12.10.

SPICE Simulation ExamplesSummaryBibliographyProblemsPart III: Digital Circuits13. MOS Digital CircuitsIntroduction13.1. Digital Circuit Desing: An Overview13.2. Design and Performance Analysis of the CMOS Inverter13.3. CMOS Logic-Gate Circuits13.

4. Pseudo-NMOS Logic Circuits13.5. Pass-Transistor Logic Circuits13.6. Dynamic Logic Circuits13.7. Latches and Flip-Flops13.

8. Multivibrator Circuits13.9. Semiconductor Memories: Types and Architectures13.10. Random-Access Memory (RAM) Cells13.11. Sense Amplifiers and Address Decoders13.

12. Read-Only Memory (ROM)13.3. SPICE Simulation ExampleSummaryBibliographyProblems14. Bipolar and Advanced-Technology Digital CircuitsIntroduction14.1. Dynamic Operation of the BJT Switch14.2.

Early Forms of BJT Digital Circuits14.3. Transistor-Transistor Logic (TTL or T2L)14.4. Characteristics of Standard TTL14.5. TTL Families with Improved Performance14.6.

Emitter-Coupled Logic (ECL)14.7. BiCMOS Digital Circuits14.8. Gallium-Arsenide Digital Circuits14.9. SPICE Simulation ExampleSummaryBibliographyProblemsAppendixesA. B.

Two-Port Network ParametersC. An Introduction to SPICED. Input Files for the SPICE ExamplesE. Some Useful Network TheoremsF. Single-Time-Constant CircuitsG. Determining the Parameter Values of the Hybrid-pi BJT ModelH. Standard Resistance Values and Unit PrefixesI. Answers to Selected ProblemsIndex.