Table of Contents
Introduction
Chapter 1 Semiconductor Devices
Section 1 Semiconductor Basics
Section 2 Semiconductor Diodes
Section 3 Semiconductor Triodes
Section 4 Acoustic-Effect Transistors (FET)
Summary of this Chapter
Reflective Questions and Exercises
Chapter 2: Basic Unit Circuits
Section 1: Amplification Concepts and Performance Indicators of Amplifier Circuits
Section 2: Components of Amplifier Circuits and Operating Principles
Section 3: Methods of Analyzing Amplifier Circuits
Section 4: Operating Point Stabilized Circuits
Section 5: The Three Configurations of Amplifier Circuits and Comparison of Their Performance
Section 6: Comparing Amplifier Circuits and Their Performance
Section VI Basic Amplifier Circuits for Field Effect Tubes
Section VII Differential Amplifier Circuits
Section VIII Current Supply Circuits
Summary of the Chapter
Reflective Questions and Exercises
Chapter III Multi-Stage Amplifier Circuits and Frequency Response
Section I. General Problems in Multi-Stage Amplifier Circuits
Section II. Coupled Amplifier Circuits
Section 3: Resistor-Capacitor Coupled Multi-Stage Amplifier Circuits
Section 4: Frequency Response of Amplifier Circuits
Summary of the Chapter
Reflection Questions and Exercises
Chapter 4: Integrated Operational Amplifiers
Section 1: Introduction to Integrated Operational Amplifiers
Section 2: General-Purpose Integrated Operational Amplifiers
Section 4: Practical Problems in the Use of Integrated Operational Amplifiers
Section 5: Ideal Operational Inputs and Three Basic Input Methods
Conclusion of this Chapter
Reflection Questions and Exercises
Chapter 5: Power Amplifier Circuits
Section 1: Characteristics and Classification of Power Amplifier Circuits
Section 2: Basic OCL Circuit and Cross-Over Loss Circuit Basic OCL Circuits and Cross-Distortion
Section 3: Distortion-Free OCL Circuits
Section 4: Introduction to OCL Circuits
Section 5: Complementary Symmetrical Amplifiers and Calculations
Section 6: Integrated Power Amplifier Circuits
Summary of the Chapter
Reflective Questions and Exercises
Configuration of the Chapter VI: Feedback in Amplifier Circuits
Chapter VI.
Section 1: Basic Concepts of Feedback
Section 2: Block Diagram of a Feedback Amplifier Circuit and General Expression for Closed-Loop Amplification
Section 3: Four Configurations of Negative Feedback Amplifier Circuits
Section 4: Improvement of Negative Feedback on Amplifier Circuit Performance
Section 5: Principle of Correctly Introducing Negative Feedback
Section 6: Deep Negative Feedback Calculation of an Amplifier Circuit
Section 7: Calculation of a Negative-Feedback Amplifier Circuit
Summary of the Chapter
Thinking Questions and Exercises
Chapter 7: Applications of Integrated Operational Amplifiers
Section 1: Basic Operational Circuits
Section 2: Integrated Analog Multipliers
Section 3: Active Filters
Section 4: Switched-Capacitor Filters Switched-Capacitor Filters
Section 5: Voltage Comparators
Summary of the Chapter
Thinking Questions and Exercises
Chapter 8: Signal Generation Circuits
Section 1: Overview
Section 2: RC Sine Wave Circuits
Section 3: LC Sine Wave Oscillators
Section 4: Quartz Crystal Oscillators Introduction
Section V Rectangular Wave Generation Circuits
Section VI Triangular Wave Generation Circuits
Section VII Sawtooth Wave Generation Circuits
Section VIII Introduction to Integrated Function Generator 8038
Summary of the Chapter
Reflective Questions and Exercises
Chapter IX DC Voltage Regulators
Section I Rectifier Circuits
Section II Filter Circuits
Section III Voltage Regulator Circuits
Section IV Switching Regulator Circuits (SMR Circuits)
Summary of the Chapter
Thinking Questions and Exercises
References
Not found in Digital Electricity
Circuit Fundamentals
Table of Contents
Section -Chapter Circuit Models and Circuit Laws
1-1 Circuits and Circuit Diagrams
1-2 Currents, Voltages, and Their Direction of Reference
1-3 Electric Power
1- 4 Resistive Elements
1-5 Capacitive Elements
1-6 Inductive Elements
1-7 Voltage and Current Sources
1-8 Controlled Sources
1 -9 Kirchhoff's Laws
1-10 Topology of Circuits Matrix Form of Kirchhoff's Laws
Exercise 1
Chapter 2 Equivalent Transformations and Simplifications of Resistive Circuits
2-1 Concept of Circuit Equivalence
2 2 Series and Parallel Connections of Resistors
2-3 Y-Delta Couplings of Resistors and Their Equivalent Interchanges
2-4 Series and Parallel Connections of Power Supplies
2-5 Equivalent Transformations for Active Resistive Circuits
2-5 Equivalent Transformations
2-6 Analysis of Simple Resistive Circuits
Exercise 2
Chapter 3: Methods of Network Analysis and Network Theorems
3-1 Branch Current Method
3-2 Loop Current Method
3 3-Node Voltage Method
3-4 Analysis of Circuits Containing Controlled Sources
3-5 Superposition Theorem
3-6 Substitution Theorem
3-7 Davignan's Theorem vs. Norton's Theorem
3-8 Teller's Theorem
3-9 Reciprocity Theorem
3-10 Pairwise Principle
Exercise 3
Chapter 4: Fundamental Concepts of Sine Circuits
4 -1 Concepts Related to Sinusoidal Quantities
4-2 Representation of Sinusoidal Quantities in Terms of Phases
4-3 Characterization of Resistive Sense and Capacitive Elements in Sinusoidal Circuits
4-4 Kirchhoff's Laws in Phasor Form
4-5 Complex Impedance and Complex Conductance
Exercise 4
Chapter 5 Steady-State Analysis of Sinusoidal Circuits
5-1 Analysis of Series-Parallel Circuits
5-2 Analysis of Complex Circuits
5 -3 Power in Sinusoidal Circuits
5-4 Maximum Power Transfer
Exercise 5
Chapter 6 Three-Phase Circuits
6-1 Symmetrical Three-Phase Power Supplies
6-2 Symmetrical Three-Phase Circuits Calculations
6-3 Concepts of Asymmetrical Three-Phase Circuits
6-4 Power and Its Measurement in Three-Phase Circuits
Exercise 6
Chapter 7 Mutual Inductance Circuits
7-l Mutual Inductance Coefficients and Coupling Coefficients
7-2 Mutually Inductive Voltages and Homonymous Terminals
7-3 Coupled Decoupled Equivalent Circuits of Mutually Inductive Elements
7-4 Analysis of Sinusoidal Circuits with Mutual Inductance
7-5 Empty-Core Transformers
Exercise VII< /p>
Chapter 8 Resonant Circuits
8-l Resonance of Series Circuits
8-2 Resonance Curves and Passbands of Series Circuits
8-3 Resonance of Parallel Circuits
8-4 Mutual Inductance Resonance of Coupled Circuits
Exercise 9
Chapter 9 Periodic Non-Sinusoidal Circuits
9-l Decomposition of Periodic Functions into Fourier Levels
9-2 RMS Mean Power of Periodic Non-Sinusoidal Voltages and Currents
9 -3 Calculation of periodic non-sinusoidal circuits
9-4 Concepts of filter circuits
Exercise 9
Chapter 10 -Order circuits
10-l Initial conditions of circuits
10 -2 Zero-Input Response
10-3 Zero-State Response
10-4 Full Response
10-5 Three-Element Method
10-6 Step Response and Impulse Response
10-7 Convolution Integration
10-8 Jumps in Capacitive Voltage and Inductive Current
Exercise 10
Chapter X- Second-Order Circuits
11-1 RLC Zero-Input Response of a Series Circuit
ll-2 Response of an RLC Series Circuit to Constant Input
Exercise X-
Circuits of 2 Kinds, and then there are the Fundamentals of Circuit Theory
Table of Contents
Chapter I. Basic Concepts of Circuits
1.1 Actual circuits and circuit models
1.2 Physical quantities in circuits
1.3 Structure of circuits
Exercise 1
Chapter 2: Fundamental Laws and Components of Electric Circuits
2.1 Kirchhoff's Laws of Current
2.2 Kirchhoff's Laws of Voltage
2.3 Two-Terminal Resistive Components
2.4 Independent Power Supplies
2.5 Two-terminal Capacitive Elements
2.6 Two-terminal Inductive Elements
2.7 Dual-port Resistors
2.8 Mutual Inductive Elements
2.9 Controlled Power Supplies
2.10 Ideal Operational Amplifiers
Exercise 2
Chapter 3 Networks for Linear DC Circuits Equation Analysis
3.1 Line Diagrams of Circuits
3.2 Independent Kirchhoff's Law Equations
3.3 Mathematical Models of Circuit Completeness and Branching Methods
3.4 Independent and Completely Complete Circuit Variables
3.5 Nodal Methods
3.6 Cutset Methods
3.7 Mesh Methods and Loop Methods
3.8 Relationships between [A], [B], and [C] Matrices
Exercise 3
Chapter 4: Circuit Theorems and Equivalent Simplifications of Circuits
4.1 Superposition and Chirality Theorems
4.2 Displacement Theorem
4.3 Tellergan's Theorem
4.4 Reciprocity Theorem
4.5 Equivalent Networks and Equivalent Transformations
4.6 Equivalent Simplification of One-Port Networks without Independent Sources
4.7 Equivalent Simplification of One-Port Networks with Contained Sources and Equivalent Power Theorem
4.8 Equivalent Parameters of Two-Port Networks without Independent Sources
4.9 Equivalent Circuits of Two-Port Networks without Independent Sources
4.10 Equivalent Parameters of Interconnected Two-Ports< /p>
4.11 Pairwise Principles
Exercise 4
Chapter 5 Phase Methods for Steady-State Analysis of Linear Sinusoidal Current Circuits
5.1 Basic Concepts of Sine Measurements
5.2 Transformations of Sine Measurements and Phase Measurements
5.3 Kirchhoff's Laws in the Form of Phasors
5.4 Circuit Elements in the Form of Phasors Constraint Equations
5.5 Complex Impedance and Complex Conductance
5.6 Phase Measurement Method for Steady-State Analysis of Sinusoidal Current Circuits
5.7 Circuits Containing Mutually Inductive Elements
5.8 Power of Sinusoidal Current Circuits
Exercise 5
Chapter 6: Nonsinusoidal Periodic Current Circuits
6.1 Nonsinusoidal Periodic Quantities for Harmonic Analysis
6.2 RMS and Almost Mean Power in Non-Sinusoidal Periodic Current Circuits
6.3 Analysis of Non-Sinusoidal Periodic Current Circuits
Exercise 6
Chapter 7 Frequency Characteristics and Resonance
7.1 Frequency Characteristics and Filtering
7.2 Series Resonant Circuits
7.3 Shunt Resonant Circuits
Exercise 7
Chapter 8 Three-Phase Circuits
8.1 Basic Concepts of Three-Phase Circuits
8.2 Voltages, Currents, and Powers of Symmetric Three-Phase Circuits
8.3 Calculations of Symmetric Three-Phase Circuits
8.4 Concepts of Asymmetric Three-Phase Circuits
Exercise 8
Chapter 9 Time-Domain Analysis of Transient Processes in Dynamic Circuits
9.1 Transient Processes in Dynamic Circuits and Their Circuit Equations
9.2 Initial Values of Transient Processes in Dynamic Circuits
9.3 Differential Equations of First-Order Circuits and Universal Forms of Their Solutions
9.4 Zero-Input Response of First-Order Circuits
9.5 Zero-State Response of First-Order Circuits
9.6 Full Response of First-Order Circuits
......
Chapter 10 Complex-Frequency-Domain Analysis of Dynamic Circuits
Chapter 11 Simple Nonlinear Resistive Circuits
Chapter 12 Analyzing Circuits by Pspice
Answers to Selected Exercises
Main Bibliography