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• Title Page
• Copyright Page
• Brief Contents
• Contents
• List of Examples
• List of Tables
• List of Analysis Methods
• Preface
• Chapter 1 Circuit Variables
• Practical Perspective: Balancing Power
• 1.1 Electrical Engineering: An Overview
• 1.2 The International System of Units
• 1.3 Circuit Analysis: An Overview
• 1.4 Voltage and Current
• 1.5 The Ideal Basic Circuit Element
• 1.6 Power and Energy
• Practical Perspective: Balancing Power
• Summary
• Problems
• Chapter 2 Circuit Elements
• Practical Perspective: Heating with Electric Radiators
• 2.1 Voltage and Current Sources
• 2.2 Electrical Resistance (Ohm’s Law)
• 2.3 Constructing a Circuit Model
• 2.4 Kirchhoff’s Laws
• 2.5 Analyzing a Circuit Containing Dependent Sources
• Practical Perspective: Heating with Electric Radiators
• Summary
• Problems
• Chapter 3 Simple Resistive Circuits
• Practical Perspective: Resistive Touch Screens
• 3.1 Resistors in Series
• 3.2 Resistors in Parallel
• 3.3 The Voltage-Divider and Current-Divider Circuits
• 3.4 Voltage Division and Current Division
• 3.5 Measuring Voltage and Current
• 3.6 Measuring Resistance— The Wheatstone Bridge
• 3.7 Delta-to-Wye (pi-toTtee) Equivalent Circuits
• Practical Perspective: Resistive Touch Screens
• Summary
• Problems
• Chapter 4 Techniques of Circuit Analysis
• Practical Perspective: Circuits with Realistic Resistors
• 4.1 Terminology
• 4.2 Introduction to the Node-Voltage Method
• 4.3 The Node-Voltage Method and Dependent Sources
• 4.4 The Node-Voltage Method: Some Special Cases
• 4.5 Introduction to the Mesh-Current Method
• 4.6 The Mesh-Current Method and Dependent Sources
• 4.7 The Mesh-Current Method: Some Special Cases
• 4.8 The Node-Voltage Method Versus the Mesh-Current Method
• 4.9 Source Transformations
• 4.10 Thévenin and Norton Equivalents
• 4.11 More on Deriving the Thévenin Equivalent
• 4.12 Maximum Power Transfer
• 4.13 Superposition
• Practical Perspective: Circuits with Realistic Resistors
• Summary
• Problems
• Chapter 5 The Operational Amplifier
• Practical Perspective: Sensors
• 5.1 Operational Amplifier Terminals
• 5.2 Terminal Voltages and Currents
• 5.3 The Inverting-Amplifier Circuit
• 5.4 The Summing-Amplifier Circuit
• 5.5 The Noninverting-Amplifier Circuit
• 5.6 The Difference-Amplifier Circuit
• 5.7 A More Realistic Model for the Operational Amplifier
• Practical Perspective: Sensors
• Summary
• Problems
• Chapter 6 Inductance, Capacitance, and Mutual Inductance
• Practical Perspective: Capacitive Touch Screens
• 6.1 The Inductor
• 6.2 The Capacitor
• 6.3 Series-Parallel Combinations of Inductance and Capacitance
• 6.4 Mutual Inductance
• 6.5 A Closer Look at Mutual Inductance
• Practical Perspective: Capacitive Touch Screens
• Summary
• Problems
• Chapter 7 Response of First-Order RL and RC Circuits
• Practical Perspective: Artificial Pacemaker
• 7.1 The Natural Response of an RL Circuit
• 7.2 The Natural Response of an RC Circuit
• 7.3 The Step Response of RL and RC Circuits
• 7.4 A General Solution for Step and Natural Responses
• 7.5 Sequential Switching
• 7.6 Unbounded Response
• 7.7 The Integrating Amplifier
• Practical Perspective: Artificial Pacemaker
• Summary
• Problems
• Chapter 8 Natural and Step Responses of RLC Circuits
• Practical Perspective: Clock for Computer Timing
• 8.1 Introduction to the Natural Response of a Parallel RLC Circuit
• 8.2 The Forms of the Natural Response of a Parallel RLC Circuit
• 8.3 The Step Response of a Parallel RLC Circuit
• 8.4 The Natural and Step Response of a Series RLC Circuit
• 8.5 A Circuit with Two Integrating Amplifiers
• Practical Perspective: Clock for Computer Timing
• Summary
• Problems
• Chapter 9 Sinusoidal Steady-State Analysis
• Practical Perspective: A Household Distribution Circuit
• 9.1 The Sinusoidal Source
• 9.2 The Sinusoidal Response
• 9.3 The Phasor
• 9.4 The Passive Circuit Elements in the Frequency Domain
• 9.5 Kirchhoff’s Laws in the Frequency Domain
• 9.6 Series, Parallel, and Delta-to-Wye Simplifications
• 9.7 Source Transformations and Thévenin–Norton Equivalent Circuits
• 9.8 The Node-Voltage Method
• 9.9 The Mesh-Current Method
• 9.10 The Transformer
• 9.11 The Ideal Transformer
• 9.12 Phasor Diagrams
• Practical Perspective: A Household Distribution Circuit
• Summary
• Problems
• Chapter 10 Sinusoidal Steady-State Power Calculations
• Practical Perspective: Vampire Power
• 10.1 Instantaneous Power
• 10.2 Average and Reactive Power
• 10.3 The rms Value and Power Calculations
• 10.4 Complex Power
• 10.5 Power Calculations
• 10.6 Maximum Power Transfer
• Practical Perspective: Vampire Power
• Summary
• Problems
• Chapter 11 Balanced Three-Phase Circuits
• Practical Perspective: Transmission and Distribution of Electric Power
• 11.1 Balanced Three-Phase Voltages
• 11.2 Three-Phase Voltage Sources
• 11.3 Analysis of the Wye-Wye Circuit
• 11.4 Analysis of the Wye-Delta Circuit
• 11.5 Power Calculations in Balanced Three-Phase Circuits
• 11.6 Measuring Average Power in Three-Phase Circuits
• Practical Perspective: Transmission and Distribution of Electric Power
• Summary
• Problems
• Chapter 12 Introduction to the Laplace Transform
• Practical Perspective: Transient Effects
• 12.1 Definition of the Laplace Transform
• 12.2 The Step Function
• 12.3 The Impulse Function
• 12.4 Functional Transforms
• 12.5 Operational Transforms
• 12.6 Applying the Laplace Transform
• 12.7 Inverse Transforms
• 12.8 Poles and Zeros of F(s)
• 12.9 Initial-and Final-Value Theorems
• Practical Perspective: Transient Effects
• Summary
• Problems
• Chapter 13 The Laplace Transform in Circuit Analysis
• Practical Perspective: Surge Suppressors
• 13.1 Circuit Elements in the s Domain
• 13.2 Circuit Analysis in the s Domain
• 13.3 Applications
• 13.4 The Transfer Function
• 13.5 The Transfer Function in Partial Fraction Expansions
• 13.6 The Transfer Function and the Convolution Integral
• 13.7 The Transfer Function and the Steady-State Sinusoidal Response
• 13.8 The Impulse Function in Circuit Analysis
• Practical Perspective: Surge Suppressors
• Summary
• Problems
• Chapter 14 Introduction to Frequency Selective Circuits
• Practical Perspective: Pushbutton Telephone Circuits
• 14.1 Some Preliminaries
• 14.2 Low-Pass Filters
• 14.3 High-Pass Filters
• 14.4 Bandpass Filters
• 14.5 Bandreject Filters
• Practical Perspective: Pushbutton Telephone Circuits
• Summary
• Problems
• Chapter 15 Active Filter Circuits
• Practical Perspective:Bass Volume Control
• 15.1 First-Order Low-Pass and High-Pass Filters
• 15.2 Scaling
• 15.3 Op Amp Bandpass and Bandreject Filters
• 15.4 Higher-Order Op Amp Filters
• 15.5 Narrowband Bandpass and Bandreject Filters
• Practical Perspective: Bass Volume Control
• Summary
• Problems
• Chapter 16 Fourier Series
• Practical Perspective: Active High-Q Filters
• 16.1 Fourier Series Analysis: An Overview
• 16.2 The Fourier Coefficients
• 16.3 The Effect of Symmetry on the Fourier Coefficients
• 16.4 An Alternative Trigonometric Form of the Fourier Series
• 16.5 An Application
• 16.6 Average-Power Calculations With Periodic Functions
• 16.7 The Rms Value of a Periodic Function
• 16.8 The Exponential Form of the Fourier Series
• 16.9 Amplitude and Phase Spectra
• Practical Perspective: Active High-Q Filters
• Summary
• Problems
• Chapter 17 The Fourier Transform
• Practical Perspective: Filtering Digital Signals
• 17.1 The Derivation of the Fourier Transform
• 17.2 The Convergence of the Fourier Integral
• 17.3 Using Laplace Transforms to Find Fourier Transforms
• 17.4 Fourier Transforms in the Limit
• 17.5 Some Mathematical Properties
• 17.6 Operational Transforms
• 17.7 Circuit Applications
• 17.8 Parseval’s Theorem
• Practical Perspective: Filtering Digital Signals
• Summary
• Problems
• Chapter 18 Two-Port Circuits
• Practical Perspective: Characterizing an Unknown Circuit
• 18.1 The Terminal Equations
• 18.2 The Two-Port Parameters
• 18.3 Analysis of the Terminated Two-Port Circuit
• 18.4 Interconnected Two-Port Circuits
• Practical Perspective: Characterizing an Unknown Circuit
• Summary
• Problems
• Appendix A The Solution of Linear Simultaneous Equations
• A.1 Preliminary Steps
• A.2 Calculator and Computer Methods
• A.3 Paper-and-Pencil Methods
• A.4 Applications
• Appendix B Complex Numbers
• B.1 Notation
• B.2 The Graphical Representation of a Complex Number
• B.3 Arithmetic Operations
• B.4 Useful Identities
• B.5 The Integer Power of a Complex Number
• B.6 The Roots of a Complex Number
• Appendix C More on Magnetically Coupled Coils and Ideal Transformers
• C.1 Equivalent Circuits for Magnetically Coupled Coils
• C.2 The Need for Ideal Transformers in Tthe Equivalent Circuits
• Appendix D The Decibel
• Appendix E Bode Diagrams
• E.1 Real, First-Order Poles and Zeros
• E.2 Straight-Line Amplitude Plots
• E.3 More Accurate Amplitude Plots
• E.4 Straight-Line Phase Angle Plots
• E.5 Bode Diagrams: Complex Poles and Zeros
• E.6 Straight-Line Amplitude Plots for Complex Poles
• E.7 Correcting Straight-Line Amplitude Plots for Complex Poles
• E.8 Phase Angle Plots for Complex Poles
• Appendix F An Abbreviated Table of Trigonometric Identities
• Appendix G An Abbreviated Table of Integrals
• Appendix H Common Standard Component Values
• Answers to Selected Problems
• Index
• Back Cover