Efnisyfirlit

• Cover
• Title Page
• Preface
  • Approach and Organization
  • What’s New in the Global Edition
  • Features Retained from Previous Editions
  • Supplements and Web Site Material
  • Acknowledgments and Commitment to Accuracy
• 1 Electric Circuit Variables
  • 1.1 Introduction
  • 1.2 Electric Circuits and Current
  • 1.3 Systems of Units
  • 1.4 Voltage
  • 1.5 Power and Energy
  • 1.6 Circuit Analysis and Design
  • 1.7 How Can We Check …?
  • 1.8 Design Example An Instrumentation Circuit
  • 1.9 SUMMARY
  • PROBLEMS
  • Design Problems
• 2 Circuit Elements
  • 2.1 Introduction
  • 2.2 Engineering and Linear Models
  • 2.3 Active and Passive Circuit Elements
  • 2.4 Resistors
  • 2.5 Independent Sources
  • 2.6 Voltmeters and Ammeters
  • 2.7 Dependent Sources
  • 2.8 Resistive Transducers
  • 2.9 Switches
  • 2.10 How Can We Check …?
  • 2.11 Design Example Temperature Sensor
  • 2.12 SUMMARY
  • PROBLEMS
  • Design Problems
• 3 Resistive Circuits
  • 3.1 Introduction
  • 3.2 Kirchhoff's Laws
  • 3.3 Series Resistors and Voltage Division
  • 3.4 Parallel Resistors and Current Division
  • 3.5 Series Voltage Sources and Parallel Current Sources
  • 3.6 Circuit Analysis
  • 3.7 Analyzing Resistive Circuits Using MATLAB
  • 3.8 How Can We Check …?
  • 3.9 Design Example Adjustable Voltage Source
  • 3.10 SUMMARY
  • PROBLEMS
  • Design Problems
• 4 Methods of Analysis of Resistive Circuits
  • 4.1 Introduction
  • 4.2 Node Voltage Analysis of Circuits with Current Sources
  • 4.3 Node Voltage Analysis of Circuits with Current and Voltage Sources
  • 4.4 Node Voltage Analysis with Dependent Sources
  • 4.5 Mesh Current Analysis with Independent Voltage Sources
  • 4.6 Mesh Current Analysis with Current and Voltage Sources
  • 4.7 Mesh Current Analysis with Dependent Sources
  • 4.8 The Node Voltage Method and Mesh Current Method Compared
  • 4.9 Circuit Analysis Using MATLAB
  • 4.10 Using PSpice to Determine Node Voltages and Mesh Currents
  • 4.11 How Can We Check…?
  • 4.12 Design Example Potentiometer Angle Display
  • 4.13 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 5 Circuit Theorems
  • 5.1 Introduction
  • 5.2 Source Transformations
  • 5.3 Superposition
  • 5.4 Thévenin’s Theorem
  • 5.5 Norton's Equivalent Circuit
  • 5.6 Maximum Power Transfer
  • 5.7 Using MATLAB to Determine the Thévenin Equivalent Circuit
  • 5.8 Using PSpice to Determine the Thévenin Equivalent Circuit
  • 5.9 How Can We Check …?
  • 5.10 Design Example Strain Gauge Bridge
  • 5.11 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 6 The Operational Amplifier
  • 6.1 Introduction
  • 6.2 The Operational Amplifier
  • 6.3 The Ideal Operational Amplifier
  • 6.4 Nodal Analysis of Circuits Containing Ideal Operational Amplifiers
  • 6.5 Design Using Operational Amplifiers
  • 6.6 Operational Amplifier Circuits and Linear Algebraic Equations
  • 6.7 Characteristics of Practical Operational Amplifiers
  • 6.8 Analysis of Op Amp Circuits Using MATLAB
  • 6.9 Using PSpice to Analyze Op Amp Circuits
  • 6.10 How Can We Check …?
  • 6.11 Design Example Transducer Interface Circuit
  • 6.12 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 7 Energy Storage Elements
  • 7.1 Introduction
  • 7.2 Capacitors
  • 7.3 Energy Storage in a Capacitor
  • 7.4 Series and Parallel Capacitors
  • 7.5 Inductors
  • 7.6 Energy Storage in an Inductor
  • 7.7 Series and Parallel Inductors
  • 7.8 Initial Conditions of Switched Circuits
  • 7.9 Operational Amplifier Circuits and Linear Differential Equations
  • 7.10 Using MATLAB to Plot Capacitor or Inductor Voltage and Current
  • 7.11 How Can We Check…?
  • 7.12 Design Example Integrator and Switch
  • 7.13 SUMMARY
  • PROBLEMS
  • Design Problems
• 8 The Complete Response of RL and RC Circuits
  • 8.1 Introduction
  • 8.2 First-Order Circuits
  • 8.3 The Response of a First-Order Circuit to a Constant Input
  • 8.4 Sequential Switching
  • 8.5 Stability of First-Order Circuits
  • 8.6 The Unit Step Source
  • 8.7 The Response of a First-Order Circuit to a Nonconstant Source
  • 8.8 Differential Operators
  • 8.9 Using PSpice to Analyze First-Order Circuits
  • 8.10 How Can We Check …?
  • 8.11 Design Example A Computer and Printer
  • 8.12 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 9 The Complete Response of Circuits with Two Energy Storage Elements
  • 9.1 Introduction
  • 9.2 Differential Equation for Circuits with Two Energy Storage Elements
  • 9.3 Solution of the Second-Order Differential Equation—The Natural Response
  • 9.4 Natural Response of the Unforced Parallel RLC Circuit
  • 9.5 Natural Response of the Critically Damped Unforced Parallel RLC Circuit
  • 9.6 Natural Response of an Underdamped Unforced Parallel RLC Circuit
  • 9.7 Forced Response of an RLC Circuit
  • 9.8 Complete Response of an RLC Circuit
  • 9.9 State Variable Approach to Circuit Analysis
  • 9.10 Roots in the Complex Plane
  • 9.11 How Can We Check …?
  • 9.12 Design Example Auto Airbag Igniter
  • 9.13 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 10 Sinusoidal Steady-State Analysis
  • 10.1 Introduction
  • 10.2 Sinusoidal Sources
  • 10.3 Phasors and Sinusoids
  • 10.4 Impedances
  • 10.5 Series and Parallel Impedances
  • 10.6 Mesh and Node Equations
  • 10.7 Thévenin and Norton Equivalent Circuits
  • 10.8 Superposition
  • 10.9 Phasor Diagrams
  • 10.10 Op Amps in AC Circuits
  • 10.11 The Complete Response
  • 10.12 Using MATLAB to Analyze AC Circuits
  • 10.13 Using PSpice to Analyze AC Circuits
  • 10.14 How Can We Check…?
  • 10.15 Design Example An Op Amp Circuit
  • 10.16 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 11 AC Steady-State Power
  • 11.1 Introduction
  • 11.2 Electric Power
  • 11.3 Instantaneous Power and Average Power
  • 11.4 Effective Value of a Periodic Waveform
  • 11.5 Complex Power
  • 11.6 Power Factor
  • 11.7 The Power Superposition Principle
  • 11.8 The Maximum Power Transfer Theorem
  • 11.9 Coupled Inductors
  • 11.10 The Ideal Transformer
  • 11.11 How Can We Check …?
  • 11.12 Design Example Maximum Power Transfer
  • 11.13 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 12 Three-Phase Circuits
  • 12.1 Introduction
  • 12.2 Three-Phase Voltages
  • 12.3 The Y-to-Y Circuit
  • 12.4 The Δ-Connected Source and Load
  • 12.5 The Y-to-Δ Circuit
  • 12.6 Balanced Three-Phase Circuits
  • 12.7 Instantaneous and Average Power in a Balanced Three-Phase Load
  • 12.8 Two-Wattmeter Power Measurement
  • 12.9 How Can We Check …?
  • 12.10 Design Example Power Factor Correction
  • 12.11 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 13 Frequency Response
  • 13.1 Introduction
  • 13.2 Gain, Phase Shift, and the Network Function
  • 13.3 Bode Plots
  • 13.4 Resonant Circuits
  • 13.5 Frequency Response of Op Amp Circuits
  • 13.6 Plotting Bode Plots Using MATLAB
  • 13.7 Using PSpice to Plot a Frequency Response
  • 13.8 How Can We Check …?
  • 13.9 Design Example Radio Tuner
  • 13.10 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 14 The Laplace Transform
  • 14.1 Introduction
  • 14.2 Laplace Transform
  • 14.3 Pulse Inputs
  • 14.4 Inverse Laplace Transform
  • 14.5 Initial and Final Value Theorems
  • 14.6 Solution of Differential Equations Describing a Circuit
  • 14.7 Circuit Analysis Using Impedance and Initial Conditions
  • 14.8 Transfer Function and Impedance
  • 14.9 Convolution
  • 14.10 Stability
  • 14.11 Partial Fraction Expansion Using MATLAB
  • 14.12 How Can We Check…?
  • 14.13 Design Example Space Shuttle Cargo Door
  • 14.14 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 15 Fourier Series and Fourier Transform
  • 15.1 Introduction
  • 15.2 The Fourier Series
  • 15.3 Symmetry of the Function f(t)
  • 15.4 Fourier Series of Selected Waveforms
  • 15.5 Exponential Form of the Fourier Series
  • 15.6 The Fourier Spectrum
  • 15.7 Circuits and Fourier Series
  • 15.8 Using PSpice to Determine the Fourier Series
  • 15.9 The Fourier Transform
  • 15.10 Fourier Transform Properties
  • 15.11 The Spectrum of Signals
  • 15.12 Convolution and Circuit Response
  • 15.13 The Fourier Transform and the Laplace Transform
  • 15.14 How Can We Check …?
  • 15.15 Design Example DC Power Supply
  • 15.16 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 16 Filter Circuits
  • 16.1 Introduction
  • 16.2 The Electric Filter
  • 16.3 Filters
  • 16.4 Second-Order Filters
  • 16.5 High-Order Filters
  • 16.6 Simulating Filter Circuits Using PSpice
  • 16.7 How Can We Check …?
  • 16.8 Design Example Anti-Aliasing Filter
  • 16.9 SUMMARY
  • PROBLEMS
  • PSpice Problems
  • Design Problems
• 17 Two-Port and Three-Port Networks
  • 17.1 Introduction
  • 17.2 T-to- Transformation and Two-Port Three-Terminal Networks
  • 17.3 Equations of Two-Port Networks
  • 17.4 Z and Y Parameters for a Circuit with Dependent Sources
  • 17.5 Hybrid and Transmission Parameters
  • 17.6 Relationships Between Two-Port Parameters
  • 17.7 Interconnection of Two-Port Networks
  • 17.8 How Can We Check …?
  • 17.9 Design Example Transistor Amplifier
  • 17.10 SUMMARY
  • PROBLEMS
  • Design Problems
• Appendix A: Getting Started with PSpice
  • A.1 PSpice
  • A.2 Getting Started
  • A.3 Drawing a Circuit in the ORCAD Capture Workspace
  • A.4 Specifying and Running the Simulation
• Appendix B: MATLAB, Matrices, and Complex Arithmetic
  • B.1 Using MATLAB as a Calculator
  • B.2 Matrices, Determinants, and Simultaneous Equations
  • B.3 Complex Numbers and Complex Arithmetic
  • B.4 Plotting Functions Using MATLAB
• Appendix C: Mathematical Formulas
  • C.1 Trigonometric Identities
  • C.2 Derivatives
  • C.3 Indefinite Integrals
• Appendix D: Resistor Specifications and Monte Carlo Analysis
• References
• Index
• End User License Agreement

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