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Engineering Circuit Analysis: International Student Version, Tenth Edition

Book Description

Maintaining its accessible approach to circuit analysis, the tenth edition includes even more features to engage and motivate engineers. Exciting chapter openers and accompanying photos are included to enhance visual learning. The book introduces figures with color-coding to significantly improve comprehension. New problems and expanded application examples in PSPICE, MATLAB, and LabView are included. New quizzes are also added to help engineers reinforce the key concepts.

Table of Contents

  1. Copyright
  2. PREFACE
    1. To the Student
    2. To the Instructor
    3. Highlights of the Tenth Edition
    4. Organization
    5. Text Pedagogy
    6. WileyPLUS
      1. WHAT DO STUDENTS RECEIVE WITH WILEYPLUS?
    7. Supplements
    8. Acknowledgments
  3. 1. BASIC CONCEPTS
    1. 1.1. System of Units
    2. 1.2. Basic Quantities
    3. 1.3. Circuit Elements
    4. 1.4. SUMMARY
    5. 1.5. PROBLEMS
  4. 2. RESISTIVE CIRCUITS
    1. 2.1. Ohm's Law
    2. 2.2. Kirchhoff's Laws
    3. 2.3. Single-Loop Circuits
    4. 2.4. Single-Node-Pair Circuits
    5. 2.5. Series and Parallel Resistor Combinations
    6. 2.6. Circuits with Series-Parallel Combinations of Resistors
    7. 2.7. Wye ⇌ Delta Transformations
    8. 2.8. Circuits with Dependent Sources
    9. 2.9. Resistor Technologies for Electronic Manufacturing
    10. 2.10. Application Examples
    11. 2.11. Design Examples
    12. 2.12. SUMMARY
    13. 2.13. PROBLEMS
    14. 2.14. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  5. 3. NODAL AND LOOP ANALYSIS TECHNIQUES
    1. 3.1. Nodal Analysis
    2. 3.2. Loop Analysis
    3. 3.3. Application Example
    4. 3.4. Design Example
    5. 3.5. SUMMARY
    6. 3.6. PROBLEMS
    7. 3.7. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  6. 4. OPERATIONAL AMPLIFIERS
    1. 4.1. Introduction
    2. 4.2. Op-Amp Models
    3. 4.3. Fundamental Op-Amp Circuits
    4. 4.4. Comparators
    5. 4.5. Application Examples
    6. 4.6. Design Examples
    7. 4.7. SUMMARY
    8. 4.8. PROBLEMS
    9. 4.9. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  7. 5. ADDITIONAL ANALYSIS TECHNIQUES
    1. 5.1. Introduction
    2. 5.2. Superposition
    3. 5.3. Thévenin's and Norton's Theorems
      1. 5.3.1. CIRCUITS CONTAINING ONLY INDEPENDENT SOURCES
    4. 5.4. Maximum Power Transfer
    5. 5.5. Application Example
    6. 5.6. Design Examples
    7. 5.7. SUMMARY
    8. 5.8. PROBLEMS
    9. 5.9. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  8. 6. CAPACITANCE AND INDUCTANCE
    1. 6.1. Capacitors
    2. 6.2. Inductors
    3. 6.3. Capacitor and Inductor Combinations
    4. 6.4. RC Operational Amplifier Circuits
    5. 6.5. Application Examples
    6. 6.6. Design Examples
    7. 6.7. SUMMARY
    8. 6.8. PROBLEMS
    9. 6.9. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  9. 7. FIRST- AND SECOND-ORDER TRANSIENT CIRCUITS
    1. 7.1. Introduction
    2. 7.2. First-Order Circuits
      1. 7.2.1. ANALYSIS TECHNIQUES
    3. 7.3. Second-Order Circuits
    4. 7.4. Application Examples
    5. 7.5. Design Examples
    6. 7.6. SUMMARY
    7. 7.7. PROBLEMS
    8. 7.8. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  10. 8. AC STEADY-STATE ANALYSIS
    1. 8.1. Sinusoids
    2. 8.2. Sinusoidal and Complex Forcing Functions
    3. 8.3. Phasors
    4. 8.4. Phasor Relationships for Circuit Elements
    5. 8.5. Impedance and Admittance
    6. 8.6. Phasor Diagrams
    7. 8.7. Basic Analysis Using Kirchhoff's Laws
    8. 8.8. Analysis Techniques
    9. 8.9. Application Examples
    10. 8.10. Design Examples
    11. 8.11. SUMMARY
    12. 8.12. PROBLEMS
    13. 8.13. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  11. 9. STEADY-STATE POWER ANALYSIS
    1. 9.1. Instantaneous Power
    2. 9.2. Average Power
    3. 9.3. Maximum Average Power Transfer
    4. 9.4. Effective or rms Values
    5. 9.5. The Power Factor
    6. 9.6. Complex Power
    7. 9.7. Power Factor Correction
    8. 9.8. Single-Phase Three-Wire Circuits
    9. 9.9. Safety Considerations
    10. 9.10. Application Examples
    11. 9.11. Design Examples
    12. 9.12. SUMMARY
    13. 9.13. PROBLEMS
    14. 9.14. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  12. 10. MAGNETICALLY COUPLED NETWORKS
    1. 10.1. Mutual Inductance
    2. 10.2. Energy Analysis
    3. 10.3. The Ideal Transformer
    4. 10.4. Safety Considerations
    5. 10.5. Application Examples
    6. 10.6. Design Examples
    7. 10.7. SUMMARY
    8. 10.8. PROBLEMS
    9. 10.9. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  13. 11. POLYPHASE CIRCUITS
    1. 11.1. Three-Phase Circuits
    2. 11.2. Three-Phase Connections
    3. 11.3. Source/Load Connections
    4. 11.4. Power Relationships
    5. 11.5. Power Factor Correction
    6. 11.6. Application Examples
    7. 11.7. Design Examples
    8. 11.8. SUMMARY
    9. 11.9. PROBLEMS
    10. 11.10. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  14. 12. VARIABLE-FREQUENCY NETWORK PERFORMANCE
    1. 12.1. Variable Frequency-Response Analysis
    2. 12.2. Sinusoidal Frequency Analysis
    3. 12.3. Resonant Circuits
    4. 12.4. Scaling
    5. 12.5. Filter Networks
    6. 12.6. Application Examples
    7. 12.7. Design Examples
    8. 12.8. SUMMARY
    9. 12.9. PROBLEMS
    10. 12.10. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  15. 13. THE LAPLACE TRANSFORM
    1. 13.1. Definition
    2. 13.2. Two Important Singularity Functions
    3. 13.3. Transform Pairs
    4. 13.4. Properties of the Transform
    5. 13.5. Performing the Inverse Transform
    6. 13.6. Convolution Integral
    7. 13.7. Initial-Value and Final-Value Theorems
    8. 13.8. Application Example
    9. 13.9. SUMMARY
    10. 13.10. PROBLEMS
    11. 13.11. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  16. 14. APPLICATION OF THE LAPLACE TRANSFORM TO CIRCUIT ANALYSIS
    1. 14.1. Laplace Circuit Solutions
    2. 14.2. Circuit Element Models
    3. 14.3. Analysis Techniques
    4. 14.4. Transfer Function
    5. 14.5. Pole-Zero Plot/Bode Plot Connection
    6. 14.6. Steady-State Response
    7. 14.7. Application Example
    8. 14.8. Design Examples
    9. 14.9. SUMMARY
    10. 14.10. PROBLEMS
    11. 14.11. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  17. 15. FOURIER ANALYSIS TECHNIQUES
    1. 15.1. Fourier Series
    2. 15.2. Fourier Transform
    3. 15.3. Application Examples
    4. 15.4. Design Example
    5. 15.5. SUMMARY
    6. 15.6. PROBLEMS
    7. 15.7. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  18. 16. TWO-PORT NETWORKS
    1. 16.1. Admittance Parameters
    2. 16.2. Impedance Parameters
    3. 16.3. Hybrid Parameters
    4. 16.4. Transmission Parameters
    5. 16.5. Parameter Conversions
    6. 16.6. Interconnection of Two-Ports
    7. 16.7. Application Examples
    8. 16.8. Design Example
    9. 16.9. SUMMARY
    10. 16.10. PROBLEMS
    11. 16.11. TYPICAL PROBLEMS FOUND ON THE FE EXAM
  19. A. COMPLEX NUMBERS