Engineering Circuit Analysis

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The hallmark feature of this classic text is its focus on the student - it is written so that students may teach the science of circuit analysis to themselves. Terms are clearly defined when they are introduced, basic material appears toward the beginning of each chapter and is explained carefully and in detail, and numerical examples are used to introduce and suggest general results. Simple practice problems appear throughout each chapter, while more difficult problems appear at the end of chapters, following the order of presentation of text material. This introduction and resulting repetition provide an important boost to the learning process.

Hayt's rich pedagogy supports and encourages the student throughout by offering tips and warnings, using design to highlight key material, and providing lots of opportunities for hands-on learning. The thorough exposition of topics is delivered in an informal way that underscores the authors' conviction that circuit analysis can and should be fun.

This book offers CONNECT and COSMOS (solutions). CONNECT is free with the text if ordered together.

Author(s): William Hayt, Jack Kemmerly, Jamie Phillips, Steven Durbin
Edition: 9
Publisher: McGraw-Hill Education
Year: 2018

Language: English
Pages: 896
Tags: Circuit Analysis

COVER
TITLE
COPYRIGHT
BRIEF CONTENTS
CONTENTS
PREFACE
CHAPTER 1 INTRODUCTION
1.1 Overview of Text
1.2 Relationship of Circuit Analysis to Engineering
1.3 Analysis and Design
1.4 Computer-Aided Analysis
1.5 Successful Problem-Solving Strategies
READING FURTHER
CHAPTER 2 BASIC COMPONENTS AND ELECTRIC CIRCUITS
2.1 Units and Scales
2.2 Charge, Current, Voltage, Power, and Energy
2.3 Voltage and Current Sources
2.4 Ohm's Law
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 3 VOLTAGE AND CURRENT LAWS
3.1 Nodes, Paths, Loops, and Branches
3.2 Kirchhoff's Current Law
3.3 Kirchhoff's Voltage Law
3.4 The Single-Loop Circuit
3.5 The Single-Node-Pair Circuit
3.6 Series and Parallel Connected Sources
3.7 Resistors in Series and Parallel
3.8 Voltage and Current Division
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 4 BASIC NODAL AND MESH ANALYSIS
4.1 Nodal Analysis
4.2 The Supernode
4.3 Mesh Analysis
4.4 The Supermesh
4.5 Nodal vs. Mesh Analysis: A Comparison
4.6 Computer-Aided Circuit Analysis
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 5 HANDY CIRCUIT ANALYSIS TECHNIQUES
5.1 Linearity and Superposition
5.2 Source Transformations
5.3 Thévenin and Norton Equivalent Circuits
5.4 Maximum Power Transfer
5.5 Delta-Wye Conversion
5.6 Selecting an Approach: A Summary of Various Techniques
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 6 THE OPERATIONAL AMPLIFIER
6.1 Background
6.2 The Ideal Op Amp
6.3 Cascaded Stages
6.4 Feedback, Comparators, and the Instrumentation Amplifier
6.5 Practical Considerations
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 7 CAPACITORS AND INDUCTORS
7.1 The Capacitor
7.2 The Inductor
7.3 Inductance and Capacitance Combinations
7.4 Linearity and its Consequences
7.5 Simple Op Amp Circuits with Capacitors
7.6 Duality
7.7 Computer Modeling of Circuits with Capacitors and Inductors
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 8 BASIC RC AND RL CIRCUITS
8.1 The Source-Free RC Circuit
8.2 Properties of the Exponential Response
8.3 The Source-Free RL Circuit
8.4 A More General Perspective
8.5 The Unit-Step Function
8.6 Driven RC Circuits
8.7 Driven RL Circuits
8.8 Predicting the Response of Sequentially Switched Circuits
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 9 THE RLC CIRCUIT
9.1 The Source-Free Parallel Circuit
9.2 The Overdamped Parallel RLC Circuit
9.3 Critical Damping
9.4 The Underdamped Parallel RLC Circuit
9.5 The Source-Free Series RLC Circuit
9.6 The Complete Response of the RLC Circuit
9.7 The Lossless LC Circuit
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 10 SINUSOIDAL STEADY-STATE ANALYSIS
10.1 Characteristics of Sinusoids
10.2 Forced Response to Sinusoidal Functions
10.3 The Complex Forcing Function
10.4 The Phasor
10.5 Impedance and Admittance
10.6 Nodal and Mesh Analysis
10.7 Superposition, Source Transformations, and Thévenin's Theorem
10.8 Phasor Diagrams
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 11 AC CIRCUIT POWER ANALYSIS
11.1 Instantaneous Power
11.2 Average Power
11.3 Maximum Power Transfer
11.4 Effective Values of Current and Voltage
11.5 Apparent Power and Power Factor
11.6 Complex Power
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 12 POLYPHASE CIRCUITS
12.1 Polyphase Systems
12.2 Single-Phase Three-Wire Systems
12.3 Three-Phase Y-Y Connection
12.4 The Delta (Δ) Connection
12.5 Power Measurement in Three-Phase Systems
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 13 MAGNETICALLY COUPLED CIRCUITS
13.1 Mutual Inductance
13.2 Energy Considerations
13.3 The Linear Transformer
13.4 The Ideal Transformer
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 14 CIRCUIT ANALYSIS IN THE s-DOMAIN
14.1 Complex Frequency
14.2 Definition of the Laplace Transform
14.3 Laplace Transforms of Simple Time Functions
14.4 Inverse Transform Techniques
14.5 Basic Theorems for the Laplace Transform
14.6 The Initial-Value and Final-Value Theorems
14.7 Z(s) and Y(s)
14.8 Nodal and Mesh Analysis in the s-Domain
14.9 Additional Circuit Analysis Techniques
14.10 Poles, Zeros, and Transfer Functions
14.11 Convolution
14.12 A Technique for Synthesizing the Voltage Ratio H(s) = V[sub(out)]/V[sub(in)]
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 15 FREQUENCY RESPONSE
15.1 Transfer Function
15.2 Bode Diagrams
15.3 Parallel Resonance
15.4 Bandwidth and High-Q Circuits
15.5 Series Resonance
15.6 Other Resonant Forms
15.7 Scaling
15.8 Basic Filter Design
15.9 Advanced Filter Design
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 16 TWO-PORT NETWORKS
16.1 One-Port Networks
16.2 Admittance Parameters
16.3 Some Equivalent Networks
16.4 Impedance Parameters
16.5 Hybrid Parameters
16.6 Transmission Parameters
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
CHAPTER 17 FOURIER CIRCUIT ANALYSIS
17.1 Trigonometric Form of the Fourier Series
17.2 The Use of Symmetry
17.3 Complete Response to Periodic Forcing Functions
17.4 Complex Form of the Fourier Series
17.5 Definition of the Fourier Transform
17.6 Some Properties of the Fourier Transform
17.7 Fourier Transform Pairs for Some Simple Time Functions
17.8 The Fourier Transform of a General Periodic Time Function
17.9 The System Function and Response in the Frequency Domain
17.10 The Physical Significance of the System Function
SUMMARY AND REVIEW
READING FURTHER
EXERCISES
APPENDIX 1 AN INTRODUCTION TO NETWORK TOPOLOGY
APPENDIX 2 SOLUTION OF SIMULTANEOUS EQUATIONS
APPENDIX 3 A PROOF OF THÉVENIN'S THEOREM
APPENDIX 4 AN LTspice[sup(®)] TUTORIAL
APPENDIX 5 COMPLEX NUMBERS
APPENDIX 6 A BRIEF MATLAB[sup(®)] TUTORIAL
APPENDIX 7 ADDITIONAL LAPLACE TRANSFORM THEOREMS
APPENDIX 8 THE COMPLEX FREQUENCY PLANE
INDEX
A
B
C
D
E
F
G
H
I
J
K
L
M
N
O
P
Q
R
S
T
U
V
W
Y
Z
ADDITIONAL CONTENT