Engineering Circuit Analysis ISE

The hallmark feature of Engineering Circuit Analysis is its focus on the student. This text is written so students may teach the science of circuit analysis to themselves. Terms are clearly defined, 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. The new edition of Engineering Circuit Analysis is also available in McGraw Hill Connect, featuring: SmartBook 2.0, Adaptive STEM Prep Modules, Application-Based Activities, a curated question bank, Proctorio, and more! Cover Title Page Copyright Page About the Authors Brief Contents Contents Preface Acknowledgments 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 EXERCISES 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 Practical Considerations 6.5 Comparators and the Instrumentation Amplifier 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) = Vout/Vin 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® TUTORIAL APPENDIX 5 COMPLEX NUMBERS APPENDIX 6 A BRIEF MATLAB® TUTORIAL APPENDIX 7 ADDITIONAL LAPLACE TRANSFORM THEOREMS APPENDIX 8 THE COMPLEX FREQUENCY PLANE INDEX ADDITIONAL CONTENT "Although in many engineering programs the introductory circuits course is preceded or accompanied by an introductory physics course in which electricity and magnetism are introduced (typically from a fields perspective), this is not required to use this book. After finishing the course, many students find themselves truly amazed that such a broad set of analytical tools have been derived from only three simple scientific laws-Ohm's law and Kirchhoff's voltage and current laws. The first six chapters assume only a familiarity with algebra and simultaneous equations; subsequent chapters assume a first course in calculus (derivatives and integrals) is being taken in tandem. Beyond that, authors have tried to incorporate sufficient details to allow the book to be read on its own"-- Provided by publisher