Circuit Analysis with PSpice. A Simplified Approach

Content: List of PSpice Simulations Preface Convention for Voltage and Current Symbols Part I: Basic Concepts in Circuit AnalysisChapter 1 Preliminaries to Circuit AnalysisObjective and Overview 1.1 What are electric circuits and what are they used for? 1.2 What laws govern the behavior of electric circuits? 1.3 What is electric current? 1.4 What is the direction of current? 1.5 What is voltage? 1.6 What is voltage polarity?1.7 How are energy and power related to voltage and current? 1.8 What are ideal circuit elements and how do they handle energy? 1.9 Why resistance, capacitance, and inductance? 1.10 What are the approximations implicit in basic electric circuits? Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 2 Fundamentals of Resistive CircuitsObjective and Overview 2.1 Nature of Resistance 2.2 Ideal Resistors 2.3 Short Circuit and Open Circuit 2.4 Ideal, Independent Voltage Source 2.5 Ideal, Independent Current Source2.6 Ideal, Dependent Sources 2.7 Nomenclature and Analysis of Resistive Circuits 2.8 Kirchhoff\'s Laws 2.9 Series and Parallel Connections 2.10 Problem-Solving Approach Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 3 Circuit EquivalenceObjective and Overview 3.1 Circuit Equivalence and its Implications 3.2 Series and Parallel Connection of Resistors 3.3 Resistivity 3.4 Star-Delta Transformation 3.5 Series and Parallel Connection of Ideal Sources 3.6 Linear-Output Sources 3.7 Problem-Solving Approach Updated Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 4 Circuit TheoremsObjective and Overview 4.1 Excitation by Dependent Sources 4.2 Thevenin\'s Theorem 4.3 Norton\'s Theorem 4.4 Substitution Theorem 4.5 Source Absorption Theorem 4.6 Problem-Solving Approach Updated Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 5 Circuit SimplificationObjective and Overview 5.1 Superposition 5.2 Output Scaling 5.3 Redundant Resistors 5.4 Partitioning of Circuits by Ideal Sources 5.5 Source Rearrangement 5.6 Exploitation of Symmetry 5.6 Problem-Solving Approach Updated Learning Checklist: What should be learned from this chapter Problem-Solving Tips Appendix 5A Wheatstone Bridge Exercises and Problems Chapter 6 Circuit EquationsObjective and Overview 6.1 Node-Voltage Method 6.2 Dependent Sources in Node-Voltage Method 6.3 Mesh-Current Method 6.4 Dependent Sources in Mesh-Current Method 6.5 Problem-Solving Approach UpdatedLearning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 7 Capacitors, Inductors, and DualityObjective and Overview 7.1 Voltage-Current Relation of a Capacitor 7.2 Voltage-Current Relation of an Inductor 7.3 Series and Parallel Connections of Initially-Uncharged Capacitors 7.4 Series and Parallel Connections of Initially-Uncharged Inductors 7.5 Duality Learning Checklist: What should be learned from this chapter Problem-Solving TipsAppendix 7A Derivation of the Dual of a Planar Circuit Exercises and Problems Chapter 8 Sinusoidal Steady StateObjective and Overview 8.1 The Sinusoidal Function 8.2 Responses to Sinusoidal Excitation 8.3 Phasors 8.4 Phasor Relations of Circuit Elements 8.5 Impedance and Reactance 8.6 Governing Equations 8.7 Representation in the Frequency Domain 8.8 Phasor Diagrams Learning Checklist: What should be learned from this chapter Problem-Solving Tips Appendix 8A ac Bridges Exercises and Problems Chapter 9 Linear TransformerObjective and Overview 9.1 Magnetic Coupling 9.2 Mutual Inductance 9.3 Linear Transformer 9.4 T-Equivalent Circuit Learning Checklist: What should be learned from this chapter Problem-Solving Tips Appendix 9A Energy Stored in Magnetically-Coupled Coils Exercises and Problems Chapter 10 Ideal TransformeObjective and Overview 10.1 Magnetic Circuit 10.2 Ideal Transformer 10.3 Reflection of Circuits 10.4 Ideal Autotransformer 10.5 Transformer Imperfections Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 11 Basic Responses of First-Order CircuitsObjective and Overview 11.1 Capacitor Discharge 11.2 Capacitor Charging 11.3 Inductor Discharge 11.4 Inductor Charging 11.5 Generalized First-Order Circuits 11.6 Role of Transient Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 12 Basic Responses of Second-Order CircuitsObjective and Overview 12.1 Natural Responses of Series RLC Circuit 12.2 Natural Response of Parallel GCL Circuit 12.3 Charging of Series RLC Circuit 12.4 Procedure for Analyzing Prototypical Second-Order Circuits Learning Checklist: What should be learned from this chapter Problem-Solving Tips Appendix 12A More General Second-Order Circuits Exercises and Problems Part II: Topics in Circuit AnalysisChapter 13 Ideal Operational AmplifierObjective and Overview 13.1 Basic Properties 13.2 Feedback 13.3 Noninverting Configuration 13.4 Inverting Configuration 13.5 Applications of the Inverting Configuration 13.6 Difference Amplifier 13.7 Solving Problems on Operational Amplifiers Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 14 Frequency ResponsesObjective and Overview 14.1 Analysis of Filters 14.2 Ideal Frequency Responses 14.3 First-Order Responses 14.4 Bode Plots 14.5 Second-Order Bandpass Response 14.6 Second-Order Bandstop Response 14.7 Second-Order Lowpass and Highpass Responses 14.8 Parallel Circuit 14.9 Summary of Second-Order Responses Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 15 Butterworth and Active FiltersObjective and Overview 15.1 Scaling 15.2 Butterworth Response 15.3 First-Order Active Filters 15.4 Non-Inverting Second-Order Active Filters 15.5 Inverting Second-Order Active Filters 15.6 Universal Filter Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 16 Responses to Periodic InputsObjective and Overview 16.1 Fourier Series 16.2 Fourier Analysis 16.3 Symmetry Properties of Fourier Series 16.4 Derivation of FSEs from those of Other Functions 16.5 Concluding Remarks on FSEs 16.6 Circuit Responses to Periodic Functions 16.7 Average Power and rms Values Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 17 Real, Reactive and Complex PowerObjective and Overview 17.1 Instantaneous and Real Power 17.2 Complex Power 17.3 Power Factor Correction 17.4 Maximum Power Transfer Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 18 Responses to Step and Impulse InputsObjective and Overview 18.1 Capacitor Response to Current Pulse 18.2 The Impulse Function 18.3 Response of Capacitive Circuits to Step and impulse inputs 18.4 Inductor Response to Voltage Pulse 18.5 Response of Inductive Circuits to Step and impulse inputs 18.6 Response of RLC Circuits to Step and Impulse Inputs Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 19 Switched Circuits with Initial Energy StorageObjective and Overview 19.1 Series and Parallel Connections of Inductors with Initial Charges 19.2 Series and Parallel Connections of Inductors with Initial Currents 19.3 Switched Circuits Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 20 ConvolutionObjective and Overview 20.1 Shifting in Time and Folding 20.2 The Convolution Integral 20.3 Operational Properties of Convolution 20.4 Special Cases of Convolution 20.5 Some General Properties of the Convolution Integral Learning Checklist: What should be learned from this chapter Problem-Solving Tips Exercises and Problems Chapter 21 Properties of the Laplace TransformObjective and Overview 21.1 General 21.2 Operational Properties of the LT 21.3 Solution of Ordinary, Linear Differential Equations 21.4 Theorems on the Laplace Transform Learning Checklist: What should be learned from this chapterProblem-Solving Tips Appendix 21A Simplification of Rational Functions of s Exercises and Problems Chapter 22 The Laplace Transform in Circuit AnalysisObjective and Overview 22.1 Representation of Circuit Elements in the s Domain 22.2 Solution of Circuit Problems in the s Domain 22.3 Transfer Function 22.4 Interpretations of Circuit Responses in the s-Domain Learning Checklist: What should be learned from this chapter Problem-Solving TipsExercises and Problems Chapter 23 Fourier TransformObjective and Overview 23.1 Derivation of the Fourier Transform 23.2 Some General Properties of the Fourier Transform 23.3 Operational Properties of the Fourier Transform 23.4 Circuit Applications of the Fourier Transform 23.5 Parseval\'s Theorem Learning Checklist: What should be learned from this chapter Exercises and Problems Chapter 24 Two-Port CircuitsObjective and Overview 24.1 Circuit Description 24.2 Parameter Interpretation and Relations 24.3 Equivalent Circuits 24.4 Composite Two-Port Circuits 24.5 Analysis of Terminated Two-Port Circuits Learning Checklist: What should be learned from this chapter Exercises and Problems Chapter 25 Balanced Three-Phase SystemsObjective and Overview 25.1 Three-Phase Variables 25.2 The Balanced Y Connection 25.3 The Balanced D Connection 25.4 Analysis of Balanced Three-Phase Systems 25.5 Power in Balanced Three-Phase Systems 25.6 Advantages of Three-Phase Systems 25.7 Power Generation, Transmission, and Distribution Learning Checklist: What should be learned from this chapter Exercises and Problems AppendicesAppendix A SI Units, Symbols, and Prefixes Appendix B Useful Mathematical Relations Appendix C PSpice Simulation Appendix D Complex Numbers and AlgebraAppendix E Solution of Linear Simultaneous Equations