Overview

Basic Engineering Circuit Analysis has long been regarded as the most dependable textbook for computer and electrical engineering majors. In this new edition, Irwin and Nelms continue to develop the most complete set of pedagogical tools available and provide the highest level of support for students entering into this complex subject. Irwin and Nelms trademark student-centered learning design focuses on helping students complete the connection between theory and practice. Key concepts are explained clearly and illustrated by detailed, worked examples. These are then followed by Learning Assessments, which allow students to work similar problems and check their results against the answers provided.

Full Product Details

Author:   J. David Irwin (Auburn University) ,  R. Mark Nelms (Auburn University)
Publisher:   John Wiley & Sons Inc
Imprint:   John Wiley & Sons Inc
Edition:   12th Revised edition
Dimensions:   Width: 21.10cm , Height: 3.10cm , Length: 27.40cm
Weight:   1.474kg
ISBN:  

9781119502012

ISBN 10:   1119502012
Pages:   768
Publication Date:   18 August 2020
Audience:   College/higher education ,  Tertiary & Higher Education
Format:   Loose-leaf
Publisher's Status:   Active
Availability:   Out of stock  
The supplier is temporarily out of stock of this item. It will be ordered for you on backorder and shipped when it becomes available.

Table of Contents

Preface ix 1 Basic Concepts 1 1.1 System of Units 1 1.2 Basic Quantities 2 1.3 Circuit Elements 8 Summary 18 2 Resistive Circuits 19 2.1 Ohm’s Law 19 2.2 Kirchhoff’s Laws 24 2.3 Single-Loop Circuits 33 2.4 Single-Node-Pair Circuits 40 2.5 Series and Parallel Resistor Combinations 45 2.6 Circuits with Series-Parallel Combinations of Resistors 51 2.7 Wye Delta Transformations 57 2.8 Circuits with Dependent Sources 61 2.9 Resistor Technologies for Electronic Manufacturing 67 2.10 Application Examples 70 2.11 Design Examples 72 Summary 78 3 Nodal and Loop Analysis Techniques 79 3.1 Nodal Analysis 79 3.2 Loop Analysis 100 3.3 Application Example 117 3.4 Design Example 118 Summary 119 4 Operational Amplifiers 120 4.1 Introduction 120 4.2 Op-Amp Models 121 4.3 Fundamental Op-Amp Circuits 127 4.4 Comparators 135 4.5 Application Examples 136 4.6 Design Examples 140 Summary 144 5 Additional Analysis Techniques 145 5.1 Introduction 145 5.2 Superposition 148 5.3 Thévenin’s and Norton’s Theorems 153 5.4 Maximum Power Transfer 171 5.5 Application Example 175 5.6 Design Examples 176 Summary 181 6 Capacitance and Inductance 182 6.1 Capacitors 182 6.2 Inductors 189 6.3 Capacitor and Inductor Combinations 198 6.4 RC Operational Amplifier Circuits 206 6.5 Application Examples 208 6.6 Design Examples 213 Summary 214 7 First- and Second-Order Transient Circuits 215 7.1 Introduction 215 7.2 First-Order Circuits 217 7.3 Second-Order Circuits 237 7.4 Application Examples 250 7.5 Design Examples 259 Summary 266 8 AC Steady-State Analysis 268 8.1 Sinusoids 268 8.2 Sinusoidal and Complex Forcing Functions 271 8.3 Phasors 275 8.4 Phasor Relationships for Circuit Elements 277 8.5 Impedance and Admittance 281 8.6 Phasor Diagrams 287 8.7 Basic Analysis Using Kirchhoff’s Laws 290 8.8 Analysis Techniques 293 8.9 Application Examples 305 8.10 Design Examples 307 Summary 310 9 Steady-State Power Analysis 311 9.1 Instantaneous Power 311 9.2 Average Power 312 9.3 Maximum Average Power Transfer 318 9.4 Effective or RMS Values 322 9.5 The Power Factor 325 9.6 Complex Power 327 9.7 Power Factor Correction 333 9.8 Single-Phase Three-Wire Circuits 337 9.9 Safety Considerations 340 9.10 Application Examples 348 9.11 Design Examples 352 Summary 355 10 Magnetically Coupled Networks 356 10.1 Mutual Inductance 356 10.2 Energy Analysis 367 10.3 The Ideal Transformer 370 10.4 Safety Considerations 379 10.5 Application Examples 380 10.6 Design Examples 385 Summary 388 11 Polyphase Circuits 389 11.1 Three-Phase Circuits 389 11.2 Three-Phase Connections 394 11.3 Source/Load Connections 396 11.4 Power Relationships 404 11.5 Power Factor Correction 408 11.6 Application Examples 410 11.7 Design Examples 413 Summary 417 12 Variable-Frequency Network Performance 418 12.1 Variable Frequency-Response Analysis 418 12.2 Sinusoidal Frequency Analysis 426 12.3 Resonant Circuits 438 12.4 Scaling 458 12.5 Filter Networks 460 12.6 Application Examples 484 12.7 Design Examples 488 Summary 494 13 The Laplace Transform 496 13.1 Definition 496 13.2 Two Important Singularity Functions 497 13.3 Transform Pairs 499 13.4 Properties of the Transform 501 13.5 Performing the Inverse Transform 503 13.6 Convolution Integral 509 13.7 Initial-Value and Final-Value Theorems 512 13.8 Solving Differential Equations with Laplace Transforms 514 Summary 516 14 Application of the Laplace Transform to Circuit Analysis 517 14.1 Laplace Circuit Solutions 517 14.2 Circuit Element Models 519 14.3 Analysis Techniques 521 14.4 Transfer Function 532 14.5 Pole-Zero Plot/Bode Plot Connection 552 14.6 Steady-State Response 554 Summary 558 15 Fourier Analysis Techniques 559 15.1 Fourier Series 559 15.2 Fourier Transform 583 15.3 Application Example 594 15.4 Design Examples 595 Summary 601 16 Two-Port Networks 602 16.1 Admittance Parameters 602 16.2 Impedance Parameters 605 16.3 Hybrid Parameters 607 16.4 Transmission Parameters 609 16.5 Parameter Conversions 611 16.6 Interconnection of Two-Ports 611 Summary 617 Appendix Complex Numbers 618 Problems 626 Index I-1 

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Author Information

J. David Irwin is an American engineering educator and author of popular textbooks in electrical engineering and related areas. He is the Earle C. Williams Eminent Scholar and former Electrical and Computer Engineering Department Head at Auburn University. R. Mark Nelms is the author of Basic Engineering Circuit Analysis, 12th Edition, published by Wiley.

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