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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 text introduces figures with color-coding to significantly improve comprehension.
List of contents
Preface xi
CHAPTER 1 BASIC CONCEPTS 1
1.1 System of Units 2
1.2 Basic Quantities 2
1.3 Circuit Elements 8
Summary 17
Problems 17
CHAPTER 2 RESISTIVE CIRCUITS 25
2.1 Ohm's Law 26
2.2 Kirchhoff's Laws 31
2.3 Single-Loop Circuits 39
2.4 Single-Node-Pair Circuits 46
2.5 Series and Parallel Resistor Combinations 51
2.6 Circuits with Series-Parallel Combinations of Resistors 55
2.7 Wye Delta Transformations 61
2.8 Circuits with Dependent Sources 64
2.9 Resistor Technologies for Electronic Manufacturing 69
2.10 Application Examples 72
2.11 Design Examples 75
Summary 81
Problems 82
CHAPTER 3 NODAL AND LOOP ANALYSIS TECHNIQUES 102
3.1 Nodal Analysis 102
3.2 Loop Analysis 122
3.3 Application Example 137
3.4 Design Example 139
Summary 139
Problems 140
CHAPTER 4 OPERATIONAL AMPLIFIERS 156
4.1 Introduction 157
4.2 Op-Amp Models 157
4.3 Fundamental Op-Amp Circuits 163
4.4 Comparators 172
4.5 Application Examples 173
4.6 Design Examples 176
Summary 179
Problems 180
CHAPTER 5 ADDITIONAL ANALYSIS TECHNIQUES 189
5.1 Introduction 190
5.2 Superposition 192
5.3 Thévenin's and Norton's Theorems 198
5.4 Maximum Power Transfer 216
5.5 Application Example 220
5.6 Design Examples 221
Summary 227
Problems 227
CHAPTER 6 CAPACITANCE AND INDUCTANCE 245
6.1 Capacitors 246
6.2 Inductors 254
6.3 Capacitor and Inductor Combinations 264
6.4 RC Operational Amplifier Circuits 272
6.5 Application Examples 274
6.6 Design Examples 279
Summary 280
Problems 281
CHAPTER 7 FIRST- AND SECOND-ORDER TRANSIENT CIRCUITS 296
7.1 Introduction 297
7.2 First-Order Circuits 298
7.3 Second-Order Circuits 319
7.4 Application Examples 333
7.5 Design Examples 343
Summary 351
Problems 351
CHAPTER 8 AC STEADY-STATE ANALYSIS 369
8.1 Sinusoids 370
8.2 Sinusoidal and Complex Forcing Functions 373
8.3 Phasors 377
8.4 Phasor Relationships for Circuit Elements 379
8.5 Impedance and Admittance 383
8.6 Phasor Diagrams 390
8.7 Basic Analysis Using Kirchhoff's Laws 393
8.8 Analysis Techniques 396
8.9 Application Examples 408
8.10 Design Examples 410
Summary 413
Problems 414
CHAPTER 9 STEADY-STATE POWER ANALYSIS 435
9.1 Instantaneous Power 436
9.2 Average Power 437
9.3 Maximum Average Power Transfer 442
9.4 Effective or rms Values 447
9.5 The Power Factor 450
9.6 Complex Power 452
9.7 Power Factor Correction 457
9.8 Single-Phase Three-Wire Circuits 461
9.9 Safety Considerations 464
9.10 Application Examples 472
9.11 Design Examples 476
Summary 478
Problems 478
CHAPTER 10 MAGNETICALLY COUPLED NETWORKS 491
10.1 Mutual Inductance 492
10.2 Energy Analysis 503
10.3 The Ideal Transformer 506
10.4 Safety Considerations 515
10.5 Application Examples 516
10.6 Design Examples 521
Summary 525
Problems 526
CHAPTER 11 POLYPHASE CIRCUITS 541
11.1 Three-Phase Circuits 542
11.2 Three-Phase Connections 547
11.3 Source/Load Connections 548
11.4 Power Relationships 557
11.5 Power Factor Correction 561
11.6 Application Examples 562
11.7 Design Examples 566
Summary 570
Problems 570CHAPTER 12 VARIABLE-FREQUENCY NETWORK PERFORMANCE 577
12.1 Variable Frequency-Response Analysis 578
12.2 Sinusoidal Frequency Analysis 586
12.3 Resonant Circuits 597
12.4 Scaling 619
12.5 Filter Networks 620
12.6 Application Examples 645
12.7 Design Examples 649
Summary 655
Problems 656
CHAPTER 13 THE LAPLACE TRANSFORM 667
13.1 Definition 668
13.2 Two Important Singularity Functions 669
13.3 Transform Pairs 671
13.4 Properties of the Transform 673
13.5 Performing the Inverse Transform 676
13.6 Convolution Integral 681
13.7 Initial-Value and Final-Value Theorems 685
13.8 Application Examples 687
Summary 689
Problems 689
CHAPTER 14 APPLICATION OF THE LAPLACE TRA
