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Basic Engineering Circuit Analysis, 9th Edition
by
Irwin, J. David, Auburn Univ.; Nelms, R. Mark, Auburn Univ.
Publisher: John Wiley & Sons
Publishing Date: 2008/01/02
eText ISBN-10
0-470-39731-4
eText ISBN-13
978-0-470-39731-2
Print ISBN-10
0-470-12869-0
Print ISBN-13
978-0-470-12869-5
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Basic Engineering Circuit Analysis, 9th Edition
by
Irwin, J. David, Auburn Univ.; Nelms, R. Mark, Auburn Univ.
eTextbook $90.50
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Copyright, vi
Preface, xv
Chapter 1. BASIC CONCEPTS...
Chapter 2. RESISTIVE CIRC...
Chapter 3. NODAL AND LOOP...
Chapter 4. OPERATIONAL AM...
Chapter 5. ADDITIONAL ANA...
Chapter 6. CAPACITANCE AN...
Chapter 7. FIRST- AND SEC...
Chapter 8. AC STEADY-STAT...
Chapter 9. STEADY-STATE P...
Chapter 10. MAGNETICALLY ...
Chapter 11. POLYPHASE CIR...
Chapter 12. VARIABLE-FREQ...
Chapter 13. THE LAPLACE T...
Chapter 14. APPLICATION O...
Chapter 15. FOURIER ANALY...
Chapter 16. TWO-PORT NETW...
Appendix: Complex Numbers...
Index, 840
Table of Contents
Copyright, vi
Preface, xv
Chapter 1. BASIC CONCEPTS, 1
1.1. System of Units, 2
1.2. Basic Quantities, 2
1.3. Circuit Elements, 8
Summary, 16
Problems, 16
Chapter 2. RESISTIVE CIRCUITS, 23
2.1. Ohm’s Law, 24
2.2. Kirchhoff’s Laws, 28
2.3. Single-Loop Circuits, 37
2.4. Single-Node-Pair Circuits, 43
2.5. Series and Parallel Resistor Combinations, 48
2.6. Circuits with Series-Parallel Combinations of Resistors, 53
2.7. Wye ⇌ Delta Transformations, 57
2.8. Circuits with Dependent Sources, 60
2.9. Resistor Technologies for Electronic Manufacturing, 64
2.10. Application Examples, 67
2.11. Design Examples, 71
Summary, 76
Problems, 77
Chapter 3. NODAL AND LOOP ANALYSIS TECHNIQUES, 95
3.1. Nodal Analysis, 96
3.2. Loop Analysis, 115
3.3. Application Example, 131
3.4. Design Example, 133
Summary, 133
Problems, 134
Chapter 4. OPERATIONAL AMPLIFIERS, 149
4.1. Introduction, 150
4.2. Op-Amp Models, 150
4.3. Fundamental Op-Amp Circuits, 156
4.4. Comparators, 164
4.5. Application Examples, 165
4.6. Design Examples, 169
Summary, 172
Problems, 172
Chapter 5. ADDITIONAL ANALYSIS TECHNIQUES, 183
5.1. Introduction, 184
5.2. Superposition, 186
5.3. Thévenin’s and Norton’s Theorems, 191
5.4. Maximum Power Transfer, 208
5.5. dc SPICE Analysis Using
Schematic
Capture, 212
5.6. Application Example, 224
5.7. Design Examples, 225
Summary, 231
Problems, 231
Chapter 6. CAPACITANCE AND INDUCTANCE, 248
6.1. Capacitors, 249
6.2. Inductors, 255
6.3. Capacitor and Inductor Combinations, 264
6.4.
RC
Operational Amplifier Circuits, 271
6.5. Application Examples, 274
6.6. Design Examples, 278
Summary, 280
Problems, 280
Chapter 7. FIRST- AND SECOND-ORDER TRANSIENT CIRCUITS, 291
7.1. Introduction, 292
7.2. First-Order Circuits, 293
7.3. Second-Order Circuits, 314
7.4. Transient PSPICE Analysis Using
Schematic
Capture, 328
7.5. Application Examples, 337
7.6. Design Examples, 348
Summary, 356
Problems, 356
Chapter 8. AC STEADY-STATE ANALYSIS, 375
8.1. Sinusoids, 376
8.2. Sinusoidal and Complex Forcing Functions, 379
8.3. Phasors, 383
8.4. Phasor Relationships for Circuit Elements, 385
8.5. Impedance and Admittance, 389
8.6. Phasor Diagrams, 396
8.7. Basic Analysis Using Kirchhoff’s Laws, 399
8.8. Analysis Techniques, 401
8.9. AC PSPICE Analysis Using
Schematic
Capture, 416
8.10. Application Examples, 429
8.11. Design Examples, 431
Summary, 434
Problems, 435
Chapter 9. STEADY-STATE POWER ANALYSIS, 455
9.1. Instantaneous Power, 456
9.2. Average Power, 457
9.3. Maximum Average Power Transfer, 462
9.4. Effective or rms Values, 466
9.5. The Power Factor, 469
9.6. Complex Power, 471
9.7. Power Factor Correction, 476
9.8. Single-Phase Three-Wire Circuits, 479
9.9. Safety Considerations, 482
9.10. Application Examples, 490
9.11. Design Example, 494
Summary, 496
Problems, 496
Chapter 10. MAGNETICALLY COUPLED NETWORKS, 507
10.1. Mutual Inductance, 508
10.2. Energy Analysis, 518
10.3. The Ideal Transformer, 521
10.4. Safety Considerations, 529
10.5. Application Examples, 530
10.6. Design Examples, 535
Summary, 539
Problems, 540
Chapter 11. POLYPHASE CIRCUITS, 553
11.1. Three-Phase Circuits, 554
11.2. Three-Phase Connections, 559
11.3. Source/Load Connections, 560
11.4. Power Relationships, 568
11.5. Power Factor Correction, 572
11.6. Application Examples, 573
11.7. Design Examples, 576
Summary, 580
Problems, 581
Chapter 12. VARIABLE-FREQUENCY NETWORK PERFORMANCE, 587
12.1. Variable Frequency-Response Analysis, 588
12.2. Sinusoidal Frequency Analysis, 596
12.3. Resonant Circuits, 608
12.4. Scaling, 629
12.5. Filter Networks, 631
12.6. Application Examples, 655
12.7. Design Examples, 659
Summary, 665
Problems, 666
Chapter 13. THE LAPLACE TRANSFORM, 677
13.1. Definition, 678
13.2. Two Important Singularity Functions, 679
13.3. Transform Pairs, 681
13.4. Properties of the Transform, 683
13.5. Performing the Inverse Transform, 686
13.6. Convolution Integral, 692
13.7. Initial-Value and Final-Value Theorems, 696
13.8. Application Example, 697
Summary, 699
Problems, 699
Chapter 14. APPLICATION OF THE LAPLACE TRANSFORM TO CIRCUIT ANALYSIS, 705
14.1. Laplace Circuit Solutions, 706
14.2. Circuit Element Models, 707
14.3. Analysis Techniques, 709
14.4. Transfer Function, 721
14.5. Pole-Zero Plot/Bode Plot Connection, 732
14.6. Steady-State Response, 735
14.7. Application Example, 737
14.8. Design Examples, 739
Summary, 746
Problems, 746
Chapter 15. FOURIER ANALYSIS TECHNIQUES, 758
15.1. Fourier Series, 759
15.2. Fourier Transform, 781
15.3. Application Examples, 788
15.4. Design Examples, 795
Summary, 801
Problems, 802
Chapter 16. TWO-PORT NETWORKS, 809
16.1. Admittance Parameters, 810
16.2. Impedance Parameters, 813
16.3. Hybrid Parameters, 815
16.4. Transmission Parameters, 817
16.5. Parameter Conversions, 818
16.6. Interconnection of Two-Ports, 819
16.7. Application Examples, 822
16.8. Design Example, 826
Summary, 828
Problems, 828
Appendix: Complex Numbers, 835
Index, 840
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