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Engineering Circuit Analysis

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en Limba Engleză Carte Paperback – 12 Jun 2015
"Basic Engineering Circuit Analysis, 11th Edition" 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 thus 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.The WileyPLUS course contains tutorial videos that show solutions to the Learning Assessments in detail, and also includes a robust set of algorithmic problems at a wide range of difficulty levels. WileyPLUS sold separately from text.
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Specificații

ISBN-13: 9781118960639
ISBN-10: 1118960637
Pagini: 736
Dimensiuni: 219 x 278 x 17 mm
Greutate: 1.47 kg
Ediția: 11th Edition International Student Version
Editura: Wiley
Locul publicării: Hoboken, United States

Cuprins

Preface xi
CHAPTER 1
Basic Concepts 1
1.1 System of Units 1
1.2 Basic Quantities 2
1.3 Circuit Elements 8
Summary 17
Problems 17
CHAPTER 2
Resistive Circuits 23
2.1 Ohm s Law 23
2.2 Kirchhoff s Laws 29
2.3 Single–Loop Circuits 38
2.4 Single–Node–Pair Circuits 45
2.5 Series and Parallel Resistor Combinations 50
2.6 Wye Delta Transformations 60
2.7 Circuits with Dependent Sources 64
2.8 Design Example 68
Summary 71
Problems 72
CHAPTER 3
Nodal and Loop Analysis Techniques 89
3.1 Nodal Analysis 89
3.2 Loop Analysis 112
Summary 130
Problems 131
CHAPTER 4
Operational Amplifiers 147
4.1 Introduction 148
4.2 Op–Amp Models 148
4.3 Fundamental Op–Amp Circuits 154
Summary 167
Problems 167
CHAPTER 5
Additional Analysis Techniques 175
5.1 Introduction 175
5.2 Superposition 178
5.3 Thévenin s and Norton s Theorems 184
5.4 Maximum Power Transfer 205
5.5 Design Example 210
Summary 214
Problems 215
CHAPTER 6
Capacitance and Inductance 231
6.1 Capacitors 232
6.2 Inductors 238
6.3 Capacitor and Inductor Combinations 250
6.4 Design Example 255
Summary 256
Problems 256
CHAPTER 7
First– and Second–Order Transient Circuits 268
7.1 Introduction 269
7.2 First–Order Circuits 270
7.3 Second–Order Circuits 292
7.4 Design Example 307
Summary 309
Problems 310
CHAPTER 8
AC Steady–State Analysis 327
8.1 Sinusoids 327
8.2 Sinusoidal and Complex Forcing Functions 331
8.3 Phasors 334
8.4 Phasor Relationships for Circuit Elements 337
8.5 Impedance and Admittance 342
8.6 Phasor Diagrams 349
8.7 Basic Analysis Using Kirchhoff s Laws 352
8.8 Analysis Techniques 355
Summary 368
Problems 369
CHAPTER 9
Steady–State Power Analysis 384
9.1 Instantaneous Power 384
9.2 Average Power 386
9.3 Maximum Average Power Transfer 392
9.4 Effective or rms Values 397
9.5 The Power Factor 401
9.6 Complex Power 403
9.7 Power Factor Correction 408
9.8 Single–Phase Three–Wire Circuits 412
9.9 Safety Considerations 415
9.10 Design Example 422
Summary 423
Problems 424
CHAPTER 10
Magnetically Coupled Networks 437
10.1 Mutual Inductance 437
10.2 Energy Analysis 450
10.3 The Ideal Transformer 453
10.4 Safety Considerations 464
Summary 466
Problems 466
CHAPTER 11
Polyphase Circuits 478
11.1 Three–Phase Circuits 478
11.2 Three–Phase Connections 482
11.3 Source/Load Connections 483
11.4 Power Relationships 494
11.5 Power Factor Correction 501
Summary 504

Problems 505
CHAPTER 12
Variable Frequency Network Performance 510
12.1 Variable Frequency–Response Analysis 511
12.2 Sinusoidal Frequency Analysis 520
12.3 Resonant Circuits 531
12.4 Scaling 553
12.5 Filter Networks 555
Summary 567
Problems 568
CHAPTER 13
The Laplace Transform 577
13.1 Definition 577
13.2 Two Important Singularity Functions 578
13.3 Transform Pairs 581
13.4 Properties of the Transform 583
13.5 Performing the Inverse Transform 585
13.6 Convolution Integral 591
13.7 Initial–Value and Final–Value Theorems 594
13.8 Solving Differential Equations with Laplace
Transforms 596
Summary 599
Problems 599
CHAPTER 14
Application of the Laplace Transform to Circuit Analysis 605
14.1 Laplace Circuit Solutions 605
14.2 Circuit Element Models 607
14.3 Analysis Techniques 609
14.4 Transfer Function 624
14.5 Steady–State Response 642
Summary 647
Problems 648
CHAPTER 15
Fourier Analysis Techniques 659
15.1 Fourier Series 660
15.2 Fourier Transform 685
Summary 696
Problems 697
CHAPTER 16∗
Two–Port Networks 16–1
16.1 Admittance Parameters 16–1
16.2 Impedance Parameters 16–5
16.3 Hybrid Parameters 16–7
16.4 Transmission Parameters 16–9
16.5 Parameter Conversions 16–10
16.6 Interconnection of Two–Ports 16–11
Summary 16–16
Problems 16–16
CHAPTER 17∗
Diodes 17–1
17.1 Introduction 17–2
17.2 Modeling Techniques 17–4
17.3 Analysis Using the Diode Equation 17–9
17.4 Diode Rectifiers 17–13
17.5 Zener Diodes 17–17
APPENDIX
Complex Numbers 704
INDEX 711