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Fundamentals of Electric Circuits 6th edition [Kõva köide]

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  • Formaat: Hardback, 992 pages, kõrgus x laius x paksus: 269x213x39 mm, kaal: 1769 g, 2131 Illustrations
  • Ilmumisaeg: 16-Mar-2016
  • Kirjastus: McGraw-Hill Inc.,US
  • ISBN-10: 0078028221
  • ISBN-13: 9780078028229
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Fundamentals of Electric Circuits 6th editionSuurem pilt
  • Formaat: Hardback, 992 pages, kõrgus x laius x paksus: 269x213x39 mm, kaal: 1769 g, 2131 Illustrations
  • Ilmumisaeg: 16-Mar-2016
  • Kirjastus: McGraw-Hill Inc.,US
  • ISBN-10: 0078028221
  • ISBN-13: 9780078028229
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780078028229.html
Märksõnad:
Fundamentals of Electric Circuits continues in the spirit of its successful previous editions, with the objective of presenting circuit analysis in a manner that is clearer, more interesting, and easier to understand than other, more traditional texts. Students are introduced to the sound, six-step problem solving methodology in chapter one, and are consistently made to apply and practice these steps in practice problems and homework problems throughout the text. A balance of theory, worked & extended examples, practice problems, and real-world applications, combined with over 468 new or changed homework problems complete this edition. Robust media offerings, renders this text to be the most comprehensive and student-friendly approach to linear circuit analysis out there. This book retains the "Design a Problem" feature which helps students develop their design skills by having the student develop the question, as well as the solution. There are over 100 "Design a Problem" exercises integrated into problem sets in the book.

McGraw-Hill's Connect, is also available as an optional, add on item. Connect is the only integrated learning system that empowers students by continuously adapting to deliver precisely what they need, when they need it, how they need it, so that class time is more effective. Connect allows the professor to assign homework, quizzes, and tests easily and automatically grades and records the scores of the student's work. Problems are randomized to prevent sharing of answers an may also have a "multi-step solution" which helps move the students' learning along if they experience difficulty.
Preface xi
Acknowledgments xv
About the Authors xxi
Part 1 DC Circuits 2(364)
Chapter 1 Basic Concepts
3(26)
1.1 Introduction
4(1)
1.2 Systems of Units
5(1)
1.3 Charge and Current
6(3)
1.4 Voltage
9(1)
1.5 Power and Energy
10(4)
1.6 Circuit Elements
14(2)
1.7 Applications
16(3)
1.7.1 TV Picture Tube
1.7.2 Electricity Bills
1.8 Problem Solving
19(3)
1.9 Summary
22(1)
Review Questions
23(1)
Problems
24(2)
Comprehensive Problems
26(3)
Chapter 2 Basic Laws
29(50)
2.1 Introduction
30(1)
2.2 Ohm's Law
30(5)
2.3 Nodes, Branches, and Loops
35(2)
2.4 Kirchhoff's Laws
37(6)
2.5 Series Resistors and Voltage Division
43(1)
2.6 Parallel Resistors and Current Division
44(7)
2.7 Wye-Delta Transformations
51(6)
Delta to Wye Conversion
Wye to Delta Conversion
2.8 Applications
57(6)
2.8.1 Lighting Systems
2.8.2 Design of DC Meters
2.9 Summary
63(1)
Review Questions
64(1)
Problems
65(12)
Comprehensive Problems
77(2)
Chapter 3 Methods of Analysis
79(46)
3.1 Introduction
80(1)
3.2 Nodal Analysis
80(6)
3.3 Nodal Analysis with Voltage Sources
86(5)
3.4 Mesh Analysis
91(5)
3.5 Mesh Analysis with Current Sources
96(2)
3.6 Nodal and Mesh Analyses by Inspection
98(4)
3.7 Nodal Versus Mesh Analysis
102(1)
3.8 Circuit Analysis with PSpice
103(2)
3.9 Applications: DC Transistor Circuits
105(5)
3.10 Summary
110(1)
Review Questions
111(1)
Problems
112(12)
Comprehensive Problem
124(1)
Chapter 4 Circuit Theorems
125(48)
4.1 Introduction
126(1)
4.2 Linearity Property
126(2)
4.3 Superposition
128(5)
4.4 Source Transformation
133(4)
4.5 Thevenin's Theorem
137(6)
4.6 Norton's Theorem
143(4)
4.7 Derivations of Thevenin's and Norton's Theorems
147(1)
4.8 Maximum Power Transfer
148(2)
4.9 Verifying Circuit Theorems with PSpice
150(3)
4.10 Applications
153(5)
4.10.1 Source Modeling
4.10.2 Resistance Measurement
4.11 Summary
158(1)
Review Questions
159(1)
Problems
160(11)
Comprehensive Problems
171(2)
Chapter 5 Operational Amplifiers
173(40)
5.1 Introduction
174(1)
5.2 Operational Amplifiers
174(4)
5.3 Ideal Op Amp
178(1)
5.4 Inverting Amplifier
179(2)
5.5 Noninverting Amplifier
181(2)
5.6 Summing Amplifier
183(2)
5.7 Difference Amplifier
185(4)
5.8 Cascaded Op Amp Circuits
189(3)
5.9 Op Amp Circuit Analysis with PSpice
192(2)
5.10 Applications
194(3)
5.10.1 Digital-to-Analog Converter
5.10.2 Instrumentation Amplifiers
5.11 Summary
197(2)
Review Questions
199(1)
Problems
200(11)
Comprehensive Problems
211(2)
Chapter 6 Capacitors and Inductors
213(38)
6.1 Introduction
214(1)
6.2 Capacitors
214(6)
6.3 Series and Parallel Capacitors
220(4)
6.4 Inductors
224(4)
6.5 Series and Parallel Inductors
228(3)
6.6 Applications
231(7)
6.6.1 Integrator
6.6.2 Differentiator
6.6.3 Analog Computer
6.7 Summary
238(1)
Review Questions
239(1)
Problems
240(9)
Comprehensive Problems
249(2)
Chapter 7 First-Order Circuits
251(60)
7.1 Introduction
252(1)
7.2 The Source-Free RC Circuit
253(4)
7.3 The Source-Free RL Circuit
257(6)
7.4 Singularity Functions
263(8)
7.5 Step Response of an RC Circuit
271(7)
7.6 Step Response of an RL Circuit
278(4)
7.7 First-Order Op Amp Circuits
282(5)
7.8 Transient Analysis with PSpice
287(4)
7.9 Applications
291(6)
7.9.1 Delay Circuits
7.9.2 Photoflash Unit
7.9.3 Relay Circuits
7.9.4 Automobile Ignition Circuit
7.10 Summary
297(1)
Review Questions
298(1)
Problems
299(10)
Comprehensive Problems
309(2)
Chapter 8 Second-Order Circuits
311(55)
8.1 Introduction
312(1)
8.2 Finding Initial and Final Values
313(4)
8.3 The Source-Free Series RLC Circuit
317(7)
8.4 The Source-Free Parallel RLC Circuit
324(5)
8.5 Step Response of a Series RLC Circuit
329(5)
8.6 Step Response of a Parallel RLC Circuit
334(3)
8.7 General Second-Order Circuits
337(5)
8.8 Second-Order Op Amp Circuits
342(2)
8.9 PSpice Analysis of RLC Circuits
344(4)
8.10 Duality
348(3)
8.11 Applications
351(3)
8.11.1 Automobile Ignition System
8.11.2 Smoothing Circuits
8.12 Summary
354(1)
Review Questions
355(1)
Problems
356(9)
Comprehensive Problems
365(1)
Part 2 AC Circuits 366(306)
Chapter 9 Sinusoids and Phasors
367(44)
9.1 Introduction
368(1)
9.2 Sinusoids
369(5)
9.3 Phasors
374(9)
9.4 Phasor Relationships for Circuit Elements
383(2)
9.5 Impedance and Admittance
385(2)
9.6 Kirchhoff's Laws in the Frequency Domain
387(1)
9.7 Impedance Combinations
388(6)
9.8 Applications
394(6)
9.8.1 Phase-Shifters
9.8.2 AC Bridges
9.9 Summary
400(1)
Review Questions
401(1)
Problems
401(8)
Comprehensive Problems
409(2)
Chapter 10 Sinusoidal Steady-State Analysis
411(44)
10.1 Introduction
412(1)
10.2 Nodal Analysis
412(3)
10.3 Mesh Analysis
415(4)
10.4 Superposition Theorem
419(3)
10.5 Source Transformation
422(2)
10.6 Thevenin and Norton Equivalent Circuits
424(5)
10.7 Op Amp AC Circuits
429(2)
10.8 AC Analysis Using PSpice
431(4)
10.9 Applications
435(4)
10.9.1 Capacitance Multiplier
10.9.2 Oscillators
10.10 Summary
439(1)
Review Questions
439(2)
Problems
441(14)
Chapter 11 AC Power Analysis
455(46)
11.1 Introduction
456(1)
11.2 Instantaneous and Average Power
456(6)
11.3 Maximum Average Power Transfer
462(3)
11.4 Effective or RMS Value
465(3)
11.5 Apparent Power and Power Factor
468(3)
11.6 Complex Power
471(4)
11.7 Conservation of AC Power
475(4)
11.8 Power Factor Correction
479(2)
11.9 Applications
481(5)
11.9.1 Power Measurement
11.9.2 Electricity Consumption Cost
11.10 Summary
486(2)
Review Questions
488(1)
Problems
488(10)
Comprehensive Problems
498(3)
Chapter 12 Three-Phase Circuits
501(52)
12.1 Introduction
502(1)
12.2 Balanced Three-Phase Voltages
503(4)
12.3 Balanced Wye-Wye Connection
507(3)
12.4 Balanced Wye-Delta Connection
510(2)
12.5 Balanced Delta-Delta Connection
512(2)
12.6 Balanced Delta-Wye Connection
514(3)
12.7 Power in a Balanced System
517(6)
12.8 Unbalanced Three-Phase Systems
523(4)
12.9 PSpice for Three-Phase Circuits
527(5)
12.10 Applications
532(9)
12.10.1 Three-Phase Power Measurement
12.10.2 Residential Wiring
12.11 Summary
541(1)
Review Questions
541(1)
Problems
542(9)
Comprehensive Problems
551(2)
Chapter 13 Magnetically Coupled Circuits
553(58)
13.1 Introduction
554(1)
13.2 Mutual Inductance
555(7)
13.3 Energy in a Coupled Circuit
562(3)
13.4 Linear Transformers
565(6)
13.5 Ideal Transformers
571(8)
13.6 Ideal Autotransformers
579(3)
13.7 Three-Phase Transformers
582(2)
13.8 PSpice Analysis of Magnetically Coupled Circuits
584(5)
13.9 Applications
589(6)
13.9.1 Transformer as an Isolation Device
13.9.2 Transformer as a Matching Device
13.9.3 Power Distribution
13.10 Summary
595(1)
Review Questions
596(1)
Problems
597(12)
Comprehensive Problems
609(2)
Chapter 14 Frequency Response
611(61)
14.1 Introduction
612(1)
14.2 Transfer Function
612(3)
14.3 The Decibel Scale
615(2)
14.4 Bode Plots
617(10)
14.5 Series Resonance
627(5)
14.6 Parallel Resonance
632(3)
14.7 Passive Filters
635(5)
14.7.1 Low-Pass Filter
14.7.2 High-Pass Filter
14.7.3 Band-Pass Filter
14.7.4 Band-Stop Filter
14.8 Active Filters
640(6)
14.8.1 First-Order Low-Pass Filter
14.8.2 First-Order High-Pass Filter
14.8.3 Band-Pass Filter
14.8.4 Band-Reject (or Notch) Filter
14.9 Scaling
646(4)
14.9.1 Magnitude Scaling
14.9.2 Frequency Scaling
14.9.3 Magnitude and Frequency Scaling
14.10 Frequency Response Using PSpice
650(3)
14.11 Computation Using MATLAB
653(2)
14.12 Applications
655(6)
14.12.1 Radio Receiver
14.12.2 Touch-Tone Telephone
14.12.3 Crossover Network
14.13 Summary
661(1)
Review Questions
662(1)
Problems
663(8)
Comprehensive Problems
671(1)
Part 3 Advanced Circuit Analysis 672
Chapter 15 Introduction to the Laplace Transform
673(40)
15.1 Introduction
674(1)
15.2 Definition of the Laplace Transform
675(2)
15.3 Properties of the Laplace Transform
677(11)
15.4 The Inverse Laplace Transform
688(7)
15.4.1 Simple Poles
15.4.2 Repeated Poles
15.4.3 Complex Poles
15.5 The Convolution Integral
695(8)
15.6 Application to Integrodifferential Equations
703(3)
15.7 Summary
706(1)
Review Questions
706(1)
Problems
707(6)
Chapter 16 Applications of the Laplace Transform
713(44)
16.1 Introduction
714(1)
16.2 Circuit Element Models
715(5)
16.3 Circuit Analysis
720(4)
16.4 Transfer Functions
724(4)
16.5 State Variables
728(7)
16.6 Applications
735(8)
16.6.1 Network Stability
16.6.2 Network Synthesis
16.7 Summary
743(1)
Review Questions
744(1)
Problems
745(11)
Comprehensive Problems
756(1)
Chapter 17 The Fourier Series
757(54)
17.1 Introduction
758(1)
17.2 Trigonometric Fourier Series
759(7)
17.3 Symmetry Considerations
766(10)
17.3.1 Even Symmetry
17.3.2 Odd Symmetry
17.3.3 Half-Wave Symmetry
17.4 Circuit Applications
776(4)
17.5 Average Power and RMS Values
780(3)
17.6 Exponential Fourier Series
783(6)
17.7 Fourier Analysis with PSpice
789(6)
17.7.1 Discrete Fourier Transform
17.7.2 Fast Fourier Transform
17.8 Applications
795(3)
17.8.1 Spectrum Analyzers
17.8.2 Filters
17.9 Summary
798(2)
Review Questions
800(1)
Problems
800(9)
Comprehensive Problems
809(2)
Chapter 18 Fourier Transform
811(40)
18.1 Introduction
812(1)
18.2 Definition of the Fourier Transform
812(6)
18.3 Properties of the Fourier Transform
818(13)
18.4 Circuit Applications
831(3)
18.5 Parseval's Theorem
834(3)
18.6 Comparing the Fourier and Laplace Transforms
837(1)
18.7 Applications
838(3)
18.7.1 Amplitude Modulation
18.7.2 Sampling
18.8 Summary
841(1)
Review Questions
842(1)
Problems
843(6)
Comprehensive Problems
849(2)
Chapter 19 Two-Port Networks
851
19.1 Introduction
852(1)
19.2 Impedance Parameters
853(4)
19.3 Admittance Parameters
857(3)
19.4 Hybrid Parameters
860(5)
19.5 Transmission Parameters
865(5)
19.6 Relationships Between Parameters
870(3)
19.7 Interconnection of Networks
873(6)
19.8 Computing Two-Port Parameters Using PSpice
879(3)
19.9 Applications
882(9)
19.9.1 Transistor Circuits
19.9.2 Ladder Network Synthesis
19.10 Summary
891(1)
Review Questions
892(1)
Problems
892(11)
Comprehensive Problem
903
Appendix A Simultaneous Equations and Matrix Inversion A
Appendix B Complex Numbers A-9
Appendix C Mathematical Formulas A-16
Appendix D Answers to Odd-Numbered Problems A-21
Selected Bibliography B-1
Index I-1
Dr. Charles K. Alexander is a Professor of Electrical and Computer Engineering at Cleveland State University, Cleveland, Ohio. He is also the Director of the Center for Research in Electronics and Aerospace Technology (CREATE). From 2002 until 2006 he was Dean of the Fenn College of Engineering. He has held the position of Dean of Engineering at Cleveland State University, California State University, Northridge, and Temple University (acting Dean for six years). He has held the position of Department Chair at Temple University and Tennessee Technological University as well as the position of Stocker Visiting Professor (an Endowed Chair) at Ohio University. He has held faculty status at all of the aforementioned Universities.





Matthew N. O. Sadiku received his PhD from Tennessee Technological University, Cookeville. From 1984 to 1988, he was Assistant Professor at Florida Atlantic University, where he did graduate work in Computer Science. From 1988 to 2000, he was at Temple University, Philadelphia, Pennsylvania, where he became a full Professor. From 2000 to 2002, he was with Lucent/Avaya, Holmdel, New Jersey, as a System Engineer and with Boeing Satellite Systems as a Senior Scientist. He is currently a professor at Prairie View A&M University.