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Electrical Engineering: Principles & Applications Plus Mastering Engineering with Pearson eText -- Access Card Package 7th edition [Multiple-component retail product]

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  • Formaat: Multiple-component retail product, 875 pages, kõrgus x laius x paksus: 261x214x36 mm, Contains 1 BR-ROM and 1 Hardback
  • Ilmumisaeg: 19-Jan-2017
  • Kirjastus: Pearson Education (US)
  • ISBN-10: 0134712870
  • ISBN-13: 9780134712871
Teised raamatud teemal:
Electrical Engineering: Principles & Applications Plus Mastering Engineering with Pearson eText -- Access Card Package 7th editionSuurem pilt
  • Formaat: Multiple-component retail product, 875 pages, kõrgus x laius x paksus: 261x214x36 mm, Contains 1 BR-ROM and 1 Hardback
  • Ilmumisaeg: 19-Jan-2017
  • Kirjastus: Pearson Education (US)
  • ISBN-10: 0134712870
  • ISBN-13: 9780134712871
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780134712871.html
For courses in Electrical Engineering.









This  package includes MasteringEngineering 













Accessible and applicable learning in electrical engineering for introductory and non-major courses

The #1 title in its market, Electrical Engineering: Principles and Applications helps students learn electrical-engineering fundamentals with minimal frustration. Its goals are to present basic concepts in a general setting, to show students how the principles of electrical engineering apply to specific problems in their own fields, and to enhance the overall learning process. This book covers circuit analysis, digital systems, electronics, and electromechanics at a level appropriate for either electrical-engineering students in an introductory course or non-majors in a survey course.  A wide variety of pedagogical features stimulate student interest and engender awareness of the materials relevance to their chosen profession. The only essential prerequisites are basic physics and single-variable calculus. The 7th Edition features technology and content updates throughout the text.



                                                                                                                                                                      

Personalize learning with MasteringEngineering.

MasteringEngineeringis an online homework, tutorial, and assessment program designed to work with this text to engage students and improve results. Interactive, self-paced tutorials provide individualized coaching to help students stay on track. With a wide range of activities available, students can actively learn, understand, and retain even the most difficult concepts. The text and MasteringEngineering work together to guide students through engineering concepts with a multi-step approach to problems.
Practical Applications of Electrical Engineering Principles vi
Preface xi
1 Introduction 1(45)
1.1 Overview of Electrical Engineering
2(4)
1.2 Circuits, Currents, and Voltages
6(7)
1.3 Power and Energy
13(3)
1.4 Kirchhoff's Current Law
16(4)
1.5 Kirchhoff's Voltage Law
20(3)
1.6 Introduction to Circuit Elements
23(8)
1.7 Introduction to Circuits
31(4)
Summary
35(1)
Problems
36(10)
2 Resistive Circuits 46(81)
2.1 Resistances in Series and Parallel
47(4)
2.2 Network Analysis by Using Series and Parallel Equivalents
51(4)
2.3 Voltage-Divider and Current-Divider Circuits
55(5)
2.4 Node-Voltage Analysis
60(20)
2.5 Mesh-Current Analysis
80(10)
2.6 Thevenin and Norton Equivalent Circuits
90(13)
2.7 Superposition Principle
103(4)
2.8 Wheatstone Bridge
107(3)
Summary
110(1)
Problems
111(16)
3 Inductance and Capacitance 127(40)
3.1 Capacitance
128(7)
3.2 Capacitances in Series and Parallel
135(3)
3.3 Physical Characteristics of Capacitors
138(4)
3.4 Inductance
142(5)
3.5 Inductances in Series and Parallel
147(2)
3.6 Practical Inductors
149(3)
3.7 Mutual Inductance
152(1)
3.8 Symbolic Integration and Differentiation Using MATLAB
153(4)
Summary
157(1)
Problems
158(9)
4 Transients 167(48)
4.1 First-Order RC Circuits
168(5)
4.2 DC Steady State
173(2)
4.3 RL Circuits
175(5)
4.4 RC and RL Circuits with General Sources
180(6)
4.5 Second-Order Circuits
186(13)
4.6 Transient Analysis Using the MATLAB Symbolic Toolbox
199(6)
Summary
205(1)
Problems
205(10)
5 Steady-State Sinusoidal Analysis 215(72)
5.1 Sinusoidal Currents and Voltages
216(6)
5.2 Phasors
222(6)
5.3 Complex Impedances
228(5)
5.4 Circuit Analysis with Phasors and Complex Impedances
233(6)
5.5 Power in AC Circuits
239(13)
5.6 Thevenin and Norton Equivalent Circuits
252(6)
5.7 Balanced Three-Phase Circuits
258(12)
5.8 AC Analysis Using MATLAB
270(4)
Summary
274(1)
Problems
275(12)
6 Frequency Response, Bode Plots, and Resonance 287(68)
6.1 Fourier Analysis, Filters, and Transfer Functions
288(8)
6.2 First-Order Lowpass Filters
296(5)
6.3 Decibels, the Cascade Connection, and Logarithmic Frequency Scales
301(5)
6.4 Bode Plots
306(3)
6.5 First-Order Highpass Filters
309(4)
6.6 Series Resonance
313(5)
6.7 Parallel Resonance
318(3)
6.8 Ideal and Second-Order Filters
321(7)
6.9 Bode Plots with MATLAB
328(3)
6.10 Digital Signal Processing
331(9)
Summary
340(1)
Problems
341(14)
7 Logic Circuits 355(53)
7.1 Basic Logic Circuit Concepts
356(3)
7.2 Representation of Numerical Data in Binary Form
359(8)
7.3 Combinatorial Logic Circuits
367(8)
7.4 Synthesis of Logic Circuits
375(6)
7.5 Minimization of Logic Circuits
381(5)
7.6 Sequential Logic Circuits
386(11)
Summary
397(1)
Problems
398(10)
8 Computers, Microcontrollers and Computer-Based Instrumentation Systems 408(51)
8.1 Computer Organization
409(3)
8.2 Memory Types
412(2)
8.3 Digital Process Control
414(3)
8.4 Programming Model for the HCS12/9S12 Family
417(4)
8.5 The Instruction Set and Addressing Modes for the CPU12
421(9)
8.6 Assembly-Language Programming
430(5)
8.7 Measurement Concepts and Sensors
435(5)
8.8 Signal Conditioning
440(7)
8.9 Analog-to-Digital Conversion
447(3)
Summary
450(2)
Problems
452(7)
9 Diodes 459(44)
9.1 Basic Diode Concepts
460(3)
9.2 Load-Line Analysis of Diode Circuits
463(3)
9.3 Zener-Diode Voltage-Regulator Circuits
466(4)
9.4 Ideal-Diode Model
470(2)
9.5 Piecewise-Linear Diode Models
472(3)
9.6 Rectifier Circuits
475(5)
9.7 Wave-Shaping Circuits
480(5)
9.8 Linear Small-Signal Equivalent Circuits
485(6)
Summary
491(1)
Problems
491(12)
10 Amplifiers: Specifications and External Characteristics 503(54)
10.1 Basic Amplifier Concepts
504(5)
10.2 Cascaded Amplifiers
509(3)
10.3 Power Supplies and Efficiency
512(3)
10.4 Additional Amplifier Models
515(3)
10.5 Importance of Amplifier Impedances in Various Applications
518(3)
10.6 Ideal Amplifiers
521(1)
10.7 Frequency Response
522(5)
10.8 Linear Waveform Distortion
527(4)
10.9 Pulse Response
531(3)
10.10 Transfer Characteristic and Nonlinear Distortion
534(2)
10.11 Differential Amplifiers
536(4)
10.12 Offset Voltage, Bias Current, and Offset Current
540(5)
Summary
545(1)
Problems
546(11)
11 Field-Effect Transistors 557(42)
11.1 NMOS and PMOS Transistors
558(8)
11.2 Load-Line Analysis of a Simple NMOS Amplifier
566(2)
11.3 Bias Circuits
568(4)
11.4 Small-Signal Equivalent Circuits
572(4)
11.5 Common-Source Amplifiers
576(4)
11.6 Source Followers
580(5)
11.7 CMOS Logic Gates
585(5)
Summary
590(1)
Problems
591(8)
12 Bipolar Junction Transistors 599(47)
12.1 Current and Voltage Relationships
600(3)
12.2 Common-Emitter Characteristics
603(1)
12.3 Load-Line Analysis of a Common-Emitter Amplifier
604(6)
12.4 pnp Bipolar Junction Transistors
610(2)
12.5 Large-Signal DC Circuit Models
612(3)
12.6 Large-Signal DC Analysis of BJT Circuits
615(7)
12.7 Small-Signal Equivalent Circuits
622(3)
12.8 Common-Emitter Amplifiers
625(5)
12.9 Emitter Followers
630(6)
Summary
636(1)
Problems
637(9)
13 Operational Amplifiers 646(52)
13.1 Ideal Operational Amplifiers
647(1)
13.2 Inverting Amplifiers
648(7)
13.3 Noninverting Amplifiers
655(3)
13.4 Design of Simple Amplifiers
658(5)
13.5 Op-Amp Imperfections in the Linear Range of Operation
663(4)
13.6 Nonlinear Limitations
667(5)
13.7 DC Imperfections
672(4)
13.8 Differential and Instrumentation Amplifiers
676(2)
13.9 Integrators and Differentiators
678(3)
13.10 Active Filters
681(4)
Summary
685(1)
Problems
686(12)
14 Magnetic Circuits and Transformers 698(46)
14.1 Magnetic Fields
699(9)
14.2 Magnetic Circuits
708(5)
14.3 Inductance and Mutual Inductance
713(4)
14.4 Magnetic Materials
717(3)
14.5 Ideal Transformers
720(8)
14.6 Real Transformers
728(5)
Summary
733(1)
Problems
733(11)
15 DC Machines 744(50)
15.1 Overview of Motors
745(9)
15.2 Principles of DC Machines
754(5)
15.3 Rotating DC Machines
759(6)
15.4 Shunt-Connected and Separately Excited DC Motors
765(5)
15.5 Series-Connected DC Motors
770(4)
15.6 Speed Control of DC Motors
774(4)
15.7 DC Generators
778(5)
Summary
783(1)
Problems
784(10)
16 AC Machines 794(42)
16.1 Three-Phase Induction Motors
795(8)
16.2 Equivalent-Circuit and Performance Calculations for Induction Motors
803(9)
16.3 Synchronous Machines
812(12)
16.4 Single-Phase Motors
824(3)
16.5 Stepper Motors and Brushless DC Motors
827(2)
Summary
829(1)
Problems
830(6)
Appendices
A Complex Numbers
836(9)
Summary
843(1)
Problems
843(2)
B Nominal Values and the Color Code for Resistors
845(2)
C The Fundamentals of Engineering Examination
847(1)
D Answers for the Practice Tests
848(9)
E On-Line Student Resources
857(1)
Index 858
Allan R. Hambley received his B.S. degree from Michigan Technological University, his M.S. degree from Illinois Institute of Technology, and his Ph.D. from Worcester Polytechnic Institute. He has worked in industry for Hazeltine Research Inc., Warwick Electronics, and Harris Government Systems. He is currently Professor of Electrical Engineering at Michigan Tech. The Michigan Tech chapter of Eta Kappa Nu named him the Outstanding Electrical Engineering Teacher of the Year in 1995. He has won the National Technological University Outstanding Instructor Award six times for his courses in communication systems. The American Society for Engineering Education presented him with the 1998 Meriam Wiley Distinguished Author Award for the first edition of his book, Electronics. His hobbies include fishing, boating in remote areas of Lake Superior, and gardening.