Introduction To Electrical Engineering
Introduction toElectrical EngineeringMulukutla S. SarmaOXFORD UNIVERSITY PRESS
INTRODUCTION TOELECTRICAL ENGINEERING
the oxford series in electrical and computer engineeringAdel S. Sedra, Series EditorAllen and Holberg, CMOS Analog Circuit DesignBobrow, Elementary Linear Circuit Analysis, 2nd EditionBobrow, Fundamentals of Electrical Engineering, 2nd EditionBurns and Roberts, Introduction to Mixed Signal IC Test and MeasurementCampbell, The Science and Engineering of Microelectronic FabricationChen, Analog & Digital Control System DesignChen, Digital Signal ProcessingChen, Linear System Theory and Design, 3rd EditionChen, System and Signal Analysis, 2nd EditionDeCarlo and Lin, Linear Circuit Analysis, 2nd EditionDimitrijev, Understanding Semiconductor DevicesFortney, Principles of Electronics: Analog & DigitalFranco, Electric Circuits FundamentalsGranzow, Digital Transmission LinesGuru and Hiziroğlu, Electric Machinery and Transformers, 3rd EditionHoole and Hoole, A Modern Short Course in Engineering ElectromagneticsJones, Introduction to Optical Fiber Communication SystemsKrein, Elements of Power ElectronicsKuo, Digital Control Systems, 3rd EditionLathi, Modern Digital and Analog Communications Systems, 3rd EditionMartin, Digital Integrated Circuit DesignMcGillem and Cooper, Continuous and Discrete Signal and System Analysis, 3rd EditionMiner, Lines and Electromagnetic Fields for EngineersRoberts and Sedra, SPICE, 2nd EditionRoulston, An Introduction to the Physics of Semiconductor DevicesSadiku, Elements of Electromagnetics, 3rd EditionSantina, Stubberud, and Hostetter, Digital Control System Design, 2nd EditionSarma, Introduction to Electrical EngineeringSchaumann and Van Valkenburg, Design of Analog FiltersSchwarz, Electromagnetics for EngineersSchwarz and Oldham, Electrical Engineering: An Introduction, 2nd EditionSedra and Smith, Microelectronic Circuits, 4th EditionStefani, Savant, Shahian, and Hostetter, Design of Feedback Control Systems, 3rd EditionVan Valkenburg, Analog Filter DesignWarner and Grung, Semiconductor Device ElectronicsWolovich, Automatic Control SystemsYariv, Optical Electronics in Modern Communications, 5th Edition
INTRODUCTION TOELECTRICAL ENGINEERINGMulukutla S. SarmaNortheastern UniversityNew YorkOxfordOXFORD UNIVERSITY PRESS2001
Oxford University PressOxford New YorkAthens Auckland Bangkok Bogotá Buenos Aires CalcuttaCape Town Chennai Dar es Salaam Delhi Florence Hong Kong IstanbulKarachi Kuala Lumpur Madrid Melbourne Mexico City MumbaiNairobi Paris São Paulo Shanghai Singapore Taipei Tokyo Toronto Warsawand associated companies inBerlin IbadanCopyright 2001 by Oxford University Press, Inc.Published by Oxford University Press, Inc.,198 Madison Avenue, New York, New York, 10016http://www.oup-usa.orgOxford is a registered trademark of Oxford University PressAll rights reserved. No part of this publication may be reproduced,stored in a retrieval system, or transmitted, in any form or by any means,electronic, mechanical, photocopying, recording, or otherwise,without the prior permission of Oxford University Press.Library of Congress Cataloging-in-Publication DataSarma, Mulukutla S., 1938–Introduction to electrical engineering / Mulukutla S. Sarmap. cm. — (The Oxford series in electrical and computer engineering)ISBN 0-19-513604-7 (cloth)1. Electrical engineering. I. Title. II. Series.TK146.S18 2001621.3—dc2100-020033Acknowledgments—Table 1.2.2 is adapted from Principles of Electrical Engineering (McGraw-Hill Series in Electrical Engineering), by Peyton Z.Peebles Jr. and Tayeb A. Giuma, reprinted with the permission of McGraw-Hill, 1991; figures 2.6.1, 2.6.2 are adapted from Getting Started withMATLAB 5: Quick Introduction, by Rudra Pratap, reprinted with the permission of Oxford University Press, 1998; figures 4.1.2–4.1.5, 4.2.1–4.2.3,4.3.1–4.3.2, are adapted from Electric Machines: Steady-State Theory and Dynamic Performance, Second Edition, by Mulukutla S. Sarma, reprintedwith the permission of Brooks/Cole Publishing, 1994; figure 4.6.1 is adapted from Medical Instrumentation Application and Design, by John G. Webster,reprinted with the permission of John Wiley & Sons, Inc., 1978; table 4.6.1 is adapted from “Electrical Safety in Industrial Plants,” IEEE Spectrum, byRalph Lee, reprinted with the permission of IEEE, 1971; figure P5.3.1 is reprinted with the permission of Fairchild Semiconductor Corporation; figures5.6.1, 6.6.1, 9.5.1 are adapted from Electrical Engineering: Principles and Applications, by Allen R. Hambley, reprinted with the permission of PrenticeHall, 1997; figure 10.5.1 is adapted from Power System Analysis and Design, Second Edition, by Duncan J. Glover and Mulukutla S. Sarma, reprintedwith the permission of Brooks/Cole Publishing, 1994; figures 11.1.2, 13.2.10 are adapted from Introduction to Electrical Engineering, Second Edition,by Clayton Paul, Syed A. Nasar, and Louis Unnewehr, reprinted with the permission of McGraw-Hill, 1992; figures E12.2.1(a,b), 12.2.2–12.2.5, 12.2.9–12.2.10, 12.3.1–12.3.3, 12.4.1, E12.4.1, P12.1.2, P12.4.3, P12.4.8, P12.4.12, 13.1.1–13.1.8, 13.2.1–13.2.9, 13.2.11–13.2.16, 13.3.1–13.3.3, E13.3.2,13.3.4, E13.3.3, 13.3.5–13.3.6 are adapted from Electric Machines: Steady-State Theory and Dynamic Performance, Second Edition, by Mulukutla S.Sarma, reprinted with the permission of Brooks/Cole Publishing, 1994; figure 13.3.12 is adapted from Communication Systems Engineering, by John G.Proakis and Masoud Salehi, reprinted with the permission of Prentice Hall, 1994; figures 13.4.1–13.4.7, E13.4.1(b), 13.4.8–13.4.12, E13.4.3, 13.4.13,13.6.1 are adapted from Electric Machines: Steady-State Theory and Dynamic Performance, Second Edition, by Mulukutla S. Sarma Brooks/ColePublishing, 1994; figures 14.2.8, 14.2.9 are adapted from Electrical Engineering: Concepts and Applications, Second Edition, by A. Bruce Carlson andDavid Gisser, reprinted with the permission of Prentice Hall, 1990; figure 15.0.1 is adapted from Communication Systems, Third Edition, by A. BruceCarlson, reprinted with the permission of McGraw-Hill, 1986; figures 15.2.15, 15.2.31, 15.3.11 are adapted from Communication Systems Engineering,by John G. Proakis and Masoud Salehi, reprinted with the permission of Prentice Hall, 1994; figures 15.2.19, 15.2.27, 15.2.28, 15.2.30, 15.3.3, 15.3.4,15.3.9, 15.3.10, 15.3.20 are adapted from Principles of Electrical Engineering (McGraw-Hill Series in Electrical Engineering), by Peyton Z. PeeblesJr. and Tayeb A. Giuma, reprinted with the permission of McGraw-Hill, 1991; figures 16.1.1–16.1.3 are adapted from Electric Machines: Steady-StateTheory and Dynamic Performance, Second Edition, by Mulukutla S. Sarma, reprinted with the permission of Brooks/Cole Publishing, 1994; table16.1.3 is adapted from Electric Machines: Steady-State Theory and Dynamic Performance, Second Edition, by Mulukutla S. Sarma, reprinted with thepermission of Brooks/Cole Publishing, 1994; table 16.1.4 is adapted from Handbook of Electric Machines, by S. A. Nasar, reprinted with the permissionof McGraw-Hill, 1987; and figures 16.1.4–13.1.9, E16.1.1, 16.1.10–16.1.25 are adapted from Electric Machines: Steady-State Theory and DynamicPerformance, Second Edition, by Mulukutla S. Sarma, reprinted with the permission of Brooks/Cole Publishing, 1994.Printing (last digit): 10 9 8 7 6 5 4 3 2 1Printed in the United States of Americaon acid-free paper
To my grandchildrenPuja SreeSruthi LekhaPallavi Devi***and those to come
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CONTENTSList of Case Studies and Computer-Aided AnalysisPreface xvOverview xxiPART 11ELECTRIC CIRCUITSCircuit Concepts1.11.21.31.41.51.61.723Electrical Quantities 4Lumped-Circuit Elements 16Kirchhoff’s Laws 39Meters and Measurements 47Analogy between Electrical and Other Nonelectric Physical SystemsLearning Objectives 52Practical Application: A Case Study—Resistance Strain Gauge 52Problems 53Circuit Analysis Techniques2.12.22.32.42.52.62.72.83xiii66Thévenin and Norton Equivalent Circuits 66Node-Voltage and Mesh-Current Analyses 71Superposition and Linearity 81Wye–Delta Transformation 83Computer-Aided Circuit Analysis: SPICE 85Computer-Aided Circuit Analysis: MATLAB 88Learning Objectives 92Practical Application: A Case Study—Jump Starting a CarProblems 94Time-Dependent Circuit Analysis3.13.23.33.45092102Sinusoidal Steady-State Phasor AnalysisTransients in Circuits 125Laplace Transform 142Frequency Response 154103vii
viiiCONTENTS3.53.63.73.84Three-Phase Circuits and Residential Wiring4.14.24.34.44.54.6PART 25Three-Phase Source Voltages and Phase Sequence 198Balanced Three-Phase Loads 202Measurement of Power 208Residential Wiring and Safety Considerations 212Learning Objectives 215Practical Application: A Case Study—Physiological Effects of Current andElectrical Safety 216Problems 218Analog Building Blocks and Operational Amplifiers268Digital Building Blocks 271Digital System Components 295Computer Systems 316Computer Networks 320Learning Objectives 325Practical Application: A Case Study—Microcomputer-ControlledBreadmaking Machine 325Problems 326Semiconductor Devices7.17.27.3223The Amplifier Block 224Ideal Operational Amplifier 229Practical Properties of Operational Amplifiers 235Applications of Operational Amplifiers 244Learning Objectives 256Practical Application: A Case Study—Automotive Power-Assisted SteeringSystem 257Problems 258Digital Building Blocks and Computer Systems6.16.26.36.46.56.67198ELECTRONIC ANALOG AND DIGITAL SYSTEMS5.15.25.35.45.55.66Computer-Aided Circuit Simulation for Transient Analysis, AC Analysis, andFrequency Response Using PSpice and PROBE 168Use of MATLAB in Computer-Aided Circuit Simulation 173Learning Objectives 177Practical Application: A Case Study—Automotive Ignition System 178Problems 179339Semiconductors 339Diodes 340Bipolar Junction Transistors358
ixCONTENTS7.47.57.67.78Transistor Amplifiers8.18.28.38.48.58.68.79PART 3393422Transistor Switches 423DTL and TTL Logic Circuits 427CMOS and Other Logic Families 431Learning Objectives 437Practical Application: A Case Study—Cardiac Pacemaker, a BiomedicalEngineering Application 438Problems 439ENERGY SYSTEMSAC Power Systems10.110.210.310.410.511380Biasing the BJT 394Biasing the FET 395BJT Amplifiers 399FET Amplifiers 405Frequency Response of Amplifiers 409Learning Objectives 414Practical Application: A Case Study—Mechatronics: Electronics Integratedwith Mechanical Systems 414Problems 415Digital Circuits9.19.29.39.49.510Field-Effect Transistors 367Integrated Circuits 378Learning Objectives 379Practical Application: A Case Study—Electronic Photo FlashProblems 380451Introduction to Power Systems 452Single- and Three-Phase Systems 455Power Transmission and Distribution 460Learning Objectives 466Practical Application: A Case Study—The Great Blackout of 1965Problems 468Magnetic Circuits and Transformers11.111.211.311.411.511.6471Magnetic Materials 472Magnetic Circuits 475Transformer Equivalent Circuits 479Transformer Performance 486Three-Phase Transformers 490Autotransformers 492466
412.512.612.713PART 4553Elementary Concepts of Rotating Machines 553Induction Machines 563Synchronous Machines 582Direct-Current Machines 594Learning Objectives 610Practical Application: A Case Study—Wind-Energy-ConversionSystems 610Problems 612INFORMATION SYSTEMSSignal Processing14.114.214.314.414.515505Basic Principles of Electromechanical Energy Conversion 505EMF Produced by Windings 514Rotating Magnetic Fields 522Forces and Torques in Magnetic-Field Systems 526Basic Aspects of Electromechanical Energy Converters 539Learning Objectives 540Practical Application: A Case Study—Sensors or Transducers 541Problems 542Rotating Machines13.113.213.313.413.513.614Learning Objectives 494Practical Application: A Case Study—Magnetic Bearings for SpaceTechnology 494Problems 495625Signals and Spectral Analysis 626Modulation, Sampling, and Multiplexing 640Interference and Noise 649Learning Objectives 658Practical Application: A Case Study—Antinoise Systems, NoiseCancellation 658Problems 659Communication Systems15.115.215.315.415.5666Waves, Transmission Lines, Waveguides, and Antenna Fundamentals 670Analog Communication Systems 685Digital Communication Systems 710Learning Objectives 730Practical Application: A Case Study—Global Positioning Systems 731Problems 732
CONTENTSPART 516CONTROL SYSTEMSBasic Control Systems16.116.216.316.416.5747Power Semiconductor-Controlled Drives 748Feedback Control Systems 779Digital Control Systems 805Learning Objectives 814Practical Application: A Case Study—Digital Process ControlProblems 816815Appendix A: References 831Appendix B: Brief Review of Fundamentals of Engineering(FE) Examination 833Appendix C: Technical Terms, Units, Constants, and ConversionFactors for the SI System 835Appendix D: Mathematical Relations 838Appendix E: Solution of Simultaneous Equations 843Appendix F: Complex Numbers 846Appendix G: Fourier Series 847Appendix H: Laplace Transforms 851Index 855xi
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LIST OF CASE STUDIES ANDCOMPUTER-AIDED ANALYSISCase 14.515.516.5Practical Application: A Case Study—Resistance Strain Gauge 52Practical Application: A Case Study—Jump Starting a Car 92Practical Application: A Case Study—Automotive Ignition System 178Practical Application: A Case Study—Physiological Effects of Current and Electrical Safety216Practical Application: A Case Study—Automotive Power-Assisted Steering System 257Practical Application: A Case Study—Microcomputer-ControlledBreadmaking Machine 325Practical Application: A Case Study—Electronic Photo Flash 380Practical Application: A Case Study—Mechatronics: Electronics Integrated with MechanicalSystems 414Practical Application: A Case Study—Cardiac Pacemaker, a Biomedical EngineeringApplication 438Practical Application: A Case Study—The Great Blackout of 1965 466Practical Application: A Case Study—Magnetic Bearings for Space Technology 494Practical Application: A Case Study—Sensors or Transducers 541Practical Application: A Case Study—Wind-Energy-Conversion Systems 610Practical Application: A Case Study—Antinoise Systems, Noise Cancellation 658Practical Application: A Case Study—Global Positioning Systems 731Practical Application: A Case Study—Digital Process Control 815Computer-Aided Analysis2.52.63.53.6Computer-Aided Circuit Analysis: SPICE 85Computer-Aided Circuit Analysis: MATLAB 88Computer-Aided Circuit Simulation for Transient Analysis, AC Analysis, and FrequencyResponse Using PSpice and PROBE 168Use of MATLAB in Computer-Aided Circuit Simulation 173xiii
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PREFACEI.OBJECTIVESThe purpose of this text is to present a problem-oriented introductory survey text for the extraordinarily interesting electrical engineering discipline by arousing student enthusiasm whileaddressing the underlying concepts and methods behind various applications ranging from consumer gadgets and biomedical electronics to sophisticated instrumentation systems, computers,and multifarious electric machinery. The focus is on acquainting students majoring in all branchesof engineering and science, especially in courses for nonelectrical engineering majors, with thenature of the subject and the potentialities of its techniques, while emphasizing the principles.Since principles and concepts are most effectively taught by means of a problem-oriented course,judicially selected topics are treated in sufficient depth so as to permit the assignment of adequatelychallenging problems, which tend to implant the relevant principles in students’ minds.In addition to an academic-year (two semesters or three quarters) introductory coursetraditionally offered to non-EE majors, the text is also suitable for a sophomore survey coursegiven nowadays to electrical engineering majors in a number of universities. At a more rapid paceor through selectivity of topics, the introductory course could be offered in one semester to eitherelectrical and computer engineering (ECE) or non-EE undergraduate majors. Although this bookis written primarily for non-EE students, it is hoped that it will be of value to undergraduate ECEstudents (particularly for those who wish to take the Fundamentals of Engineering examination,which is a prerequisite for becoming licensed as a Professional Engineer), to graduate ECEstudents for their review in preparing for qualifying examinations, to meet the continuingeducation needs of various professionals, and to serve as a reference text even after graduation.II.MOTIVATIONThis text is but a modest attempt to provide an exciting survey of topics inherent to the electricaland computer engineering discipline. Modern technology demands a team approach in whichelectrical engineers and nonelectrical engineers have to work together sharing a common technicalvocabulary. Nonelectrical engineers must be introduced to the language of electrical engineers,just as the electrical engineers have to be sensitized to the relevance of nonelectrical topics.The dilemma of whether electrical engineering and computer engineering should be separatecourses of study, leading to distinctive degrees, seems to be happily resolving itself in the directionof togetherness. After all, computers are not only pervasive tools for engineers but also theirproduct; hence there is a pressing need to weave together the fundamentals of both the electricaland the computer engineering areas into the new curricula.An almost total lack of contact between freshmen and sophomore students and the Departmentof Electrical and Computer Engineering, as well as little or no exposure to electrical and computerxv
xviPREFACEengineering, seems to drive even the academically gifted students away from the program. Aninitial spark that may have motivated them to pursue electrical and computer engineering has tobe nurtured in the early stages of their university education, thereby providing an inspiration tocontinue.This text is based on almost 40 years of experience teaching a wide variety of courses toelectrical as well as non-EE majors and, more particularly, on the need to answer many of thequestions raised by so many of my students. I have always enjoyed engineering (teaching, research,and consultation); I earnestly hope that the readers will have as much fun and excitement in usingthis book as I have had in developing it.III.PREREQUISITES AND BACKGROUNDThe student will be assumed to have completed the basic college-level courses in algebra,trigonometry, basic physics, and elementary calculus. A knowledge of differential equationsis helpful, but not mandatory. For a quick reference, some useful topics are included in theappendixes.IV.ORGANIZATION AND FLEXIBILITYThe text is developed to be student-oriented, comprehensive, and up to date on the subject withnecessary and sufficient detailed explanation at the level for which it is intended. The key wordin the organization of the text is flexibility.The book is divided into five parts in order to provide flexibility in meeting differentcircumstances, needs, and desires. A glance at the Table of Contents will show that Part 1 concernsitself with basic electric circuits, in which circuit concepts, analysis techniques, time-dependentanalysis including transients, as well as three-phase circuits are covered. Part 2 deals withelectronic analog and digital systems, in which analog and digital building blocks are consideredalong with operational amplifiers, semiconductor devices, integrated circuits, and digital circuits.Part 3 is devoted to energy systems, in which ac power systems, magnetic circuits andtransformers, principles of electromechanics, and rotating machines causing electromechanicalenergy conversion are presented. Part 4 deals with information systems, including the underlyingprinciples of signal processing and communication systems. Finally, Part 5 presents cont
Santina, Stubberud, and Hostetter, Digital Control System Design, 2nd Edition Sarma, Introduction to Electrical Engineering Schaumann and Van Valkenburg, Design of Analog Filters Schwarz, Electromagnetics for Engineers Schwarz and Oldham, Electrical Engineering: An Introduction, 2nd Edition Sedra and Smith, Microelectronic Circuits, 4th Edition
Replacing: ND: Engineering: Electrical Diploma in Engineering Technology in Electrical Engineering (Extended), Replacing: ND: Engineering: Electrical (Extended) Diploma in Engineering Technology in Computer Engineering, Replacing: ND: Engineering: Computer Systems Bachelor of Engineering Technology in Electrical Engineering *New Qualification*
Electrical Infrastructure includes an electrical installation, electrical equipment, electrical line or associated equipment for an electrical line. 1.9 Electrical installation As per the Electrical Safety Act 2002 (s15) (a) An electrical installation is a group of items of electrical equipment that—
Materials Science and Engineering, Mechanical Engineering, Production Engineering, Chemical Engineering, Textile Engineering, Nuclear Engineering, Electrical Engineering, Civil Engineering, other related Engineering discipline Energy Resources Engineering (ERE) The students’ academic background should be: Mechanical Power Engineering, Energy .
(vi) Electrical Engineering/ Electrical Shop: First Class B.E/B.Tech/ Diploma in Electrical Engineering/ Electrical and Electronics Engineering or B.Sc/M.ScWith Electrical Sciences/ Electrical Engineering/ Physics/ Applied Physics as a subject. (vii) Mechanical Engineering/ Workshop/ Fitting Shop/ Welding Shop/ Machine Shop/ Blacksmith .
study programmes, i.e the Electronic Engineering Programme leading to the Bachelor of Engineering (Honours) (Electronic Engineering) and Electrical Engineering Programme leading to the Bachelor of Engineering (Honours) (Electrical Engineering). As of 2002/2003, another programme has been offered,
DIPLOMA IN ELECTRICAL & ELECTRONICS ENGINEERING State Board of Technical Education & Training Telangana State HYDERABAD. D:\Backup\SBTET_C14\DEEE - 1st Proof - 2 2 2 3 . 5 EE -105 Electrical Engineering Materials 66 6 EE -106 Basic Electrical Engineering 71 7 EE -107 Engineering Drawing 76 8 EE -108 Basic Electrical & Electronics
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Electrical Engineering 8 4. Curriculum Review Basis B.Sc./BS/BE Degrees 15 5. Recommended list of Non-Engineering Domain Courses 16 6. Recommended list of Engineering Domain Courses in Electrical Engineering 17 7. Recommended list of Elective Courses in Electrical Engineering distributed according to variants 18 8.
