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200 10$aIntroduction to electrical engineering
210 31$a[Place of publication not identified]$cOxford University Press$d2000
215   $a1 online resource (896 pages)
225 0 $aThe Oxford series in electrical and computer engineering Introduction to electrical engineering 
300   $aBibliographic Level Mode of Issuance: Monograph
311   $a0-19-513604-7 
327   $aIntro -- Contents -- List of Case Studies and Computer-Aided Analysis -- Preface -- Overview -- PART 1 ELECTRIC CIRCUITS -- 1 Circuit Concepts -- 1.1 Electrical Quantities -- 1.2 Lumped-Circuit Elements -- 1.3 Kirchhoff's Laws -- 1.4 Meters and Measurements -- 1.5 Analogy between Electrical and Other Nonelectric Physical Systems -- 1.6 Learning Objectives -- 1.7 Practical Application: A Case Study-Resistance Strain Gauge -- Problems -- 2 Circuit Analysis Techniques -- 2.1 The?venin and Norton Equivalent Circuits -- 2.2 Node-Voltage and Mesh-Current Analyses -- 2.3 Superposition and Linearity -- 2.4 Wye-Delta Transformation -- 2.5 Computer-Aided Circuit Analysis: SPICE -- 2.6 Computer-Aided Circuit Analysis: MATLAB -- 2.7 Learning Objectives -- 2.8 Practical Application: A Case Study-Jump Starting a Car -- Problems -- 3 Time-Dependent Circuit Analysis -- 3.1 Sinusoidal Steady-State Phasor Analysis -- 3.2 Transients in Circuits -- 3.3 Laplace Transform -- 3.4 Frequency Response -- 3.5 Computer-Aided Circuit Simulation for Transient Analysis, AC Analysis, and Frequency Response Using PSpice and PROBE -- 3.6 Use of MATLAB in Computer-Aided Circuit Simulation -- 3.7 Learning Objectives -- 3.8 Practical Application: A Case Study-Automotive Ignition System -- Problems -- 4 Three-Phase Circuits and Residential Wiring -- 4.1 Three-Phase Source Voltages and Phase Sequence -- 4.2 Balanced Three-Phase Loads -- 4.3 Measurement of Power -- 4.4 Residential Wiring and Safety Considerations -- 4.5 Learning Objectives -- 4.6 Practical Application: A Case Study-Physiological Effects of Current and Electrical Safety -- Problems -- PART 2 ELECTRONIC ANALOG AND DIGITAL SYSTEMS -- 5 Analog Building Blocks and Operational Amplifiers -- 5.1 The Amplifier Block -- 5.2 Ideal Operational Amplifier -- 5.3 Practical Properties of Operational Amplifiers.
327   $a5.4 Applications of Operational Amplifiers -- 5.5 Learning Objectives -- 5.6 Practical Application: A Case Study-Automotive Power-Assisted Steering System -- Problems -- 6 Digital Building Blocks and Computer Systems -- 6.1 Digital Building Blocks -- 6.2 Digital System Components -- 6.3 Computer Systems -- 6.4 Computer Networks -- 6.5 Learning Objectives -- 6.6 Practical Application: A Case Study-Microcomputer-Controlled Breadmaking Machine -- Problems -- 7 Semiconductor Devices -- 7.1 Semiconductors -- 7.2 Diodes -- 7.3 Bipolar Junction Transistors -- 7.4 Field-Effect Transistors -- 7.5 Integrated Circuits -- 7.6 Learning Objectives -- 7.7 Practical Application: A Case Study-Electronic Photo Flash -- Problems -- 8 Transistor Amplifiers -- 8.1 Biasing the BJT -- 8.2 Biasing the FET -- 8.3 BJT Amplifiers -- 8.4 FET Amplifiers -- 8.5 Frequency Response of Amplifiers -- 8.6 Learning Objectives -- 8.7 Practical Application: A Case Study-Mechatronics: Electronics Integrated with Mechanical Systems -- Problems -- 9 Digital Circuits -- 9.1 Transistor Switches -- 9.2 DTL and TTL Logic Circuits -- 9.3 CMOS and Other Logic Families -- 9.4 Learning Objectives -- 9.5 Practical Application: A Case Study-Cardiac Pacemaker, a Biomedical Engineering Application -- Problems -- PART 3 ENERGY SYSTEMS -- 10 AC Power Systems -- 10.1 Introduction to Power Systems -- 10.2 Single- and Three-Phase Systems -- 10.3 Power Transmission and Distribution -- 10.4 Learning Objectives -- 10.5 Practical Application: A Case Study-The Great Blackout of 1965 -- Problems -- 11 Magnetic Circuits and Transformers -- 11.1 Magnetic Materials -- 11.2 Magnetic Circuits -- 11.3 Transformer Equivalent Circuits -- 11.4 Transformer Performance -- 11.5 Three-Phase Transformers -- 11.6 Autotransformers -- 11.7 Learning Objectives.
327   $a11.8 Practical Application: A Case Study-Magnetic Bearings for Space Technology -- Problems -- 12 Electromechanics -- 12.1 Basic Principles of Electromechanical Energy Conversion -- 12.2 EMF Produced by Windings -- 12.3 Rotating Magnetic Fields -- 12.4 Forces and Torques in Magnetic-Field Systems -- 12.5 Basic Aspects of Electromechanical Energy Converters -- 12.6 Learning Objectives -- 12.7 Practical Application: A Case Study-Sensors or Transducers -- Problems -- 13 Rotating Machines -- 13.1 Elementary Concepts of Rotating Machines -- 13.2 Induction Machines -- 13.3 Synchronous Machines -- 13.4 Direct-Current Machines -- 13.5 Learning Objectives -- 13.6 Practical Application: A Case Study-Wind-Energy-Conversion Systems -- Problems -- PART 4 INFORMATION SYSTEMS -- 14 Signal Processing -- 14.1 Signals and Spectral Analysis -- 14.2 Modulation, Sampling, and Multiplexing -- 14.3 Interference and Noise -- 14.4 Learning Objectives -- 14.5 Practical Application: A Case Study-Antinoise Systems, Noise Cancellation -- Problems -- 15 Communication Systems -- 15.1 Waves, Transmission Lines, Waveguides, and Antenna Fundamentals -- 15.2 Analog Communication Systems -- 15.3 Digital Communication Systems -- 15.4 Learning Objectives -- 15.5 Practical Application: A Case Study-Global Positioning Systems -- Problems -- PART 5 CONTROL SYSTEMS -- 16 Basic Control Systems -- 16.1 Power Semiconductor-Controlled Drives -- 16.2 Feedback Control Systems -- 16.3 Digital Control Systems -- 16.4 Learning Objectives -- 16.5 Practical Application: A Case Study-Digital Process Control -- Problems -- Appendix A: References -- Appendix B: Brief Review of Fundamentals of Engineering (FE) Examination -- Appendix C: Technical Terms, Units, Constants, and Conversion Factors for the SI System -- Appendix D: Mathematical Relations -- Appendix E: Solution of Simultaneous Equations.
327   $aAppendix F: Complex Numbers -- Appendix G: Fourier Series -- Appendix H: Laplace Transforms -- Index.
330   $aThe purpose of this text is to present a problem-oriented introductory survey of electrical engineering, by arousing student enthusiasm while addressing 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 majroing in all branches of engineering and science, especially in courses for non-electrical-engieering majors, with the nature of the subject and the potentialities of its techniques, while emphasizing the principles. Sine 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 adequately challenging problems which tend to implant the relevant principles in student's minds. In addition to an academic-year (two semesters or three quarters) introductory course traditionally offered to non-electrical engineering majors in a number of universities.Modern technology demands a team approach in which electrical engineers and non-electrical engineers have to work together sharing a common technical vocabulary. This text is a result based on almost 40 years of experience teaching a wide variety of courses to electrical as well as non-electrical majors, an dmore particularly on the need to answer many of the questions raised by so many of my students. The book is divided into five parts in order to provide flexibility. A glance at the Table of Contents will show that Part I concerns itself with basic electric circuits, in which circuit concepts, analysis techniques, time-dependent analysis including transients, as well as three-phase circuits are covered. Part II deals with electronic ananlog and digital systems, in which analog and
330 8 $adigital building blocks are considered along with operational amplifiers, semiconductor devices, integrated circuits, and digital circuits. Part III of the book is devoted to energy systems, in which AC power systems, magnetic circuits and transformers, principles of electromechanics, and rotating machines causing electromechanical energy conversion are presented.Part IV of the text deals with information systems, in which the underlying principles of signal processing and communication systems are included. Finally, Part V presents control systems, including the concepts of feedback control, digital control, and power semiconductor-controlled drives. The text material is organized for optimum flexibility, so that certain topics my be omitted without loss of continuity when lack of time or interest dictates.
606   $aElectrical engineering
606   $aElectrical & Computer Engineering$2HILCC
606   $aEngineering & Applied Sciences$2HILCC
606   $aElectrical Engineering$2HILCC
615  0$aElectrical engineering.
615  7$aElectrical & Computer Engineering
615  7$aEngineering & Applied Sciences
615  7$aElectrical Engineering
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