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Basic Electrical and Electronics Engineering.

By: Material type: TextTextEdition: 0Description: 1 online resource (735 pages)ISBN:
  • 9789332501126
Genre/Form: Additional physical formats: Print version:: Basic Electrical and Electronics EngineeringDDC classification:
  • 23 621.381
Online resources:
Contents:
Cover -- Contents -- Preface -- About the Author -- Chapter 1: Basic Concepts, Laws, and Principles -- 1.1 Introduction -- 1.2 Atomic Structure and Electric Charge -- 1.3 Conductors, Insulators, and Semiconductors -- 1.4 Electric Field and Magnetic Field -- 1.5 Electric Current, Resistance, Potential, and Potential Difference -- 1.5.1 Electric Current -- 1.5.2 Resistance -- 1.5.3 Potential and Potential Difference -- 1.6 Ohm's Law -- 1.7 The Effect of Temperature on Resistance -- 1.8 Work, Power, and Energy -- 1.8.1 Work -- 1.8.2 Power -- 1.8.3 E nergy -- 1.8.4 Units of Work, Power, and Energy -- 1.9 Electromagnetism and Electromagnetic Induction -- 1.9.1 Introduction -- 1.9.2 Magnetic Field Around a Current-carrying Conductor -- 1.9.3 Magnetic Field Around a Coil -- 1.9.4 A Current-carrying Conductor Placed in a Magnetic Field -- 1.9.5 A Current-carrying Coil Placed in a Magnetic Field -- 1.10 Laws of Electromagnetic Induction -- 1.11 Induced EMF in a Coil Rotating in a Magnetic Field -- 1.12 EMF Induced in a Conductor -- 1.13 Dynamically Induced EMF and Statically Induced EMF -- 1.14 Self-induced EMF and Mutually induced EMF -- 1.15 Self-Inductance of a Coil -- 1.16 Mutual Inductance -- 1.17 Inductance of Coils Connected in Series Having a Common Core -- 1.18 Energy Stored in a Magnetic Field -- 1.19 Electrical Circuit Elements -- 1.19.1 Resistors -- 1.19.2 Inductors -- 1.19.3 Capacitors -- 1.20 Energy Stored in a Capacitor -- 1.21 Capacitor in Parallel and in Series -- 1.22 Review Questions -- Chapter 2: DC Networks and Network Theorems -- 2.1 Introduction -- 2.2 DC Network Terminologies, Voltage, and Current Sources -- 2.2.1 Network Terminologies -- 2.2.2 V oltage and Current Sources -- 2.2.3 Source Transformation -- 2.3 Series-Parallel Circuits -- 2.3.1 Series Circuits -- 2.3.2 Parallel Circuits -- 2.3.3 Series-Parallel Circuits.
2.4 Voltage and Current Divider Rules -- 2.4.1 Voltage Divider Rule -- 2.4.2 Current Divider Rule -- 2.5 kirchhoff's laws -- 2.5.1 kirchhoff's Current law -- 2.5.2 kirchhoff's voltage law -- 2.5.3 Solution of Simultaneous Equations Using Cramer's Rule -- 2.5.4 M ethod of Evaluating Determinant -- 2.6 Maxwell's Mesh Current Method -- Nodal Voltage Method (Nodal Analysis) -- 2.8 Network Theorems -- 2.8.1 Superposition Theorem -- 2.8.2 Thevenin's Theorem -- 2.8.3 Norton's Theorem -- 2.8.4 Millman's Theorem -- 2.8.5 Maximum Power Transfer Theorem -- 2.9 Star-Delta Transformation -- 2.9.1 Transforming Relations for Delta to Star -- 2.9.2 T ransforming Relations for Star to Delta -- 2.10 DC Transients -- 2.10.1 Introduction -- 2.10.2 Transient in R-L Circuit -- 2.10.3 Transient in R-C Circuit -- 2.10.3 Transient in R-C Circuit -- 2.11 Review Questions -- Chapter 3: AC Fundamentals and Single-phase Circuits -- 3.1 AC Fundamentals -- 3.1.1 Introduction -- 3.1.2 Generation of Alternating Voltage in an Elementary Generator -- 3.1.3 Concept of Frequency, Cycle, Time Period, Instantaneous Value, Average Value, and Maximum Value -- 3.1.4 Sinusoidal and Non-sinusoidal Wave Forms -- 3.1.5 Concept of Average Value and Root Mean Square (RMS)Value of an Alternating Quantity -- 3.1.6 Analytical Method of Calculation of RMS Value, Average Value, and Form Factor -- 3.1.7 RMS and Average Values of Half-wave-rectified Alternating Quantity -- 3.1.8 Concept of Phase and Phase Difference -- 3.2 Single-phase AC Circuits -- 3.2.1 Behaviour of R, L, and C in AC Circuits -- 3.2.2 L-R Series Circuit -- 3.2.3 Apparent Power, Real Power, and Reactive Power -- 3.2.4 Power in an AC Circuit -- 3.2.5 R-C Series Circuit -- 3.2.6 R-L-C Series Circuit -- 3.2.7 AC Parallel Circuits -- 3.2.8 AC Series-Parallel Circuits -- 3.3 Resonance in AC Circuits -- 3.3.1 Resonance in AC Series Circuit.
3.3.2 Resonance in AC Parallel Circuits -- 3.4 Review Questions -- Chapter 4: Three-phase System -- 4.1 Introduction -- 4.2 Advantages of Three-phase Systems -- 4.3 Generation of Three-Phase Voltages -- 4.4 Terms Used in Three-phase Systems and Circuits -- 4.5 Three-phase Winding Connections -- 4.5.1 Star Connection -- 4.5.2 Delta Connection -- 4.5.3 Relationship of Line and Phase Voltages, and Currents in a Star-connected System -- 4.5.4 Relationship of Line and Phase Voltages and Currents in a Delta-connected System -- 4.6 Active and Reactive Power -- 4.7 Comparison between Star Connection and Delta Connection -- 4.8 Measurement of Power in Three-phase Circuits -- 4.8.1 One-Wattmeter Method -- 4.8.2 Two-Wattmeter Method -- 4.8.3 Three-Wattmeter Method -- 4.9 Review Questions -- Chapter 5: Electromagnetism and Magnetic Circuits -- 5.1 Magnets and Magnetic Fields -- 5.1.1 Field Around a Current-carrying Conductor -- 5.1.2 Magnetic Flux Density -- 5.1.3 Magnetic Field Strength -- 5.1.4 Permeability -- 5.1.5 Relative Permeability -- 5.2 Magnetic Field Due to Current-carrying Conductor Laws of Electromagnetism -- 5.2.1 Ampere's Circuital Law -- 5.2.2 Biot-Savart Law -- 5.2.3 Application of Biot-Savart Law -- 5.3 Magnetization Curve of a Magnetic Material -- 5.4 Hysteresis Loss and Eddy Current Loss in Magnetic Materials -- 5.4.1 Hysteresis Loss -- 5.4.2 Eddy Current Loss -- 5.5 Magnetic Circuits -- 5.6 Comparison Between Magnetic and Electric Circuits -- 5.7 Magnetic Leakage and Fringing -- 5.8 Series and Parallel Magnetic Circuits -- 5.9 Attractive Force or the Lifting Power of Electromagnets -- 5.10 Review Questions -- Chapter 6: Transformers -- 6.1 Introduction -- 6.2 Applications of Transformers -- 6.3 Basic Principle and Constructional Details -- 6.3.1 Basic Principle -- 6.3.2 Constructional Details -- 6.4 Core-Type and Shell-Type Transformers.
6.4.1 Power Transformers and Distribution Transformers -- 6.5 EMF Equation -- 6.6 Transformer on No-Load -- 6.7 Transformer on Load -- 6.8 Transformer Circuit Parameters and Equivalent Circuit -- 6.9 Phasor Diagram of a Transformer -- 6.10 Concept of Voltage Regulation -- 6.11 Concept of an Ideal Transformer -- 6.12 Transformer Tests -- 6.12.1 Open-circuit Test or No-load Test -- 6.12.2 Short-circuit Test -- 6.13 Efficiency of a Transformer -- 6.14 Condition for Maximum Efficiency -- 6.15 All-day Efficiency -- 6.16 Calculation of Regulation of a Transformer -- 6.17 Factors Affecting Losses in a Transformer -- 6.18 Solved Numerical Problems -- 6.19 Review Questions -- Chapter 7: DC Machines -- 7.1 Introduction and Principle of Working -- 7.1.1 Nature of Load Current When Output is Taken Out Through Brush and Slip-ring Arrangement -- 7.1.2 Nature of Load Current When Output Is Taken Through Brush and Commutator Arrangement -- 7.1.3 Function of Brush and Commutators in Motoring Action -- 7.2 Constructional Details -- 7.2.1 The Field System -- 7.2.2 The Armature -- 7.2.3 Armature Winding -- 7.2.4 Types of Armature Winding -- 7.3 EMF Equation of a DC Machine -- 7.3.1 Induced EMF is Equated to Flux Cut Per Second -- 7.4 Types of DC Machines -- 7.5 Characteristics of DC Generators -- 7.5.1 No-load Characteristics -- 7.5.2 Load Characteristics -- 7.6 Applications of DC Generators -- 7.7 Operation of a DC Machine As a Motor -- 7.7.1 Working Principle of a DC Motor -- 7.7.2 Changing the Direction of Rotation -- 7.7.3 Energy Conversion Equation -- 7.8 Torque Equation -- 7.9 Starting a DC Motor -- 7.10 Speed Control of DC Motors -- 7.10.1 Voltage Control Method -- 7.10.2 Field Control Method -- 7.10.3 Armature Control Method -- 7.11 Starter for a DC Motor -- 7.11.1 Three-point Starter -- 7.11.2 Four-point Starter -- 7.12 Types and Characteristics of DC Motors.
7.12.1 Characteristics of DC Shunt Motors -- 7.12.2 Characteristics of DC Series Motors -- 7.12.3 Characteristics of DC Compound Motors -- 7.13 Losses and Efficiency -- 7.13.1 Losses in a DC Machine -- 7.13.2 Efficiency of DC Machine -- 7.13.3 Condition for Maximum Efficiency -- 7.14 Applications of DC Machines -- 7.14.1 DC Generators -- 7.14.2 DC Motors -- 7.14.3 DC Series Motors -- 7.14.4 DC Compound Motors -- 7.15 Solved Numerical Problems -- 7.16 Review Questions -- Chapter 8: Three-phase Induction Motors -- 8.1 Introduction -- 8.2 Constructional Details -- 8.3 Windings and Pole Formation -- 8.4 Production of Rotating Magnetic Field -- 8.5 Principle of Working -- 8.6 Rotor-Induced EMF, Rotor Frequency, Rotor Current -- 8.7 Losses in Induction Motors -- 8.8 Power Flow Diagram -- 8.9 Torque Equation -- 8.10 Starting Torque -- 8.11 Condition for Maximum Torque -- 8.12 Torque-Slip Characteristic -- 8.13 Variation of Torque-slip Characteristic With Change in Rotor-Circuit Resistance -- 8.14 Starting of Induction Motors -- 8.14.1 Direct-on-Line Starting -- 8.14.2 Manual Star-Delta Starter -- 8.15 Speed Control of Induction Motors -- 8.16 Determination of Efficiency -- 8.16.1 No-load Test -- 8.16.2 Blocked-rotor Test -- 8.17 Applications of Induction Motors -- 8.18 Solved Numerical Problems -- 8.19 Review questions -- Chapter 9: Single-phase Motors -- 9.1 Introduction to Single-phase Induction Motors -- 9.2 Constructional Details -- 9.3 Double Revolving Field Theory and Principle of Working of Single-phase Induction Motors -- 9.4 Torque-Speed Characteristic -- 9.5 Split-Phase Induction Motors -- 9.6 Shaded Pole Induction Motor -- 9.7 Single-Phase AC Series Motors -- 9.8 Operation of a Series Motor on DC and AC (Universal Motors) -- 9.9 Single-Phase Synchronous Motors -- 9.9.1 Reluctance Motors -- 9.9.2 Hysteresis Motors -- 9.10 Stepper Motors.
9.11 Review Questions.
Summary: Basic Electrical and Electronics Engineering provides an overview of the basics of electrical and electronic engineering that are required at the undergraduate level. Efforts have been taken to keep the complexity level of the subject to bare minimum so that students outside electrical and electronics engineering can easily understand the basics. It offers an unparalleled exposure to the entire gamut of topics such as electricity fundamentals, network theory, electro-magnetism, electrical machines, transformers, measuring instruments, power systems, semiconductor devices, digital electronics and integrated circuits. Extensive use of illustrations, examples and exercises in accordance with the progressive development of the concepts covered within the chapter make the reading more exciting.
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Holdings
Item type Current library Call number Status Date due Barcode Item holds
E- Books E- Books Digital Library Digital Library 621.381 BHA-B Available E0014
Total holds: 0

Cover -- Contents -- Preface -- About the Author -- Chapter 1: Basic Concepts, Laws, and Principles -- 1.1 Introduction -- 1.2 Atomic Structure and Electric Charge -- 1.3 Conductors, Insulators, and Semiconductors -- 1.4 Electric Field and Magnetic Field -- 1.5 Electric Current, Resistance, Potential, and Potential Difference -- 1.5.1 Electric Current -- 1.5.2 Resistance -- 1.5.3 Potential and Potential Difference -- 1.6 Ohm's Law -- 1.7 The Effect of Temperature on Resistance -- 1.8 Work, Power, and Energy -- 1.8.1 Work -- 1.8.2 Power -- 1.8.3 E nergy -- 1.8.4 Units of Work, Power, and Energy -- 1.9 Electromagnetism and Electromagnetic Induction -- 1.9.1 Introduction -- 1.9.2 Magnetic Field Around a Current-carrying Conductor -- 1.9.3 Magnetic Field Around a Coil -- 1.9.4 A Current-carrying Conductor Placed in a Magnetic Field -- 1.9.5 A Current-carrying Coil Placed in a Magnetic Field -- 1.10 Laws of Electromagnetic Induction -- 1.11 Induced EMF in a Coil Rotating in a Magnetic Field -- 1.12 EMF Induced in a Conductor -- 1.13 Dynamically Induced EMF and Statically Induced EMF -- 1.14 Self-induced EMF and Mutually induced EMF -- 1.15 Self-Inductance of a Coil -- 1.16 Mutual Inductance -- 1.17 Inductance of Coils Connected in Series Having a Common Core -- 1.18 Energy Stored in a Magnetic Field -- 1.19 Electrical Circuit Elements -- 1.19.1 Resistors -- 1.19.2 Inductors -- 1.19.3 Capacitors -- 1.20 Energy Stored in a Capacitor -- 1.21 Capacitor in Parallel and in Series -- 1.22 Review Questions -- Chapter 2: DC Networks and Network Theorems -- 2.1 Introduction -- 2.2 DC Network Terminologies, Voltage, and Current Sources -- 2.2.1 Network Terminologies -- 2.2.2 V oltage and Current Sources -- 2.2.3 Source Transformation -- 2.3 Series-Parallel Circuits -- 2.3.1 Series Circuits -- 2.3.2 Parallel Circuits -- 2.3.3 Series-Parallel Circuits.

2.4 Voltage and Current Divider Rules -- 2.4.1 Voltage Divider Rule -- 2.4.2 Current Divider Rule -- 2.5 kirchhoff's laws -- 2.5.1 kirchhoff's Current law -- 2.5.2 kirchhoff's voltage law -- 2.5.3 Solution of Simultaneous Equations Using Cramer's Rule -- 2.5.4 M ethod of Evaluating Determinant -- 2.6 Maxwell's Mesh Current Method -- Nodal Voltage Method (Nodal Analysis) -- 2.8 Network Theorems -- 2.8.1 Superposition Theorem -- 2.8.2 Thevenin's Theorem -- 2.8.3 Norton's Theorem -- 2.8.4 Millman's Theorem -- 2.8.5 Maximum Power Transfer Theorem -- 2.9 Star-Delta Transformation -- 2.9.1 Transforming Relations for Delta to Star -- 2.9.2 T ransforming Relations for Star to Delta -- 2.10 DC Transients -- 2.10.1 Introduction -- 2.10.2 Transient in R-L Circuit -- 2.10.3 Transient in R-C Circuit -- 2.10.3 Transient in R-C Circuit -- 2.11 Review Questions -- Chapter 3: AC Fundamentals and Single-phase Circuits -- 3.1 AC Fundamentals -- 3.1.1 Introduction -- 3.1.2 Generation of Alternating Voltage in an Elementary Generator -- 3.1.3 Concept of Frequency, Cycle, Time Period, Instantaneous Value, Average Value, and Maximum Value -- 3.1.4 Sinusoidal and Non-sinusoidal Wave Forms -- 3.1.5 Concept of Average Value and Root Mean Square (RMS)Value of an Alternating Quantity -- 3.1.6 Analytical Method of Calculation of RMS Value, Average Value, and Form Factor -- 3.1.7 RMS and Average Values of Half-wave-rectified Alternating Quantity -- 3.1.8 Concept of Phase and Phase Difference -- 3.2 Single-phase AC Circuits -- 3.2.1 Behaviour of R, L, and C in AC Circuits -- 3.2.2 L-R Series Circuit -- 3.2.3 Apparent Power, Real Power, and Reactive Power -- 3.2.4 Power in an AC Circuit -- 3.2.5 R-C Series Circuit -- 3.2.6 R-L-C Series Circuit -- 3.2.7 AC Parallel Circuits -- 3.2.8 AC Series-Parallel Circuits -- 3.3 Resonance in AC Circuits -- 3.3.1 Resonance in AC Series Circuit.

3.3.2 Resonance in AC Parallel Circuits -- 3.4 Review Questions -- Chapter 4: Three-phase System -- 4.1 Introduction -- 4.2 Advantages of Three-phase Systems -- 4.3 Generation of Three-Phase Voltages -- 4.4 Terms Used in Three-phase Systems and Circuits -- 4.5 Three-phase Winding Connections -- 4.5.1 Star Connection -- 4.5.2 Delta Connection -- 4.5.3 Relationship of Line and Phase Voltages, and Currents in a Star-connected System -- 4.5.4 Relationship of Line and Phase Voltages and Currents in a Delta-connected System -- 4.6 Active and Reactive Power -- 4.7 Comparison between Star Connection and Delta Connection -- 4.8 Measurement of Power in Three-phase Circuits -- 4.8.1 One-Wattmeter Method -- 4.8.2 Two-Wattmeter Method -- 4.8.3 Three-Wattmeter Method -- 4.9 Review Questions -- Chapter 5: Electromagnetism and Magnetic Circuits -- 5.1 Magnets and Magnetic Fields -- 5.1.1 Field Around a Current-carrying Conductor -- 5.1.2 Magnetic Flux Density -- 5.1.3 Magnetic Field Strength -- 5.1.4 Permeability -- 5.1.5 Relative Permeability -- 5.2 Magnetic Field Due to Current-carrying Conductor Laws of Electromagnetism -- 5.2.1 Ampere's Circuital Law -- 5.2.2 Biot-Savart Law -- 5.2.3 Application of Biot-Savart Law -- 5.3 Magnetization Curve of a Magnetic Material -- 5.4 Hysteresis Loss and Eddy Current Loss in Magnetic Materials -- 5.4.1 Hysteresis Loss -- 5.4.2 Eddy Current Loss -- 5.5 Magnetic Circuits -- 5.6 Comparison Between Magnetic and Electric Circuits -- 5.7 Magnetic Leakage and Fringing -- 5.8 Series and Parallel Magnetic Circuits -- 5.9 Attractive Force or the Lifting Power of Electromagnets -- 5.10 Review Questions -- Chapter 6: Transformers -- 6.1 Introduction -- 6.2 Applications of Transformers -- 6.3 Basic Principle and Constructional Details -- 6.3.1 Basic Principle -- 6.3.2 Constructional Details -- 6.4 Core-Type and Shell-Type Transformers.

6.4.1 Power Transformers and Distribution Transformers -- 6.5 EMF Equation -- 6.6 Transformer on No-Load -- 6.7 Transformer on Load -- 6.8 Transformer Circuit Parameters and Equivalent Circuit -- 6.9 Phasor Diagram of a Transformer -- 6.10 Concept of Voltage Regulation -- 6.11 Concept of an Ideal Transformer -- 6.12 Transformer Tests -- 6.12.1 Open-circuit Test or No-load Test -- 6.12.2 Short-circuit Test -- 6.13 Efficiency of a Transformer -- 6.14 Condition for Maximum Efficiency -- 6.15 All-day Efficiency -- 6.16 Calculation of Regulation of a Transformer -- 6.17 Factors Affecting Losses in a Transformer -- 6.18 Solved Numerical Problems -- 6.19 Review Questions -- Chapter 7: DC Machines -- 7.1 Introduction and Principle of Working -- 7.1.1 Nature of Load Current When Output is Taken Out Through Brush and Slip-ring Arrangement -- 7.1.2 Nature of Load Current When Output Is Taken Through Brush and Commutator Arrangement -- 7.1.3 Function of Brush and Commutators in Motoring Action -- 7.2 Constructional Details -- 7.2.1 The Field System -- 7.2.2 The Armature -- 7.2.3 Armature Winding -- 7.2.4 Types of Armature Winding -- 7.3 EMF Equation of a DC Machine -- 7.3.1 Induced EMF is Equated to Flux Cut Per Second -- 7.4 Types of DC Machines -- 7.5 Characteristics of DC Generators -- 7.5.1 No-load Characteristics -- 7.5.2 Load Characteristics -- 7.6 Applications of DC Generators -- 7.7 Operation of a DC Machine As a Motor -- 7.7.1 Working Principle of a DC Motor -- 7.7.2 Changing the Direction of Rotation -- 7.7.3 Energy Conversion Equation -- 7.8 Torque Equation -- 7.9 Starting a DC Motor -- 7.10 Speed Control of DC Motors -- 7.10.1 Voltage Control Method -- 7.10.2 Field Control Method -- 7.10.3 Armature Control Method -- 7.11 Starter for a DC Motor -- 7.11.1 Three-point Starter -- 7.11.2 Four-point Starter -- 7.12 Types and Characteristics of DC Motors.

7.12.1 Characteristics of DC Shunt Motors -- 7.12.2 Characteristics of DC Series Motors -- 7.12.3 Characteristics of DC Compound Motors -- 7.13 Losses and Efficiency -- 7.13.1 Losses in a DC Machine -- 7.13.2 Efficiency of DC Machine -- 7.13.3 Condition for Maximum Efficiency -- 7.14 Applications of DC Machines -- 7.14.1 DC Generators -- 7.14.2 DC Motors -- 7.14.3 DC Series Motors -- 7.14.4 DC Compound Motors -- 7.15 Solved Numerical Problems -- 7.16 Review Questions -- Chapter 8: Three-phase Induction Motors -- 8.1 Introduction -- 8.2 Constructional Details -- 8.3 Windings and Pole Formation -- 8.4 Production of Rotating Magnetic Field -- 8.5 Principle of Working -- 8.6 Rotor-Induced EMF, Rotor Frequency, Rotor Current -- 8.7 Losses in Induction Motors -- 8.8 Power Flow Diagram -- 8.9 Torque Equation -- 8.10 Starting Torque -- 8.11 Condition for Maximum Torque -- 8.12 Torque-Slip Characteristic -- 8.13 Variation of Torque-slip Characteristic With Change in Rotor-Circuit Resistance -- 8.14 Starting of Induction Motors -- 8.14.1 Direct-on-Line Starting -- 8.14.2 Manual Star-Delta Starter -- 8.15 Speed Control of Induction Motors -- 8.16 Determination of Efficiency -- 8.16.1 No-load Test -- 8.16.2 Blocked-rotor Test -- 8.17 Applications of Induction Motors -- 8.18 Solved Numerical Problems -- 8.19 Review questions -- Chapter 9: Single-phase Motors -- 9.1 Introduction to Single-phase Induction Motors -- 9.2 Constructional Details -- 9.3 Double Revolving Field Theory and Principle of Working of Single-phase Induction Motors -- 9.4 Torque-Speed Characteristic -- 9.5 Split-Phase Induction Motors -- 9.6 Shaded Pole Induction Motor -- 9.7 Single-Phase AC Series Motors -- 9.8 Operation of a Series Motor on DC and AC (Universal Motors) -- 9.9 Single-Phase Synchronous Motors -- 9.9.1 Reluctance Motors -- 9.9.2 Hysteresis Motors -- 9.10 Stepper Motors.

9.11 Review Questions.

Basic Electrical and Electronics Engineering provides an overview of the basics of electrical and electronic engineering that are required at the undergraduate level. Efforts have been taken to keep the complexity level of the subject to bare minimum so that students outside electrical and electronics engineering can easily understand the basics. It offers an unparalleled exposure to the entire gamut of topics such as electricity fundamentals, network theory, electro-magnetism, electrical machines, transformers, measuring instruments, power systems, semiconductor devices, digital electronics and integrated circuits. Extensive use of illustrations, examples and exercises in accordance with the progressive development of the concepts covered within the chapter make the reading more exciting.

Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2018. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.

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