Fundamental Electrical and Electronic Principles

✍ Scribed by Christopher R. Robertson, Jo Verhaevert

Publisher: Routledge
Year: 2024
Tongue: English
Leaves: 272
Edition: 4
Category: Library

No coin nor oath required. For personal study only.

✦ Synopsis

Fundamental Electrical and Electronic Principles covers the essential principles that form the foundations for electrical and electronic engineering courses. This new edition is extensively updated with a greater focus on electronic principles, evenly balanced with electrical principles. Fuller coverage is given to active electronics, with the additional topics of diodes and transistors, and core topics such as oscilloscopes now reflect state-of-the-art technology.

Each main chapter starts with learning outcomes tied to the syllabus. All theory is explained in detail and backed up with numerous worked examples and handy summaries of equations. Students can test their understanding with end-of-chapter assignment questions for which answers are provided. The book also provides detailed suggested practical assignments outlining apparatus and methods.

The book forms an excellent core work for beginning further education students with some mathematics background preparing for careers as technicians, and an introductory text for first-year undergraduate students in all engineering disciplines.

✦ Table of Contents

Cover
Half Title
Title Page
Copyright Page
Contents
Preface
Chapter 1 Fundamentals
1.1 Units
1.2 Standard Form Notation
1.3 ‘Scientific’ Notation
1.4 Electric versus Electronic
1.5 Basic Electrical Concepts
1.5.1 Bohr Model
1.5.2 Electric Current
1.5.3 Electromotive Force (emf)
1.5.4 Resistance (R)
1.5.5 Potential Difference (p.d.)
1.5.6 Conventional Current and Electron Flow
1.5.7 Ohm’s Law
1.5.8 Internal Resistance (r)
1.5.9 Energy (W) and Power (P)
1.5.10 Alternating and Direct Quantities
1.5.11 Use of Meters
1.6 Simulation Packages
Assignment Questions
Chapter 2 D.C. Circuits
2.1 Resistors in Series
2.2 Resistors in Parallel
2.3 Series/Parallel Combinations
2.4 Kirchhoff’s Current Law
2.5 Kirchhoff’s Voltage Law
2.6 Potentiometer
Assignment Questions
Suggested Practical Assignments
Assignment 1
Assignment 2
Assignment 3
Assignment 4
Chapter 3 Electric Fields and Capacitors
3.1 Coulomb’s Law
3.2 Electric Fields
3.3 Electric Field Strength (E), Electric Flux (.) and Flux Density (D)
3.4 The Charging Process and Potential Gradient
3.5 Capacitance (C)
3.6 Permittivity
3.7 Calculating Capacitor Values
3.8 Capacitors in Parallel
3.9 Capacitors in Series
3.10 Series/Parallel Combinations
3.11 Energy Stored
3.12 Dielectric Strength and Working Voltage
3.13 Capacitor Types
3.13.1 Paper
3.13.2 Air
3.13.3 ‘Plastic’
3.13.4 Silvered Mica
3.13.5 Mixed Dielectric
3.13.6 Electrolytic
Assignment Questions
Suggested Practical Assignment
Chapter 4 Magnetic Fields and Circuits
4.1 Magnetic Materials
4.2 Magnetic Fields
4.3 The Magnetic Circuit
4.4 Magnetic Flux and Flux Density
4.5 Magnetomotive Force (mmf)
4.6 Magnetic Field Strength
4.7 Permeability
4.8 Magnetisation (B/H) Curve
4.9 Composite Series Magnetic Circuits
4.10 Reluctance (S)
4.11 Magnetic Hysteresis
4.12 Parallel Magnetic Circuits
Assignment Questions
Suggested Practical Assignments
Assignment 1
Assignment 2
Chapter 5 Electromagnetism
5.1 Faraday’s Law of Electromagnetic Induction
5.2 Fleming’s Right-Hand Rule
5.3 Emf Induced in a Single Straight Conductor
5.4 Force on a Current-Carrying Conductor
5.5 The Motor Principle
5.6 Force between Parallel Conductors
5.7 Eddy Currents
5.8 Self- and Mutual Inductance
5.8.1 Self-Inductance
5.8.2 Flux Linkages
5.8.3 Factors Affecting Inductance
5.8.4 Mutual Inductance
5.8.5 Relationship between Self- and Mutual Inductance
5.9 Energy Stored
5.10 The Transformer Principle
Assignment Questions
Suggested Practical Assignments
Assignment 1
Assignment 2
Assignment 3
Chapter 6 Semiconductor Theory and Diodes
6.1 Atomic Structure
6.2 Intrinsic (Pure) Semiconductors
6.3 Electron–Hole Pair Generation and Recombination
6.4 Conduction in Intrinsic and Extrinsic (Impure) Semiconductors
6.5 n-type Semiconductor
6.6 p-type Semiconductor
6.7 The p-n Junction
6.8 Forward-Biased and Reverse-Biased Diode
6.9 Diode Characteristics
6.10 The Zener Diode
6.11 The LED
6.12 The Solar Cell
Assignment Questions
Suggested Practical Assignments
Assignment 1
Assignment 2
Chapter 7 Transistors
7.1 Bipolar Transistor
7.2 Transistor Effect
7.3 Transistor as Switch
7.4 Transistor as Amplifier
7.5 Field Effect Transistor
7.6 Integrated Circuits and Moore’s Law
7.7 Opamps
7.8 Inverting and Non-Inverting Amplifiers with Opamps
Assignment Questions
Chapter 8 Alternating Quantities
8.1 Production of an Alternating Waveform
8.2 Angular Velocity and Frequency
8.3 Standard Expression for an Alternating Quantity
8.4 Average and r.m.s. Value and Peak and Form Factor
8.5 Rectifiers
8.6 Phase and Phase Angle
8.7 Phasor Representation
8.8 Addition of Alternating Quantities
8.9 Oscilloscope
Assignment Questions
Chapter 9 D.C. Machines
9.1 Motor/Generator Duality
9.2 The Generation of d.c. Voltage
9.3 Separately Excited Generator
9.4 Shunt Generator
9.5 Series Generator
9.6 Shunt Motor
9.7 Series Motor
Assignment Questions
Chapter 10 D.C. Transients
10.1 Capacitor-Resistor Series Circuit: Charging
10.2 Capacitor-Resistor Series Circuit: Discharging
10.3 Inductor-Resistor Series Circuit: Charging
10.4 Inductor-Resistor Series Circuit: Discharging
Assignment Questions
Suggested Practical Assignments
Assignment 1
Appendix
Index

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