Electrical Engineering Know It All 1st Edition by Clive Maxfield, John Bird, Tim Williams, Walt Kester, Dan Bensky 1856175286 9781856175289

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ISBN 10: 1856175286

ISBN 13: 9781856175289

Author: Clive Maxfield, John Bird, Tim Williams, Walt Kester, Dan Bensky

The Newnes Know It All Series takes the best of what our authors have written to create hard-working desk references that will be an engineer’s first port of call for key information, design techniques and rules of thumb. Guaranteed not to gather dust on a shelf!

Electrical engineers need to master a wide area of topics to excel. The Electrical Engineering Know It All covers every angle including Real-World Signals and Systems, Electromagnetics, and Power systems.

• A 360-degree view from our best-selling authors
• Topics include digital, analog, and power electronics, and electric circuits
• The ultimate hard-working desk reference; all the essential information, techniques and tricks of the trade in one volume

Electrical Engineering Know It All 1st Table of contents:

Chapter 1. An Introduction to Electric Circuits

1.1 SI Units

1.2 Charge

1.3 Force

1.4 Work

1.5 Power

1.6 Electrical Potential and e.m.f.

1.7 Resistance and Conductance

1.8 Electrical Power and Energy

1.9 Summary of Terms, Units and Their Symbols

1.10 Standard Symbols for Electrical Components

1.11 Electric Current and Quantity of Electricity

1.12 Potential Difference and Resistance

1.13 Basic Electrical Measuring Instruments

1.14 Linear and Nonlinear Devices

1.15 Ohm’s Law

1.16 Multiples and Submultiples

1.17 Conductors and Insulators

1.18 Electrical Power and Energy

1.19 Main effects of electric current

Chapter 2. Resistance and Resistivity

2.1 Resistance and Resistivity

2.2 Temperature Coefficient of Resistance

Chapter 3. Series and Parallel Networks

3.1 Series Circuits

3.2 Potential Divider

3.3 Parallel Networks

3.4 Current Division

3.5 Relative and Absolute Voltages

Chapter 4. Capacitors and Inductors

4.1 Introduction to Capacitors

4.2 Electrostatic Field

4.3 Electric Field Strength

4.4 Capacitance

4.5 Capacitors

4.6 Electric Flux Density

4.7 Permittivity

4.8 The Parallel Plate Capacitor

4.9 Capacitors Connected in Parallel and Series

4.10 Dielectric Strength

4.11 Energy Stored

4.12 Practical Types of Capacitors

4.13 Inductance

4.14 Inductors

4.15 Energy Stored

Chapter 5. DC Circuit Theory

5.1 Introduction

5.2 Kirchhoff’s Laws

5.3 The superposition Theorem

5.4 General DC Circuit Theory

5.5 Thévenin’s Theorem

5.6 Constant-Current Source

5.7 Norton’s Theorem

5.8 Thévenin and Norton Equivalent Networks

5.9 Maximum Power Transfer Theorem

Chapter 6. Alternating Voltages and Currents

6.1 The AC Generator

6.2 Waveforms

6.3 AC Values

6.4 The Equation of a Sinusoidal Waveform

6.5 Combination of Waveforms

6.6 Rectification

Chapter 7. Complex Numbers

7.1 Introduction

7.2 Operations Involving Cartesian Complex Numbers

7.3 Complex Equations

7.4 The Polar Form of a Complex Number

7.5 Applying Complex Numbers to Series AC Circuits

7.6 Applying Complex Numbers to Parallel AC Circuits

Chapter 8. Transients and Laplace Transforms

8.1 Introduction

8.2 Response of R-C Series Circuit to a Step Input

8.3 Response of R-L Series Circuit to a Step Input

8.4 L-R-C Series Circuit Response

8.5 Introduction to Laplace Transforms

8.6 Inverse Laplace Transforms and the Solution of Differential Equations

Chapter 9. Frequency Domain Circuit Analysis

9.1 Introduction

9.2 Sinusoidal AC Electrical Analysis

9.3 Generalized Frequency Domain Analysis

9.3.4 Linear Distortion

References

Chapter 10. Digital Electronics

10.1 Semiconductors

10.3 Bipolar Junction Transistors

10.4 Metal-Oxide Semiconductor Field-Effect Transistors

10.5 The Transistor as a Switch

10.6 Gallium Arsenide Semiconductors

10.7 Light-Emitting Diodes

10.8 BUF and NOT Functions

10.9 AND, OR, and XOR Functions

10.10 NAND, NOR, and XNOR Functions

10.11 Not a Lot

10.12 Functions Versus Gates

10.13 Not and BUF Gates

10.14 Nand and AND Gates

10.15 NOR and OR Gates

10.16 XNOR and XOR Gates

10.17 Pass-Transistor Logic

10.17.1 Boolean Algebra

10.18 Combining a Single Variable With Logic 0 or Logic 1

10.19 The Idempotent Rules

10.20 The Complementary Rules

10.21 The Involution Rules

10.22 The Commutative Rules

10.23 The Associative Rules

10.24 Precedence of Operators

10.25 The First Distributive Rule

10.26 The Second Distributive Rule

10.27 The Simplification Rules

10.28 DeMorgan Transformations

10.29 Minterms and Maxterms

10.30 Sum-of-Products and Product-of-Sums

10.31 Canonical Forms

10.32 Karnaugh Maps

10.33 Minimization Using Karnaugh Maps

10.34 Grouping Minterms

10.35 Incompletely Specified Functions

10.36 Populating Maps Using 0s Versus 1s

10.37 Scalar Versus Vector Notation

10.38 Equality Comparators

10.39 Multiplexers

10.41 Tri-State Functions

10.42 Combinational Versus Sequential Functions

10.43 RS Latches

10.44 D-Type Latches

10.45 D-Type Flip-Flops

10.46 JK and T Flip-Flops

10.47 Shift Registers

10.48 Counters

10.49 Setup and Hold Times

10.50 Brick by Brick

10.51 State Diagrams

10.52 State Tables

10.53 State Machines

10.54 State Assignment

10.55 Don’t Care States, Unused States, and Latch-Up Conditions

Chapter 11. Analog Electronics

11.1 Operational Amplifiers Defined

11.2 Symbols and Connections

11.3 Operational Amplifier Parameters

11.4 Operational Amplifier Characteristics

11.5 Operational Amplifier Applications

11.6 Gain and Bandwidth

11.7 Inverting Amplifier With Feedback

11.8 Operational amplifier configurations

11.9 Operational Amplifier Circuits

11.10 The Ideal Op-Amp

11.11 The Practical Op-Amp

11.12 Comparators

11.13 Voltage References

Chapter 12. Circuit Simulation

12.1 Types of Analysis

12.2 Netlists and Component Models

12.3 Logic Simulation

Chapter 13. Interfacing

13.1 Mixing Analog and Digital

13.2 Generating Digital Levels From Analog Inputs

13.3 Classic Data Interface Standards

13.4 High Performance Data Interface Standards

Chapter 14. Microcontrollers and Microprocessors

14.1 Microprocessor Systems

14.2 Single-Chip Microcomputers

14.3 Microcontrollers

14.4 PIC Microcontrollers

14.5 Programmed Logic Devices

14.6 Programmable Logic Controllers

14.7 Microprocessor Systems

14.8 Data Representation

14.9 Data Types

14.10 Data Storage

14.11 The Microprocessor

14.12 Microprocessor Operation

14.13 A Microcontroller System

14.14 Symbols Introduced in this Chapter

Chapter 15. Power Electronics

15.1 Switchgear

15.3 Conductors

15.4 Capacitors

15.5 Resistors

15.6 Fuses

15.7 Supply Voltages

15.8 Enclosures

15.9 Hipot, Corona, and BIL

15.10 Spacings

15.11 Metal Oxide Varistors

15.12 Protective Relays

15.13 Symmetrical Components

15.14 Per Unit Constants

15.15 Circuit Simulation

15.15.1 Circuit Simulation Notes

15.16 Simulation Software

15.17 Feedback Control Systems

15.18 Power Supplies

Chapter 16. Signals and Signal Processing

16.1 Origins of Real-World Signals and their Units of Measurement

16.2 Reasons for Processing Real-World Signals

16.3 Generation of Real-World Signals

16.4 Methods and Technologies Available for Processing Real-World Signals

16.5 Analog Versus Digital Signal Processing

16.6 A Practical Example

Uncited References

References

Chapter 17. Filter Design

17.1 Introduction

17.2 Passive Filters

17.3 Active Filters

17.4 First-Order Filters

17.5 Design of First-Order Filters

17.6 Second-Order Filters

17.7 Using the Transfer Function

17.8 Using Normalized Tables

17.9 Using Identical Components

17.10 Second-Order High-Pass Filters

17.11 Bandpass Filters

17.12 Switched Capacitor Filter

17.13 Monolithic Switched Capacitor Filter

17.14 The Notch Filter

17.15 Choosing Components for Filters

17.16 Testing Filter Response

17.17 Fast Fourier Transforms

17.18 Digital Filters

References

Chapter 18. Control and Instrumentation Systems

18.1 Introduction

18.2 Systems

18.3 Control Systems Models

18.4 Measurement Elements

18.5 Signal Processing

18.6 Correction Elements

18.7 Control Systems

18.8 System Models

18.9 Gain

18.10 Dynamic Systems

18.11 Differential Equations

18.12 Transfer Function

18.13 System Transfer Functions

18.14 Sensitivity

18.15 Block Manipulation

18.16 Multiple Inputs

Chapter 19. Communications Systems

19.1 Introduction

19.2 Analog Modulation Techniques

19.3 The Balanced Modulator/Demodulator

19.4 Frequency Modulation and Demodulation

19.5 FM Modulators

19.6 FM Demodulators

19.7 Digital Modulation Techniques

19.8 Information Theory

19.9 Applications and Technologies

Reference

Chapter 20. Principles of Electromagnetics

20.1 The Need for Electromagnetics

20.2 The Electromagnetic Spectrum

20.3 Electrical Length

20.4 The Finite Speed of Light

20.5 Electronics

20.6 Analog and Digital Signals

20.7 RF Techniques

20.8 Microwave Techniques

20.9 Infrared and the Electronic Speed Limit

20.10 Visible Light and Beyond

20.11 Lasers and Photonics

20.12 Summary of General Principles

20.13 The Electric Force Field

20.14 Other Types of Fields

20.15 Voltage and Potential Energy

20.16 Charges in Metals

20.17 The Definition of Resistance

20.18 Electrons and Holes

20.19 Electrostatic Induction and Capacitance

20.20 Insulators (dielectrics)

20.21 Static Electricity and Lightning

20.22 The Battery Revisited

20.23 Electric Field Examples

20.24 Conductivity and Permittivity of Common Materials

References

Chapter 21. Magnetic Fields

21.1 Moving Charges: Source of All Magnetic Fields

21.2 Magnetic Dipoles

21.3 Effects of the Magnetic Field

21.4 The Vector Magnetic Potential and Potential Momentum

21.5 Magnetic Materials

21.6 Magnetism and Quantum Physics

References

Chapter 22. Electromagnetic Transients and EMI

22.1 Line Disturbances

22.2 Circuit Transients

22.3 Electromagnetic Interference

Chapter 23. Traveling Wave Effects

23.1 Basics

23.2 Transient Effects

23.3 Mitigating Measures

Chapter 24. Transformers

24.1 Voltage and Turns Ratio

Chapter 25. Electromagnetic Compatibility (EMC)

25.1 Introduction

25.2 Common Terms

25.3 The EMC Model

25.4 EMC Requirements

25.5 Product design

25.6 Device Selection

25.7 Printed Circuit Boards

25.8 Interfaces

25.9 Power Supplies and Power-Line Filters

25.10 Signal Line Filters

25.11 Enclosure Design

25.12 Interface Cable Connections

25.13 Golden Rules for Effective Design for EMC

25.14 System Design

25.15 Buildings

25.16 Conformity Assessment

25.17 EMC Testing and Measurements

25.18 Management Plans

References

Appendix A. General Reference

Appendix B.

B.1 Differential Equations

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