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Electromagnetic Foundations of Electrical Engineering by Prof. Brandão Faria

5 Junho 2008, 18:36 - Pedro Flores Correia

DEEC congratulates Prof. Brandão Faria, DEEC faculty, and researcher of the Cie3, for the 1st edition of his book titled "Electromagnetic Foundations of Electrical Engineering", edited by Wiley.


About the Author
J A. Brandão Faria received his PhD degree and aggregate title in electrical engineering from the Instituto Superior Técnico of the Technical University of Lisbon, where, since 1994, he has been a Full Professor of Electrical Engineering teaching undergraduate and graduate courses in electromagnetics. His teaching activities also include lecturing courses at the Portuguese Air Force Academy.

Professor Brandão Faria was a senior scientist with the former Centro de Electrotecnia Teórica e Medidas Eléctricas where he served as President from 1994 until 2000. Since 2008, he has been at the recently created CIEEE (Center for Innovation in Electrical Engineering and Energy).

Professor Brandão Faria was the recipient of two Honorable Mentions awarded in 1994 and 2007 by the Portuguese State Department of Science and Technology, and by the Technical University of Lisbon, respectively.

His areas of interest include electromagnetic-field problems, power lines, and wave propagation phenomena in multiconductor transmission lines. He is the author of two books on electrical engineering subjects, namely Optica and Multiconductor Transmission-Line Structures, and has published over 100 technical papers.

Professor Brandão Faria is a member of the Editorial Board of the European Transactions on Electrical Power (John Wiley & Sons, Ltd), and a senior member of the IEEE.

For more details follow the author's website link at https://fenix.ist.utl.pt:443/homepage/ist11545


Book Cover

ELECTROMAGNETIC FOUNDATIONS OF ELECTRICAL ENGINEERING

CONTENTS

About the Author

PREFACE
For Electrical Engineer Practitioner
For Students i
For Instructors

ACKNOWLEDGEMENTS

PROJECT PORTFOLIO
P01 - Analysis of a power delivery system
P02 - Cylindrical type transmission lines
P03 - DC transducer
P04 - Determination of the conductivity of a circular conducting disk
P05 - Directional coupler analysis
P06 - Ill-defined grounding problems
P07 - Induction machine analysis
P08 - Line matching technique using an exponential transmission-line section
P09 - Linear variable differential transformer
P10 - Magnetic actuator and sensor device
P11 - Overhead-line protection by ground wires
P12 - Power line carrier communication
P13 - Pseudo-balanced three-phase lines
P14 - Screened high-voltage three-phase installation
P15 - Shielded three-phase cable analysis
P16 - Three-route microwave splitter
P17 - Transmission-line system with balun transformer for even to odd-mode conversion
P18 - Transmission-line system with transformer-stage matching
P19 - Two-way loudspeaker analysis
P20 - Variable reluctance transformer

PART I - A BRIEF OVERVIEW
INTRODUCTION

CHAPTER 1 - BASIC FIELD VECTORS
1.1 - The Electric and Magnetic Field Vectors
1.2 - Constitutive Relations
1.3 - Units and Notation
1.4 - Fundamental Concepts of Voltage and Current Intensity

PART II - STATIONARY FIELD PHENOMENA
INTRODUCTION

CHAPTER 2 - ELECTROSTATICS
2.1 - Fundamental Equations
2.2 - Gradient Electric Field, Electric Potential, Voltage, Kirchhoff's Voltage Law
2.3 - Electric Charge, Electric Displacement Vector
2.4 - Dielectric Media, Permittivity, Polarization, Dielectric Strength
2.5 - Conductors in Electrostatic Equilibrium
2.6 - Application Example (Filament of charge)
2.7 - Capacitor, Capacitance, Electric Energy
2.8 - Application Example (Two-wire transmission line)
2.9 - Multiple Conductor Systems
2.9.1 - Capacitance Matrix
2.9.2 - Partial Capacitances Scheme
2.10 - Application Example (Electric coupling in printed circuit boards)
2.11 - Electric Forces and Torques
2.12 - Proposed Homework Problems

CHAPTER 3 - STATIONARY CURRENTS
3.1 - Fundamental Equations
3.2 - Conductivity, Current Density, Electric Circuits
3.3 - Current Intensity, Kirchhoff's Current Law
3.4 - Resistor, Conductance, Resistance, Ohm's Law
3.5 - Application Example (The potentiometer)
3.6 - Application Example (The Wheatstone bridge)
3.7 - Joule Losses, Generator Applied Field
3.8 - Generator Electromotive Force, Power Balance
3.9 - Proposed Homework Problems

CHAPTER 4 - MAGNETIC FIELD OF STATIONARY CURRENTS
4.1 - Fundamental Equations
4.2 - Ampère's Law, Magnetomotive Force, Magnetic Voltage
4.3 - Magnetic Induction Field, Magnetic Induction Flux
4.4 - Application Example (Power line magnetic fields)
4.5 - Magnetic Materials, Ferromagnetic Media, Saturation and Hysteresis
4.6 - Magnetic Circuits
4.7 - Application Example (Three-legged transformer)
4.8 - Magnetic Reluctance
4.9 - Inductor, Inductance, Magnetic Flux Linkage, Magnetic Energy
4.10 - Application Example (Coaxial cable)
4.11 - Hysteresis Losses
4.12 - Multiple Circuit Systems
4.13 - Magnetic Forces and Torques
4.14 - Application Example (U-shaped electromagnet)
4.15 - Proposed Homework Problems

PART III - SLOW TIME-VARYING FIELDS
INTRODUCTION

CHAPTER 5 - MAGNETIC INDUCTION PHENOMENA
5.1 - Fundamental Equations
5.2 - Gradient and Induction Electric Fields, Potential Vector
5.3 - Revisiting the Voltage Concept
5.4 - Induction Law
5.5 - Application Example (Magnetic noise effects)
5.6 - Voltages and Currents in Magnetically Multicoupled Systems
5.7 - Application Example (Magnetic coupling in printed circuit boards)
5.8 - Eddy Currents
5.9 - Generalization of the Induction Law to Moving Circuit Systems
5.10 - Application Example (Electromechanical energy conversion)
5.11 - DC Voltage Generation
5.12 - AC Voltage Generation
5.13 - Proposed Homework Problems

CHAPTER 6 - ELECTRIC INDUCTION PHENOMENA
6.1 - Fundamental Equations
6.2 - Displacement Current, Generalized Ampère's Law
6.3 - Charge Continuity Equation
6.4 - Revisiting the Current Intensity Concept
6.5 - Application Example (Capacitor self-discharge)
6.6 - Voltages and Currents in Electrically Multicoupled Systems
6.7 - Proposed Homework Problems

CHAPTER 7 - LUMPED PARAMETERS CIRCUIT ANALYSIS
7.1 - Introduction
7.2 - Steady-State Harmonic Regimes
7.2.1 - Characterization of Sinusoidal Quantities
7.2.2 - Complex Amplitudes or Phasors
7.2.3 - Application Example (RLC circuit)
7.2.4 - Instantaneous Power, Active Power, Power Balance Equation
7.2.5 - Complex Power, Complex Poynting's Theorem
7.2.6 - Impedance and Admittance Operators
7.2.7 - Resonance
7.2.8 - Application Example (RL//C circuit)
7.3 - Transformer Analysis
7.3.1 - The Ideal Transformer
7.3.2 - Transformer Impedance, Pseudo Lenz's Law
7.3.3 - Equivalent Circuits
7.3.4 - Application Example (Capacitively loaded transformer)
7.4 - Transient Regimes
7.4.1 - Free-Regime and Steady-State Solutions
7.4.2 - Initial Conditions
7.4.3 - Analysis of the Capacitor Charging Process
7.4.4 - Connecting an Inductive Load to an AC Generator
7.4.5 - Disconnecting an Inductive Load
7.4.6 - Application Example (Switching off a transformer protected by a capacitor)
7.5 - Proposed Homework Problems

PART IV - RAPID TIME-VARYING FIELDS
INTRODUCTION

CHAPTER 8 - ELECTROMAGNETIC FIELD PHENOMENA
8.1 - Electromagnetic Waves
8.2 - Poynting's Theorem, Poynting's Vector, Power Flow
8.3 - Time-Harmonic Fields, Field Polarization, RMS Field Values
8.4 - Phasor-Domain Maxwell Equations, Material Media Constitutive Relations
8.5 - Application Example (Uniform plane waves)
8.6 - Complex Poynting's Vector
8.7 - Application Example (Skin effect)
8.8 - Proposed Homework Problems

CHAPTER 9 - TRANSMISSION LINE ANALYSIS
9.1 - Introduction
9.2 - Time-Domain Transmission-Line Equations for Lossless Lines
9.2.1 - Wave Parameters, Propagation Velocity, Characteristic Wave Resistance
9.2.2 - Pulse Propagation, Pulse Reflection
9.3 - Application Example (Parallel-plate transmission line)
9.4 - Frequency-Domain Transmission-Line Equations for Lossy Lines
9.4.1 - Per-Unit-Length Longitudinal Impedance, Per-Unit-Length Transverse Admittance
9.4.2 - Propagation Constant, Phase Velocity, Characteristic Wave Impedance
9.4.3 - Transfer Matrix, Nonuniform Line Analysis
9.5 - Frequency-Domain Transmission-Line Equations for Lossless Lines
9.5.1 - Terminated Line, Load Reflection Coefficient, Line Input Impedance
9.5.2 - Matched Line, Open Line, Short-Circuited Line
9.5.3 - Standing-Wave Pattern, Standing Wave Ratio, Active Power
9.5.4 - The Low-Frequency Limit Case, Short Lines
9.6 - Application Example (Line matching techniques)
9.7 - Multiconductor Transmission Lines
9.8 - Application Example (Even and odd modes)
9.9 - Proposed Homework Problems

APPENDICES
Appendix 1 - Formulas from Vector Analysis
Appendix 2 - Lorentz Transformation
Appendix 3 - Elements of Complex Algebra
Appendix 4 - Elements of Fourier Analysis

BIBLIOGRAPHY