Contents

  • PREFACE
  • To the Electrical Engineer Practitioner
  • To the Student
  • To the Instructor
  • PROJECT PORTFOLIO
  • P01 - Analysis of a power delivery system
  • P02 - Cylindrical type transmission lines
  • P03 - DC current 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed 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 - Homework Proposed Problems