Description

Book Synopsis
Tough Test Questions? Missed Lectures? Not Enough Time?


Fortunately, thereâs Schaumâs. 


More than 40 million students have trusted Schaumâs to help them succeed in the classroom and on exams. Schaumâs is the key to faster learning and higher grades in every subject. Each Outline presents all the essential course information in an easy-to-follow, topic-by-topic format. You also get hundreds of examples, sovled problems, and practice exercises to test your skills. 


This Schaumâs Outline gives you:


â Hundreds of supplementary problems to reinforce knowledge
â Concise exaplanations of all electromagentic concepts
â Information on current density, capacitance, magnetic fields, inductance, electromagnetic waves, transmission lines, and antennas
â New section on transmission line parameters
â New section illustrating the use of admit

Table of Contents
Preface
Contents
Chapter 1 The Subject of Electromagnetics
1.1 Historical Background
1.2 Objectives of the Chapter
1.3 Electric Charge
1.4 Units
1.5 Vectors
1.6 Electrical Force, Field, Flux, and Potential
1.7 Magnetic Force, Field, Flux, and Potential
1.8 Electromagnetic Induction
1.9 Mathematical Operators and Identities
1.10 Maxwell’s Equations
1.11 Electromagnetic Waves
1.12 Trajectory of a Sinusoidal Motion in Two Dimensions
1.13 Wave Polarization
1.14 Electromagnetic Spectrum
1.15 Transmission Lines
Chapter 2 Vector Analysis
2.1 Introduction
2.2 Vector Notation
2.3 Vector Functions
2.4 Vector Algebra
2.5 Coordinate Systems
2.6 Differential Volume, Surface, and Line Elements
Chapter 3 Electric Field
3.1 Introduction
3.2 Coulomb’s Law in Vector Form
3.3 Superposition
3.4 Electric Field Intensity
3.5 Charge Distributions
3.6 Standard Charge Configurations
Chapter 4 Electric Flux
4.1 Net Charge in a Region
4.2 Electric Flux and Flux Density
4.3 Gauss’s Law
4.4 Relation between Flux Density and Electric Field Intensity
4.5 Special Gaussian Surfaces
Chapter 5 Gradient, Divergence, Curl, and Laplacian
5.1 Introduction
5.2 Gradient
5.3 The Del Operator
5.4 The Del Operator and Gradient
5.5 Divergence
5.6 Expressions for Divergence in Coordinate Systems
5.7 The Del Operator and Divergence
5.8 Divergence of D
5.9 The Divergence Theorem
5.10 Curl
5.11 Laplacian
5.12 Summary of Vector Operations
Chapter 6 Electrostatics: Work, Energy, and Potential
6.1 Work Done in Moving a Point Charge
6.2 Conservative Property of the Electrostatic Field
6.3 Electric Potential between Two Points
6.4 Potential of a Point Charge
6.5 Potential of a Charge Distribution
6.6 Relationship between E and V
6.7 Energy in Static Electric Fields
Chapter 7 Electric Current
7.1 Introduction
7.2 Charges in Motion
7.3 Convection Current Density J
7.4 Conduction Current Density J
7.5 Conductivity σ
7.6 Current I
7.7 Resistance R
7.8 Current Sheet Density K
7.9 Continuity of Current
7.10 Conductor-Dielectric Boundary Conditions
Chapter 8 Capacitance and Dielectric Materials
8.1 Polarization P and Relative Permittivity εr
8.2 Capacitance
8.3 Multiple-Dielectric Capacitors
8.4 Energy Stored in a Capacitor
8.5 Fixed-Voltage D and E
8.6 Fixed-Charge D and E
8.7 Boundary Conditions at the Interface of Two Dielectrics
8.8 Method of Images
Chapter 9 Laplace’s Equation
9.1 Introduction
9.2 Poisson’s Equation and Laplace’s Equation
9.3 Explicit Forms of Laplace’s Equation
9.4 Uniqueness Theorem
9.5 Mean Value and Maximum Value Theorems
9.6 Cartesian Solution in One Variable
9.7 Cartesian Product Solution
9.8 Cylindrical Product Solution
9.9 Spherical Product Solution
Chapter 10 Magnetic Field and Boundary Conditions
10.1 Introduction
10.2 Biot-Savart Law
10.3 Ampère’s Law
10.4 Relationship of J and H
10.5 Magnetic Flux Density B
10.6 Boundary Relations for Magnetic Fields
10.7 Current Sheet at the Boundary
10.8 Summary of Boundary Conditions
10.9 Vector Magnetic Potential A
10.10 Stokes’ Theorem
Chapter 11 Forces and Torques in Magnetic Fields
11.1 Magnetic Force on Particles
11.2 Electric and Magnetic Fields Combined
11.3 Magnetic Force on a Current Element
11.4 Work and Power
11.5 Torque
11.6 Magnetic Moment of a Planar Coil
Chapter 12 Inductance and Magnetic Circuits
12.1 Inductance
12.2 Standard Conductor Configurations
12.3 Faraday’s Law and Self-Inductance
12.4 Internal Inductance
12.5 Mutual Inductance
12.6 Magnetic Circuits
12.7 The B-H Curve
12.8 Ampère’s Law for Magnetic Circuits
12.9 Cores with Air Gaps
12.10 Multiple Coils
12.11 Parallel Magnetic Circuits
Chapter 13 Time-Varying Fields and Maxwell’s Equations
13.1 Introduction
13.2 Maxwell’s Equations for Static Fields
13.3 Faraday’s Law and Lenz’s Law
13.4 Conductors’ Motion in Time-Independent Fields
13.5 Conductors’ Motion in Time-Dependent Fields
13.6 Displacement Current
13.7 Ratio of Jcto JD
13.8 Maxwell’s Equations for Time-Varying Fields
Chapter 14 Electromagnetic Waves
14.1 Introduction
14.2 Wave Equations
14.3 Solutions in Cartesian Coordinates
14.4 Plane Waves
14.5 Solutions for Partially Conducting Media
14.6 Solutions for Perfect Dielectrics
14.7 Solutions for Good Conductors; Skin Depth
14.8 Interface Conditions at Normal Incidence
14.9 Oblique Incidence and Snell’s Laws
14.10 Perpendicular Polarization
14.11 Parallel Polarization
14.12 Standing Waves
14.13 Power and the Poynting Vector
Chapter 15 Transmission Lines
15.1 Introduction
15.2 Distributed Parameters
15.3 Incremental Models
15.4 Transmission Line Equation
15.5 Impedance, Admittance, and Other Features of Interest
15.6 Sinusoidal Steady-State Excitation
15.7 Lossless Lines
15.8 The Smith Chart
15.9 Admittance Plane
15.10 Quarter-Wave Transformer
15.11 Impedance Matching
15.12 Single-Stub Matching
15.13 Double-Stub Matching
15.14 Impedance Measurement
15.15 Transients in Lossless Lines
Chapter 16 Waveguides
16.1 Introduction
16.2 Transverse and Axial Fields
16.3 TE and TM Modes; Wave Impedances
16.4 Determination of the Axial Fields
16.5 Mode Cutoff Frequencies
16.6 Dominant Mode
16.7 Power Transmitted in a Lossless Waveguide
16.8 Power Dissipation in a Lossy Waveguide
Chapter 17 Antennas
17.1 Introduction
17.2 Current Source and the E and H Fields
17.3 Electric (Hertzian) Dipole Antenna
17.4 Antenna Parameters
17.5 Small Circular-Loop Antenna
17.6 Finite-Length Dipole
17.7 Monopole Antenna
17.8 Self- and Mutual Impedances
17.9 The Receiving Antenna
17.10 Linear Arrays
17.11 Reflectors
Chapter 18 Propagation of Electromagnetic Waves in the Atmosphere
18.1 Introduction and Summary
18.2 Plane Waves in Homogeneous Media
18.3 Propagation Parameters
18.4 Complex Dielectric Constant
18.5 Power Equation
18.6 Refraction
18.7 Reflection, Diffraction, and Scattering
18.8 The Atmosphere
18.9 Atmospheric Effects on Propagation of Radio Waves
18.10 Attenuation by Gaseous Absorption
18.11 Attenuation by Hydrometeors
18.12 Ground and Sky Waves
18.13 Models of the Troposphere
18.14 Tropospheric Refractivity
18.15 Tropospheric Excess Delay
18.16 Bending Effect of Tropospheric Refraction
18.17 Conductivity, Permittivity, and Refraction Index of the Ionosphere
18.18 Satellite Microwave Ranging
18.19 Ionospheric Range Error
18.20 Tropospheric Range Error
Appendix
Index
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    Description

    Book Synopsis
    Tough Test Questions? Missed Lectures? Not Enough Time?


    Fortunately, thereâs Schaumâs. 


    More than 40 million students have trusted Schaumâs to help them succeed in the classroom and on exams. Schaumâs is the key to faster learning and higher grades in every subject. Each Outline presents all the essential course information in an easy-to-follow, topic-by-topic format. You also get hundreds of examples, sovled problems, and practice exercises to test your skills. 


    This Schaumâs Outline gives you:


    â Hundreds of supplementary problems to reinforce knowledge
    â Concise exaplanations of all electromagentic concepts
    â Information on current density, capacitance, magnetic fields, inductance, electromagnetic waves, transmission lines, and antennas
    â New section on transmission line parameters
    â New section illustrating the use of admit

    Table of Contents
    Preface
    Contents
    Chapter 1 The Subject of Electromagnetics
    1.1 Historical Background
    1.2 Objectives of the Chapter
    1.3 Electric Charge
    1.4 Units
    1.5 Vectors
    1.6 Electrical Force, Field, Flux, and Potential
    1.7 Magnetic Force, Field, Flux, and Potential
    1.8 Electromagnetic Induction
    1.9 Mathematical Operators and Identities
    1.10 Maxwell’s Equations
    1.11 Electromagnetic Waves
    1.12 Trajectory of a Sinusoidal Motion in Two Dimensions
    1.13 Wave Polarization
    1.14 Electromagnetic Spectrum
    1.15 Transmission Lines
    Chapter 2 Vector Analysis
    2.1 Introduction
    2.2 Vector Notation
    2.3 Vector Functions
    2.4 Vector Algebra
    2.5 Coordinate Systems
    2.6 Differential Volume, Surface, and Line Elements
    Chapter 3 Electric Field
    3.1 Introduction
    3.2 Coulomb’s Law in Vector Form
    3.3 Superposition
    3.4 Electric Field Intensity
    3.5 Charge Distributions
    3.6 Standard Charge Configurations
    Chapter 4 Electric Flux
    4.1 Net Charge in a Region
    4.2 Electric Flux and Flux Density
    4.3 Gauss’s Law
    4.4 Relation between Flux Density and Electric Field Intensity
    4.5 Special Gaussian Surfaces
    Chapter 5 Gradient, Divergence, Curl, and Laplacian
    5.1 Introduction
    5.2 Gradient
    5.3 The Del Operator
    5.4 The Del Operator and Gradient
    5.5 Divergence
    5.6 Expressions for Divergence in Coordinate Systems
    5.7 The Del Operator and Divergence
    5.8 Divergence of D
    5.9 The Divergence Theorem
    5.10 Curl
    5.11 Laplacian
    5.12 Summary of Vector Operations
    Chapter 6 Electrostatics: Work, Energy, and Potential
    6.1 Work Done in Moving a Point Charge
    6.2 Conservative Property of the Electrostatic Field
    6.3 Electric Potential between Two Points
    6.4 Potential of a Point Charge
    6.5 Potential of a Charge Distribution
    6.6 Relationship between E and V
    6.7 Energy in Static Electric Fields
    Chapter 7 Electric Current
    7.1 Introduction
    7.2 Charges in Motion
    7.3 Convection Current Density J
    7.4 Conduction Current Density J
    7.5 Conductivity σ
    7.6 Current I
    7.7 Resistance R
    7.8 Current Sheet Density K
    7.9 Continuity of Current
    7.10 Conductor-Dielectric Boundary Conditions
    Chapter 8 Capacitance and Dielectric Materials
    8.1 Polarization P and Relative Permittivity εr
    8.2 Capacitance
    8.3 Multiple-Dielectric Capacitors
    8.4 Energy Stored in a Capacitor
    8.5 Fixed-Voltage D and E
    8.6 Fixed-Charge D and E
    8.7 Boundary Conditions at the Interface of Two Dielectrics
    8.8 Method of Images
    Chapter 9 Laplace’s Equation
    9.1 Introduction
    9.2 Poisson’s Equation and Laplace’s Equation
    9.3 Explicit Forms of Laplace’s Equation
    9.4 Uniqueness Theorem
    9.5 Mean Value and Maximum Value Theorems
    9.6 Cartesian Solution in One Variable
    9.7 Cartesian Product Solution
    9.8 Cylindrical Product Solution
    9.9 Spherical Product Solution
    Chapter 10 Magnetic Field and Boundary Conditions
    10.1 Introduction
    10.2 Biot-Savart Law
    10.3 Ampère’s Law
    10.4 Relationship of J and H
    10.5 Magnetic Flux Density B
    10.6 Boundary Relations for Magnetic Fields
    10.7 Current Sheet at the Boundary
    10.8 Summary of Boundary Conditions
    10.9 Vector Magnetic Potential A
    10.10 Stokes’ Theorem
    Chapter 11 Forces and Torques in Magnetic Fields
    11.1 Magnetic Force on Particles
    11.2 Electric and Magnetic Fields Combined
    11.3 Magnetic Force on a Current Element
    11.4 Work and Power
    11.5 Torque
    11.6 Magnetic Moment of a Planar Coil
    Chapter 12 Inductance and Magnetic Circuits
    12.1 Inductance
    12.2 Standard Conductor Configurations
    12.3 Faraday’s Law and Self-Inductance
    12.4 Internal Inductance
    12.5 Mutual Inductance
    12.6 Magnetic Circuits
    12.7 The B-H Curve
    12.8 Ampère’s Law for Magnetic Circuits
    12.9 Cores with Air Gaps
    12.10 Multiple Coils
    12.11 Parallel Magnetic Circuits
    Chapter 13 Time-Varying Fields and Maxwell’s Equations
    13.1 Introduction
    13.2 Maxwell’s Equations for Static Fields
    13.3 Faraday’s Law and Lenz’s Law
    13.4 Conductors’ Motion in Time-Independent Fields
    13.5 Conductors’ Motion in Time-Dependent Fields
    13.6 Displacement Current
    13.7 Ratio of Jcto JD
    13.8 Maxwell’s Equations for Time-Varying Fields
    Chapter 14 Electromagnetic Waves
    14.1 Introduction
    14.2 Wave Equations
    14.3 Solutions in Cartesian Coordinates
    14.4 Plane Waves
    14.5 Solutions for Partially Conducting Media
    14.6 Solutions for Perfect Dielectrics
    14.7 Solutions for Good Conductors; Skin Depth
    14.8 Interface Conditions at Normal Incidence
    14.9 Oblique Incidence and Snell’s Laws
    14.10 Perpendicular Polarization
    14.11 Parallel Polarization
    14.12 Standing Waves
    14.13 Power and the Poynting Vector
    Chapter 15 Transmission Lines
    15.1 Introduction
    15.2 Distributed Parameters
    15.3 Incremental Models
    15.4 Transmission Line Equation
    15.5 Impedance, Admittance, and Other Features of Interest
    15.6 Sinusoidal Steady-State Excitation
    15.7 Lossless Lines
    15.8 The Smith Chart
    15.9 Admittance Plane
    15.10 Quarter-Wave Transformer
    15.11 Impedance Matching
    15.12 Single-Stub Matching
    15.13 Double-Stub Matching
    15.14 Impedance Measurement
    15.15 Transients in Lossless Lines
    Chapter 16 Waveguides
    16.1 Introduction
    16.2 Transverse and Axial Fields
    16.3 TE and TM Modes; Wave Impedances
    16.4 Determination of the Axial Fields
    16.5 Mode Cutoff Frequencies
    16.6 Dominant Mode
    16.7 Power Transmitted in a Lossless Waveguide
    16.8 Power Dissipation in a Lossy Waveguide
    Chapter 17 Antennas
    17.1 Introduction
    17.2 Current Source and the E and H Fields
    17.3 Electric (Hertzian) Dipole Antenna
    17.4 Antenna Parameters
    17.5 Small Circular-Loop Antenna
    17.6 Finite-Length Dipole
    17.7 Monopole Antenna
    17.8 Self- and Mutual Impedances
    17.9 The Receiving Antenna
    17.10 Linear Arrays
    17.11 Reflectors
    Chapter 18 Propagation of Electromagnetic Waves in the Atmosphere
    18.1 Introduction and Summary
    18.2 Plane Waves in Homogeneous Media
    18.3 Propagation Parameters
    18.4 Complex Dielectric Constant
    18.5 Power Equation
    18.6 Refraction
    18.7 Reflection, Diffraction, and Scattering
    18.8 The Atmosphere
    18.9 Atmospheric Effects on Propagation of Radio Waves
    18.10 Attenuation by Gaseous Absorption
    18.11 Attenuation by Hydrometeors
    18.12 Ground and Sky Waves
    18.13 Models of the Troposphere
    18.14 Tropospheric Refractivity
    18.15 Tropospheric Excess Delay
    18.16 Bending Effect of Tropospheric Refraction
    18.17 Conductivity, Permittivity, and Refraction Index of the Ionosphere
    18.18 Satellite Microwave Ranging
    18.19 Ionospheric Range Error
    18.20 Tropospheric Range Error
    Appendix
    Index
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