Schaum’s Outline of Electromagnetics, Third Edition
by: Joseph Edminister
Abstract: Modified to conform to the current curriculum, Schaum’s Outline of Electromagnetics complements these courses in scope and sequence to help you understand its basic concepts. The book offers extra practice on topics such as current density, capacitance, magnetic fields, inductance, electromagnetic waves, transmission lines, and antennas. Features 351 solved problems and support for all the major textbooks for electromagnetics courses. Topics include: Vector Analysis, Coulomb Forces and Electric Field Intensity , Electric Flux and Gauss’ Law, Divergence and the Divergence Theorem, The Electrostatic Field: Work, Energy, and Potential, Current, Current Density, and Conductors, Capacitance and Dielectric Materials, Laplace’s Equation, Ampere’s Law and the Magnetic Field, Forces and Torques in Magnetic Fields, Inductance and Magnetic Circuits, Displacement Current and Induced EMF, Maxwell’s Equations and Boundary Conditions, Electromagnetic Waves, Transmission Lines, Waveguides, Antennas.
Full details
Table of Contents
- A. Preface
- 1. The Subject of Electromagnetics
- 2. Vector Analysis
- 3. Electric Field
- 4. Electric Flux
- 5. Gradient, Divergence, Curl, and Laplacian
- 6. Electrostatics: Work, Energy, and Potential
- 7. Electric Current
- 8. Capacitance and Dielectric Materials
- 9. Laplace’s Equation
- 10. Magnetic Field and Boundary Conditions
- 11. Forces and Torques in Magnetic Fields
- 12. Inductance and Magnetic Circuits
- 13. Time-Varying Fields and Maxwell’s Equations
- 14. Electromagnetic Waves
- 15. Transmission Lines
- 16. Waveguides
- 17. Antennas
- A. APPENDIX
Tools & Media
Expanded Table of Contents
-
A.
Preface
-
1.
The Subject of Electromagnetics
- Historical Background
- Objectives of the Chapter
- Electric Charge
- Units
- Vectors
- Electrical Force, Field, Flux, and Potential
- Magnetic Force, Field, Flux, and Potential
- Electromagnetic Induction
- Mathematical Operators and Identities
- Maxwell’s Equations
- Electromagnetic Waves
- Trajectory of a Sinusoidal Motion in Two Dimensions
- Wave Polarization
- Electromagnetic Spectrum
- Transmission Lines
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
- 2. Vector Analysis
- 3. Electric Field
- 4. Electric Flux
-
5.
Gradient, Divergence, Curl, and Laplacian
- Introduction
- Gradient
- The Del Operator
- The Del Operator and Gradient
- Divergence
- Expressions for Divergence in Coordinate Systems
- The Del Operator and Divergence
- Divergence of D
- The Divergence Theorem
- Curl
- Laplacian
- Summary of Vector Operations
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
6.
Electrostatics: Work, Energy, and Potential
- Work Done in Moving a Point Charge
- Conservative Property of the Electrostatic Field
- Electric Potential between two Points
- Potential of a Point Charge
- Potential of a Charge Distribution
- Relationship between E and V
- Energy in Static Electric Fields
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
- 7. Electric Current
-
8.
Capacitance and Dielectric Materials
- Polarization P and Relative Permittivity
- Capacitance
- Multiple-Dielectric Capacitors
- Energy Stored in a Capacitor
- Fixed-Voltage D and E
- Fixed-Charge D and E
- Boundary Conditions at the Interface of Two Dielectrics
- Method of Images
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
9.
Laplace’s Equation
- Introduction
- Poisson’s Equation and Laplace’s Equation
- Explicit Forms of Laplace’s Equation
- Uniqueness Theorem
- Mean Value and Maximum Value Theorems
- Cartesian Solution in One Variable
- Cartesian Product Solution
- Cylindrical Product Solution
- Spherical Product Solution
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
10.
Magnetic Field and Boundary Conditions
- Introduction
- Biot-Savart Law
- Ampère’s Law
- Relationship of J and H
- Magnetic Flux Density B
- Boundary Relations for Magnetic Fields
- Current Sheet at the Boundary
- Summary of Boundary Conditions
- Vector Magnetic Potential A
- Stokes’ Theorem
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
- 11. Forces and Torques in Magnetic Fields
-
12.
Inductance and Magnetic Circuits
- Inductance
- Standard Conductor Configurations
- Faraday’s Law and Self-Inductance
- Internal Inductance
- Mutual Inductance
- Magnetic Circuits
- The B-H Curve
- Ampère’s Law for Magnetic Circuits
- Cores with Air Gaps
- Multiple Coils
- Parallel Magnetic Circuits
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
13.
Time-Varying Fields and Maxwell’s Equations
- Introduction
- Maxwell’s Equations for Static Fields
- Faraday’s Law and Lenz’s Law
- Conductors’ Motion in Time-Independent Fields
- Conductors’ Motion in Time-Dependent Fields
- Displacement Current
- Ratio of J c to J D
- Maxwell’s Equations for Time-Varying Fields
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
14.
Electromagnetic Waves
- Introduction
- Wave Equations
- Solutions in Cartesian Coordinates
- Plane Waves
- Solutions for Partially Conducting Media
- Solutions for Perfect Dielectrics
- Solutions for Good Conductors; Skin Depth
- Interface Conditions at Normal Incidence
- Oblique Incidence and Snell’s Laws
- Perpendicular Polarization
- Parallel Polarization
- Standing Waves
- Power and the Poynting Vector
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
15.
Transmission Lines
- Introduction
- Distributed Parameters
- Incremental Models
- Transmission Line Equation
- Sinusoidal Steady-State Excitation
- Sinusoidal Steady-State in Lossless Lines
- The Smith Chart
- Impedance Matching
- Single-Stub Matching
- Double-Stub Matching
- Impedance Measurement
- Transients in Lossless Lines
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
- 16. Waveguides
-
17.
Antennas
- Introduction
- Current Source and the E and H Fields
- Electric (Hertzian) Dipole Antenna
- Antenna Parameters
- Small Circular-Loop Antenna
- Finite-Length Dipole
- Monopole Antenna
- Self- and Mutual Impedances
- The Receiving Antenna
- Linear Arrays
- Reflectors
- SOLVED PROBLEMS
- SUPPLEMENTARY PROBLEMS
- ANSWERS TO SUPPLEMENTARY PROBLEMS
-
A.
APPENDIX
Book Details
Title: Schaum’s Outline of Electromagnetics, Third Edition
Publisher: : New York, Chicago, San Francisco, Lisbon, London, Madrid, Mexico City, Milan, New Delhi, Seoul, Singapore, Sydney, Toronto
Copyright / Pub. Date: 2011, 1993, 1979 The McGraw-Hill Companies, Inc
ISBN: 9780071632355
Authors:
Joseph Edminister is the author of this McGraw-Hill Professional publication.
Description: Modified to conform to the current curriculum, Schaum’s Outline of Electromagnetics complements these courses in scope and sequence to help you understand its basic concepts. The book offers extra practice on topics such as current density, capacitance, magnetic fields, inductance, electromagnetic waves, transmission lines, and antennas. Features 351 solved problems and support for all the major textbooks for electromagnetics courses. Topics include: Vector Analysis, Coulomb Forces and Electric Field Intensity , Electric Flux and Gauss’ Law, Divergence and the Divergence Theorem, The Electrostatic Field: Work, Energy, and Potential, Current, Current Density, and Conductors, Capacitance and Dielectric Materials, Laplace’s Equation, Ampere’s Law and the Magnetic Field, Forces and Torques in Magnetic Fields, Inductance and Magnetic Circuits, Displacement Current and Induced EMF, Maxwell’s Equations and Boundary Conditions, Electromagnetic Waves, Transmission Lines, Waveguides, Antennas.
Required field
