Engineering Electromagnetics 6th Edition Edition by William Hayt, John Buck ISBN 978-0072304244 0072304243
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Product details:
ISBN 10: 0072304243
ISBN 13: 978-0072304244
Author: William H. Hayt, John A. Buck
“Engineering Electromagnetics” is a “classic” in Electrical Engineering textbook publishing. First published in 1958 it quickly became a standard and has been a best-selling book for over 4 decades. A new co-author from Georgia Tech has come aboard for the sixth edition to help update the book. Designed for introductory courses in electromagnetics or electromagnetic field theory at the junior-level and offered in departments of electrical engineering, the text is a widely respected, updated version that stresses fundamentals and problem solving and discusses the material in an understandable, readable way. As in the previous editions, the book retains the scope and emphasis that have made the book very successful while updating all the problems.
Table of contents:
Chapter 1
Vector Analysis
1.1. Scalars and Vectors
1.2. Vector Algebra
1.3. The Cartesian Coordinate System
1.4. Vector Components and Unit Vectors
1.5. The Vector Field
1.6. The Dot Product
1.7. The Cross Product
1.8. Other Coordinate Systems: Circular Cylindrical Coordinates
1.9. The Spherical Coordinate System
Chapter 2
Coulomb’s Law and Electric Field Intensity
2.1. The Experimental Law of Coulomb
2.2. Electric Field Intensity
2.3. Field Due to a Continuous Volume Charge Distribution
2.4. Field of a Line Charge
2.5. Field of a Sheet Charge
2.6. Streamlines and Sketches of Fields
Chapter 3
Electric Flux Density, Gauss’ Law, and Divergence
3.1. Electric Flux Density
3.2. Gauss Law
3.3. Applications of Gauss’ Law: Some Symmetrical Charge Distributions
3.4. Application of Gauss’ Law: Differential Volume Element
3.5. Divergence
3.6. Maxwell’s First Equation (Electrostatics)
3.7. The Vector Operator V and the Divergence Theorem
Chapter 4
Energy and Potential
4.1. Energy and Potential in a Moving Point Charge in an Electric Field
4.2. The Line Integral
4.3. Definition of Potential Difference and Potential
4.4. The Potential Field of a Point Charge
4.5. The Potential Field of a System of Charges: Conservative Property
4.6. Potential Gradient
4.7. The Dipole
4.8. Energy Density in the Electric Field
Chapter 5
Conductors, Dielectrics, and Capacitance
5.1. Current and Current Density
5.2. Continuity of Current
5.3. Metallic Conductors
5.4. Conductor Properties and Boundary Conditions
5.5. The Method of Images
5.6. Semiconductors
5.7. The Nature of Dielectric Materials
5.8. Boundary Conditions for Perfect Dielectric Materials
5.9. Capacitance
5.10. Several Capacitance Examples
5.11. Capacitance of a Two-Wire Line
Chapter 6
Experimental Mapping Methods
6.1. Curvilinear Squares
6.2. The Iteration Method
6.3. Current Analogies
6.4. Physical Models
Chapter 7
Poisson’s and Laplace’s Equations
7.1 Poisson’s and Laplace’s Equations
7.2. Uniqueness Theorem
7.3. Examples of the Solution of Laplace’s Equation
7.4. Example of the Solution of Poisson’s Equation
7.5. Product Solution of Laplace’s Equation
Chapter 8
The Steady Magnetic Field
8.1. Biot-Savart Law
8.2. Ampere’s Circuital Law
8.3. Curl
8.4. Stokes Theorem
8.5. Magnetic Flux and Magnetic Flux Density
8.6. The Scalar and Vector Magnetic Potentials
8.7. Derivation of the Steady-Magnetic-Field Laws
Chapter 9
Magnetic Forces, Materials and Inductance
9.1. Force on a Moving Charge
9.2. Force on a Differential Current Element
9.3. Force Between Differential Current Elements
9.4. Force and Torque on a Closed Circuit
9.5. The Nature of Magnetic Materials
9.6. Magnetization and Permeability
9.7. Magnetic Boundary Conditions
9.8. The Magnetic Circuit
9.9. Potential Energy and Forces on Magnetic Materials
9.10. Inductance and Mutual Inductance
Chapter 10
Time-Varying Fields and Maxwell’s Equations
10.1. Faraday’s Law
10.2. Displacement Current
10.3. Maxwell’s Equations in Point Form
10.4. Maxwell’s Equations in Integral Form
10.5. The Retarded Potentials
Chapter 11
The Uniform Plane Wave
11.1. Wave Propagation in Free Space
11.2. Wave Propagation in Dielectrics
11.3. The Poynting Vector and Power Considerations
11.4. Propagation in Good Conductors: Skin Effect
11.5. Wave Polarization
Chapter 12
Plane Waves at Boundaries and in Dispersive Media
12.1. Reflection of Uniform Plane Waves at Normal Incidenc
12.2. Standing Wave Ratio
12.3. Wave Reflection from Multiple Interfaces
12.4. Plane Wave Propagation in General Directions
12.5. Plane Wave Reflection at Oblique Incidence Angles
12.6. Wave Propagation in Dispersive Media
Chapter 13
Transmission Lines
13.1. The Transmission-Line Equations
13.2. Transmission-Line Parameters
13.3. Some Transmission-Line Examples
13.4. Graphical Methods
13.5. Several Practical Problems
13.6. Transients on Transmission Lines
Chapter 14
Waveguide and Antenna Fundamentals
14.1. Basic Waveguide Operation
14.2. Plane Wave Analysis of the Parallel-Plate Waveguide
14.3. Parallel-Plate Guide Analysis Using the Wave Equation
14.4. Rectangular Waveguides
14.5. Dielectric Waveguides
14.6. Basic Antenna Principles
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