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Engineering Electromagnetics

by:
ISBN: 9780070274068 | 0070274061
Edition: 5th
Format: Hardcover
Publisher: MCG
Pub. Date: 1/1/1988

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Table of Contents
Prefacexi
Chapter 1 Vector Analysis
1(25)
1.1 Scalars and Vectors
2(1)
... MORE1.2 Vector Algebra
3(1)
1.3 The Cartesian Coordinate System
4(2)
1.4 Vector Components and Unit Vectors
6(3)
1.5 The Vector Field
9(1)
1.6 The Dot Product
10(2)
1.7 The Cross Product
12(2)
1.8 Other Coordinate Systems: Circular Cylindrical Coordinates
14(5)
1.9 The Spherical Coordinate System
19(7)
Chapter 2 Coulomb's Law and Electric Field Intensity
26(26)
2.1 The Experimental Law of Coulomb
27(3)
2.2 Electric Field Intensity
30(4)
2.3 Field Due to a Continuous Volume Charge Distribution
34(3)
2.4 Field of a Line Charge
37(6)
2.5 Field of a Sheet of Charge
43(2)
2.6 Streamlines and Sketches of Fields
45(7)
Chapter 3 Electric Flux Density, Gauss's Law, and Divergence
52(28)
3.1 Electric Flux Density
52(4)
3.2 Gauss's Law
56(4)
3.3 Application of Gauss's Law: Some Symmetrical Charge Distributions
60(5)
3.4 Application of Gauss's Law: Differential Volume Element
65(3)
3.5 Divergence
68(3)
3.6 Maxwell's First Equation (Electrostatics)
71(1)
3.7 The Vector Operator XXX and the Divergence Theorem
72(8)
Chapter 4 Energy and Potential
80(34)
4.1 Energy Expended in Moving a Point Charge in an Electric Field
81(1)
4.2 The Line Integral
82(5)
4.3 Definition of Potential Difference and Potential
87(2)
4.4 The Potential Field of a Point Charge
89(2)
4.5 The Potential Field of a System of Charges: Conservative Property
91(4)
4.6 Potential Gradient
95(7)
4.7 The Dipole
102(4)
4.8 Energy Density in the Electrostatic Field
106(8)
Chapter 5 Conductors, Dielectrics, and Capacitance
114(48)
5.1 Current and Current Density
115(2)
5.2 Continuity of Current
117(2)
5.3 Metallic Conductors
119(5)
5.4 Conductor Properties and Boundary Conditions
124(5)
5.5 The Method of Images
129(2)
5.6 Semiconductors
131(1)
5.7 The Nature of Dielectric Materials
132(6)
5.8 Boundary Conditions for Perfect Dielectric Materials
138(6)
5.9 Capacitance
144(3)
5.10 Several Capacitance Examples
147(3)
5.11 Capacitance of a Two-Wire Line
150(12)
Chapter 6 Experimental Mapping Methods
162(26)
6.1 Curvilinear Squares
163(6)
6.2 The Iteration Method
169(6)
6.3 Current Analogies
175(3)
6.4 Physical Models
178(10)
Chapter 7 Poisson's and Laplace's Equations
188(28)
7.1 Poisson's and Laplace's Equations
189(2)
7.2 Uniqueness Theorem
191(2)
7.3 Examples of the Solution of Laplace's Equation
193(7)
7.4 Example of the Solution of Poisson's Equation
200(4)
7.5 Product Solution of Laplace's Equation
204(12)
Chapter 8 The Steady Magnetic Field
216(49)
8.1 Biot-Savart Law
217(7)
8.2 Ampere's Circuital Law
224(7)
8.3 Curl
231(7)
8.4 Stokes' Theorem
238(5)
8.5 Magnetic Flux and Magnetic Flux Density
243(3)
8.6 The Scalar and Vector Magnetic Potentials
246(7)
8.7 Derivation of Steady-Magnetic-Field Laws
253(12)
Chapter 9 Magnetic Forces, Materials, and Inductance
265(46)
9.1 Force on a Moving Charge
266(1)
9.2 Force on a Differential Current Element
267(4)
9.3 Force between Differential Current Elements
271(2)
9.4 Force and Torque on a Closed Circuit
273(5)
9.5 The Nature of Magnetic Materials
278(4)
9.6 Magnetization and Permeability
282(5)
9.7 Magnetic Boundary Conditions
287(2)
9.8 The Magnetic Circuit
289(7)
9.9 Potential Energy and Forces on Magnetic Materials
296(2)
9.10 Inductance and Mutual Inductance
298(13)
Chapter 10 Time-Varying Fields and Maxwell's Equations
311(25)
10.1 Faraday's Law
312(6)
10.2 Displacement Current
318(4)
10.3 Maxwell's Equations in Point Form
322(2)
10.4 Maxwell's Equations in Integral Form
324(2)
10.5 The Retarded Potentials
326(10)
Chapter 11 The Uniform Plane Wave
336(45)
11.1 Wave Motion in Free Space
336(9)
11.2 Wave Motion in Perfect Dielectrics
345(2)
11.3 Plane Waves in Lossy Dielectrics
347(6)
11.4 The Poynting Vector and Power Considerations
353(4)
11.5 Propagation in Good Conductors: Skin Effect
357(7)
11.6 Reflection of Uniform Plane Waves
364(6)
11.7 Standing-Wave Ratio
370(11)
Chapter 12 Transmission Lines
381(33)
12.1 The Transmission-Line Equations
382(5)
12.2 Transmission-Line Parameters
387(6)
12.3 Some Transmission-Line Examples
393(4)
12.4 Graphical Methods
397(7)
12.5 Several Practical Problems
404(10)
Chapter 13 Several Other Applications of Maxwell's Equations
414(26)
13.1 The Laws of Circuit Theory
414(3)
13.2 The Resonant Coaxial Cavity
417(10)
13.3 Radiation
427(13)
Appendix A Vector Analysis
440(5)
A.1 General Curvilinear Coordinates
440(1)
A.2 Divergence, Gradient, and Curl in General Curvilinear Coordinates
441(2)
A.3 Vector Identities
443(2)
Appendix B Units
445(5)
Appendix C Material Constants
450(4)
Appendix D Answers to Odd-Numbered Problems
454(7)
Index461

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