Electromagnetic fields : theory and applications

The study of electromagnetic field theory is required for proper understanding of every device wherein electricity is used for operation. The proposed textbook on electromagnetic fields covers all the generic and unconventional topics including electrostatic boundary value problems involving two- and three-dimensional Laplacian fields and one- and two- dimensional Poissonion fields, magnetostatic boundary value problems, eddy currents, and electromagnetic compatibility. The subject matter is supported by practical applications, illustrations to supplement the theory, solved numerical problems, solutions manual and Powerpoint slides including appendices and mathematical relations. Aimed at undergraduate, senior undergraduate students of electrical and electronics engineering, it: Presents fundamental concepts of electromagnetic fields in a simplified manner Covers one two- and three-dimensional electrostatic boundary value problems involving Laplacian fields and Poissonion fields Includes exclusive chapters on eddy currents and electromagnetic compatibility Discusses important aspects of magneto static boundary value problems Explores all the basic vector algebra and vector calculus along with couple of two- and three-dimensional problems

1.Introduction 2. Field Applications 3. Coordinate Systems and Vector Algebra 4. Vector Calculus 5. Electric Field Intensity 6. Electric Flux Density 7. Potential and Potential Energy 8. Electrical Field in Materials 9. Electrostatic Boundary Value Problems Involving Laplacian Fields 10. Electrostatic Boundary Value Problems Involving Poisson's Fields 11. Steady Magnetic Fields 12. Fields in Magnetic Materials 13. Magnetic Circuits 14. Magnetostatic Boundary Value Problems 15. Time-Varying Fields 16. Electromagnetic Waves 17. Reflection and Refraction of Electromagnetic Waves 18. Transmission Lines 19. Waveguides and Cavity Resonators 20. Radiation Mechanism 21. Eddy Currents 22. Electromagnetic Compatibility