ECE 60400 - Electromagnetic Field Theory
Course Details
Credits: 3
Areas of Specialization:
- Fields and Optics
Counts as:
Normally Offered:
Each Fall, Spring
Campus/Online:
On-campus and online
Catalog Description:
Review of general concepts (Maxwell's equations, materials interaction, boundary conditions, energy flow); statics (Laplace's equation, Poisson's equation); distributed parameter systems (classification of solutions, transmission lines, and waveguides); radiation and antennas (arrays, reciprocity, Huygen's principle); a selected special topic (e.g. magnetostatics, waves in anisotropic media and optical fibers).
Required Text(s):
None.
Recommended Text(s):
- Electromagnetic Field Theory (full text provided in Brightspace) , Chew, W. , Lecture Book
- Fields and Waves in Communication Electronics (full text provided in Brightspace) , 3rd Edition , Ramo, S.; Whinnery, J. R.; Van Duzer, T. , John Wiley & Sons , 1994 , ISBN No. 0471585513
Lecture Outline:
Major Topics | |
---|---|
1 | Module 1 - Fundamentals, Complex Media, Theorems, and Principles: Fundamentals of Maxwell's equations; Gauss' and Stokes' theorems; wave equation, scalar and vector potentials, boundary conditions; phasor and frequency domain techniques; Drude-Lorentz- Sommerfeld model, plane waves; gyrotropic media; instantaneous and complex Poynting's theorem; electromagnetic theorems and principles. |
2 | Module 2 - Transmission Lines, Waves in Layered Media, Waveguides, and Cavity Resonators: Circuit and transmission line theory; duality principle; single interface reflection and transmission; total internal reflection; Brewster angle; surface plasmon polariton; waves in layered media; phase and group velocities; transverse resonance condition; dielectric waveguide; hollow rectangular and circular waveguides; Q of resonators. |
3 | Module 3, - Radiation, High-Frequency Approximation, Computational Electromagnetics, Quantum Theory of Light: Radiation of Hertzian dipole and general sources; array antennas, near field, Fresnel zone, and far-field approximation; types of antennas; image theory; high-frequency approximations; plane wave expansion of point source field; Sommerfeld integrals; computational electromagnetics; quantum theory of light. |
Assessment Method:
Homework, exams. (3/2022)