Latest EECS News
1. Ulaby, et al, Fundamentals of Applied Electromagnetics , Prentice Hall, 6/e edition, 2010
2. Plonus, M. A. Applied Electromagnetics, McGraw-Hill, 1978 (as reference)
Martin Plonus, Professor, EECS
Office: Tech L310, hours W F 4-5 PM
Phone: (847) 491-3445; email: email@example.com
COURSE GOALS: To provide the electrical engineering student with detailed information regarding key applications of electromagnetic fields and waves in modern communications technology, especially antennas, fiber optics and photonic devices.
PREREQUISITE: EECS 224
ORGANIZATION: Three lectures per week (MWF). Weekly homework assignment.
DETAILED COURSE TOPICS:
Week 1: Review of Maxwell's equations and plane wave propagation. Review of plane wave reflection and transmission at normal incidence
Week 2: Review of transmission lines, transients
Week 3: Plane wave reflection and transmission at oblique incidence.
Week 4: Geometric optics. Images formed by mirrors and lenses.
Week 5: Waveguides: Infinite parallel metal plate waveguide. Propagation and cutoff phenomena. Hollow rectangular metal waveguide.
Week 6: Waveguides, continued: Hollow circular cylindrical metal waveguide. Dielectric waveguides including sheets and rods. Fiber optics.
Week 7: Radiation and antennas: The short dipole. Antenna radiation characteristics. Half-wave dipole antenna.
Week 8: Radiation and antennas, continued: Aperture antennas. Antenna arrays.
Week 9: Contemporary applications of antennas: Friis transmission formula. Satellite communication systems. Global positioning system. Cellular telephone systems. Radar and radar cross section.
Week 10: Contemporary photonic devices, including micron-scale waveguides, couplers, resonators, photonic bandgap structures, and lasers.
COURSE OBJECTIVES: When a student completes this course, s/he should understand:
1) Key aspects of the behavior and design of antennas for wireless communications systems, including satellite direct-broadcast and terrestrial cellular / personal communications systems.
2) Propagation and cutoff behavior of electromagnetic wave modes in metal waveguides comprised of parallel plates, rectangular pipes, and circular pipes.
3) Waveguiding phenomena for light in optical fibers.
4) Electromagnetic phenomena associated with contemporary photonic devices, including micron-scale waveguides, couplers, resonators, photonic bandgap structures, and lasers.
ABET CONTENT CATEGORY: 100% Engineering (Design component).