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Prerequisites:
MATH 2433, PHYS 1322, and credit for or concurrent
enrollment in ECE 2331 and MATH 3321. Fundamentals of electricity and magnetism, vector calculus, Maxwell's equations, Kirchhoff's laws, static electric and magnetic fields, resistance, capacitance, inductance, magnetic circuits and transformers. |
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Prerequisites:
ECE 2317 and credit for or concurrent enrollment in ECE
3337. Maxwell's equations in time and frequency domains, Poynting's theorem, plane wave propagation, reflection and transmission in lossless and lossy media, transmission lines, waveguides, and antennas. |
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Prerequisite:
ECE 3317. Transmission lines; waveguides; microstrip circuits; microwave circuit theory; scattering matrices; impedance transformers; passive microwave devices; resonators; microwave tubes; solid state active devices. |
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Prerequisite:
ECE 3317. Antenna concepts: linear, aperture and wire antennas; printed circuit radiators; frequency-independent antennas; measurement techniques. |
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Prerequisite: ECE
3317 Maxwell's equations, properties of matter, transmission lines, waveguides, plane waves, radiation from antennas, duality, image methods, equivalence principle, reciprocity, radiation from sources in layered media. |
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Prerequisite:
ECE 6340 TE-TM decomposition, cylindrical wave functions, Spherical wave functions, asymptotic methods, spectral-domain methods for layered media, radiation and scattering from periodic structures, phased arrays. |
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Prerequisite:
Consent of instructor. Overview of microstrip antennas with focus on basic concepts, radiation models, calculation of far-field radiation patterns, spectral-domain analysis, CAD formulas for rectangular microstrip antennas, input impedance models, mutual coupling, and infinite and finite array analysis. |
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Prerequisite:
ECE 6340 or consent of instructor. Formulation and numerical solution of integral equations for scattreing and radiation by thin wires, two and three dimensional conducting structures, bodies of revolution, dielectric bodies. |
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Prerequisite:
ECE 3317. Transmission lines; waveguides; microstrip circuits; microwave circuit theory; scattering matrices; impedance transformers; passive microwave devices; resonators; microwave tubes; solid state active devices. |
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Prerequisite:
ECE 3317. Antenna concepts: linear, aperture and wire antennas; printed circuit radiators; frequency-independent antennas; measurement techniques. |
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Prerequisite:
Undergraduate electrodynamics and electronics courses. A course in microwave engineering is desirable. The intent of this course is to cover the techniques necessary for the design and analysis of RF and microwave electronic circuits. The emphasis in the course will be a practical understanding of high frequency electronic circuit analysis and design. Mathematical derivations and analysis will be done in as direct a way as possible and computer simulations will be used to illustrate practical design considerations. |
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Prerequisite:
ECE 6340 and ECE 6382. Modern geometrical optics; differential geometry; vector ray theory; high frequency antenna and scattering applications. |
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Prerequisite:
Consent of instructor. May be repeated for credit. Topics from the following: antenna theory, guided wave propagation, scattering theory, computer aided design, electromagnetic theory, microstrip circuits and antennas, high frequency methods, millimeter waves. |
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