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Course Criteria
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3.00 Credits
Modern physics approach to electrons in solids; elementary quantum mechanics; statistics; plasmas; band theory; application of these principles to modern amplifiers; e.g., the traveling-wave tube, tunnel diode, masers, and parametric amplifiers.
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3.00 Credits
Course provides fundamental knowledge about generating solar electricity by the use of solar cells. Special attention is given to demonstrating the potential role of photovoltaic systems as clean and sustainable electricity generation sources for current and future generations of mankind. Students are expected to have completed courses comparable to ECE 4040 and ECE 4060 before enrolling in this course.
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3.00 Credits
Investigates finite-difference methods (FD) as applied to electromagentics; FD approximations, error, stability and numerical dispersion; solution of Poisson's, Helmholtz and wave equations; banded matrices, iterative methods and eigensolutions; the finite-difference time-domain method, Yee Lattice, mesh truncation methods, perfectly matched layers, source conditions, near-to-far field transformation, subcellular modeling for fine features and wide-band characterization. Students are expected to have completed a course comparable to ECE 4360 or ECE 4460 before enrolling in this course; and are expected to have completed or be concurrently enrolled in a course comparable to ECE 8300 when enrolling in this course.
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3.00 Credits
Covers several important topics of applied electromagnetics, including advanced transmission-line theory for guided electromagnetic waves, analysis of electromagnetic wave propagation in layered media and computation of electromagnetic radiation in stratified regions. Preq: ECE 8290 and ECE 8300.
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3.00 Credits
Complex calculus and analytic functions; origin of special functions in engineering; series and integral representations of special functions; properties and applications of gamma, Bessel, Legendre, Chebyschev, etc. functions; computation of special functions; applications in selected engineering problems. Students are expected to have completed courses comparable to ECE 3810 and MATH 4340 before enrolling in this course.
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3.00 Credits
Wave equations and waves, electromagnetic potentials, theorems and advanced concepts, guided waves, radiation, boundary value problems and simple Green's functions. Preq or concurrent enrollment: ECE 8290.
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3.00 Credits
Advanced boundary-value problems in cylindrical and spherical coordinates, special functions, Sommerfeld integrals, Green's functions and integral equations. Preq: ECE 8300.
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3.00 Credits
Covers Fourier optics and optical signal processing. Topics include multidimensional Fourier analysis, correlation and convolutions, propagation and diffraction of optical waves, forming systems with coherent and incoherent systems, optical filtering, holography diffractive optics, and spatio-temporal processing of optical fields.
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3.00 Credits
Canonical diffraction problems for which exact solutions are available; asymptotic reevaluation of these solutions in terms of incident, reflected and diffracted rays leads to Keller's postulates for an extended theory or geometrical theory of diffraction; application of diffraction from edges and curved surfaces to scattering and antenna problems. Preq: ECE 8300.
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3.00 Credits
Finite-element methods (FEM) as applied to electromagnetics; fundamentals of list-linked FEM data structures, sparse matrix solutions, edge-based vector bases, radiation boundary conditions and perfectly absorbing media. Preq or concurrent enrollment: ECE 8300.
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