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Course Criteria
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3.00 Credits
Study of the dynamic behavior of discrete event systems and techniques for analyzing and optimizing the performance of such systems. Covers both classical and recent approaches. Classical topics include Markov chains, queueing theory, networks of queues, related algorithms, and simulation methods. Recent approaches include decomposition and aggregation, approximation, and perturbation analysis of nonclassical systems. Applications are drawn from various areas, including production systems. Prerequisites: Math 217, ESE 326 or equivalent, CSE 126 or equivalent.
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3.00 Credits
Principles and practice of modeling dynamic systems in the sciences, engineering, social sciences, and business. Model structure and its relationships to prior knowledge and assumptions, measurable quantities, and ultimate use in solving problems in application areas. Problems considered are in the areas of intervention, policy-making, business, and engineering systems. Model verification. The basic theory and practice of system dynamics. Quantitative methods are emphasized. Senior or graduate standing.
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3.00 Credits
An introduction to current numerical methods: root finding, direct solution of linear systems, iterative solution of linear systems, interpolation, data fitting, numerical differentiation and integration, application to physical and engineering problems. For graduate credit, a term project is required. Prerequisites: Math 217, CSE 131, 126 or 200 or equivalent, and sophomore standing.
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3.00 Credits
Optimization problems with and without constraints. The projection theorem. Convexity, separating hyperplane theorems; Lagrange multipliers, Kuhn-Tucker-type conditions, duality; computational procedures. Optimal control of linear dynamic systems; maximum principles. Use of optimization techniques in engineering design. Prerequisites: ESE 309 or permission of instructor.
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3.00 Credits
Introduces analytical functions of a complex variable as a primary tool in the formulation and solution of engineering problems. Topics: Elementary functions, contour integration in the complex plane, power series, residue theory, conformal mapping, Laplace and Fourier inverse transforms, two-dimensional potential theory. Prerequisite: Engineering ESE 317 or equivalent.
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3.00 Credits
Same as Math 493
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3.00 Credits
Study of important applications of electromagnetic theory. Solution of electrostatic and magnetostatic problems involving Laplace and Poisson's equations subject to boundary conditions. Maxwell's equations, including boundary conditions for dielectrics and conductors, reflection and transmission characteristics with effects due to losses. Study of guided waves in rectangular and optical wave guides, including effects of dispersion. S-parameters and transmission networks, including S-matrix properties, relation to impedance, reflection coefficient, VSWR, and Smith chart. Study of antennas, including exposure to terminology and thin-wire antennas. Prerequisite: ESE 330.
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3.00 Credits
Same as Physics 471
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3.00 Credits
Design and analysis of analog electronic circuits and operational amplifiers for use in control systems, instrumentation, and telecommunications. Large-signal analysis of high-power circuits including transfer characteristics, distortion, power efficiency, impedance, and high-frequency behavior. Frequency response, stability, and frequency-compensation of multistage feedback amplifiers. Fundamental treatment of electronic noise in circuits including thermal noise, shot noise, and 1/f noise. Review of general-purpose op-amps, wideband video op-amps, and high-performance precision operational amplifiers and chip layout. Linear and nonlinear analog applications, including power-booster amplifiers, precision rectifiers, differentiators, integrators, phase-locked loops, high-frequency analog multipliers, and mixers. Prerequisite: ESE 337.
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3.00 Credits
Focus is on the components and associated techniques employed to implement analog and digital radio frequency (RF) and microwave (MW) transceivers for wireless applications, including: cell phones; pagers; wireless local area networks; global positioning satellite-based devices; and RF identification systems. A brief overview of system-level considerations is provided, including modulation and detection approaches for analog and digital systems; multiple-access techniques and wireless standards; and transceiver architectures. Focus is on RF and MW: transmission lines; filter design; active component modeling; matching and biasing networks; amplifier design; and mixer design. Prerequisite: ESE 330.
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