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Course Criteria
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2.00 Credits
Credits: 2 Implementation of project for which preliminary work was done in ECE 492. Project includes designing and constructing hardware, writing required software, conducting experiments or studies, and testing complete system. Requires oral and written reports during project and at completion. Prerequisites ECE 492, preferably in preceding semester. Notes Students planning to use microcontroller technology in their projects should enroll in ECE 447 before taking ECE 493. Completing this course with a C or better satisfies university's general education synthesis requirement. Hours of Lecture or Seminar per week 2 Hours of Lab or Studio per week 0 When Offered F, S
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3.00 Credits
Credits: 1-3 Directed self-study of special topics of current interest in ECE. Topic must be arranged with an instructor and approved by department chair before registering. Notes Maximum 3 credits. Hours of Lecture or Seminar per week 0 Hours of Lab or Studio per week 0 When Offered F, S
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0.00 - 4.00 Credits
Credits: 0-4 Topics of special interest to undergraduates. Prerequisites Permission of instructor; specific prerequisites vary with nature of topic. Notes May be repeated for maximum of 6 credits if topics substantially different. Hours of Lecture or Seminar per week 0 Hours of Lab or Studio per week 0 When Offered F, S
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3.00 Credits
Credits: 3 Introduces microprocessor software and hardware architecture. Includes fundamentals of microprocessor system integration, instruction set design, programming memory interfacing, input/output, direct memory access, interrupt interfacing, and microprocessor architecture evolution. Studies Intel family of microprocessors, and reviews other microprocessor families and design trends. Prerequisites ECE 445 or equivalent. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0
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3.00 Credits
Credits: 3 Maxwell's Equations, electromagnetic wave propagation, wave guides, transmission lines, radiation, and antennas. Prerequisites ECE 305 or equivalent. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0 When Offered F
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3.00 Credits
Credits: 3 Studies analog and digital integrated circuits mainly from communications applications point of view. Covers analog, digital, and mixed (analog/digital) building block circuits used in system design including operational amplifiers, comparators, voltage regulators, video amplifiers, oscillators, modulators, phaselocked loops, multiplexers, active filters, A/D and D/A converters, and optoelectronic circuits. Prerequisites ECE 433 and 431, or permission of instructor. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0
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3.00 Credits
Credits: 3 Introduces linear systems theory and design of linear feedback control systems. Reviews linear algebra, state variables, state-space description of dynamic systems, analysis of continuous-time and discrete-time linear systems, controllability and observability of linear systems, and stability theory. Prerequisites ECE 320 or equivalent Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0
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3.00 Credits
Credits: 3 Provides fundamentals of process control methodologies that are applicable in manufacturing industries, such as semiconductor manufacturing. Introduces the basic concepts of controlled processes equipped with digital control loops, starting with basic discrete-time models, deterministic and random signals and parameter estimation. Provides exposition of fundamentals and applications of feedback control principles, self-tuning control, run-to-run control and system diagnostics. Prerequisites Graduate standing.
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3.00 Credits
Credits: 3 Provides fundamentals of modern computer system and hardware/software integration through the use of quantitative approaches, cost-performance-power tradeoffs, and engineering designs. Introduces design considerations where hardware and software interlock with each other. Course topics include quantitative computer design, exploitation of hardware and software parallelism at instruction-, multiprocessor-, and thread-level, memory hierarchy, storage system, interconnection network, and embedded system design. Prerequisites Graduate standing
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3.00 Credits
Credits: 3 Probability and random processes are fundamental to communications, control, signal processing, and computer networks. Provides basic theory and important applications. Topics include probability concepts and axioms; stationarity and ergodicity; random variables and their functions; vectors; expectation and variance; conditional expectation; moment-generating and characteristic functions; random processes such as white noise and Gaussian; autocorrelation and power spectral density; linear filtering of random processes, and basic ideas of estimation and detection. Prerequisites ECE 220 and STAT 346, or permission of instructor. Hours of Lecture or Seminar per week 3 Hours of Lab or Studio per week 0
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