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Course Criteria
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1.00 Credits
Exercises on DC and AC circuits, three-phase circuits, operational amplifiers, resonant and filter circuits, and basic electronic circuits. One two-hour lab per week. Click here for course fees.
Prerequisite:
Or Concurrent [[EE-217]]
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1.00 - 3.00 Credits
Selected topics in the field of electrical engineering. Requirements: Sophomore standing and permission of the instructor. Click here for course fee for lab courses.
Prerequisite:
Sophomore standing and permission of the instructor.
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3.00 Credits
Laplace transforms and matrices. Mathematical modeling of physical systems. Block diagram and signal flow graph representation. Time-domain performance specifications. Stability analysis, Routh-Hurwitz criterion. Steady state error analysis. Root-locus and frequency response techniques. Design and compensation of feedback systems. Introductory state space analysis. Two hours of lecture and one two-hour laboratory per week. Click here for course fees.
Prerequisite:
[[PHY-214]] and [[EE-217]] (or [[EE-211]])
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3.00 Credits
Magnetic circuit calculations. Principle of operation and applications of transformers, DC machines, synchronous machines, and induction motors. Applications of power electronics. Energy conversion schemes.
Prerequisite:
[[EE-251]] and [[EE-217]]
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3.00 Credits
Waves and phasors; concepts of flux and fields; transmission line, Smith chart, and impedance matching; vector calculus; Maxwell's equations for electrostatic and magnetostatic fields. Click here for course fees.
Prerequisite:
[[MTH211]], [[MTH212]], [[PHY-202]].
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4.00 Credits
Obtain an understanding of Maxwell's equations and be able to apply them to solving practical electromagnetic field problems. Fundamental concepts covered will include laws governing electrodynamics, plane wave propagation in different media, power flow, polarization, transmission and reflection at an interface, microwave networks, waveguides, radiation, and antennas. Experiment and computer simulation based laboratories are used to reinforce the course material.Three hours of lecture and one three-hour lab per week. Click here for course fee.
Prerequisite:
[[EE-337]].
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3.00 Credits
Principles of embedded computing systems: architecture, hardware/software components, interfacing, hardware/software co-design, and communication issues. Three hours of lecture and project per week. Click here for course fee.
Prerequisite:
Or Concurrent [EE-222]], [[EE-241]], [[EE-247]] or [[CS-126]]
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3.00 Credits
Computer architecture and design, CPU, memory system, cache, data, input/output devices, bus architecture and control units. Processor types, instruction set and assembly language programming. Three hours of lecture and project per week. Clicl here for course fees.
Prerequisite:
[[EE-140]] or [[CS-125]], [[EE-222]], [[EE-241]].
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3.00 Credits
The theoretical and practical aspects of techniques utilized in the fabrication of bipolar junction transistors (BJTs). Includes crystal characteristics, wafer cleaning, oxidation, lithography, etching, deposition, diffusion, metallization, process metrics, and device characterization. One-and-a-half hour lecture and one three-hour lab per week. Click here for course fee.
Prerequisite:
Or Concurrent [[EE-271]], [[EE-251]]
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4.00 Credits
Fundamentals of analog and digital modulation, modeling random signals and noise in communication systems, and elements of digital receivers. Laboratory exercises provide hands-on experience with circuits and measurement instruments as well as an introduction to communication system simulation. Three hours of lecture and 3-hour lab per week. Click here for course fee.
Prerequisite:
[[EE-252]], [[PHY-214]], [[MTH-212]]
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