|
|
|
|
|
|
|
|
|
|
Course Criteria
Add courses to your favorites to save, share, and find your best transfer school.
-
3.00 Credits
Model formulation techniques for physical systems. Transformation between state-space and classical system representations. Classical solution of LTI system equations. Time and frequency domain solutions of linear state equations. Three lectures. Spring. Prerequisite: EECE 303. (Cr. 3)
-
3.00 Credits
Introduction to electrical machinery. Magnetic circuits. Single and three phase transformers. Autotransformers. Synchronous machines. Three phase induction motors. Direct current machinery. Three lectures. Prerequisite: Senior status.* (Cr. 3)
-
3.00 Credits
Design of selected SSI, MSI, LSI, and microcomputer-based digital systems from the following topic areas: oscillators, phase lock loops, one-shots, switch debouncing, sequential circuits, A/D & D/A conversion, motor control, waveform generation, and serial data transmission. Three lectures. Fall. Prerequisites: EECE 230, 306. (Cr. 3)
-
3.00 Credits
The design process utilizing electrical and computer engineering principles. Problem specification and constraints. Sources of information. Comparison of alternate solutions. Group or individual reports required. Three lectures. Spring. Prerequisites: EECE 304, 306. (Cr. 3)
-
1.00 Credits
Experiments in the areas of computers, power, communications, controls, high frequency techniques. Experiment design techniques. One-hour lecture, three hours laboratory. Prerequisites: EECE 230, 306, 318. (Cr. 2, 2)
-
1.00 - 3.00 Credits
Independent investigation, under the guidance of an approved advisor and the sponsorship of an electrical engineering faculty member, terminating in a final report, and when feasible, a tested design. Written permission of departmental chair is required. (Cr. 1-3, 1-3)
-
3.00 Credits
Principles of linear feedback control systems. System modeling. Transient response and steady-state error analysis. Stability and analysis of systems from Routh-Hurwitz, Nyquist, and Root Locus viewpoints. Controller design and compensation techniques. Three lectures. Prerequisite: EECE 303. (Cr. 3)
-
3.00 Credits
Introduction to Optical Engineering. Principles of reflection and refraction of light. Geometrical Optics: lenses and optical instruments. Elements of Lasers, Light Modulators and Detectors. Optics from a systems perspective, Diffraction and Interference of light waves. Coherent optical signal processing. Three lectures. Spring. Prerequisite: EECE 303, ELEC 310. (Cr. 3)
-
3.00 Credits
Optical waves in material media. Propagation of Gaussian beams. Interference and concepts of coherence. Optical resonators. Radiation and its interaction with atomic systems. Spontaneous and stimulated emission. Light amplification; gain saturation. Laser oscillators. Applications to optical communication and holography. Three lectures. Corequisite: ELEC 310. Prerequisite: Senior Status*. (Cr. 3)
-
3.00 Credits
An introductory lecture and demonstration (laboratory) course designed to familiarize the student with microwaves & optical concepts, devices, and measurement techniques. Topics include microwave & optical sources, measurement of power, reflection coefficient & impedance, Use of isolators & directional couplers at microwave & optical frequencies. Propagation of Gaussian beams, polarization of optical waves, optical modulation and detection. Prerequisite: Senior Status*. (Cr. 3)
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Privacy Statement
|
Terms of Use
|
Institutional Membership Information
|
About AcademyOne
Copyright 2006 - 2025 AcademyOne, Inc.
|
|
|