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Course Criteria
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3.00 Credits
Introduction to the use and limitations of basic instruments used in electrical testing and measurement. Experimental techniques and laboratory safety. Data gathering, interpretation and presentation. Statistical data evaluation methods. Preparation of laboratory reports. Experimental work supporting theoretical concepts developed in E&C-ENGR 276. Prerequisite: E&C-ENGR 276. 2-3 hrs
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4.00 Credits
Continuous and discrete-time signals and systems, linearity and time-invariance, impulse response and convolution. Fourier analysis of discrete and continuous signals and systems and the application of Laplace, z, and Fourier transforms. Prerequisite: E&C-ENGR 341, and E&C-ENGR 381 concurrently. Offered: Fall 4 hrs
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3.00 Credits
Computer Laboratory for E&C-ENGR 380. Various signal processing software programs (MATLAB and DSP) are used to investigate properties and applications of continous and discrete time signals and systems. Corequisite: E&C-ENGR 380. Offered: Fall 1 hr
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1.00 - 4.00 Credits
Analytic or experimental problems pertaining to electrical or computer engineering. Prerequisites: Senior standing, instructor's approval and an approved petition from his or her degree coordinator. 1-4 hrs
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1.00 - 4.00 Credits
CI 1-4 hrs
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2.00 Credits
First capstone design course in electrical and computer engineering. Provides and accounts for laboratory, library, research and other work needed for the development of the project proposal. Stresses written and oral presentations and ethics. Prerequisites: E&C-ENGR 330, E&C-ENGR 380, and E&C-ENGR 428R. Must have passed the WEPT test and can only be taken if student is within three semesters of graduation. 2 hrs
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3.00 Credits
Second capstone design course in electrical and computer engineering. Project management, professional engineering practice, economic, environmental and safety considerations in project design, the development of written and oral presentation skills and working in teams. Provides laboratory experiences in prototyping, fabrication and troubleshooting of a design project. Prerequisite: E&C-ENGR 402WI. 3 hrs
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3.00 Credits
Fundamental concepts of electromagnetic radiation from Maxwell's equations; basic antenna parameters-gain, directivity, radiation & aperture efficiency,effective area, polarization; calculation of radiation patterns of linear antennas (proof omitted); electromagnetic boundary conditions; oblique incidence of plan waves; Snell's laws and polarizationsimilarities between traveling waves on transmission lines and plane waves; Friis formulas; antenna noise temperature; basic antennas-dipole and monopoles; simple array theory and beamforming concepts; propagation path loss-ground reflections; review of transmission lines & Smith Chart; quarter-wave transformers and L-section matching; single stub tuning; microwave network analysis-port-matrices; fundamentals of filter theory; low - and high-pass filters; scaling and transformations; cellular propagation and link loss prediction; 2-ray and 3-ray (optional) models; introduction to smart antenna concepts; WiMAX systems, introduction to and applications of the state of art r.f. CAD tools, but not necessarily restricted to, IE3D, FIDELITY, for simulation and modeling projects for the course. PrerequisiteS: E&C-ENGR 302, E&C-ENGR 380, E&C-ENGR 341 OR E&C-ENGR 401H, MATLAB proficiency. 3 hrs
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1.00 Credits
Design of probe-and stripline-fed rectangular and circular patch microstrip antennas; simulation of performance using CAD tools; modeling of R.F. propagation path loss using CAD tools for site-specific prediction applications. Prerequisites: E&C-ENGR 302, E&C-ENGR 380, E&C-ENGR 341 or E&C-ENGR 401H, MATLAB proficiency. Co-requisite: E&C-ENGR 412. Offered on demand 1 hr
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3.00 Credits
Microwave networks; s-, z-, y- and abcd matrices; signal flow graphs; circular waveguides; stripline & microstrip characteristics; impedance transformers; power dividers and directional couplers; microwave filters; microwave resonators; active microwave circuits. Prerequisites: ECE 302, ECE 380, ECE 398 Restrictions: MATLAB proficiency required. Offered on demand 3 hrs
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