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Course Criteria
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3.00 Credits
Techniques for CMOS digital integrated circuit design at circuit, subsystem, and system levels. CAD tools for design from schematic capture to physical layout. Design methodologies: programmable logic, standard cell, full custom CMOS fabrication technology. Design issues: speed, power, reliability, testability. CMOS design case studies. Laboratory project. Prerequisites: Graduate or senior ECE standing with ECE 362 and ECE 354 (minimum grade of C-). Laboratory fee.
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3.00 Credits
Techniques for CMOS analog integrated circuit design at circuit, subsystem, and system levels. Analog circuit building blocks, CAD tools for design from schematic capture to physical layout. Design case studies, structured laboratory, and laboratory project. Design economics, quality, and reliability issues. VLSI performance optimization: objectives, constraints, designable parameters, algorithms. Introduction to neural networks for modeling and optimization. Prerequisites: ECE 565 (minimum grade of C-) and senior or graduate standing. Laboratory fee.
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3.00 Credits
Introduction to circuit modeling of electrical power systems and their components. Topics include symmetrical components, perunit analysis, three-phase and DC transmission lines, transient analysis, lightning effects, corona, short-circuit fault analysis, power system protection devices and relaying schemes. Professional elective in the B.S.E.E. program. Prerequisites: Graduate or senior ECE standing with ECE 471. Laboratory fee.
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3.00 Credits
Theory and operation of power diodes, power transistors, silicon-controlled rectifiers, diacs, triacs, and unijunction transistors. Design of phase-controlled rectifiers and DC-DC converters and inverters. Professional elective in the B.S.E.E. program. Prerequisites: Graduate or senior ECE standing with ECE 362 (minimum grade of C-). Laboratory fee.
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1.00 - 6.00 Credits
Selected topics in electrical engineering at the graduate level. Significant topics in the field are chosen on the basis of student and faculty needs and interests. Prerequisites: Graduate or senior ECE standing and permission of instructor. Laboratory fee.
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1.00 - 3.00 Credits
Work experience in an electronic engineering technology industry/business setting under the supervision of the co-op faculty coordinator. Objectives and evaluation criteria set by a learning contract are required. Pass/No Pass grading. Prerequisites: Sophomore standing and 2.5 GPA. May be used as a professional or unrestricted elective, not as a technical specialty.
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4.00 Credits
Topics include an introduction to the origins of mankind's awareness of electricity and the development of scientific understanding of it in the 19th and 20th centuries; static vs. dynamic, DC vs. AC, power generation/distribution and uses, costs, electrical safety and hazards; common electrical circuits, elementary use of Ohm's law, power and cost considerations; electronics from a block diagram approach: power supplies, amplifiers, oscillators, RF devices, and systems, including radio, television, satellite communication, cellular phone technology, and GPS. Three lecture hours, three lab hours. Prerequisite: MTH 112 (or concurrent). Laboratory fee.
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2.00 Credits
Familiarization with the personal computer as tool for generating effective written communications and for analysis and presentation of data taken in the laboratory. An introduction to the use of appropriate technical software in the discipline of electronic engineering technology. Two hours of combined lecture/laboratory. Prerequisite: ECT 111 (or concurrent). Laboratory fee.
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4.00 Credits
Topics include review of DC circuits; phasors; sinusoids applied to R, L, C series and parallel circuits; DC and AC source conversions and circuit theorems, mesh and nodal analysis; transformers. Three lecture hours, three lab hours. Prerequisite: ECT 111 or EDT 245 (minimum grade of C-). Laboratory fee.
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4.00 Credits
This course covers digital logic concepts, including number systems and codes, basic logic gates, programmable logic devices, Boolean algebra and reduction techniques, arithmetic operations and circuits, code converters, multiplexing and demultiplexing, flip flops and registers, and HDL programming. Laboratory experience includes prototyping, computer simulation, and implementing programmable devices. Three lecture hours, three lab hours. Prerequisite: ECT 111 or ECT 245. Laboratory fee.
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