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Course Criteria
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3.00 Credits
Study of electric circuits and networks. Includes resistive circuits and first-order transients. Emphasizes the basic principles and their application to circuit analysis using calculus and linear algebra. Prerequisite: PHY 182. Concurrent course: MTH 249 or MTH 251 or MTH 257H. 2 Lec 1 Lab.
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3.00 Credits
Principles of Von Neumann computer architecture. Data representation and computer arithmetic. Memory hierarchy. CPU structure and instruction sets. Assembly language programming to better understand and illustrate computer architecture concepts. Performance considerations and alternative computer architectures. Prerequisite: CSA 271 or equivalent. Cross-listed with CSA 278.
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4.00 Credits
Topics include switching algebra and switching functions, logic design of combinational and sequential circuits using TTL, combinational logic design with MSI and LSI, busing, flip-flops, registers, counters, programmable logic devices, memory devices, register-level design, and microcomputer system organization. Students must show competency in the computer-aided design (CAD) and laboratory implementation of digital systems. 3 Lec. 2 Lab.
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4.00 Credits
Advanced topics in electric circuit analysis are combined with an in-depth study of theory and application of instrumentation and experimentation; power analysis, transformer principles, frequency response and filters, second order systems, LaPlace transform, and signal conditioning circuits are covered as well as components, and concepts of computer-machine interface systems; design of computer-controlled experimentation for real-time measurement, monitoring, and control of automated-industrial processes. Prerequisite: ECE 205, MME 211, STA 368 or STA 301. 3 Lec. 1 Lab. Cross-listed with MME 303.
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3.00 Credits
Analysis and design of electronic circuits and subsystems; study of diodes, transistors, and operational amplifier characteristics; amplification, frequency response and feedback in small signal amplifiers; applications of electronic devices and circuits. Prerequisite: ECE 305 or ECE/ MME 303. 2 Lec. 1 Lab.
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3.00 Credits
In depth study of electric circuits and networks. Includes sinusoid and complex number manipulations, AC circuit analysis, AC power analysis, poly-phase and magnetically coupled circuits, electric machines, frequency response and filters, Laplace transform, and S-domain circuit analysis. Prerequisites: ECE 205 or PHY 292/294. Concurrent course: MTH 245 or MTH 347. 2 Lec. 1 Lab.
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3.00 Credits
Introductory course covering the principles of signals and systems. The course combines lectures, Matlab simulation laboratory exercises, and design projects to expose students to the theories and concepts of both continuous-time and discrete time forms of signals and systems, as well as applications of the theories and concepts in communication systems, control systems, and signal processing. Prerequisites: ECE 205 or PHY 292/294. Concurrent courses: ECE 205, MTH 245 or MTH 347.
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3.00 Credits
Theories and applications of electromagnetic fields and waves; Including electrostatics, magnetostatics, Maxwell's Equations, plane wave propagation and reflection, transmission lines, and antennas. Prerequisites: MTH 245 or MTH 347 and ECE 305 or ECE 303.
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4.00 Credits
Fundamentals of computer systems design. Interfacing and basics of embedded computers (microprocessors). Laboratory projects will require students to successfully design, implement, debug, and document computer solutions requiring a mix of hardware and software. Models and methodologies for designing systems containing hardware and software. Models and methodologies for designing systems containing both hardware and software components, or codesign, will be introduced. Substantial design projects will be required of each student. Prerequisite: ECE 287, CSA 153 or CSA 274. 3 Lec. 1 Lab.
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3.00 Credits
Fundamentals of modern VLSI IC design. Introduces three main aspects of CMOS IC engineering: device operation, circuit design and circuit layout, as well as three main aspects of VLSI system engineering: system-level simulation, interconnect analysis and basics of high-volume manufacturability. Provides hand-on experience with modern IC design software. Prerequisite: ECE 287 and ECE 304.
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