![]() ![]() Topics include professional and ethical responsibilities, risks and liabilities, intellectual property, and privacy. Introduction to engineering as a profession including issues surrounding electrical engineering. See a Sample Syllabus ECE 380: Engineering Profession for Electrical Engineers Primary topics include static electric and magnetic fields, Maxwell's equations and force laws, wave propagation, reflection and refraction of plane waves, transient and steady-state behavior of waves on transmission lines. This course prepared the students to formulate and solve electromagnetic problems relevant to all fields of electrical and computer engineering and that will find application in subsequent courses in RF circuits, photonics, microwaves, wireless networks, computers, bioengineering, and nanoelectronics. ![]() See a Sample Syllabus ECE 303: Electromagnetic Fields Introduction to the physics of semiconductors, diode (pn-junctions, and transistors (MOSFET, BJT): Physics of operation, I-V characteristics, circuit models, PSPICE analysis diode circuits Single Stage Transistor Amplifiers: Common Emitter, Common Source, Common Base, Common Gate, Common Collector and Common Drain configurations, biasing, calculations of small signal voltage gain and current gain, input and output resistances Logic Inverters, CMOS logic. See a Sample Syllabus ECE 302: Microelectronics Emphasis on interpreting system descriptions in terms of transient and steady-state response. Representation and analysis of linear systems using differential equations: impulse response and convolution, Fourier series, and Fourier and Laplace transformations for discrete time and continuous time signals. See a Sample Syllabus ECE 301: Linear Systems Major topics of the course include complex numbers, real and complex functions, signal representation, elementary matrix algebra, solutions to linear systems of equations, linear differential equations, laplace transforms used for solving linear differential equations, fourier series and transforms and their uses in solving ECE problems. The concepts covered in this course will be used in higher level courses and, more importantly, throughout your career as an engineer. This course is designed to acquaint you with the basic mathematical tools used in electrical and computer engineering. See a Sample Syllabus ECE 220: Analytical Foundations of Electrical and Computer Engineering Use of several CAD tools for simulation, logic minimization, synthesis, state assignment, and technology mapping. Boolean algebra, switching functions, Karnaugh maps, modular combinational circuit design, latches, flip-flops, finite state machines, synchronous sequential circuit design, datapaths, memory technologies, caches, and memory hierarchies. ![]() See a Sample Syllabus ECE 212: Fundamentals of Logic Design Kirchhoff's laws node analysis, mesh analysis, Thevenin's theorem, Norton's theorem, steady state and transient analysis, AC, DC, phasors, operational amplifiers, transfer functions. Voltage, current, power, energy, resistance, capacitance, inductance. Introduction to theory, analysis and design of electric circuits. See a Sample Syllabus ECE 211: Electric Circuits Introduction to fundamental data structures: array, list, tree, hash table. See a Sample Syllabus ECE 209: Computer Systems ProgrammingĬomputer systems programming using the C language. Weekly hardware laboratory utilizing multimeter, function generator, oscilloscope and spectrum analyzer and custom hardware for experiments on various circuits and systems. Ohm's law and Kirchoff's laws circuits with resistors, photocells, diodes and LEDs rectifier circuits first order RC circuits periodic signals in time and frequency domains, instantaneous, real and apparent power DC and RMS value magnitude andpower spectra, dB, dBW, operational amplifier circuits, analog signal processing systems including amplification, clipping, filtering, addition, multiplication, AM modulation sampling and reconstruction. See a Sample Syllabus ECE 200: Introduction to Signals, Circuits and Systems Number representations, switching circuits, logic design, microprocessor design, assembly language programming, input/output, interrupts and traps. Introduction to key concepts in computer systems. ![]() PY 209 Physics for Engineers & Scientists II LabĮCE 109: Introduction to Computer Systems PY 208 Physics for Engineers & Scientists II PY 206 Physics for Engineers & Scientists I LabĮ 102 Engineering in the 21st Century (GEP-IP) PY 205 Physics for Engineers & Scientists I 1 ![]()
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