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Course Criteria
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1.00 Credits
1 hr. This course is the companion lab to EE-203 and includes both analysis, simulation and fabrication of analog electronic circuits including diode circuits, bipolar junction transistor amplifiers, operational amplifiers and circuits using operational amplifiers such as oscillators and filters. Corequisite: EE 203
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3.00 Credits
3 hrs. Analysis and design of those circuits where the nonlinearity of the active element is significant. Includes basic digital circuits, Boolean algebra, Karnaugh maps, encoding and decoding, flip-flops, finite state machines, and analog-digital conversion. Prerequisite: EE 101
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3.00 Credits
3 hrs. Continuous time signals and systems; impulse and step functions, signal synthesis, convolution integrals, impulse response, transfer functions, poles and zeros, system responses, and state space methods, introduction: discrete time Fourier series. Discrete time Fourier transforms, discrete time systems, difference equations, and Z-transforms are introduced in this course. Prerequisites: EE 202 and MTH 238
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3.00 Credits
3 hrs. A study of random signals and random input systems; probability, density functions, random variables, random processes, Gaussian and Poisson processes; correlation functions, spectral density; random input systems, analysis, and signal-to-noise ratio concepts. Prerequisite: EE 301
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3.00 Credits
3 hrs. A review of coordinate systems; vector analysis; study of electrostatics to include Coulomb's Law, Gauss's Law, electric field intensity, and flux densitycalculations, electric potential calculations; magnetostatics to include Biot-Savart law, Ampere's law, magnetic field intensity and flux density concepts; introduction to magnetic vector potential; time varying fields, Maxwell's equations; and transmission lines. Prerequisites: MTH 238 and EE 202
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3.00 Credits
3 hrs. In this course numerical techniques are applied to the solution of scientific and engineering problems. Topics include software development techniques, solution of both liner and nonlinear equations, numerical integration and differentiation, interpolation and curve fitting, solution of differential equations, and optimization techniques. Emphasis is placed on developing programs in C++ language for execution in a UNIX environment. Prerequisites: EE 109 and MTH 238
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3.00 Credits
3 hrs. A study of semiconductor fundamentals and physics of semiconductor devices to include: properties of materials and devices used in electrical engineering; theory of operation of semiconductor devices; p-n junction diodes, bipolar transistors ( n-p-n and p-np), and field-effect devices. Prerequisites: EE 203
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3.00 Credits
3 hrs. This course is an introduction to Ohm's Law, KCL and KVL equations, dc circuit analysis; inductance and capacitance, AC circuit analysis; electrical machines, transformers, DC motors, DC generators, induction motors, alternators, synchronous motors, principle of operation, characteristics, and applications. This course is offered for non-EE majors only. Prerequisite: MTH 238. Corequisite: EE 311L
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1.00 Credits
1 hr. This course is a companion lab to EE 311. Corequisite: EE 311
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3.00 Credits
3 hrs. Basic concepts used in computer hardware design and computer system architecture are studied. The computer is presented as an infinite state machine. Basic computer functions such as address and data paths, instruction sets and memory cycles, components such as registers, arithmetic units, instruction decoders, and types of memories are discussed. A general purpose instruction set computer will be analyzed. Prerequisites: EE 204 , Corequisite: EE 320L
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