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Course Criteria
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4.00 Credits
Prerequisites: EE: EEC 314, EEC 315, EEC 382; CE: EEC 313, EEC 316, EEC 382. Modeling of DSP operations using discrete-time signals and systems: difference equations, Z-transforms, Fourier methods; signal sampling (A/D) and reconstruction (D/A); digital filters; sample rate converters and oversampling; DFT, fast convolution, and spectrum estimation; and selected applications. Out-of-class projects done on DSP equipment in lab.
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4.00 Credits
Prerequisites: EE: EEC 314, EEC 315; CE: EEC 313, EEC 316. Feedback control systems: characteristics and analysis of feedback control systems; controlled system modeling; performance measures; stability; design using the root locus, frequency response, and state variable methods; characteristics of digital control loops; and digital controller design using the emulation method.
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2.00 Credits
Prerequisite: EE: EEC 315, CE: EEC 316. Pre- or co-requisite for EE and CE: EEC 440. A series of control system experiments including process control using a PID controller, and modeling and digital control of a torsion mechanism.
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4.00 Credits
Prerequisites: Senior standing. This course traces the idea of feedback control throughout history and is made broadly accessible to engineering and science majors alike at both undergraduate and graduate levels. By going back in time and trying to understand the problems that precipitated the great discoveries in controls, students strive to grasp the thought process of the great minds in the history of controls, leading to understanding and appreciation of the art and science of problem solving in the area of automatic control systems.
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4.00 Credits
Prerequisites: EE: EEC 314, EEC 315; CE: EEC 313, EEC 316. Applications of PLC's including ladder logic concepts, data manipulation, analog input and output with an emphasis on PID control, network configurations and concepts, and the solution of practical industrial problems through design projects.
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4.00 Credits
Prerequisites: EE: EEC 314, ESC 310; CE: EEC 311, EEC 313, ESC 310. Analog modulation techniques, system performance under noise, digital communication concepts, pulse and digital modulation schemes, data communication techniques, and spread spectrum communications.
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2.00 Credits
Prerequisites: EE: EEC 314, EEC 315; CE: EEC 313, EEC 316. Pre- or co-requisite for EE and CE: EEC 450. Use of communications-specific test and measurement equipment. Experiments on spectrum analysis, noise, amplitude, frequency and phase modulation, mixers, IF amplifiers, pulse modulation, sampling, baseband modulation, optimum receivers, and amplitude-, frequency-, and phase-shift keying.
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4.00 Credits
Prerequisites: EEC 361. Fundamental laws of electromagnetic fields: Gauss’s, Faraday’s, Ampere’s, and Biot-Savart’s. Maxwell’s equations as applicable to finite and infinitesimal regions in three-dimensional space and their engineering implications. Source distribution and boundary value engineering problems and their analytical or numerical solution. Electromagnetic waves propagation. Applications to the design of transmission lines, waveguides, and antennas.
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4.00 Credits
Prerequisites: EEC 314 and EEC 361. Analysis, performance characterization, and design of power electronics converters using diodes, thyristors, and controllable semiconductor switches. Power supplies and DC and AC motor drives.
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2.00 Credits
Pre- or co-requisite: EEC 470. Experiments dealing with single-phase and three-phase transformers; steady-state performance of dc, induction, and synchronous machines; rectifiers, inverters, switch-mode converters and their applications in adjustable motor drives.
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