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Course Criteria
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3.00 Credits
Practical microprocessor principles, programming, and interfacing. Design of programs for basic data acquisition and control using the microprocessor as a system component. Review of number systems and digital logic. Fall semester. Lecture 2 hours, projects 3 hours. Prerequisites: ENGR 2250, ENEE 3720L, ENEE 3720, ENEE 3770, ENEE 3770L with minimum grades of C or department head approval. Laboratory/Studio course fee will be assessed. Supplementary course fee assessed.
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3.00 Credits
Power Systems component modeling, transmission lines, machines, transformers. Load flow analysis, symmetrical components, symmetrical and unsymmetrical fault analysis. Fall semester. Lecture 3 hours. Prerequisite: ENEE 380 with grade of C or better.
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3.00 Credits
Power Systems component modeling, transmission lines, machines, transformers. Load flow analysis, symmetrical components, symmetrical and unsymmetrical fault analysis. Fall semester. Lecture 3 hours.
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4.00 Credits
Definitions and basic concepts of analog and digital modulation techniques. Fourier series and transform techniques used to study transmission of signals through linear filters, time-bandwidth relationships. Amplitude, frequency, and pulse modulation techniques described and analyzed. Periodic sampling and the Nyquist sampling criterion. Fall semester. Lecture 4 hours. Prerequisites: ENGR 222 and ENEE 373 with grades of C or better.
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4.00 Credits
Definitions and basic concepts of analog and digital modulation techniques. Fourier series and transform techniques used to study transmission of signals through linear filters, time-bandwidth relationships. Amplitude, frequency, and pulse modulation techniques described and analyzed. Periodic sampling and the Nyquist sampling criterion. Fall semester. Lecture 4 hours. Prerequisites: ENGR 2220 and ENEE 3730 with minimum grades of C or department head approval. Laboratory/Studio course fee will be assessed. Supplementary course fee assessed.
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3.00 Credits
Optical fiber as a transmission medium using ray theory and wave theory approaches. Characteristics and practical aspects of optical fiber communications Measurements undertaken in the laboratory and field. Light sources and detectors with particular emphasis on System design, application, and performance. Basic principles used for optical sensors. Electro-optic devices. On demand. Lecture 3 hours. Prerequisites: Physics 232, Mathematics 245, 255.
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3.00 Credits
Optical fiber as a transmission medium using ray theory and wave theory approaches. Characteristics and practical aspects of optical fiber communications Measurements undertaken in the laboratory and field. Light sources and detectors with particular emphasis on System design, application, and performance. Basic principles used for optical sensors. Electro-optic devices. On demand. Lecture 3 hours. Prerequisites: PHYS 2320, MATH 2450, MATH 2550 or department head approval. Supplementary course fee assessed.
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3.00 Credits
Definitions and basic concepts of analog and digital modulation techniques. Ethical considerations; global and societal effects of communications technology. Transmission of signals through linear filters, time-bandwidth relationships. Amplitude, frequency, and pulse modulation techniques described and analyzed. Periodic sampling and the Nyquist sampling criterion. Applications of probability to error rates and noise probabilities. Fall semester. Lecture 3 hours. Prerequisites: Engineering 222 and 325 with grades of C or better.
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3.00 Credits
Definitions and basic concepts of analog and digital modulation techniques. Ethical considerations; global and societal effects of communications technology. Transmission of signals through linear filters, time-bandwidth relationships. Amplitude, frequency, and pulse modulation techniques described and analyzed. Periodic sampling and the Nyquist sampling criterion. Applications of probability to error rates and noise probabilities. Fall semester. Lecture 3 hours. Prerequisites: ENGR 2220 and ENEE 3250 with minimum grades of C or department head approval. Supplementary course fee assessed.
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3.00 Credits
Basic principles of operation of commonly used sensors. Signal conditioning and grounding considerations. Introduction to programming of virtual instruments using software such as LabVIEW. Specification and design of systems to acquire, condition, display, and control using data from multiple sensors and programmable controllers. Semester group design project included. Spring semester. Lecture 3 hours. Prerequisites: Senior standing within 24 semester hours of graduation, or approval of the instructor; ENGR 225, ENEE 377, 378, 340 with grades of C or better.
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