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Course Criteria
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3.00 Credits
Credits: 3 Prerequisites: EE 352 Corequisites: EE 311 Type: LEC/LAB An engineering design lab. Fifty-minute lecture and 30-minute lab per week. Involves analyzing and designing single and multistage electronic circuits using FETs, BJTs, and op amps. Asks students to design a variety of amplifiers to meet certain specifications. They practice SPICE and use their knowledge of analog circuits to complete the projects.
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3.00 Credits
Credits: 3 Prerequisites: EE 02 Corequisites: EE 310 Type: LEC Topics include number systems; arithmetic; codes; Boolean algebra; minimization techniques; logic design; programmable logic devices; memory devices; registers; counters; synchronous sequential networks.
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3.00 Credits
Credits: 3 Prerequisites: EE 03 Corequisites: None Type: LEC The first of a two-course sequence in the area of RF and microwave circuit design. Initial topics include transmission line equations, reflection coefficient, VSWR, return loss, and insertion loss. Examples include impedance matching networks using lumped elements, single-section and multi-section quarter wave transformers, single-stub and double-stub tuners, the design of directional couplers, and hybrids. There is a student design project for a planar transmission line circuit based upon the software package Microwave Office. The design is fabricated and tested.
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3.00 Credits
Credits: 3 Prerequisites: MTH 4or MTH 306; PHY 108 Corequisites: None Type: LEC Introduces plasma processing including plasma deposition, plasma etching, gaseous electronics, gas lasers and plasma materials processing. Topics include basic atomic theory, elementary kinetic theory of gases, motion of charges in electric and magnetic fields, plasma properties, plasma generation and devices, plasma-surface interactions, electrodes and discharge characteristics, plasma diagnostics and plasma simulation. Students prepare web-based presentations in current plasma technologies with focus on applications in electrical engineering field.
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1.00 Credits
Credits: 1 Prerequisites: None Corequisites: None Type: SEM Covers the ethical, social, economic, and safety considerations in engineering practice essential for a successful engineering career.
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4.00 Credits
Credits: 4 Prerequisites: EE 310 Corequisites: None Type: LEC/LAB Design of electronic instruments, with emphasis on the use of analog and digital integrated circuits. Topics include techniques for precise measurements; sensors and their use for measurement of temperature, displacement, light, and other physical quantities; active and passive signal conditioning; and power supplies. Individuals or groups design and demonstrate an instrument, and provide a written report.
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4.00 Credits
Credits: 4 Prerequisites: EE 35and EE 353 Corequisites: None Type: LEC/LAB Examines operation and signaling in communications systems with a strong emphasis on circuits. Covers radio frequency systems (AM, FM, TV), telephone switching systems, microwave/wireless systems, fiber optics, modulation schemes, coding, multiplexing/demultiplexing, protocols, and networking. Discusses both analog and digital/data communication systems. Requires students to complete a capstone design project.
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: None Type: LEC Intended for first-year graduate students. Silicon-based integrated MEMS promise reliable performance, miniaturization and low-cost production of sensors and actuator systems with broad applications in data storage, biomedical systems, inertial navigation, micromanipulation, optical display and microfluid jet systems. The course covers such subjects as materials properties, fabrication techniques, basic structure mechanics, sensing and actuation principles, circuit and system issues, packaging, calibration, and testing.
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3.00 Credits
Credits: 3 Prerequisites: EE 303 or permission of instructor Corequisites: EAS 305 Type: LEC/REC Signals and samples, the z-transform. The discrete Fourier transform. Frequency and time-domain response of filters. Digital filter design, FIR and IIR filters. Digital filter structures. Multi-rate filters and signals. Fast convolution and correlation algorithms. Interdisciplinary aspects: VLSI for DSP; SAW and CCD devices; computational aspects. Heavy design experience with signal processing software. Students are expected to complete several design studies and a final project in the areas of digital filter design and signal processing algorithms. Matlab or similar packages are to be used both in the design process as well as in verification of design objectives.
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3.00 Credits
Credits: 3 Prerequisites: Senior Standing Corequisites: None Type: LEC Relation to classical mechanics, wave properties, Schrodinger equation, finite barrier potentials, tunneling, perturbation theory, nano-scale devices.
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