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Course Criteria
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3.00 Credits
Description: This course covers the implementation and design of both hybrid and monolithic microwave integrated circuits(MIC). Emphasis is placed on the modeling and simulation of circuit designs involving active and passive elements. CAE tools will be heavily used to perform case studies on the basic building blocks that make-up typical MIC systems, such as amplifiers, mixers, switches, and filters. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Fundamental principles for design of integrated circuits for use at radio frequency using CMOS technology. Topics: introduction to communications circuits and parameters, issues in RFIC design: noise, linearity, filters, review of technology; fabrication process, MOSFET transistors, design, simulation and use of passive elements in the MOS process, impedance matching, amplifier design; and low noise and general gain circuits, mixers, oscillators, power amplifiers. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Principles of operation, terminal chacteristics and circuit implementation of various optoelectronic devices. Devices: light emitting diodes, semiconductor lasers, infrared photodetectors, optoisolators, charge coupled devices, solar cells, and optoelectronic switching. SPICE modeling of devices and circuits containing these devices will be emphasized. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 7500 Minimum Grade of C
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3.00 Credits
Description: Application of semiconductor power devices (e.g., power FET's SCR's, TRIAC's) with emphasis on high-reliability applications. Device characteristics; linear and switch-mode power supplies; voltage regulators; power amplifiers; high-current switching applications. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8550 Minimum Grade of C
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3.00 Credits
Description: Beginning graduate course in electromagnetics. Material covered is a prerequisite for advanced course in applied electromagnetism. Topics: Maxwell's equations, boundary conditions, wave propagation, reflection and transmission, waveguides and transmission lines and cavity resonators. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8001 Minimum Grade of C
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3.00 Credits
Description: Continuation of Engineering Electromagnetics I. Topics: scattering theory, moment methods, geometircal theory of diffraction and Green's functions as applied to electromagnetic problems. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Modern analysis and design techniques for use with microwave and millimeter-wave frequency range. Topics a review of Maxwell's equation; transmission lines and waveguides; planar guiding structures including stripline, microstrip, slotline and coplanar waveguides; scattering parameters and microwave network theory with applications to transmission line and waveguide junctions and obstacles; Impedance matching and tuning; examples of microwave passive devices including power dividers, couplers and hybrids. Prerequisite: Undergraduate Electromagentic Theory 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Undergraduate level ECE 3690 Minimum Grade of D-
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3.00 Credits
Description: Continuation of study of microwave passive devices and network theory covered in ECE 8670. Analysis and design of two and three terminal microwave solid-state devices and ciricuits such as mixers, frequency multipliers, oscillators, control circuits and amplifiers are covered. Included is the study of microwave filters, systems and ferromagnetic devices. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8670 Minimum Grade of C
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3.00 Credits
Description: Fundamental principles of antenna theory and application to analysis and design of various antennas. Topics: antenna fundamentals including radiation from an ideal dipole, pattern, gain, polarization, antenna temperature, radar range equation and link budget calculations; analyses of wire and loop antennas; antenna arrays, analysis and synthesis; impedance concept and mutual coupling; broadband and frequency independent antennas; antenna radiation above ground, modes of propagation and multipath; numerical modeling of wire antennas using method of moments. System application of various antennas in radar, satellite and mobile communications. Prerequisite: Undergraduate Electromagnetic Theory 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Continuation of Antenna Theory I. Topics: Method of Moments, Geometrical Theory of diffraction, aperture and horn antennas, microstrip and low profile antennas, reflector antennas, lens antennas, dielectric and leaky-wave antennas, application of high Tc superconductors to antenna systems. Review of mathematical and numerical techniques required for understanding advanced topics, modern trends in modeling and application of various antenna systems. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8675 Minimum Grade of C
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