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Course Criteria
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3.00 Credits
3 hrs. A review of discrete time signals and systems; sampling of continuous time signals, sampling theorem; discrete time Fourier transforms; Z-transforms; region of convergence; applications; discrete Fourier transforms; fast Fourier transforms; design of digital filters, IIR filters, FIR filters, and computer-aided design. Prerequisite: EE 301
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3.00 Credits
3 hrs. Solution of Laplace's equation in two dimensions, circular harmonics, cylindrical harmonics, method of finite differences; wave propagation, perfect dielectrics, conductors, lossy dielectrics, transmission line analogy, Smith chart solutions; and computer applications are covered. Prerequisite: EE 303
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3.00 Credits
3 hrs. Introduction to principles of monolithic IC fabrication including bipolar and MOS transistor processing. The course includes active and passive device and process design, simulation, cleanroom procedures, in-process and final test and evaluation techniques, yield, chip assembly and packaging. A practicum is required. Prerequisite: EE 305, Corequisite: EE 451L
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1.00 Credits
1 hr. This laboratory course provides a hand-on clean room experience fabricating an integrated circuit (IC) chip. Silicon-based semiconductor technology and standard IC microfabrication processes for the fabrication of the microchip will be implemented through the course. Specific clean room fabrication processes and techniques used in the class include basic clean room skills, mask layout and fabrication, UV lithography, wet and dry oxidation, wet and dry etching, thermal diffusion, metallization, packaging, and device characterization. The students will fabricate a device wafer and characterize the electrical properties of the fabricated devices and circuits on the wafer. Corequisite: EE 451
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3.00 Credits
3 hrs. Basic principles of semiconductor testing and evaluation. Various tools and techniques will be introduced for test and evaluation of semiconductor materials, devices and integrated circuits. Prerequisite: EE 305
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3.00 Credits
3 hrs. A review of state space methods; optimal control problems, performance criterion, minimum time problems, minimum energy problems, and minimum fuel problems; optimization, using calculus of variations, Lagrange, Meyer, and Bolza problems, Lagrange equations, solution, applications; Pontryagin's maximum principle, formulation, costate variables, solution; dynamic programming, principle of optimality, discrete control processes; Hamilton-Jacobi approach, closed loop control law, matrix Riccati equation, applications; and stability in the sense of Lyapunov are covered. Prerequisite: EE 403
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3.00 Credits
3 hrs. A study of nonlinearities, classification, saturation, dead zone, hysteresis; phase plane formulation, phase portraits; describing function approach, limit cycles, and relay servomechanisms. Prerequisite: EE 403
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2.00 Credits
2 hrs. Students must demonstrate their complete engineering capabilities by participating in a capstone design project. Project management and engineering ethics are included. This first course is provided to facilitate project selection, literature survey, and orientation. Meeting times are flexible. Prerequisite: Senior Standing and Approval of Instructor
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2.00 Credits
2 hrs. This is a continuation of EE 470 and is provided to facilitate completion of the capstone design project. Meeting times are flexible. Prerequisite: EE 470
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3.00 Credits
3 hrs. This course focuses on topics based on modern trends in electrical engineering. This course can be taken multiple times with students receiving additional credit each time. The specifics of each course will be identified at the beginning of each semester. Prerequisite: Senior Standing or Approval of Instructor
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