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Course Criteria
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3.00 Credits
Description: Integrated Circuit Model, application of integrated circuits to the design of amplifiers, active filters, oscillators, modulators, regulators and analog systems. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Principles, applications, and engineering of micro- electromechanical systems. Various MEMS designs and fabrication technologies are studied that are currently employed in a wide range of devices for actuation, sensing, micro-fluid manipulations, and RF and optical applications. Projects using MEMS device layout and simulation tools. Laboratory exercises with simple MEMS actuating devices. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: ECE 3500
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3.00 Credits
Description: Real-time computation of digital signal processing, adaptive filtering, spectrum estimation; implementation on a real-time digital signal processing chip; chip architecture, assembly language, and arithmetic; consideration of real-time processing such as aliasing, data quantization, computational limitations, signal level limiting, scaling, and I/O handling. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Undergraduate level ECE 5790 Minimum Grade of D-
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3.00 Credits
Description: Hardware implementation of real-time DSP. Parallel processing and architecture size/speed tradeoffs; Field Programmable Gate Arrays (FPGAs) and the use of the VHDL design language; development tools and libraries; FPGA implementation of filters and filter banks multirate processors, digital communication system components, implementation of advanced signal processing functions 3.00credit(s) 3.00 lecture hours Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: ECE 5790
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3.00 Credits
Description: System objectives and requirements for base-band transmission and recording of audio-frequency signals, especially music, emphasizing signal processing strategies used to meet these objectives. Topics: signal modeling and measurement, electronic-channel modeling and evaluation, digital audio, room acoustics, and system architecture. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: This class is a survey of popular synthesis techniques used to create electronic sounds and music. With a "hands on" approach to both analog and digital implementations of these techniques students will gain a solid understanding of the fundamentals of electronic sound generation and related measurements, all from an engineering perspective. Some of the theories and techniques covered will be: FM synthesis, AM synthesis, Physical modeling, Granular synthesis, wave-shaping, additive synthesis, Analysis-based Resynthesis, and more. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Undergraduate level ECE 3220 Minimum Grade of D- or Graduate Engineering level ECE 8240 Minimum Grade of C
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3.00 Credits
Description: Building blocks of radio communication systems; modulators, mixers, narrow & broadband small signal amplifiers, oscillators & power amplifiers. Interstage matching networks in detail, practical design techniques. Present day communication systems used as examples. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: The design of renewable energy systems. Topics include: Solar Thermal Energy, Photovoltaics, Bioenergy, Hydroelectricity, Tidal Power, Wind Power and Geothermal Energy. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Applied mathematics course tailored to the needs of EE graduate students. Topics: i) Complex variable theory, ii) Sturm-Liouville problem, eigen-function expansion and special functions, iii) Matrix theory, eigen value and diagonalization, iv) Fourier analysis, multi-dimensional Fourier series and transforms, and v) Partial differential equations. Various examples from engineering and physics will be incorporated as appropriate. 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 Engineering Mathematics I. Topics: asymptotic expansions, integral equations, calculus of variations, regular and singular perturbation theory, inverse scattering transforms, and numerical methods. 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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