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EE 462: Principles of Medical and Radar Imaging
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: EE 303 Corequisites: None Type: LEC Applications of multidimensional signal theory and Fourier analysis. Topics include review of signal processing tools and systems used in array imaging, including coherent receivers, pulsed and continuous wave signaling, temporal Doppler phenomenon, and monostatic, quasi-monostatic, bistatic transmitters/receivers, and -D signal processing; examining specific array imaging systems, including phased array imaging, synthetic aperture (SAR and ISAR) imaging, passive array imaging, and bistatic array imaging with emphasis on transmission imaging problems of diagnostic medicine and geophysical exploration.
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EE 462 - Principles of Medical and Radar Imaging
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EE 465: Current Research Topics of Pulsed Power Applications
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: None Corequisites: None Type: LEC/LAB Involves a design project based on pulsed power that utilizes the fundamentals needed to become a successful engineer in the business world. Pulsed power focuses on achieving high peak powers by impulse and rep-rate methods. Topics in this area of research include switching, surface flashover of insulators, and other related areas. Students form Integrated Project Teams to work on their projects and address the relevant issues in a multidisciplinary (electrical engineering) team. Student grades are based on peer reviewed effort, technical reports, and oral presentations.
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EE 465 - Current Research Topics of Pulsed Power Applications
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EE 476: High-Voltage Engineering
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: EE 03, EE 48 Corequisites: None Type: LEC Topics include introduction to high-voltage engineering; generation of high voltages (AC, DC, impulse, pulse); measurements of high voltages; destructive and nondestructive insulation test techniques; shielding and grounding; electric shock and safety. Paper in a related high-voltage area and an in-class presentation required.
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EE 476 - High-Voltage Engineering
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EE 478: Digital Design
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: EE 378 Corequisites: None Type: LEC Topics include analysis and design of clocked synchronous sequential networks; design of algorithmic state machines; analysis and design of asynchronous sequential networks; CPLDs and FPGAs; CAD tools; introduction to VHDL.
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EE 478 - Digital Design
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EE 480: Biomedical Electronics
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: None Corequisites: None Type: LEC Covers the principles and designs of various important biomedical instruments including pacemaker, EEG, ECG, EMG, and ICU equipment and diagnostic imaging devices (such as blood bank monitor), CT, MRI, mammography, ultrasound, endoscope, confocal microscope, and multiphoton non-linear microscope (-photon fluorescent, SHG and THG). Imaging devices (e.g., CCDs) and medical image processing are also covered. Includes a general introduction to biological systems; emphasizes the structural and functional relationship between various biological compartments.
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EE 480 - Biomedical Electronics
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EE 482: Power Systems Engineering I
4.00 Credits
University at Buffalo
Credits: 4 Prerequisites: EE 03 or EE 34 Corequisites: None Type: LEC/LAB Surveys the field of modern energy systems, with the foundation being classical electrical power and related power electronics. Topics include complex power, per unit analysis, transmission line parameters and modeling, and compensation. Students also study alternative energy systems in this course. Course also includes use of a Power Simulation Program in which modeling can be done. This program is also used for the final system design project paper which accounts for 50% of the course grade.
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EE 482 - Power Systems Engineering I
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EE 483: Communications Systems I
4.00 Credits
University at Buffalo
Credits: 4 Prerequisites: EE 303 Corequisites: EAS 305 Type: LEC/LAB Fourier transforms and spectra; linear filters; transmission of signals through linear systems; bandpass signals; bandpass systems; continuous wave modulation; amplitude modulation (AM); double sideband modulation (DSB); single sideband modulation (SSB), phase modulation (PM); frequency modulation (FM); quadrature amplitude modulation (QAM); frequency division multiplexing (FDM); demodulation of analog modulated signals; random variables; statistical averages; random processes; autocorrelation and power spectral density; stationarity; transmission of random processes through linear systems; white noise; colored noise; Gaussian noise; noise in continuous wave modulation systems; signal-to-noise-ratio (SNR); sampling; pulse amplitude modulation (PAM).
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EE 483 - Communications Systems I
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EE 484: Communications Systems II
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: EE 483 Corequisites: None Type: LEC Topics include review of PAM-, PDM-, PPM-pulsed modulation techniques; principles of digital communications; pulse code modulation; signal quantization; binary communications systems; M-ary communications systems; detection and parameter estimation for pulses in noise; the likelihood ratio receiver; and applications to radar signal processing.
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EE 484 - Communications Systems II
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EE 488: VLSI Devices
3.00 Credits
University at Buffalo
Credits: 3 Prerequisites: EE 311 Corequisites: None Type: LEC Device fundamentals of CMOS field effect transistors and BiCMOS bipolar transistors. Device parameters and performance factors important for VLSI devices of deep-submicron dimensions. Reviews silicon materials properties, basic physics of p-n junctions and MOS capacitors, and fundamental principles of MOSFET and bipolar transistors. Design and optimization of MOSFET and bipolar devices for VLSI applications. Discusses interdependency and tradeoffs of device parameters pertaining to circuit performance and manufacturability. Also discusses effects in small-dimension devices: quantization in surface inversion layer in a MOSFET device, heavy-doping effect in the bipolar transistor, etc.
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EE 488 - VLSI Devices
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EE 489: Lasers and Photonics
4.00 Credits
University at Buffalo
Credits: 4 Prerequisites: EE 311 Corequisites: None Type: LAB/LEC Topics include an introduction to lasers and photonics; a short review of electromagnetic theory; ray tracing and lens systems; polarization of light and polarization modulators; Gaussian beams and wave propagation; optical resonators and cavity stability; spontaneous emission, stimulated emission and absorption; rate equations for gain medium; population inversion; characteristics and applications of specific lasers; waveguides and fiber optics; fiber optic communications systems; electro-optic modulators; and acoustic-optic modulators. Requires students to complete a project focusing on the design of a laser system including choice of gain medium, cavity optics, pumping mechanism, power and efficiency estimates, and cost analysis. Requires reports and presentations.
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EE 489 - Lasers and Photonics
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