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Course Criteria
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3.00 Credits
(247) (Formerly offered as EE 247.) Semester by arrangement. Three credits. Prerequisite: ECE 3101. Discrete-time signals and systems. The ztransform. Digital filters; stability, frequency response, canonic realizations and state equations. Fourier methods for discrete signal representation; Fourier transform of sequences, the discrete Fourier transform, and the FFT. Design of linear digital filters in time and frequency domains. Spectrum analysis and filtering via the FFT.
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3.00 Credits
(292) First semester. Three credits. Prerequisite or corequisite: ECE 4111 or 4112 or instructor consent. Laboratory experiments in signal processing, realtime digital filters, image processing, imaging systems, data acquisition using detectors, pattern recognition, communication receivers, and system performance evaluation. Emphasis is on real-time information processing systems with interface between sensors and computer/processors. Applications of analog and digital techniques to design, implementation and testing of real-time information processing systems.
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3.00 Credits
(227) Semester by arrangement. Three credits. Prerequisite: ECE 3001. An introduction to the general hardware components, system parameters, and architectures of radio-frequency (RF) and microwave wireless systems. Practical examples will be drawn from communication as well as radar/sensor systems.
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3.00 Credits
(240) (Formerly offered as EE 240.) Second semester. Three credits. Prerequisite: ECE 3201 or 3608. Recommended preparation: ECE 3111. Analysis and design of linear amplifiers. The effects of feedback in tuned, video, and operational amplifiers. Noise, stability, and frequency compensation. Applications encompass active filters, oscillators, phase lock loops and nonlinear operations such as multiplication, modulation, sampling, and analog-to-digital conversion.
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3.00 Credits
(245) (Formerly offered as EE 245.) Second semester. Three credits. Prerequisite: ECE 3201 or 3608. Principles and applications of contemporary solid state devices such as light-emitting diodes, injection lasers, solar cells, p-n-p-n diodes, SCR and Triacs, IMPATT diodes, Schottky devices, bipolar and MOS transistors, MESFETs and MODFETs, and fundamentals of integrated circuits.
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3.00 Credits
(228) (Formerly offered as EE 228.) Semester by arrangement. Three credits. Prerequisite: ECE 207 or 3001 or PHYS 3201. Application of Maxwell's equations and geometric optics first to two-dimensional dielectric waveguides and then to cylindrical fibers. Ray and mode theory, eigenvalues, Goos-Haenchen shift. Step-index, gradedindex, and single-mode fibers. Splicers, couplers, sources, detectors and optical design. Fiber manufacturing techniques.
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3.00 Credits
(229) (Formerly offered as EE 229.) Second semester. Three credits. One four-hour laboratory period. Prerequisite: ECE 4231. Hands-on design and measurement of fiber-optic applications. Fiber-optic communications and fiberoptic sensors. Structured experiments and design projects centered around available equipment.
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3.00 Credits
(268) (Formerly offered as EE 268.) First semester. Three credits. One class period, and one 4-hour laboratory period. Prerequisite: ECE 3221, 4211. Semiconductor wafer preparation and characterization including: determination of carrier concentration, mobility, and lifetime; oxidation, diffusion, metallization, mask layouts, and photolithographic techniques as employed in the realization of discrete devices (e.g., bipolar and MOS transistors, solar cells) and integrated circuits; design of basic IC components such as transistors, resistors, and capacitors; monolithic fabrication of simple digital/ analog circuits. Design project. Written and oral presentations of laboratory results.
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3.00 Credits
(251) (Also offered as ENGR 4244) Second semester.Three credits. One-hour lecture and fourhour laboratory. Prerequisites: Senior standing and ECE 4211 or ENGR 4243. Growth and characterization of carbon nanotube using vapor phase nucleation; growth of CdSe quantum dots using liquid phase precipitation and vapor phase MOCVD reactor; characterization using AFM and TEM and dynamic scattering techniques; device processing highlighting nanolithography (E-Beam), and self assembly techniques; project work involving fabrication of devices such as LEDs, carbon nanotube based FETs, and sensors using self-assembled quantum dots hosted in inorganic or organic/polymer layers.
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3.00 Credits
(280) (Also offered as CSE 3350.) (Formerly offered as EE 280.) First semester. Three credits. Four hours of laboratory. Prerequisite or corequisite: CSE 3302/ ECE 3401. Digital designing with PLA and FPGA, A/D and D/A conversion, floating point processing, ALU design, synchronous and asynchronous controllers, control path; bus master; bus slave; memory interface; I/O interface; logic circuits analysis, testing, and trouble shooting; PBC; design and manufacturing.
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