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DESCRIPTION OF GRADUATE COURSES |
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 ELEN-602 - ELEN-686
ELEN-701 - ELEN-799
ELEN-801 - ELEN-885
ELEN-991 - ELEN-999
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| ELEN-602 |
Semiconductor Theory and Devices |
Credit 3(3-0) |
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| This course is a study of the phenomena of solid-state conduction and devices using band models, excess carriers in semiconductors, p-n junctions, and devices. Prerequisites: ELEN-460 or consent of instructor. |
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| ELEN-606 |
Digital Electronics |
Credit 3(3-0) |
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This course covers analysis, design and applications of digital integrated circuits. These circuits may include resistor-transistor logic (RTL), diode transistor logic (DTL), transistor-transistor (TTL), emitter-coupled logic (ECL), metal-oxide-semiconductor (MOS) gates and n-channel MOS (NMOS) logic, complementary MOS (CMOS) logic, Bipolar CMOS (BiCMOS) structures, memory circuits, and interfacing circuits. Prerequisite: ELEN-460 or consent of instructor. |
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| ELEN-608 |
Analog Electronics |
Credit 3(3-0) |
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| This course covers the analysis, design and application of analog integrated circuits. These circuits may include operational amplifiers, voltage comparators, voltage regulators, Integrated Circuit (IC) power amplifiers, Digital to Analog (D/A) and Analog to Digital (A/D) converters, voltage-controlled oscillators, phase-locked loops, other special-function integrated circuits. Prerequisite: ELEN-460 or consent of instructor. |
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| ELEN-610 |
Power Electronics |
Credit 3(3-0) |
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| This course is an introduction to principles and methods of power electronics. Subjects covered are semiconductor devices and their complementary components and systems, different static switching converters like AC to DC AC to AC, DC to DC and DC to AC converters and their applications. Pre-requisite: ELEN-320 or consent of instructor. |
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| ELEN-614 |
Integrated Circuit Fabrication Methods |
Credit 3(3-0) |
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| This course presents the various processes utilized in the fabrication of semiconductor integrated circuits. Oxidation, diffusion, ion implantation, metalization, and epitaxial processes will be discussed. Limits on device design and performance will be considered. Prerequisite: ELEN-470 or consent of instructor. |
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| ELEN-615 |
Silicon Device Fabrication Laboratory |
Credit 2(1-3) |
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| Laboratory experiments in the fabrication of silicon p-n junction diodes, MOS capacitors and MOS field effect transistors will be performed. Oxidation, diffusion, photolithography, and metalization techniques will be presented. Co-requisite: ELEN-614. |
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| ELEN-621 |
Embedded Systems Design |
Credit 3(3-0) |
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| This course is a survey of modern methods for specifying algorithms, simulating systems, and mapping specifications onto embedded systems. It presents an introduction to the technologies used in the design and implementation of programmable embedded systems, such as programmable processors, cores, memories, dedicated and configurable hardware, software tools, schedulers, code generators, and system-level design tools. Prerequisite: ELEN-427 or consent of instructor. |
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| ELEN-622 |
Embedded Systems Design Laboratory |
Credit 2(1-3) |
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| This laboratory course is an introduction to developing processor-based embedded systems. The development tools include a C++ cross compiler, an Electronically Programmable Read Only Memory (EPROM), and an Application Specific Integrated Circuit (ASIC) programmer. A student project is part of the laboratory requirements. Co-requisite: ELEN-621. |
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| ELEN-623 |
Digital Systems |
Credit 3(3-0) |
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| Digital system top-down design and analysis will be presented. Topics include timing, power and performance issues in digital circuits, Very High Speed Integrated Circuit Hardware Description Language (VHDL)-based system analysis and synthesis, hardware-software co-design, data-flow models, and digital system primitives. Pre-requisite: ELEN 427 or consent of instructor. |
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| ELEN-624 |
Computer Organization and Architecture Design |
Credit 3(3-0) |
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| This course covers the design of modern uniprocessors and their memory, and Input/Output (I/O) subsystems. Performance, microarchitecture, and design philosophies used to realize pipeline, superscalar, Reduced Instruction Set Computer (RISC) and Complete Instruction Set Computer (CISC) processors will be studied. Prerequisites: ELEN-427 or consent of instructor. |
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| ELEN-629 |
VLSI Circuit Design |
Credit 3(3-0) |
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| This course will study CMOS technology and device characteristics in order to develop layout design rules for VLSI circuit building blocks, such as inverters and logic gates. Layout techniques for complex gates and designing combinational and sequential logic circuits will be introduced. Prerequisite: ELEN-427 or consent of instructor. |
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| ELEN-630 |
VLSI Design Laboratory |
Credit 2(1-3) |
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| This is an introduction of Computer Aided Design (CAD) tools for integrated circuit design and verification. These CAD tools include; geometric pattern generators, design rule checkers, circuit simulators, and Programmable Logic Array (PLA) generators. A student design project is part of the laboratory requirements. Co-requisite: ELEN-629. |
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| ELEN-647 |
Introduction to Telecommunication Networks |
Credit 3(3-0) |
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| This course introduces telecommunications networks utilization and design. Emphasis is on using and designing voice, video and image digital networks. Prerequisite: ELEN-400. |
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| ELEN-650 |
Digital Signal Processing I |
Credit 3(3-0) |
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| This course develops a working knowledge of the basic signal processing functions, such as digital filtering spectral analysis, and detection/post-detection processing. Methods of generating the coefficients for digital filters will be derived. Alternate structures for filters, such as infinite impulse response and finite impulse response will be compared. The effect of finite register length will be covered. Prerequisites: ELEN-400 or consent of instructor. |
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| ELEN-651 |
Digital Signal Processing Laboratory |
Credit 2(1-3) |
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| Experiments and student projects will be performed which are related to the practical applications of digital signal processing techniques to data acquisition, digital filtering, control, spectral analysis, and communications, etc. Co-requisite: ELEN-650 or consent of instructor. |
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| ELEN-656 |
Probability and Random Processes |
Credit 3(3-0) |
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| This course covers sample space, events, conditional probabilities, independent events, Bayes' formula, discrete random variables, expectation of random variables, joint distribution, conditional expectation, Markov chains, stationary processes, ergodicity, correlation and power spectrum of stationary processes, and Gaussian processes. Prerequisite: ELEN-310 or consent of instructor. |
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| ELEN-657 |
Digital Image Processing |
Credit 3(3-0) |
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| This course deals with concepts and techniques for digital image analysis and processing. Topics include image representation, image enhancement, edge extraction, image segmentation, geometric structure, feature extraction, knowledge representation, and image understanding. Prerequisite: ELEN-400 or consent of instructor. |
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| ELEN-658 |
Digital Image Processing Laboratory |
Credit 2(1-3) |
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| This laboratory course will demonstrate many important and practical applications of digital image processing techniques. The experiments include image enhancement, feature extraction, Hough transform, and various transforms in spatial and frequency domains, image understanding and quantization. Co-requisite: ELEN- 657 or consent of instructor. |
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| ELEN-661 |
Power Systems Analysis |
Credit 3(3-0) |
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| The course studies power system representation, transmission lines, symmetrical and asymmetrical faults, electric power flow, power systems control and stability. Prerequisite: ELEN-430. |
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| ELEN-662 |
Advanced Power Systems Laboratory |
Credit 2(1-3) |
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| In this laboratory course, basic concepts, transmission lines, power flows, faults, and transient and steady-state stability will be investigated. Prerequisite: ELEN-436 or consent of instructor Co-requisite: ELEN-661. |
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| ELEN-668 |
Automatic Control Theory |
Credit 3(3-0) |
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| This course introduces the theory of linear systems represented by state equations. Topics include Jordan canonical form, solutions to state equations, relationship to transfer functions, stability, controllability, and pole placement design. Prerequisite: ELEN-410 or consent of instructor. |
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| ELEN-669 |
Control Laboratory |
Credit 2(1-3) |
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| This laboratory course demonstrates methods of system identification and control. Verifications of control system designs in both the time domain and frequency domain will be studied. Co-requisite: ELEN-661. |
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| ELEN-674 |
Genetic Algorithms |
Credit 3(3-0) |
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| This course covers the theory and application of genetic algorithms. Genetic algorithms combine a Darwinian survival-of-the-fittest with a randomized, yet structured, information exchange to form an improved search mechanism with surprising robustness. Engineering applications of genetic algorithms for design and control will be presented. Prerequisite: ELEN-410 or consent of instructor. |
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| ELEN-678 |
Introduction to Artificial Neural Networks |
Credit 3(3-0) |
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| This course introduces neural network design and development. Emphasis is on designing and implementing information processing systems that autonomously develop operational capabilities in adaptive response to an information environment. Prerequisite: ELEN-400 or consent of instructor. |
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| ELEN-679 |
Machine Intelligence Laboratory |
Credit 2(1-3) |
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| This laboratory will explore the design and development of intelligent, autonomous, physical agents. An emphasis will be placed upon machine intelligence experiments with visual sensors, tactile sensors, robotic manipulators and autonomous inexpensive mobile robots. Prerequisite: ELEN-433 or consent of instructor. Co-requisite: ELEN-678. |
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| ELEN-685 |
Selected Topics in Engineering |
Credit 3(3-0) |
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| This lecture course is used to introduce engineering topics of current interest to students and faculty. The subject matter will be identified before the beginning of the course. Prerequisite: consent of instructor. |
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| ELEN-686 |
Special Projects |
Credit Var (1-3) |
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| This is an investigation of an engineering topic which is arranged between a student and a faculty advisor. Project topics may be analytical and/or experimental and should encourage independent study. Prerequisite: consent of instructor. |
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| ELEN-701 |
Electronic Ceramics |
Credit 3(3-0) |
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| This course introduces the properties of ceramic materials in electronic applications. The effects of processing parameters on the ultimate device characteristics will be investigated. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-710 |
Wave and Fields in Radio Frequency (RF) and Optoelectronics |
Credit 3(3-0) |
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| This course emphasizes principles, phenomena and methods relevant to RF and lightwave technology. The topics will include basic electromagnetic propagation in free space and material media, guided electromagnetic waves, modes and mode coupling, and Bragg and other types of scattering. This course will establish the field principles of RF, integrated optic and fiber based devices and circuits. Prerequisite: ELEN-450 or ELEN-470 or consent of instructor. |
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| ELEN-720 |
Theoretical Issues in Computer Engineering |
Credit 3(3-0) |
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| This course is designed to introduce some basic theoretical aspects of computer engineering. It includes selected topics in the set theory, elements of algebra such as semigroups, monoids, groups, rings, and fields, quotient groups and homomorphism theorems. It also includes finite state machines, the Myhill-Nerode theory, pseudo/random generators, linear feed back registers, introduction to error correcting codes and Turing Machines. Various applications will be demonstrated. Prerequisite: ELEN-427 or consent of instructor. |
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| ELEN-721 |
Fault-Tolerant Digital System Design |
Credit 3(3-0) |
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| This course covers reliability, test generation, self checking techniques, principles and applications of fault-tolerant design techniques. Prerequisite: ELEN-625 or consent of instructor. |
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| ELEN-723 |
System Design Using Programmable Logic Devices |
Credit 3(3-0) |
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| This course will cover and compare many commercially available Programmable Logic Devices and consider their applications in both combinational and sequential logic system design. Students will also be familiarized with hardware description language such as VHDL and ABELTM and shown how design ideas can be efficiently translated into programmable hardware implementations. Prerequisite: ELEN-623 or consent of instructor. |
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| ELEN-724 |
Mixed-Signal VLSI Design |
Credit 3(3-0) |
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| This course will introduce CMOS circuit techniques for low-power, low-voltage mixed-signal integrated circuits. Continuous-time signal processing, sampled-data analog filters, delta-sigma data converters, and mixed analog-digital layout techniques will be introduced. Prerequisite: ELEN-629 or consent of instructor. |
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| ELEN-725 |
Pervasive Computing Systems |
Credit 3(3-0) |
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| This course is a study of Pervasive Computing (a.k.a. Ubiquitous Computing) which is the integration of computer technology into day-to-day life in a seamless manner. This course will address accepted design and implementation approaches relevant to this field, including those used for wearable computing, smart devices, intelligent environments, context aware computing, and user interfaces and interaction models. A course project will be assigned. Prerequisite: ELEN-621 or consent of instructor. |
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| ELEN-727 |
Switching and Finite Automata Theory |
Credit 3(3-0) |
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| This course presents the abstract mathematical modeling of combinational and sequential switching networks. Finite automata theory and fault tolerant concepts with applications to both combinational networks and finite state machines will be presented. Prerequisite: ELEN-427 or consent of instructor. |
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| ELEN-749 |
Digital Communications |
Credit 3(3-0) |
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| The fundamental theory and applications of the digital communications system are discussed based on the knowledge of the probability theory. Topics in digital communications include sampling, quantizing, coding, detection, modulation/ demodulation, signal-to-noise ratio, and error probability. Prerequisites: ELEN-449 or consent of instructor. |
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| ELEN-752 |
Wireless Information Networks |
Credit 3(3-0) |
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| Fundamental theory and applications of wireless mobile communication systems are covered for voice, data, and multimedia. Topics in wireless networks include characterization of radio propagation, source and channel coding, theory and analysis of wireless data networks, and wireless Local Area Networks (LANs). The wireless LANs discussion includes multiple access techniques and computer simulation of radio channels. Prerequisites: ELEN-452 or consent of instructor. |
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| ELEN-762 |
Network Matrices and Graphs |
Credit 3(3-0) |
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| Use of vector space techniques in the description, analysis and realization of networks modeled as matrices and graphs. The course investigates vector space concepts in the modeling and study of networks. The system concept of networks is introduced and explored as a dimensional space consideration in terms of matrices and graphs. Prerequisite: ELEN-400 or equivalent. |
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| ELEN-764 |
Power System Planning |
Credit 3(3-0) |
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| This course presents an overview of the issues and methods relevant to power systems planning. The course reviews the basics of financial analysis, regression analysis, forecasting, and reliability. Special topics relevant to power systems, such as deregulation, peak-load forecasts, load management and representation, and the loss-of-load probability (LOLP) method are also considered. Prerequisite: ELEN-661 or consent of instructor. |
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| ELEN-785 |
Masters Special Topics |
Credit 3(3-0) |
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| This lecture course is used to introduce engineering topics of current interest to master students and faculty. The subject matter will be identified before the beginning of the course. Prerequisite: Consent of instructor. |
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| ELEN-792 |
Masters Seminar |
Credit 1(1-0) |
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| Discussions and reports of subjects in electrical engineering and allied fields will be presented. Prerequisite: Master level standing. |
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| ELEN-793 |
Masters Supervised Teaching |
Credit 3(3-0) |
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| Students will gain teaching experience under the mentorship of faculty who assist the student in planning for the teaching assignment, observe and provide feedback to the student during the teaching assignment, and evaluate the student upon completion of the assignment. Prerequisite: Master level standing. |
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| ELEN-794 |
Masters Supervised Research |
Credit 3(3-0) |
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| This course is supervised research under the mentorship of a faculty member. It is not intended to serve as the project or thesis topic of the masters student. Prerequisite: Master level standing and consent of instructor. |
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| ELEN-796 |
Masters Project |
Credit 3(3-0) |
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| The student will conduct advanced research of interest to the student and the instructor. A written proposal, which outlines the nature of the project, must be submitted for approval. This course is only available to project option students. Prerequisite: Masters standing and consent of instructor. |
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| ELEN-797 |
Masters Thesis |
Credit Var.(3-6) |
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| Master of Science thesis research will be conducted under the supervision of the thesis committee chairperson leading to the completion of the Masters thesis. This course is only available to thesis option students. Prerequisite: Consent of advisor. |
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| ELEN-799 |
Masters Thesis Continuation |
Credit 1(0-1) |
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| The course is for Master’s students who have completed all required course works and all Master Project or Thesis credits. This optional course assists the student in maintaining full-time enrollment following completion of the Masters Project, ELEN796 or Masters Thesis, ELEN797. The course may be taken to allow time for the student to complete the final project or thesis write-up and to prepare for the masters project or thesis defense. Prerequisite: Completion of all required course works and master project or thesis credits. |
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| ELEN-801 |
Solid State Devices |
Credit 3(3-0) |
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| This course deals with p-n junction and Schottky barrier diodes, bipolar junction and field effect transistors, heterostructure devices (e.g., heterojunction bipolar transistors and solar cells), and device modeling and simulation. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-802 |
Advanced Solid State Theory |
Credit 3(3-0) |
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| This course presents the physical properties of solids, including crystal lattice structure, atomic bonding, the band theory of electronic conduction, carrier mobilities, and scattering mechanisms. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-803 |
Compound Semiconductor Materials and Devices |
Credit 3(3-0) |
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| This course presents the physics of compound semiconductors, epitaxial crystal growth, quantum well and superlattice devices, compound semiconductor FETs, and photonic devices. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-804 |
Semiconductor Material and Device Characterization |
Credit 3(3-0) |
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| This course covers electrical, optical, and physical/chemical characterization of semiconductor materials and devices. Laboratory demonstrations will be presented on selected characterization techniques. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-805 |
Thin Film Technology for Device Fabrication |
Credit 3(3-0) |
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| This course will focus on the preparation and properties of thin film electronic materials (dielectrics, metals, epitaxial layers). Topics will include: basic vacuum technology; theories of condensation, nucleation and growth of thin films; deposition techniques (chemical vapor deposition, vaporization, sputtering); epitaxial growth of semiconductor materials (molecular beam epitaxy, vapor phase epitaxy, liquid phase epitaxy); and applications of the deposition processes to the fabrication of heterostructure devices. Prerequisite: ELEN-602 or consent of instructor. |
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| ELEN-810 |
Theory and Techniques in Photonics |
Credit 3(3-0) |
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| This course will concentrate on photonic materials such as semiconductors and oxide materials for opto-electronic integrated optic and nonlinear optic guided wave devices such as lasers, modulators and fibers. The course will also cover photonic systems for computing, communications, sensing, and data acquisition, processing and storage. Prerequisites: ELEN-450 or ELEN-470 and ELEN-602. |
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| ELEN-812 |
RF CMOS Integrated Circuits |
Credit 3(2-3) |
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| This course covers the design of RF CMOS integrated circuits. Passive and active RF components and their modeling using modern CAD tools, high-frequency circuit design techniques, noise analysis and RF circuits such as low-noise amplifiers (LNA), mixers, voltage-controlled oscillators (VCO), power amplifiers, and wireless transceiver architectures will be presented. Prerequisite: ELEN-608 or consent of instructor. |
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| ELEN-821 |
Advanced Computer Organization and Architecture |
Credit 3(3-0) |
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| This course introduces the design and performance issues of array processors and multiprocessors. Very Long Instruction Word (VLIW), data-flow machines, array processors, interconnection networks, and memory structures will be discussed. Prerequisite: ELEN-624 or consent of instructor. |
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| ELEN-822 |
Error-Correcting Codes |
Credit 3(3-0) |
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| In this course, the basic principles of coding, such as error control schemes, coding in communication systems, and block coding, are studied. Linear block codes, polynomial algebra and cyclic codes, block codes based on finite field arithmetic, convolution codes, coding for bursty channels, coding for bandwidth limited channels, codes for computer memories and error detection and correction methods will be discussed. Prerequisite: ELEN-625. |
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| ELEN-823 |
Advanced VLSI Design |
Credit 3(3-0) |
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| This course introduces the design of very high performance digital circuits, interconnect modeling, and packaging. Timing issues in digital circuits, designing memory and array structures, reliability and yield predictions, design synthesis, and validation and testing of VLSI circuits will be discussed. Prerequisite: ELEN-629 or consent of instructor. |
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| ELEN-847 |
Telecommunication Networks |
Credit 3(3-0) |
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| The course familiarizes the student with the concepts of the International Standards Organization Open Systems Interconnection (ISO OSI) standards for the seven layer network model. This course introduces techniques for the analysis and optimization of computer networks, and illustrates some of the technical issues of current networks. Prerequisites: ELEN-647. |
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| ELEN-848 |
Information Theory |
Credit 3(3-0) |
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| This course covers topics in classical information theory such as entropy, source coding, channel coding, and rate distortion theory. Several related topics are discusses, including entropy for Markov sources and entropy for the extension of sources. Prerequisite: ELEN-749. |
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| ELEN-849 |
Data Communications |
Credit 3(3-0) |
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| This course is an extended study of digital communications. Various topics in the upper level of digital communications, such as channel coding, synchronization, multiplexing, multiple access, and frequency spreading are discussed. Prerequisite: ELEN-749 or consent of instructor. |
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| ELEN-850 |
Digital Signal Processing II |
Credit 3(3-0) |
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| This course deals with advanced topics in digital signal processing. Topics include the 2-D sampling theorem, the 2-D z-transform, the 2-D discrete Fourier transform, 2-D filters, and computational structures for the implementation of multi-dimensional digital signal processing algorithms. Prerequisite: ELEN-650 or consent of instructor. |
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| ELEN-857 |
Pattern Recognition |
Credit 3(3-0) |
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| This course covers classical topics in statistical decision function, Bayesian learning, error probability estimation, cluster-seeking, and deterministic approach. Several related topics are discussed, including stochastic approximation, feature selection and ranking, syntactic and structural pattern recognition. Prerequisite: ELEN-657. |
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| ELEN-861 |
Power System Control and Protection |
Credit 3(3-0) |
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| This course deals with power and voltage control systems, and power systems protection by relays. Related topics are also covered. Prerequisite: ELEN-661 or ELEN-668. |
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| ELEN-862 |
Computer Methods in Power Systems |
Credit 3(3-0) |
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| This course deals with commercially available software for modeling and analysis of electric power systems. Prerequisites: ELEN-661 or equivalent. |
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| ELEN-865 |
Theory of Linear Systems |
Credit 3(3-0) |
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| This course introduces modern control system design and analysis. Topics include linear-quadratic regulators, state estimators, and discrete-time control systems. Issues discussed include stability, robustness, and optimality. Prerequisites: ELEN-668 or equivalent. |
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| ELEN-866 |
Discrete Time Systems |
Credit 3(3-0) |
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| In this course, analyses and syntheses of discrete time systems are carried out using Z-transform and state variable representations. The controllability and observability, stability criteria, sampled spectral densities and correlation sequence, optimum filtering and control of random processes are discussed. Prerequisite: ELEN-668 or equivalent. |
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| ELEN-867 |
Neural Networks Design |
Credit 3(3-0) |
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| This course covers the design of neural network systems using CMAC (Cerebellum Model Articulation Controller), back propagation, and multifunction hybrid networks. Prerequisite: ELEN –678 or equivalent. |
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| ELEN-868 |
Intelligent Methods for Control Systems |
Credit 3(3-0) |
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| The course covers advanced control methods for dynamic systems. The focus will be on intelligent control algorithms, and adaptive and self-learning methods. Stability analysis and performance simulation will also be addressed. Prerequisite: ELEN –668 or consent of instructor. |
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| ELEN-869 |
Machine Vision for Intelligent-Robotics |
Credit 3(3-0) |
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| The course covers advanced control methods for dynamic systems. The focus will be on intelligent control algorithms, and adaptive and self-learning methods. Stability analysis and performance simulation will also be addressed. Prerequisite: ELEN –668 or consent of instructor. |
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| ELEN-870 |
Fuzzy Logic With Applications |
Credit 3(3-0) |
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| The course objective is to understand the basic theory and the foundations of fuzzy sets. Fuzzy logic is shown to contain evidence, possibility, and probability logic. This course emphasizes engineering applications in control, decisions-making, and pattern recognition. The hardware/software implementation of those applications is also demonstrated. Prerequisite: ELEN –668 or consent of instructor. |
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| ELEN-871 |
Nonlinear Control Systems |
Credit 3(3-0) |
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| This course explores the basic issues of nonlinear system analysis and control. The course will introduce the general characteristics of nonlinear behavior and some of the tools needed to analyze and understand them. It will also introduce basic concepts of stability theory, especially Lyaunov’s. Some basic design techniques for the control of these systems, such as the sliding mode method and feedback linearization, will be introduced. Prerequisite: ELEN –668 or consent of instructor. |
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| ELEN-885 |
Doctoral Special Topics |
Credit 3(3-0) |
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| This lecture course is used to introduce engineering topics of current interest to doctoral students and faculty. The subject matter will be identified before the beginning of the course. Prerequisite: Doctoral student and consent of instructor. |
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| ELEN-991 |
Doctoral Qualifying Examination |
Credit 3(3-0) |
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| This course is for students who are preparing for and taking the written qualifying examination. Prerequisite: Doctoral student and consent of advisor. |
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| ELEN-992 |
Doctoral Seminar |
Credit 1(1-0) |
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| In this course, doctoral students attend colloquia or seminars. These consist of presentations by doctoral students on dissertation topics and works-in-progress and by guests on important classical, contemporary, or research problems in electrical engineering. Prerequisite: Doctoral level standing. |
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| ELEN-993 |
Doctoral Supervised Teaching |
Credit 3(3-0) |
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| Students will gain teaching experience under the mentorship of faculty who assist the student in planning for the teaching assignment, observe and provide feedback to the student during the teaching assignment, and evaluate the student upon completion of the assignment. Prerequisite: Doctoral level standing. |
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| ELEN-994 |
Doctoral Supervised Research |
Credit 3(3-0) |
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| This is supervised research under the mentorship of a member of the graduate faculty. It is not intended to serve as the dissertation topic of the doctoral student. Prerequisite: Doctoral level standing and consent of instructor. |
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| ELEN-995 |
Doctoral Preliminary Examination |
Credit 3(3-0) |
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| This course is for students who are preparing for and taking the written and/oral preliminary examination. Prerequisite: Doctoral student and consent of advisor. |
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| ELEN-997 |
Doctoral Dissertation |
Credit Var.(3-12) |
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| This supervised research serves as the dissertation of the doctoral student. Twelve credits of dissertation are required for graduation. Prerequisite: Doctoral student and consent of advisor. |
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| ELEN-999 |
Doctoral Dissertation Continuation |
Credit 1(0-1) |
| |
| The course is for doctoral students who have completed all required course works and all dissertation credits. This optional course assists the student in maintaining full-time enrollment following completion of the Doctoral Dissertation, ELEN997. The course may be taken to allow time for the student to complete the dissertation write-up and to prepare for the dissertation defense. Prerequisite: Completion of all required course works and dissertation credits. |
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