ELEE 2500 Fundamentals of ECE I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A spiral coverage of the fundamental principles of Electrical & Computer Engineering involving DC and transient circuit analysis techniques, diodes, operational amplifiers, logic circuit concepts, DC motors. The course will feature an intertwined development of theory and applications of the above topics. | 3 | 0 | 0 | | |
ELEE 2510 Fundamentals of ECE I Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A companion laboratory course to ELEE 2500 that provides practical insights for the theoretical topics covered in that course. Analysis and design of simple circuits involving applications of diodes, operational amplifiers, digital logic circuits, motors. Introduction to Electronic Design Automation software. Introduction to use of basic electronic instrumentation. | 1 | 0 | 0 | | |
ELEE 2520 Fundamentals Of ECE II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Continuation of a spiral coverage of the fundamental principles of Electrical & Computer Engineering, providing an integrated treatment of advanced circuits, electronics, and power electronics. The course will feature an intertwined development of theory and applications of the above topics. | 3 | 0 | 0 | | |
ELEE 2530 Fundamentals Of ECE II Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A companion laboratory course to ELEE 2520 that provides practical insights for the theoretical topics addressed in that course. Analysis and design of circuits involving applications of diodes, operational amplifiers, digital logic circuits, motors, and other components. | 1 | 0 | 0 | | |
ELEE 2640 Digital Logic Circuits I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Binary numbers and arithmetic. Fundamentals of Boolean algebra. Basic logic circuit concepts. Karnaugh maps. Multiplexers, decoders, flip-flops, counters, PLDs and FPGAs. Design of sequential circuits, computer modeling and simulation of digital systems. | 3 | 0 | 0 | | |
ELEE 2650 Dig Log Circ Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Design and implementation of combinational and sequential logic circuits including counters, adders, shift registers, etc. Computer simulation of logic circuits. | 1 | 0 | 0 | | |
ELEE 3540 Electronic Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Electronic systems: signal conditioning, interface and drive circuitry for sensors and actuators, hybrid analog-digital systems, etc. | 3 | 0 | 0 | | |
ELEE 3550 Electronic Systems Laboratory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A companion project-based course to ELEE 3540 that provides practical insights for the theoretical topics addressed in that course. | 1 | 0 | 0 | | |
ELEE 3560 Electronics I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Study of the underlying physical behavior of semiconductor devices, circuit modelling of active devices. Analysis and design of diode and transistor circuits: power supplies, basic amplifier configurations, bias and stability analysis, multi-stage amplifiers. | 3 | 0 | 0 | | |
ELEE 3660 Electromagnetics I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Vector analysis, electrostatics, conductor and dielectric, magnetostatics, magnetic materials, boundary conditions and boundary value problems, Maxwell's equations. | 3 | 0 | 0 | | |
ELEE 3680 Solid State I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to the physical principles of modern semiconductor devices. Quantum mechanical descriptions of energy bands and conduction processes in n and p type semiconductors. Physics of equilibrium and biased p-n junctions. Effects of junction capacitance. | 3 | 0 | 0 | | |
ELEE 3720 Electromechanical Energy Conv
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Analysis and design of magnetic circuits, transformers, induction motors, synchronous motors and generators, DC motors and generators. | 3 | 0 | 0 | | |
ELEE 3740 Communication Theory I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Mathematical representation of signals, Fourier transforms. Power spectra, auto-correlation, transmission through linear systems, sampling theory, modulation theory. Analysis and design of modulation systems: amplitude modulation, angle modulation, and pulse modulation. | 3 | 0 | 0 | | |
ELEE 3860 Intro to Microcontrollers
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Microprocessor evolution, microprocessor and microcomputer organization, assembly language, interrupts, peripherals, interfacing, A/D and D/A systems. | 3 | 0 | 0 | | |
ELEE 3870 Intro to Microcontrollers Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Familiarity with microprocessor/microcontroller development and training systems: memory, I/O CPU. Assembly language. Hardware and software experiments. Microcontroller design projects involving design, prototyping and construction. | 1 | 0 | 0 | | |
ELEE 3880 Signals & Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Fundamental techniques for the analysis of signals and systems. Laplace and Fourier transforms with a focus on applications to transfer functions, frequency response, and control and communication systems. Continuous-time and discrete-time signals and systems. | 3 | 0 | 0 | | |
ELEE 4010 ECE Senior Capstone Design I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A capstone design course which integrates materials from all areas of Electrical Engineering. This course provides an engineering design experience comparable to that encountered in industry. Students have an opportunity to participate in a creative and realistic design effort requiring written, oral, and visual communication skills, as well as teamwork and planning. The course lectures present discussions on design methodology, designing for mass production, reliability, safety, and ethics among others. A literature search, detailed feasibility study, and an initial design are undertaken. | 3 | 0 | 0 | | |
ELEE 4030 ECE Senior Capstone Design II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Continuation of EE 401 requiring a completion of the design (and construction) effort and a professional presentation of the results. | 3 | 0 | 0 | | |
ELEE 4400 Computational Intel Tech
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Topics chosen from neural networks, hybrid systems, evolutionary computing methods and their applications | 3 | 0 | 0 | | |
ELEE 4520 Real-Time Cont Sys
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Fundamentals of real-time control systems simulation: plant modeling, controller design, real-time simulations analysis using MATLAB/SIMULINK, and Hardware-in-the-loop (HIL) systems & applications. | 3 | 0 | 0 | | |
ELEE 4540 Fuzzy System Theory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A study of the fundamental concepts of fuzzy set theory and its engineering applications. Topics include fuzzy sets and relations, operations on fuzzy sets, fuzzy rules and inference systems, defuzzification methods, selected applications in the area of controls, image processing, etc. | 3 | 0 | 0 | | |
ELEE 4570 Vehicular Electrical Power Sys
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The course will cover items like: (a) fundamentals of power electronics; (b) electrical machines; © automotive power systems; (d) electric, hybrid vehicles, and fuel cell based vehicles; (e) modeling techniques for automotive electric and hybrid vehicles; (f) automotive motor drives for vehicular applications; (g) multiconverter vehicular dynamics and control. | 3 | 0 | 0 | | |
ELEE 4580 Advanced Electronics
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Ideal and non-ideal operational amplifiers, linear and nonlinear op amp circuit analysis and design. Active filter design. Frequency response and noise analysis in op amp circuits. Digital Electronic circuits. | 3 | 0 | 0 | | |
ELEE 4590 Electronics Manufacturing
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
This course provides the student with a broad foundation in electronics manufacturing. Mainstream technologies included silicon semiconductor and FR4 circuit board manufacturing, electronics packaging, automated assembly and solder processes are examined in detail. Circuit board design methodology with a focus on design for cost optimization is stressed throughout. Electronics packaging, interconnection and thermal management are investigated. Design verification, and manufacturing hand-off conclude the course. | 3 | 0 | 0 | | |
ELEE 4600 Comp Aided Dsgn Integ Circuits
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to the basic electrical properties and the technology of fabrication of MOS devices. Automatic layout generation, routing and design simulation with CAD tools using digital logic circuit examples. Case study and design project. | 3 | 0 | 0 | | |
ELEE 4620 Random Variables & Processes
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Probability, random variables, distribution and density functions, functions of random variables, joint distributions and density functions. Random processes, autocorrelation and crosscorrelation, linear system response. | 3 | 0 | 0 | | |
ELEE 4640 Hardware Description Lang
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Analysis and modelling of digital systems using hardware programming languages. More specifically VHDL (VHSIC Hardware Description Language) is introduced as a powerful EDA (Electronic Design Automation) tool for the design of complex digital systems. The course explores the design of specific systems ranging from simple counters to complete microprocessors. An industry standard language compiler and simulator are utilized throughout the course. Several ASIC (Application Specific Integrated Circuit) designs are implemented with FPGAs (Field Programmable Gate Arrays) in the laboratory. | 3 | 0 | 0 | | |
ELEE 4650 Hardware Description Lang Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Focus on VHDL for synthesis on FPGA and PSOC devices. Altera and/or Xilinx device description. Hardware projects utilizing FPGA development boards and/or stand-alone system implementations. | 1 | 0 | 0 | | |
ELEE 4660 Electromagnetics II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Maxwell's equations constitutive relations, boundary condition. Poynting theorem. Plane waves, wave polarization, phase and group velocities. Reflection, refraction and attenuation of plane waves in various media. Transmission lines, waveguides and resonators. Antennas and radiation. Wave propagation and radar equation. | 3 | 0 | 0 | | |
ELEE 4680 Computer Networkng
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Study of local area networks (LAN) and wide area networks (WAN). Survey of the state-of-the-art computer network. Topics include networking theory, design approaches, standards, topologies, OSI and TCP/IP, protocols, applications and distributed processing. | 3 | 0 | 0 | | |
ELEE 4690 Computer Networking Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The Networking Laboratory (NL) will provide students with hands-on design, setup, configuration and managing network devices and their applications. In addition, the NL will provide researchers and educators with a controlled environment to validate and evaluate their research, education, and training programs. This lab will educate undergraduate and graduate students about the fundamental design, analysis, operation, control and management of networked systems. Students will be able to build and simulate CAN networks using Canoe. The NL will enable students to better understand and get hands-on experiences. | 1 | 0 | 0 | | |
ELEE 4700 Controls II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Advanced study of root locus analysis. Frequency response analysis. Design and compensation techniques. Describing-function analysis of nonlinear control systems. Control system analysis and design using state-space methods. | 3 | 0 | 0 | | |
ELEE 4740 Communication Theory II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Digital communication, probability and random variables, mathematical representation of noise, effect of noise upon system performance, pulse amplitude modulation, multiple pulse detection of signals, detection of signals in colored Gaussian noise, estimation of signal parameters. | 3 | 0 | 0 | | |
ELEE 4760 Digital Control Theory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Basic theory of sampling and quantizing, z-transform analysis. System error analysis, modeling and optimal design of discrete data systems by performance indices. Stability of discrete data systems and design compensation. | 3 | 0 | 0 | | |
ELEE 4780 Embedded Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Design of embedded systems (hardware and software). Advanced topics including interrupt, multitasking, Programming 68HC12 micro controller in C. An open-ended embedded system design project which requires consideration of alternatives, economic and aesthetic constraints, and detailed system description is compulsory. | 3 | 0 | 0 | | |
ELEE 4790 Embedded Systems Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Students will perform advanced interfacing and development in the lab. They are taught a system design methodology based on top-down principles. A semester design/construction project provides the students with an excellent opportunity to develop strengths in embedded system design, construction, testing, and development. | 1 | 0 | 0 | | |
ELEE 4800 Computer Org & Architecture
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Basic and advanced concepts of CPU design, memory systems, and I/O interfacing. Alternative design and evaluation of the control unit, the arithmetic and logic unit, and memory hierarchy. | 3 | 0 | 0 | | |
ELEE 4840 Electromagnetic Compatibility
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
EMC requirements for electronic systems, non-ideal behavior of passive components, radiated emissions and susceptibility, conducted emissions and susceptibility, crosstalk, shielding, electrostatic discharge, measurements, system design for EMC. | 3 | 0 | 0 | | |
ELEE 4870 Intro to Microcontrollers Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Familiarity with microprocessor/microcontroller development and training systems: memory, I/O CPU. Assembly language. Hardware and software experiments. Microcontroller design projects involving design, prototyping and construction. | 1 | 0 | 0 | | |
ELEE 4880 Digital Signal Processing I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to Discrete-Time Signals and Systems. Fourier Transforms of Discrete-Time Signals, Discrete Fourier Transform, z transforms. Digital filter design. Implementation using digital signal processors. | 3 | 0 | 0 | | |
ELEE 4900 Radiation & Antennas
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Radiation from simple sources; directivity, gain, and effective aperture; radiation resistance; linear antennas; mutual coupling; travelling wave antennas; receiving antennas and reciprocity; Friis formula and radar equation; propagation of waves. | 3 | 0 | 0 | | |
ELEE 4920 Dig Image Proc & Comp Vision
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
This course provides an introduction to the basic concepts and techniques of digital image processing and computer vision. Topics include sampling and quantization, image transforms, image enhancement, restoration, and coding. | 3 | 0 | 0 | | |
ELEE 5086 Intro to Microprocessors
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Microprocessor and microcontroller evolution, MSI components, microcontroller-based system design. Microprocessor and microcontroller organization and architecture, assembly language. Interrupts, memory, and peripheral interfacing, A/D and D/A systems. | 3 | 0 | 0 | | |
ELEE 5087 Intro to Microsprocessor Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Familiarity with microprocessor/microcontroller development and training systems: memory, I/O CPU. Assembly language. Hardware and software experiments. Microcontroller design projects involving design, prototyping and construction. | 1 | 0 | 0 | | |
ELEE 5100 Network Security
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
This course explores the world of network security. It presents all of the practical principles, methods and technology necessary to construct an effective network defense in depth. Upon leaving this course students will be able to execute every common form of professional intrusion detection and response including pen testing, network attack/defense and host and network based IDS and policy enforcement. Students will do hands-on work in the lab with all common elements of network hardware and software. | 3 | 0 | 0 | | |
ELEE 5200 Auton Mobility Rob
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Autonomous Mobility Robotics is concerned with the theory and applications associated with the development of mobile robots that possess sensors and local intelligence sufficient to operate independently in constrained environments. Topics are selected from the four sub-areas of perception, localization, cognition, and motion control. | 3 | 0 | 0 | | |
ELEE 5400 Computational Intell Technique
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Topics chosen from neural networks, hybrid systems, evolutionary computing methods and their applications. | 3 | 0 | 0 | | |
ELEE 5490 Grad Sem In ECE
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Students will work on projects related to their areas of interests. The instructor will provide a list of topics to choose from. This course should be taken by graduate students in the final year of study. | 1 | 0 | 0 | | |
ELEE 5520 Real-Time Cont Sys
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Fundamentals of real-time control systems simulation: plant modeling, controller design real-time simulation analysis using MATLAB/SIMULINK, and Hardware-in-the-loop (HIL) systems and applications. | 3 | 0 | 0 | | |
ELEE 5540 Fuzzy System Theory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
A study of the fundamental concepts of fuzzy set theory and its engineering applications. Topics include fuzzy sets and relations, operations on fuzzy sets, fuzzy rules and inference systems, defuzzification methods, selected applications in the area of controls, image processing, etc. | 3 | 0 | 0 | | |
ELEE 5570 Vehicular Electrical Pwr Sys
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The course will cover items like:(a) fundamentals of power electronics, (b) electrical machines (briefly), © automotive power systems, (d) electric hybrid vehicles, and fuel cell based vehicles, (e) modeling techniques for automotive electric and hybrid vehicles, (f) automotive motor drives for vehicular applications, (g) multi-converter vehicular dynamics and control. | 3 | 0 | 0 | | |
ELEE 5580 Advanced Electronics
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The special topics on 1) Design and Applications with operational amplifiers: linear and non-linear op-amp circuits, active filters, DA/AD converters, signal generators and switching capacitors, 2) power electronics: ac switching controllers, inverteres, choppers, ac/dc motor speed control circuits. | 3 | 0 | 0 | | |
ELEE 5590 Electronics Manufacturing
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
This course provides the student with a broad foundation in electronics manufacturing. Mainstream technologies included silicon semiconductor and FR4 circuit board manufacturing, electronics packaging, automated assembly and solder processes are examined in detail. Circuit board design methodology with a focus on design for cost optimization is stressed throughout. Electronics packaging, interconnection and thermal management are investigated. Design verification, and manufacturing hand-off conclude the course. | 3 | 0 | 0 | | |
ELEE 5600 Comp Aided Dsgn Integ Circuits
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to the basic electrical properties and the technology of fabrication of MOS devices. Automatic layout generation, routing and design simulation with CAD tools using digital logic circuit examples. Case study. | 3 | 0 | 0 | | |
ELEE 5620 Random Variables/Processes
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Probability, random variables, distribution and density functions, functions of random variables, joint distributions and density functions. Random processes, auto-correlation and cross-correlation, linear system response. | 3 | 0 | 0 | | |
ELEE 5640 Hardware Description Lang
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Design methodology using hardware programming languages specifically VHDL. Design simulation and synthesis of digital circuits with a focus on FPGA ASIC implementation. | 3 | 0 | 0 | | |
ELEE 5650 Harware Description Lang Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Focus on VHDL for synthesis on FPGA and PSOC devices. Altera and/or Xilinx device description. Hardware projects utilizing FPGA development boards and/or stand-alone system implementations. | 1 | 0 | 0 | | |
ELEE 5680 Computer Networkng
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to computer networks including LAN, MAN, WAN, CAN, OSI and TCP/IP layering protocols. TCP/IP internetworking and their applications are covered. Simulation tools such as COMNET III are used to evaluate different network designs, architectures, and topologies. | 3 | 0 | 0 | | |
ELEE 5690 Networking Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The networking laboratory (NL)will provide students with hands-on design, setup, configure, and manage network devices and their applications. In addition, the NL will provide researchers and educators with a controlled environment to validate and evaluate their research, education, and training programs. This lab will educate undergraduate and graduate students about the fundamental design, analysis, operation, control and management of networked systems. The NL will enable students to better understand and get hands-on experiences. | 1 | 0 | 0 | | |
ELEE 5700 Controls II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Advanced study of root locus analysis. Frequency response analysis. Design and compensation techniques. Describing-function analysis of nonlinear control systems. Control system analysis and design using state-space methods. | 3 | 0 | 0 | | |
ELEE 5720 Linear Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Linear spaces, linear operator theory, existence and uniqueness of solutions of differential equations, the fundamental matrix solution, state transition matrix, Lyapunov stability, controllability, observability, state feedback, pole placement, observers, output feedback. Special topics include Kalman filtering, linear quadratic regulator optimal control, geometric linear control. | 3 | 0 | 0 | | |
ELEE 5740 Pattern Recognitio
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Representation of patterns as multi-dimensional feature vectors. Bayesian decision theory. Parameter estimation and supervised learning. Feature selection. Non-parametric techniques. Linear discriminant functions. Unsupervised learning and clustering. | 3 | 0 | 0 | | |
ELEE 5760 Dir Digital Contr
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Basic theory of sampling and quantizing, z-transform analysis. System error analysis, modeling and optimal design of discrete data systems by performing indices. Stability of discrete data systems and design compensation. | 3 | 0 | 0 | | |
ELEE 5770 Embedded Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Design of embedded systems (hardware and software); advanced topics include behavioral/subsumption programming, multitasking, real-time systems, and programming the 68HS12 in Forth, C, and assembly languages. An open-ended embedded system design project which requires consideration of alternatives, economic and aesthetic constraints, and detailed system description is compulsory. | 3 | 0 | 0 | | |
ELEE 5780 Optimization & Optimal Control
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Fundamental concepts of calculus of variations. Functionals of a single and several independent functions, constrained optimization. Necessary conditions for optimal control. Linear regulatory problem. Pontryagin's minimum principle. Introduction to dynamic programming. | 3 | 0 | 0 | | |
ELEE 5790 Embedded Systm Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Students will perform advanced interfacing and development in the lab. They are taught a system design methodology based on top-down principles. A semester design/construction project provides the students with an excellent opportunity to develop strengths in embedded system design, construction, testing, and development. | 1 | 0 | 0 | | |
ELEE 5800 Comp Architecture
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The design of computational systems and circuits. Investigation of alternative structures for computers. | 3 | 0 | 0 | | |
ELEE 5840 Electromagnetic Compatibility
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
EMC requirements for electronic system. Signal spectra. Radiated emissions and susceptibility. Conducted emissions and susceptibility. Cross talk. Shielding. Electrostatic discharge. Noise in electronic devices. System design for EMC. | 3 | 0 | 0 | | |
ELEE 5860 Adv Microprocessor
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Treatment of the architecture and organization of 16-bit and 32-bit microprocessors and microcomputers. Design of microcomputers which include dynamic memory, cache memories, interfacing, coprocessors, direct memory, access (DMA), serial and parallel processors. | 3 | 0 | 0 | | |
ELEE 5880 Digital Signal Processing I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Introduction to discrete-time signals and systems. Sampling and reconstruction. Frequency domain analysis of signals and systems, Z-transforms. Digital filters. Implementation using digital signal processors. | 3 | 0 | 0 | | |
ELEE 5900 Dig Sig Proc Ii
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Multidimensional signal processing. Signal estimation, noise reduction, image restoration and enhancement and pattern recognition. DSP chip architecture, algorithms and programming. IIR and FIR filter design. Deconvolution. | 3 | 0 | 0 | | |
ELEE 5920 Image Processing
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Basic concepts and techniques of digital image processing. Sampling and quantization. Image transforms; image enhancement, restoration and coding. Design, implementation and testing of algorithms and concepts through class projects. | 3 | 0 | 0 | | |
ELEE 5940 Advanced Topics ELEE
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
The special topics such as Parallel Processing, Distributed Processing, Neural Networks, etc. will be offered under this course number. | 1 | 0 | 0 | | |
ELEE 5990 Master's Thesis
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Research, study and other activity appropriate to the Electrical Engineering masters thesis. Students should consult the Electrical Engineering Department for thesis format requirements. | 1 | 0 | 0 | | |
ELEE 7990 Dissertation
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Research, study and other activity appropriate to the doctoral dissertation. Students should consult the Electrical Engineering Department for format requirements. | 0 | 0 | 0 | | |
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