Electrical Engineering Course
Descriptions
ECSC 5177 CS IPP
Assignment (1 semester hour) Work in an approved,
supervised, computer science position.
Students will complete an IPP Work Report including a written Narrative
focusing on the accomplishments and learning gained through the IPP
experience. May be
repeated. (1-0) Y
ECSC 5179 ENG IPP
Assignment (1 semester hour) Work in an approved,
supervised, engineering position.
Students will complete an IPP Work Report including a written Narrative
focusing on the accomplishments and learning gained through the IPP
experience. May be
repeated. (1-0) Y
EEMF 5283 Plasma
Technology Laboratory (2 semester hours) Laboratory will
provide a hands-on experience to accompany EEMF 5383. Topics to include: Vacuum
technology [pumps, gauges, gas feed], plasma uses [etch, deposition, lighting
and plasma thrusters] and introductory diagnostics. Corequisite:
EEMF 5383. Recommended Corequisite:
EEMF 7171. (0-2) R
EEGR 5300 Advanced
Engineering Mathematics (3 semester hours) Advanced
mathematical topics needed in the study of engineering. Topics may include
advanced differential equations, linear algebra, vector calculus, complex
analysis, and numerical methods. Credit does not apply to the 33 hour M.S.E.E.
requirement. (3-0) R
EEGR 5301 (CS 5301)
Professional and Technical Communication (3 semester hours)
EEGR 5301 utilizes an integrated approach to writing and speaking for the
technical professions. The advanced writing components of the course focus on
writing professional quality technical documents such as proposals, memos,
abstracts, reports, letters, emails, etc. The advanced oral communication
components of the course focus on planning, developing, and delivering dynamic,
informative and persuasive presentations. Advanced skills in effective
teamwork, leadership, listening, multimedia and computer generated visual aids
are also emphasized. Graduate students will have a successful communication
experience working in a functional team environment using a real time, online
learning environment. (3-0) Y
EERF
5305 Radio Frequency Engineering (3 semester hours)
Introduction to generation, transmission, and radiation of electromagnetic
waves. Microwave-frequency
measurement techniques. Characteristics of guided-wave
structures and impedance matching. Fundamentals of
antennas and propagation. Prerequisite: EE 4301 or equivalent. (3-0) Y
EEMF 5320
Introduction to Devices and Circuits (3 semester hours)
This course provides a background in Electrical
Engineering for students entering the M.S.E.E. program from other fields of
science and engineering. Topics include circuit analysis and simulation,
semiconductor device fundamentals and operation, and basic transistor circuits.
Credit does not apply to the 33 hour M.S.E.E. requirement. Prerequisite:
differential equations. (3-0) R
EECT
5321 Introduction to Circuits and Systems (3 semester
hours) Continuation of EEMF 5320. Topics include
analog circuits, digital circuits, digital systems and communication systems.
Credit does not apply to the 33 hour M.S.E.E. requirement. (3-0) R
EEDG 5325 (CE 5325)
Hardware Modeling Using HDL (3 semester hours) This
course introduces students to hardware description languages (HDL) beginning
with simple examples and describing tools and methodologies. It covers the
language, dwelling on fundamental simulation concepts. Students are also
exposed to the subset of HDL that may be used for synthesis of custom logic.
HDL simulation and synthesis labs and projects are performed using commercial
and/or academic VLSI CAD tools. Prerequisite: EE 3320 or equivalent. (3-0) T
EECT 5340 Analog
Integrated Circuit Analysis and Design (3 semester hours)
Application of MOSFET and BJT large-signal and small-signal models to analyze
and design amplifiers, analysis and design of current mirrors and differential
amplifiers, analysis of frequency response of amplifiers, and feedback
theories. Prerequisite: EE 3311 or equivalent. (3-0) Y
EESC 5350 Signals,
Systems, and Digital Communications (3 semester hours)
Advanced methods of analysis of electrical networks
and linear systems. Laplace transforms, Fourier series, and Fourier
transforms. Response
of linear systems to step, impulse, and sinusoidal inputs. Convolution, system
functions, and frequency response.
Z transforms and digital systems. Fundamentals
of digital communication systems such as information, digital transmission, channel capacity, modulation and demodulation techniques are
introduced. Signaling schemes and
performance of binary as well as M-ary modulated
digital communication systems are introduced.
Overall design considerations and performance evaluation of various
digital communication systems are discussed.
Prerequisite: ENGR 3300 or equivalent. (3-0) R
EESC 5360
Introduction to Communications and Signal Processing
(3 semester hours) This course is designed to provide the necessary background
for someone with a technical degree to enter the M.S.E.E. program in the
Communications and Signal Processing concentration. It will focus on linear systems theory, to
include Fourier series, Fourier and Laplace transforms, transfer functions,
frequency response, and convolution. It
will also include introductions to the solution of ordinary differential
equations and to communications systems. Credit does not apply to the 33 hour
M.S.E.E. requirement. Prerequisites: One
year of calculus and one semester of probability theory. (3-0) R
EEGR
5365 Engineering Leadership (3 semester hours)
Interpersonal influence and organizational influence in leading engineering
organizations. Leadership is addressed from the
point of view of the technical manager as well as from that of the technical
professional. Topics include staffing, motivation, performance evaluation,
communication, project selection and planning, intellectual property and
professional ethics. (3-0) R
EEGR 5381
Curriculum Practical Training in Electrical Engineering (3
semester hours) This course is required of students
who need additional training in engineering practice. Credit does not apply to
the 33 hour M.S.E.E. requirement. Consent of Graduate Adviser required. (May be
repeated to a maximum of 9 hours) (3-0) R
EEMF 5383 (MECH
5383, MSEN 5383, PHYS 5383) Plasma Processing (3
semester hours) Hardware oriented study of useful laboratory plasmas. Topics will include vacuum technology, gas
kinetic theory, basic plasma theory and an introduction to the uses of plasmas
in various industries. (3-0) T
EECT 5385 Analog
Filters (3 semester hours) This
course aims at bridging the intermediate-level and the advanced-level knowledge
in analog filter design. It moves from basic theory of analog passive filters
to theoretical and practical aspects of active, switched-capacitor, and
continuous time filters. For active solutions the focus is on integrated
implementations on silicon. Prerequisites: ENGR 3301 and EE 3111. (3-0) Y
EEGR 5V80 Special
Topics in Electrical Engineering (1-6 semester
hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) S
EEMF 6283 Plasma
Science Laboratory (2 semester hours) Laboratory will
provide a hands-on experience to accompany EEMF 6383. Experiments will include
measurements of fundamental plasma properties and understanding of important
plasma diagnostics. Co-requisite: EEMF 6383, recommended co-requisite: EEMF
7171. (0-2) T
EEDG
6301 (CE 6301) Advanced Digital Logic (3 semester hours)
Modern design techniques for digital logic.
Logic synthesis and design methodology. Link between
front-end and back-end design flows. Field programmable gate
arrays and reconfigurable digital systems. Introduction to testing,
simulation, fault diagnosis and design for testability. Prerequisites: EE 3320
or equivalent and background in VHDL/Verilog. (3-0) T
EEDG 6302 (CE 6302)
Microprocessor Systems (3 semester hours) Design of microprocessor
based systems including I/O and interface devices. Microprocessor
architectures. Use of emulators and other sophisticated test equipment. Extensive laboratory work. Prerequisite: EE 4304 or
equivalent and background in VHDL/Verilog. (2-3) Y
EEDG
6303 (CE 6303) Testing and Testable Design (3 semester
hours) Techniques for detection of failures in digital circuits and systems.
Fault modeling and detection. Functional testing and
algorithms for automatic test pattern generation (ATPG). Design of easily testable digital systems. Techniques for introducing built-in self test
(BIST) capability. Test of various digital modules, such as PLA's,
memory circuits, datapath, etc. Prerequisite: EE 3320
or equivalent and background in VHDL/Verilog. (3-0) Y
EEDG 6304 (CE 6304)
Computer Architecture (3 semester hours) Trends in
processor, memory, I/O and system design. Techniques for quantitative analysis
and evaluation of computer systems to understand and compare alternative design
choices in system design. Components in high performance processors and
computers: pipelining, instruction level parallelism, memory hierarchies, and
input/output. Students will undertake a major computing system analysis and
design project. Prerequisite: EE 4304 and C/C++. (3-0) Y
EEDG 6305 (CE 6305)
Computer Arithmetic (3 semester hours) Carry look ahead
systems and carry save adders. Multipliers, multi-bit recoding schemes, array
multipliers, redundant binary schemes, residue numbers, slash numbers.
High-speed division and square root circuits. Multi-precision
algorithms. The IEEE floating point standard, rounding processes, guard
bits, error accumulation in arithmetic processes. Cordic algorithms.
Prerequisites: EE 3320 and C/C++. (3-0) Y
EEDG 6306 (CE 6306)
Application Specific Integrated Circuit Design
(3 semester hours) This course discusses the design of
application specific integrated circuits (ASIC). Specific topics include: VLSI
system design specification, ASIC circuit structures, synthesis, and
implementation of an ASIC digital signal processing (DSP) chip. Prerequisite:
EE 3320 (3-0) Y
EEDG 6307 (CE 6307)
Fault-Tolerant Digital Systems (3 semester hours)
Concepts in hardware and software fault tolerance. Topics include fault models,
coding in computer systems, fault diagnosis and fault-tolerant routing, clock
synchronization, system reconfiguration, etc. Survey of
practical fault-tolerant systems. Prerequisite: EEDG 6301, ENGR 3341 or
equivalent. (3-0) R
EEDG
6308 (CE 6308, CS 6396) Real-Time Systems (3 semester
hours) Introduction to real-time applications and concepts.
Real-time operating systems and resource management. Specification and design methods for real-time systems. System performance analysis and optimization techniques. Project to specify, analyze, design, implement and test small
real-time system. Prerequisite: CS 5348. (3-0) R
EEOP
6309 Fourier Optics (3 semester hours) Description of
coherent optics using a linear systems approach. The concepts of impulse
response and transfer functions for unbounded wave propagation, diffraction,
and image formation. Introduction to holography and optical data processing.
Prerequisites: ENGR 3302 and EE 4301 or equivalents. (3-0) R
EEOP
6310 Optical Communication Systems (3 semester hours)
Operating principles of optical communications systems and fiber optic
communication technology. Characteristics of
optical fibers, laser diodes, and laser modulation, laser and fiber amplifiers,
detection, demodulation, dispersion compensation, and network topologies. System topology, star network, bus networks,
layered architectures, all-optical networks.
Prerequisite: EE 3350 or equivalent. (3-0) T
EERF
6311 RF and Microwave Circuits (3 semester hours)
Analysis and design of RF and microwave circuits.
Topics include impedance matching, network theory, S-parameters, transmission
line media (waveguide, coax, microstrip, stripline, coplanar waveguide, etc.) and passive component
design (power dividers, couplers, switches, attenuators, phase shifters, etc.).
Industry-standard microwave CAD tools will be used. Prerequisite: EE 4368 or
equivalent. (3-0) R
EEOP
6312 Laser and Modern Optics (3 semester hours)
Theory and applications of lasers, including ray and beam optics. Design issues include power maximization,
noise properties, spectral purity and high-speed modulation. Particular
emphasis on semiconductor lasers and their relevance to optical communications. Prerequisite: EE 4301 or equivalent. (3-0) Y
EEOP 6313 (MSEN
6313) Semiconductor Opto-Electronic Devices
(3 semester hours) Physical principles of semiconductor optoelectronic devices:
optical properties of semiconductors, optical gain and absorption, wave
guiding, laser oscillation in semiconductors, LEDs, physics of detectors,
applications. Prerequisite: EE 3310 or equivalent. (3-0) R
EEOP 6314
Principles of Fiber and Integrated Optics (3 semester
hours) Theory of dielectric waveguides, modes of planar waveguides, strip
waveguides, optical fibers, coupled-mode formalism, directional couplers,
diffractive elements, switches, wavelength-tunable filters, polarization
properties of devices and fibers, step and graded-index fibers, devices for
fiber measurements, fiber splices, polarization properties, and fiber
systems. Prerequisites: ENGR 3300 and EE
4301 or equivalents. (3-0) T
EEOP 6315 Engineering
Optics (3 semester hours) Fundamental concepts of
geometrical optics, first-order optical system design and analysis, paraxial
ray tracing, aperture and field stops.
Optical materials and properties; third order aberration theory. Prerequisite: PHYS 2326 or equivalent. (3-0) T
EEGR 6316 Fields
and Waves (3 semester hours) Study of electromagnetic
wave propagation beginning with Maxwell's equations; reflection and refraction
at plane boundaries; guided wave propagation; radiation from dipole antennas
and arrays; reciprocity theory; basics of transmission line theory and
waveguides. Prerequisite: EE 4301 or equivalent. (3-0) Y
EEOP 6317 Physical
Optics (3 semester hours) Study of optical
phenomena based primarily on the electromagnetic nature of light; mathematical
description of polarized light; Jones and Mueller matrices; interference of
polarized waves; interferometers, diffractive phenomena based on scalar
formalisms; diffraction gratings; and diffraction in optical instruments. Prerequisite: EE 4301 or equivalent. (3-0) T
EEMF
6319 Quantum Physical Electronics (3 semester hours)
Quantum-mechanical foundation for study of nanometer-scale electronic devices.
Principles of quantum physics, stationary-state eigenfunctions and eigenvalues for one-dimensional
potentials, interaction with the electromagnetic field, electronic conduction
in solids, applications of quantum structures. Prerequisite: ENGR 3300
or equivalent. (3-0) Y
EEMF 6320 (MSEN
6320) Fundamentals of Semiconductor Devices (3 semester
hours) Semiconductor material properties, band structure, equilibrium carrier
distributions, non-equilibrium current-transport processes, and
recombination-generation processes. Prerequisite: EEMF 6319 or equivalent.
(3-0) R
EEMF 6321 (MSEN
6321) Active Semiconductor Devices (3 semester hours)
The physics of operation of active devices will be
examined, including p-n junctions, bipolar junction transistors and
field-effect transistors: MOSFETs, JFETS, and MESFETS. Active two-terminal
devices and optoelectronic devices will be presented. Recommended
co-requisite: EEMF 6320. (3-0) R
EEMF
6322 (MECH 6348, MSEN 6322) Semiconductor Processing Technology
(3 semester hours) Modern techniques for the manufacture of semiconductor
devices and circuits. Techniques for both silicon and
compound semiconductor processing are studied as well as an introduction to the
design of experiments. Topics include: wafer growth, oxidation, diffusion, ion
implantation, lithography, etch and deposition. (3-0) R
EEMF 6323 Circuit
Modeling of Solid-State Devices (3 semester hours)
Provide physical insight into the operation of MOSFETs and BJTs, with
particular emphasis on new physical effects in advanced devices. Compact
(SPICE-level) transistor models will be derived from basic semiconductor
physics; common simplifications made in the derivations of model equations will
be detailed to provide an appreciation for the limits of model capabilities.
Prerequisites: EEMF 6320 and EEMF 6321. (3-0) R
EEMF 6324 (MSEN
6324) Electronic, Optical and Magnetic Materials
(3 semester hours)
Foundations of materials properties for electronic, optical and
magnetic applications. Electrical and thermal conduction, elementary quantum
physics, modern theory of solids, semiconductors and devices, dielectrics, properties
of magnetic and optical materials. Prerequisite: MSEN 5300 or PHYS 5376 or
equivalent. (3-0) S
EECT
6325 (CE 6325) VLSI Design (3 semester hours) Introduction to
MOS transistors. Analysis of the
CMOS inverter. Combinational and sequential design techniques
in VLSI; issues in static, transmission gate and dynamic logic design. Design and layout of complex gates, latches and flip-flops,
arithmetic circuits, memory structures. Low power
digital design. The method of logical effort. CMOS technology. Use of CAD tools to design, layout, check,
extract and simulate a small project. Prerequisites: EE 3320, ENGR 3301 or
equivalent. (3-0) Y
EECT
6326 Analog Integrated Circuit Design (3 semester hours)
Introduction to MOS transistor, CMOS technology and analog circuit modeling.
Basic analog circuits: MOS switches, active resistors, current sources, current
mirrors, current amplifiers, inverting amplifier, differential amplifier,
cascade amplifier and the output amplifier. Complex circuits: comparators and
operational amplifiers. Use of CAD tools to layout and simulate analog
circuits. Prerequisite: EECT 5340. (3-0) Y
EEOP 6328 Nonlinear
Optics (3 semester hours) Survey of nonlinear
optical effects; origins of optical nonlinearities; laser-pulse propagation
equations in bulk media and optical fibers; the nonlinear optical
susceptibility tensor; second-order nonlinear optical effects (second harmonic
generation, optical rectification, parametric mixing and amplification);
third-order nonlinear optical effects in fiber optic communication systems
(self-phase modulation, cross-phase modulation, stimulated Brillouin
scattering, stimulated Raman scattering, four-wave mixing, nonlinear
polarization mode dispersion); self-focusing and self-defocusing in bulk media;
computational methods for nonlinear optics.
Prerequisite: EE 4301 or equivalent; EEOP 6310 recommended. (3-0) R
EEOP 6329 Optical
Signal Conditioning (3 semester hours) Engineering
principles and applications of laser beam modulation and deflection (acousto-optics and electro-optics), harmonic generation and
optical parametric processes, optical pulse compression and shaping. Prerequisites: EE 4301 or equivalent and EEOP
6317 recommended. (3-0) R
EERF 6330 RF Integrated Circuit Design (3 semester hours)
Introduction to RF and wireless systems; basic concepts of RF design:
linearity, distortion, (P1dB, IIP3), sensitivity, noise figure; RF passives:
Q-factors, impedance transformation, matching network; transceiver
architectures: Receivers-Heterodyne, direct downconversion,
image reject receivers, direct conversion transmitter, two-step transmitter;
low noise amplifier design; mixer design; oscillator design; basic
architectures of power amplifiers. Use of Agilent ADS for
design projects. Prerequisite EE 4340. (3-0). Y
EESC 6331 Linear
Systems (SYSM 6307, MECH 6300)(3
semester hours) State space methods of analysis and design of linear dynamical
systems. Coordinate transformations,
controllability and observability. Lyapunov stability analysis. Pole assignment, stabilizability, detectability. State estimation for
deterministic models, observers. Introduction to the
optimal linear quadratic regulator problem. Prerequisites: MECH 4310 or equivalents (3-0)
Y
EEGR 6332 Advanced
Control (3 semester hours) Modern control techniques
in state space and frequency domain: optimal control, robust control, and
stability. Prerequisite: EESC 6331. (3-0) R
EEOP 6334 Advanced
Geometrical and Physical Optics (3 semester hours)
Geometrical optics as a limiting case of the propagation of electromagnetic
waves; geometrical theory of optical aberrations; the diffraction theory of
aberrations; image formation with partially coherent and partially polarized
light; computational methods for physical optics. Other topics may be selected from the
following: diffraction theory of vector electromagnetic fields, diffraction of
light by ultrasonic waves, optics of metals, Lorenz-Mie theory of the
scattering of light by small particles, and optics of crystals. Prerequisite:
EEOP 6317. (3-0) R
EEOP 6335
Engineering of Infrared Imaging Systems (3 semester hours)
Thermal optics, review of Fourier optics, review of information theory,
embedded system design principles, and system modeling. Prerequisites: EEOP 6309 or EEOP 6315 or
equivalents. (3-0) T
EEGR 6336 (MECH
6313) Nonlinear Systems (3 semester hours) Fundamental
concepts and tools for the analysis of nonlinear systems, design of controllers
and estimators for nonlinear systems. Prerequisite: MECH 6300 or equivalent.
(3-0) T
EEOP 6338 High-Speed
Optical Receivers and Transmitters (3 semester hours)
Review of optical communication systems.
Definitions of attenuation and dispersion. Architecture of optical
transmitters and receivers. Principles of operation of photodetectors
(PIN and APD). Application
of digital communication theory to the analysis of optical receivers. Definition of sensitivity
and dynamic range in optical receivers.
Definition of sensitivity and dynamic range in optical
receivers. Study
of high-speed transimpedance and limiting amplifiers. Principles of operation of
lasers (DFB and Fabry-Perot). Study of tunable lasers and
high-speed external modulators. Direct and externally
modulated transmitters. Study of high-speed drivers
for laser and modulators. Characteristics of optical
transmitters. Prerequisite: EE
3311 or equivalent. (3-0) R
EESC
6340 Introduction to Telecommunications Networks
(3 semester hours) Circuit, message and packet switching. The hierarchy of the
ISO-OSI Layers. The physical layer: channel characteristics, coding, and
error detection. The data link control
layer: retransmission strategies, framing, multiaccess
protocols, e.g., Aloha, slotted Aloha, CSMA, and CSMA/CD. The network layer: routing, broadcasting,
multicasting, flow control schemes. Co-requisite:
EESC 6349. (3-0) Y
EESC 6341
Information Theory I (3 semester hours) Self information,
mutual information, discrete memoryless sources,
entropy, source coding for discrete memoryless
channels, homogeneous Markov sources, discrete memoryless
channels, channel capacity, converse to the coding theorem, noisy channel
coding theorem, random coding exponent, Shannon limit. Prerequisite: EESC 6352. (3-0) R
EESC
6343 Detection and Estimation Theory (3 semester hours)
Parameter estimation.
Least-square, mean-square, and minimum-variance
estimators. Maximum A Posteriori (MAP) and
Maximum-Likelihood (ML) estimators. Bayes estimation. Cramer-Rao lower bound. BLUE estimator and Wiener
filtering. Prerequisite: EESC 6349. (3-0) R
EESC 6344 Coding
Theory (3 semester hours) Groups, fields,
construction and properties of Galois fields, error detection and correction,
Hamming distance, linear block codes, syndrome decoding of linear block codes,
cyclic codes, BCH codes, error trapping decoding and majority logic decoding of
cyclic codes, non-binary codes, Reed Solomon codes, burst error correcting
codes, convolutional codes, Viterbi decoding of convolutional codes. Prerequisite: EESC 6352. (3-0) R
EEDG 6345 (CE 6345)
Engineering of Packet-Switched Networks (3 semester hours)
Detailed coverage, from the point of view of engineering design, of the
physical, data-link, network and transport layers of IP (Internet Protocol)
networks. This course is a masters-level introduction to packet networks. Prior
knowledge of digital communication systems is strongly recommended.
Prerequisite: EE 3350 or equivalent. (3-0) Y
EEMF 6348 (MECH
6341, MSEN 6348) Lithography and Nanofabrication
(3 semester hours) Study of the principles, practical considerations, and
instrumentation of major lithography technologies for nanofabrication of
devices and materials. Advanced photolithography, electron beam lithography, nanoimprint lithography, x-ray lithography, ion beam
lithography, soft lithography, and scanning probe lithography, basic resist and
polymer science, applications in nanoelectronic and
biomaterials. (3-0) Y
EESC 6349 (MECH
6312) Random Processes (3 semester hours) Introductory
course to discrete and continuous stochastic process. Spectral
analysis, response of linear systems to stochastic inputs. Introduction
to estimation theory, Kalman filtering. Prerequisite:
MECH 6300 or equivalent. (3-0) T
EESC 6350 Signal
Theory (3 semester hours) Signal processing
applications and signal spaces, vector spaces, matrix inverses and orthogonal
projections, four fundamental subspaces, least squares and minimum norm
solutions, the SVD and principal component analysis, subspace approximation,
infinite dimensional spaces, linear operators, norms, inner products and
Hilbert spaces, projection theorems, spectral properties of Hermitian
operators, Hilbert spaces of random variables, linear minimum variance
estimation and the Levinson-Durbin algorithm, general optimization over Hilbert
spaces, methods and applications of optimization. Prerequisite: ENGR 3302 or equivalent. (3-0)
Y
EERF 6351
Computational Electromagnetics (3 semester hours)
Review of Maxwell's equations; numerical propagation of scalar waves;
finite-difference time-domain solutions of Maxwell's equations; numerical
implementations of boundary conditions; numerical stability; numerical
dispersion; absorbing boundary conditions for free space and waveguides;
selected applications in telecommunications, antennas, microelectronics and
digital systems. Prerequisite: EE 4301 or equivalent. (3-0) R
EESC 6352 Digital
Communication Systems (3 semester hours) Digital
communication systems are discussed.
Source coding and channel coding techniques are introduced. Signaling schemes and
performance of binary and M-ary modulated digital
communication systems. The
overall design considerations performance evaluations of various digital
communications systems are emphasized.
Prerequisite: EESC 6349 or equivalent. (3-0) Y
EESC
6353 Broadband Digital Communication (3 semester hours)
Characterization of broadband wireline and wireless
channels. MAP and ML detection.
Intersymbol Interference (ISI) effects. Equalization methods to
mitigate ISI including single-carrier and multi-carrier techniques. Equalization techniques and
structures including linear, decision-feedback, precoding,
zero-forcing, mean square-error, FIR versus IIR. Multi-Input Multi-Output
(MIMO) Equalization. Implementation issues including complexity, channel
estimation, error propagation, etc.
Real-world case studies from Digital Subscriber Lines (DSL) and wireless
systems. Students work individually or
in small teams on project and present their findings to class. Prerequisites: EE 4360 and knowledge of MATLAB. (3-0) T
EERF 6355 RF and
Microwave Amplifier Design (3 semester hours) Design of
high-frequency active circuits. Review of transmission line theory. RF and microwave matching circuits using discrete and guided wave
structures. Detailed study of S-parameters. Design of narrow band, broadband and low noise amplifiers. Detailed study of noise figure, noise parameters and stability of
RF and microwave circuits using S-parameters. Prerequisite: EE 4368 or
equivalent. (3-0) R
EESC 6360 Digital
Signal Processing I (3 semester hours) Analysis of
discrete time signals and systems, Z-transform, discrete Fourier transform,
fast Fourier transform, analysis and design of digital filters. Prerequisite: ENGR 3302 or EE 4361 or
equivalent. (3-0) Y
EESC 6361 Digital
Signal Processing II (3 semester hours) Continuation of
EESC 6360. Includes advanced topics in
signal processing such as: Digital filter structures and finite-word-length
effects, digital filter design and implementation methods, multirate
digital signal processing, linear prediction and optimum filtering, spectral
analysis and estimation methods. Prerequisite: EESC 6360. (3-0) T
EESC 6362
Introduction to Speech Processing (3 semester hours)
Introduction to the fundamentals of speech signal processing and speech
applications. Speech analysis and speech
synthesis techniques, speech enhancement and speech coding techniques including ADPCM and
linear-predictive based methods such as CELP. Prerequisite: EESC 6360. (3-0) Y
EESC 6363 Digital
Image Processing (3 semester hours) Image formation,
image sampling, 2D Fourier transform and properties, image wavelet transform,
image enhancement in spatial and frequency domains, image restoration, color
image processing, image segmentation, edge detection, morphological operations,
object representation and description, introduction to image compression.
Prerequisites: EE 4361 and knowledge of C or MATLAB. (3-0) T
EESC 6364 Pattern
Recognition (3 semester hours) Pattern recognition
system, Bayes decision theory, maximum likelihood and Bayesian parametric
classifiers, linear discriminant functions and decision boundaries, density
estimation and nonparametric classifiers, unsupervised classification and
clustering, multilayer neural networks, decision trees, classifier comparison.
Prerequisite: Knowledge of C or MATLAB.
Co-requisite: EESC 6349. (3-0) T
EESC 6365 Adaptive
Signal Processing (3 semester hours) Adaptive signal
processing algorithms learn the properties of their environments. Transversal and lattice versions of the Least
Mean Squares (LMS) and Recursive Least Squares (RLS) adaptive filter algorithms
and other modern algorithms will be studied.
These algorithms will be applied to network and acoustic echo
cancellation, speech enhancement, channel equalization, interference rejection,
beam forming, direction finding, active noise control, wireless systems, and
others. Prerequisites: EESC 6349, EESC
6360 and knowledge of matrix algebra. (3-0) T
EESC 6366 Speech
and Speaker Recognition (3 semester hours) Introduction to concepts in automatic
recognition methods for speech applications; the primary emphasis is for
automatic speech recognition and speaker identification techniques. Topics
include speech features for recognition, hidden Markov models (HMMs) for
acoustic and language applications (speech recognition, dialect/language
recognition), Gaussian mixture models (GMMs) for speaker characterization,
robustness issues to address noise and channel conditions for automatic
recognition. (3-0) Y
EESC 6367 Applied
Digital Signal Processing (3 semester hours) Implementation of
signal processing algorithms, combination of textual and graphical programming
of DSP systems, fixed-point versus floating-point, FPGA/DSP chip architecture,
FPGA/DSP software development tools, code optimization, application
project. Prerequisites: EE 4361 or
equivalent and knowledge of C or MATLAB. (2-3) Y
EESC 6368
Multimodal Signal Processing (3 semester hours)
Theory and applications in the field of multimodal signal processing. Robustness and performance of systems by considering cross-modal
integration. Introduction to speech processing, natural language and
dialog processing, image and video processing (face
recognition, gestures and action recognition). Statistical
algorithms and machine learning methods used for fusion/fission of multimodal
content at feature, decision and model level. Common graphical models
used in multimodal analysis including Dynamic Bayesian Network, Product HMM, Multistream HMM, coupled HMM, Factorial HMM, Input Output
HMM and segmental models. Prerequisite: ENGR 3341 or equivalent. Recommended Co-requisite: EESC 6349. (3-0) T
EEDG 6370 (CE 6370)
Design and Analysis of Reconfigurable Systems (3 semester
hours) Introduction to reconfigurable computing, programmable logic: FPGAS,
CPLDs, CAD issues with FPGA based design, reconfigurable systems: emulation,
custom computing, and embedded application based computing, static and dynamic
hardware, evolutionary design, software environments for reconfigurable
systems. Prerequisite: EE 3320 or equivalent. (3-0) R
EEBM 6371 Lecture
Course in Biomedical Applications of Electrical Engineering
(3 semester hours) This course provides an
introduction to different areas of biomedical applications of electrical
engineering. A special emphasis will be placed on research topics that are
actively pursued at UTD. (3-0) Y
EEMF 6372
Semiconductor Process Integration (3 semester hours)
The integration of semiconductor processing technology
to yield integrated circuits. The course will emphasize MOSFET design based
upon process integration, in particular as it applies to short channel devices
of current interest. Process simulation will be used to study diffusion,
oxidation, and ion implantation. (3-0) R
EEBM 6373 (BMEN
6373) Anatomy and Human Physiology for Engineers
(3 semester hours) This course provides an introduction
to anatomy and human physiology for engineers and other non-life-scientists.
Topics include nervous system, muscle and cardiac function, digestive system,
and immune system. (3-0) Y
EEBM 6374 (BMEN
6374) Molecular and Cell Biology for Engineers
(3 semester hours) An introduction to principles of
modern molecular and cellular biology for engineers and other
non-life-scientists. Topics include genes, protein structure and function,
organization of cells and cellular trafficking. (3-0) Y
EEDG 6375 (CE 6375)
Design Automation of VLSI Systems (3 semester hours)
This course deals with various topics related to the development of CAD tools
for VLSI systems design. Algorithms, data structures, heuristics and design
methodologies behind CAD tools. Design and analysis of algorithms for layout,
circuit partitioning, placement, routing, chip floor planning, and design rule
checking (DRC). Introduction to CAD algorithms for RTL and
behavior level synthesis, module generators, and silicon compilation.
Prerequisite: CS 5343. Co-requisite: EECT 6325. (3-0) Y
EEBM 6376 (BMEN
6376) Lecture Course in Biomedical Applications of Electrical Engineering
(3 semester hours) This course provides an introduction to different areas of
biomedical applications of electrical engineering. A special emphasis will be placed on research
topics that are actively pursued at UTD. (3-0) Y
EECT 6378 Power
Management Circuits (3 semester hours): This course
introduces different circuits related to power management systems. Topics include analysis and design of voltage
references, magnetic, and different dc-dc converters
including: switched-mode power converters, linear regulators and
switched-capacitor charge pump. Use of CAD tools to design and simulate power management circuits. Prerequisite: EECT 6326 or equivalent. (3-0)
Y
EECT 6379 Energy
Harvesting, Storage and Powering for Microsystems (3
semester hours) This course studies the electrical characteristics of various
renewable energy sources and the corresponding approaches on harvesting and
storage, with emphasis on the imposed requirements of microscale
dimension. They are followed by the discussion on power conditioning and
cross-layer energy/power management with circuit implementations. Prerequisite: EE 3311 or equivalent. (3-0) Y
EEBM 6380 (BMEN
6380) Introduction to Cellular Microscopy (3 semester
hours) Image formation, diffraction, labeling techniques, fluorescence and
image processing techniques will be introduced. (3-0) Y
EEBM 6381 (BMEN
6381) Advanced Concepts in Microscopy (3 semester hours) Continuation of EEBM 6380, with emphasis on advanced approaches such as vectorial diffraction, stochastic aspects of image formation and analysis. Prerequisites: BMEN/EEBM 6380 or by instructor permission. (3-0) Y
EEGR
6381 (MECH 6391) Computational Methods (3 semester hours)
Numerical techniques and their applications in engineering.
Topics will include: numerical methods of linear algebra, interpolation,
solution of nonlinear equations, numerical integration, Monte Carlo methods,
numerical solution of ordinary and partial differential equations, and
numerical solution of integral equations. Prerequisites: ENGR 2300 and ENGR
3300 or equivalents, and knowledge of a scientific programming language. (3-0)
R
EEMF
6382 (MECH 6347, MSEN 6382) Introduction to MEMS
(3 semester hours) Study of micro-electro-mechanical devices and systems and
their applications. Microfabrication
techniques and other emerging fabrication processes for MEMS are studied along
with their process physics. Principles of operations of various MEMS devices
such as mechanical, optical, thermal, magnetic, chemical/biological
sensors/actuators are studied. Topics include: bulk/surface micromachining,
LIGA, microsensors and microactuators
in multiphysics domain. (3-0) R
EEMF 6383 (MECH
6383, PHYS 6383) Plasma Science (3 semester hours)
Theoretically oriented study of plasmas. Topics to include: fundamental properties of
plasmas, fundamental equations (kinetic and fluid theory, electromagnetic
waves, plasma waves, plasma sheaths) plasma chemistry and plasma diagnostics. Prerequisite: PHYS 5320 or EEGR 6316. (3-0) T
EESC
6390 Introduction to Wireless Communication Systems
(3 semester hours) Principles, practice, and system overview of mobile systems. Modulation, demodulation,
coding, encoding, and multiple-access techniques. Performance
characterization of mobile systems.
Prerequisite: EE 3350 or equivalent. (3-0) Y
EESC 6391 Signaling
and Coding for Wireless Communication Systems (3 semester
hours) Study of signaling and coding for wireless communication systems. Topics
which will be covered include digital modulation schemes, digital multiple
access technologies, their performance under wireless channel impairments,
equalization, channel coding, interleaving, and diversity schemes. Prerequisites: EESC 6352 and EESC 6390. (3-0)
T
EESC 6392
Propagation and Devices for Wireless Communications
(3 semester hours) Mobile communication fundamentals, models of wave
propagation, simulation of electromagnetic waves in the cellular environment,
multipath propagation, compensation for fading, mobile and cell antenna
designs, problems of interference and incompatibility, design of active and
passive cellular components, comparison of analog and digital cellular
designs. Prerequisites: EE 4301 or
equivalent; EESC 6390. (3-0) R
EERF 6392 Millimeter Wave Integrated Circuit Design
(3 semester hours) Millimeter wave applications, silicon integrated circuits
technology trends, passive components in silicon IC's for millimeter wave
operation, Drude model for silicon substrate, parasitic
modeling, NQS transistor model, High frequency limit for thermal noise, chip
interface including packaging and antenna, comparison between RF and mm-wave
circuits, techniques for extending circuit operation frequency (injection locking and frequency multiplication),
and diode circuits including a parametric amplifier. Prerequisite: EECT 6325
and EERF 6311 or equivalent. (3-0) R
EESC 6393 Imaging
Radar Systems Design and Analysis (3 semester hours)
Radar systems, antenna systems, the radar equation, electromagnetic waves
scattering from targets, radar signal and noise, detection and extraction of
signal from noise or clutter, range and Doppler profiles, radar image
formation, real aperture radar imaging, SAR imaging, ISAR imaging, image
distortion, super resolution radar imaging techniques, and advanced holographic
radar imaging techniques. Prerequisites:
EE 3350 and EE 4301 or equivalents. (3-0) T
EERF 6394 Antenna
Engineering and Wave Propagation (3 semester hours)
Operating principles for microwave antennas used in modern wireless
communications and radar systems. Prerequisite: EEGR 6316 or equivalent. (3-0)
T
EERF 6395
Radiofrequency and Microwave Systems Engineering
(3 semester hours) Review of RF and microwave systems, such as cellular,
point-to-point radio, satellite, RFID and RADAR. Topics include: system
architectures, noise & distortion, antennas & propagation, transmission
lines & network analysis, active & passive components, modulation
techniques and specification flowdown. Prerequisite:
EE 4368 or equivalent. (3-0) R
EESC
6395 Wireless Sensor Systems and Networks (3 semester
hours) Sensor mote architecture and design.
Sensor network types, architecture and protocol stack. Studies on and design of
physical layer, data link layer, network layer, transport layer, and
application layer. Time
synchronization, localization, topology, mobility and task management issues in
wireless sensor networks. Security and privacy issues. Case studies on applications.
Prerequisite: ECS 4390 or equivalent. (3-0) T
EERF 6396 Microwave
Design and Measurement (3 semester hours) This
lecture and lab course covers the fundamentals of microwave component design
and measurements, including vector impedance (scattering parameters), scalar
measurements and spectrum analysis. Microwave components, such as filters,
directional couplers, switches, amplifiers, and oscillators, will be designed
and simulated with various CAD tools and then built and measured to compare
performance with theory. Prerequisite: EE 4368 or equivalent. (2-1) R
EEDG 6398 (CE 6398,
CS 6398) DSP Architectures (3 semester hours) Typical DSP
algorithms, representation of DSP algorithms, data-graph, FIR filters,
convolutions, Fast Fourier Transform, Discrete Cosine Transform, low power
design, VLSI implementation of DSP algorithms, implementation of DSP algorithms
on DSP processors, DSP applications including wireless communication and
multimedia. Prerequisite: CS 5343. (3-0) Y
EEGR 6V98 Thesis
(3-9 semester hours) (May be repeated for credit.) For
pass/fail credit only. ([3-9]-0) S
EE 6V99 Special
Topics in Electrical Engineering (1-9 semester
hours) Topics vary from semester to semester. May be repeated
for credit as topics vary. ([1-9]-0) S
EEMF 7171 Current
Topics in Plasma Processing (1 semester hour) discussion of
current literature on plasma processing; applications, diagnostics, sources,
chemistry and technology. May be repeated for credit.
Prerequisite: Knowledge of plasma processing technology (EEMF 5383 or EEMF 6383
preferred) or consent of instructor (1-0) Y
EEDG
7304 (CE 7304) Advanced Computer Architecture (3 semester
hours) Advanced research topics in multi-processor, network and reconfigurable
architectures. Focuses on current
research in the area of computer system architecture to prepare students for a
career in computer architecture research. Course will use articles from
current technical literature to discuss relevant topics, such as digital signal
processors and VLIW processors. Prerequisites: EEDG 6304, CS 5348, ENGR 3341
and knowledge of C/C++. (3-0) R
EEMF
7320 (MSEN 7320) Advanced Semiconductor Device Theory
(3 semester hours) Quantum mechanical description of fundamental semiconductor
devices; carrier transport on the submicron scale; heterostructure
devices; quantum-effect devices. Prerequisites: EEMF 6320 and EEMF 6321. (3-0)
R
EECT 7325 (CE 7325)
Advanced VLSI Design (3 semester hours) Advanced topics in
VLSI design covering topics beyond the first course (EECT 6325). Topics
include: use of high-level design, synthesis, and simulation tools, clock
distribution and routing problems, (a) synchronous circuits, low-power design
techniques, study of various VLSI-based computations, systolic arrays, etc.
Discussions on current research topics in VLSI design. Prerequisite: EECT 6325
or equivalent. (3-0) R
EECT 7326 Advanced
Analog Integrated Circuit Design (3 semester hours)
Advanced topics in analog design including a rigorous
treatment of noise, feedback and distortion in analog circuits. Selected topics
from other advanced topics such as continuous-time filter,
oscillator, phase-locked loop (PLL) and delay-locked loop (DLL) are also
covered. Prerequisite: EECT 6326. (3-0) Y
EECT 7327 Data Converters (3 semester hours)
Data converter circuits in modern mixed-signal VLSI systems. Topics include sampling, switched-capacitor amplifiers and integrators, sample-and-hold circuits, voltage comparators, Nyquist-rate and oversampling converters. Prerequisite: EECT 6326 and EECT 6325. (3-0) Y
EEDG
7328 (CE 7328) Physical Design of High-Speed VLSI Circuits
(3 semester hours) Techniques for the physical design of high-speed VLSI
circuits. Topics related to interconnection circuit
modeling, performance-driven routing, buffer and wire sizing, placement and
floor planning, technology mapping and performance evaluation issues
encountered in high-speed VLSI circuit designs. Discussion of
state-of-the-art practical industrial design examples. A project related
to the development of a prototype CAD tool. Prerequisites: CE/EECT 6325 and
knowledge of programming in C. (3-0) T
EERF 7330 Advanced
RF Integrated Circuit Design (3 semester hours)
Power Amplifiers, different classes of linear (A, B, AB, C) and switching power
amplifiers (E, G, H), CMOS Integrated power amplifiers, High Efficiency Power
Amplifiers (Doherty Power Amplifier); Phase Locked Loops: Basic concepts of
PLL, Charge pumps, Type-I and Type-II PLLs, Noise in PLLs, Phase Noise,
Frequency multiplication, RF Synthesizer Architectures, Frequency Dividers,
Fractional-N PLLs, Delta-Sigma based PLLs, ADPLL; Advanced RF transceivers;
Wideband and multiband radio design; Complete link budget analysis for wireless
systems. Design project will focus on design of the entire transmitter using
Agilent ADS. Prerequisite: EERF 6330 (RF Integrated Circuit Design). (3-0) Y
EECT 7331 Physics
of Noise (3 semester hours) The
physics of fluctuation phenomena, generically called Noise. The class will cover the fundamental physical
principles underlying generation-recombination, thermal, shot, l/f noise and
other, related fluctuation phenomena.
The statistical nature of these physical processes will be
developed. The physics of noise in
resistors, diodes, bipolar, JFETS, and MOSFETs will be discussed and how to
model it in circuits. Approximately two
thirds of the class will be devoted to the physics of noise and the rest will
cover how to use this knowledge to design low-noise integrated circuits. Prerequisite: EECT 6326. (3-0) Y
EEOP
7340 Optical Network Architectures and Protocols
(3 semester hours) Introduction to optical networks. The ITU Optical Layer. First-generation optical
networks. Standards,
e.g. SONET/SDH,
FDDI. Second-generation
optical networks. Broadcast and
select networks. The lightpath concept. Wavelength
routing networks. Virtual topology design.
Photonic packet switching. Advanced solutions and test
beds. Prerequisite: EESC 6340.
(3-0) R
EEDG 7V81 Special
Topics in Digital Systems (1-6 semester hours) For letter grade credit only. (May be
repeated to a maximum of 9 hours.) ([1-6]-0) S
EEMF 7V82 Special
Topics in Microelectronics (1-6 semester hours) For letter grade credit only. (May be
repeated to a maximum of 9 hours.) ([1-6]-0) S
EEOP 7V83 Special
Topics in Optics and Fields (1-6 semester hours) For letter grade credit only. (May be
repeated to a maximum of 9 hours.) ([1-6]-0) S
EESC 7V84 Special
Topics in Telecommunications (1-6 semester
hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) R
EESC 7V85 Special
Topics in Signal Processing (1-6 semester hours) For letter grade credit only. (May be
repeated to a maximum of 9 hours.) ([1-6]-0) S
EESC 7V86 Special
Topics in Wireless Communications (1-6 semester
hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) S
EEBM 7V87 Special
Topics in Biomedical Applications of Electrical Engineering
(1-6 semester hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) S
EECT 7V88 Special
Topics in Circuits and Systems (1-6 semester
hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) S
EERF 7V89 Special
Topics in RF and Microwave Systems (1-6 semester
hours) For letter grade credit only. (May be repeated to a maximum of 9 hours.) ([1-6]-0) S
EEGR 8V40
Individual Instruction in Electrical Engineering
(1-6 semester hours) (May be repeated for credit.) For
pass/fail credit only. ([1-6]-0) R
EEGR 8V70 Research
in Electrical Engineering (3-9 semester hours) (May be repeated
for credit.) For pass/fail credit only. ([3-9]-0) R
EEGR 8V99
Dissertation (3-9 semester hours) (May be repeated for
credit.) For pass/fail credit only. ([3-9]-0) S
