Department of Electrical and Biomedical Engineering
Academics - Courses
Electrical Engineering Courses
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EE191 INTRODUCTION TO ELECTRICAL ENGINEERING
Lecture+Lab: 2+3
Credit(s): 3
History and overview of electrical engineering including professional ethics, areas of specialization, and engineering creativity. (Formerly EE 101; implemented Spring 2005.)
Syllabus: EE191 [PDF]Prerequisite(s): NoneCorequisite(s): None -
EE120 FUNDAMENTALS OF ELECTRICAL ENGINEERING
Lecture+Lab: 3
Credit(s): 3
Transistors, op-amps used to build amplifiers and comparators, AM radio receivers, AC power generation and conversion, signals, power supply design, filters, intuitive NI-Multisim design projects.
Syllabus: NOSYLLABUS [PDF]Prerequisite(s): EE 191 OR ENGR 100.NoneCorequisite(s): None
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EE220 CIRCUITS I
Lecture+Lab: 3+0
Credit(s): 3
Introduction to analysis methods and network theorems used to describe operation of electric circuits. Includes resistive, capacitive and inductive components in DC and AC circuits. (Formerly EE 201; implemented Spring 2005.) (Offered every semester.)
Syllabus: EE220 [PDF]Prerequisite(s):PHYS 181 with a "C" or BetterCorequisite(s):EE220L for Electrical Engineering Students -
EE220L CIRCUITS I LABORATORY
Lecture+Lab: 0+3
Credit(s): 1
Introduction to electrical engineering basic laboratory procedures and equipment. (Offered every semester.)
Syllabus: EE220L [PDF]Prerequisite(s): NoneCorequisite(s):EE220 -
EE221 CIRCUITS II
Lecture+Lab: 3+0
Credit(s): 3
Time domain and Laplace transform methods for analysis of electric circuits. Applications to passive and active filters. Modeling, analysis and simulation of circuits and systems. (Formerly EE 301; implemented Spring 2005.) (Offered every semester.)
Syllabus: EE221 [PDF]Prerequisite(s): MATH 285 with a "C" or better.Corequisite(s):EE291 -
EE240 FUNDAMENTALS & ECONOMICS OF RENEWABLE & NONRENEWABLE ENERGY
Lecture+Lab: 3+0
Credit(s): 3
Fundamentals of renewable and nonrenewable energy: generation, transmission, distribution, dispatch, and economics.
Syllabus: EE240 [PDF]Prerequisite(s): MATH 128Corequisite(s):None -
EE290L ELECTRICAL PROJECTS LAB
Lecture+Lab: 0+3 or 6
Credit(s): 1 OR 2
Offers the opportunity to undertake an independent project of the students own interest, upon individual arrangement with a staff member. Maximum of 4 credits. (Formerly EE 290; implemented Spring 2005.)
Prerequisite(s): Corequisite(s): -
EE291 COMPUTER METHODS FOR ELECTRICAL ENGINEERS
Lecture+Lab: 3+0
Credit(s): 3
Solving engineering problems using a computer. Errors, root finding, matrix algebra, complex numbers, graphics and programming. (Formerly EE 231; implemented Spring 2005.) (Offered fall semesters.)
Syllabus: EE291 [PDF]Prerequisite(s):CS 135; EE 191 and MATH 182 with a "C" or better. Corequisite(s): -
EE296 INTERNSHIP I
Lecture+Lab: 1+0
Credit(s): 1
Preparation of written reports based on cooperative program assignments. Required of all students in cooperative programs during the summer or other semesters when on work assignments with cooperative program employers. (Formerly EE 298; implemented Spring 2005.)
Prerequisite(s):Corequisite(s):
Junior and Senior Courses
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EE320 RELECTRONICS I
Lecture+Lab: 3+0
Credit(s): 3
Study of active devices, their behavior in analog and digital circuits. Introduction to integrated circuits as building blocks in digital and analog circuits. (Formerly EE 321; implemented Spring 2005.) (Offered fall semesters.)
Syllabus: EE320R [PDF]Prerequisite(s):Corequisite(s):EE221; EE320L -
EE320 LELECTRONICS I LAB
Lecture+Lab: 3+0
Credit(s): 3
Analysis of discrete and integrated analog electronic components. Design, construction and testing of analog electronic circuits. (Formerly EE 320; implemented Spring 2005.) (Offered fall semesters.)
Syllabus: EE320L [PDF]Prerequisite(s):Corequisite(s): EE320 R -
EE330 RENGINEERING ELECTROMAGNETICS
Lecture+Lab: 3+0
Credit(s): 3
Basic concepts of electromagnetic fields and their applications in transmission lines, antennas, communications and optical fibers. (Formerly EE 351; implemented Spring 2005.) (Offered spring semesters.)
Syllabus: EE330 R [PDF]Prerequisite(s):EE 220 with a "C" or better; PHYS 181 with a "C" or better; MATH 285 with a "C" or better.Corequisite(s): -
EE340POWER SYSTEM FUNDAMENTALS
Lecture+Lab: 3+0
Credit(s): 3
Basic power system analytical concepts, three-phase systems, phasers, impedance, steady-state network analysis, normalization, transmission lines, transformers, synchronous machines. (Formerly EE 361; implemented Spring 2005.) (Offered spring semesters.)
Syllabus: EE340 [PDF]Prerequisite(s):EE 220 with a "C" or better; EE 291.Corequisite(s): -
EE362SIGNALS AND SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Frequency and time domain analysis of continuous and discrete signals and systems: orthogonal functions and Fourier series; continuous and discrete Fourier transforms; the z-transform; and introduction to modulation and modulating systems. (Formerly EE 381; implemented Spring 2005.) (Offered fall semesters.)
Syllabus: EE362 [PDF]Prerequisite(s):Corequisite(s): EE221 -
EE370 LCONTROL SYSTEMS LABORATORY
Lecture+Lab: 0+3
Credit(s): 1
Modeling and simulation of physical engineering systems. Implementation and testing of control system designs. (Formerly EE 370; implemented Spring 2005.) (Offered spring semesters.)
Syllabus: EE370 L [PDF]Prerequisite(s):Corequisite(s):EE370 R -
EE370 RCONTROL SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Analysis and modeling of engineering systems including input-output and state-variable descriptions. Root locus and frequency domain methods. Introduction to classical control design. (Formerly EE 371; implemented Spring 2005.) (Offered spring semesters.)
Syllabus: EE370 R [PDF]Prerequisite(s):EE 221, ME 241 or CEE 241.Corequisite(s):EE370 L -
EE390 LINDEPENDANT STUDY
Lecture+Lab: 0 + 3 OR 6
Credit(s): 1 OR 2
Independent project of the students own interest, upon individual arrangement with a staff member. Maximum of 4 credits. (Formerly EE 390; implemented Spring 2005.)
Prerequisite(s):Corequisite(s): -
EE396INTERNSHIP II
Lecture+Lab: 1+ 0
Credit(s): 1
Preparation of written reports based on cooperative program assignments. Required of all students in cooperative programs during the summer or other semesters when on work assignments with cooperative program employers. (Formerly EE 398; implemented Spring 2005.)
Prerequisite(s):Corequisite(s): -
EE410OPTICAL FIBER COMMUNICATION
Lecture+Lab: 3 + 0
Credit(s): 3
Optical fiber structures, propagation characteristics, fabrication, cabling and packaging, optical measurements, optical sources, modulation, power launching and coupling, communication links. (Formerly EE 448/648; implemented Spring 2005.)
Syllabus: EE 410 [PDF]Prerequisite(s):EE330 RCorequisite(s):EE410 L -
EE410 LOPTICAL FIBER COMMUNICATION LABORATORY
Lecture+Lab: 0 + 3
Credit(s): 1
Measurements of optical fiber propagation characteristics, losses, source characteristics and transmission information. (Formerly EE 445/645; implemented Spring 2005.)
Syllabus: EE 410 L [PDF]Prerequisite(s):EE330 RCorequisite(s):EE410 -
EE420ELECTRONICS II
Lecture+Lab: 3 + 0
Credit(s): 3
Examines circuit design and integrated circuit use with emphasis on operational amplifiers, active filters and analog applications. (Formerly EE 422/622; implemented Spring 2005.)
Syllabus: EE 420 [PDF]Prerequisite(s):EE320 RCorequisite(s): -
EE421DIGITAL ELECTRONICS
Lecture+Lab: 3 + 0
Credit(s): 3
Hardware-related design considerations for combinatorial and sequential logic using integrated circuits. Includes TTL, CMOS, shift registers, arithmetic units, RAM, ROM and edge-triggered devices. (Formerly EE 427/627; implemented Spring 2005.)
Syllabus: EE 421 [PDF]Prerequisite(s):EE320 R, CPE 301Corequisite(s): -
EE423INTEGRATED CIRCUIT ENGINEERING
Lecture+Lab: 3 + 0
Credit(s): 3
Introduction to the design and fabrication of integrated circuits. Factors limiting integrated circuits specifications are considered and new technologies are studied.
Prerequisite(s):EE320 RCorequisite(s): -
EE424BIOMEDICAL INSTRUMENTATION
Lecture+Lab: 3 + 0
Credit(s): 3
Principles of modern electronic design including microcomputer applications, transducer technology, digital design, interface design, biomedical information systems. (Formerly EE 426/626; implemented Spring 2005.)
(Same as BME 426/626.)
Prerequisite(s):EE320 R, EE362Corequisite(s): -
EE426MICROPROCESSOR APPLICATIONS
Lecture+Lab: 3 + 1
Credit(s): 3
Students implement an embedded application of their choice. Design and analysis, communication, and ability to complete a working project on time, within budget. (Formerly EE 439/639; implemented Spring 2005.)
Syllabus: EE426 [PDF] Prerequisite(s):CPE 301 RCorequisite(s): -
EE433DISTRIBUTED SYSTEMS AND ANTENNA DESIGN
Lecture+Lab: 3 + 0
Credit(s): 3
Introduction to concepts of distributed systems, wave propagation and antenna design. (Formerly EE 451/651; implemented Spring 2005.)
Syllabus: EE433 [PDF] Prerequisite(s):EE 330 RCorequisite(s): -
EE434ELECTROMAGNETIC COMPATIBILITY
Lecture+Lab: 3 + 0
Credit(s): 3
Electronic design to minimize electromagnetic coupling and crosstalk. Topics include grounding and shielding, conducted and radiated emissions, susceptibility and EMC regulations. (Formerly EE 453/653; implemented Spring 2005.)
Prerequisite(s):EE 320 R, EE330 RCorequisite(s): -
EE435 RELECTROACOUSTICS
Lecture+Lab: 3 + 0
Credit(s): 3
Theory of sonic and ultrasonic vibrations and acoustics, including electromechanical transducers. (Formerly EE 456/656; implemented Spring 2005.)
Prerequisite(s):EE330 RCorequisite(s): -
EE436 LMICROWAVE ENGINEERING LABORATORY
Lecture+Lab: 0 + 3
Credit(s): 1
Basic microwave measurements including slotted lines, stub tuners, power meters, directional couplers, spectrum analyzer, network analyzer, filter design using commercially available software. (Formerly EE 450/650; implemented Spring 2005.)
Syllabus: EE436L {PDF} Prerequisite(s):EE433Corequisite(s):EE436 R -
EE436 RMICROWAVE ENGINEERING
Lecture+Lab: 3+0
Credit(s): 3
Microwave network analysis, passive components, impedance matching, striplines and microstriplines, power dividers, directional couplers, filter and amplifier design. (Formerly EE 452/652; implemented Spring 2005.)
Syllabus: EE436 R [PDF]
Prerequisite(s):EE433Corequisite(s):EE436 L -
EE440POWER SYSTEMS ANALYSIS
Lecture+Lab: 3+0
Credit(s): 3
Power flow, symmetrical components, faulted system analysis, protection, stability. (Formerly EE 461/661; implemented Spring 2005.)
Syllabus: EE 440 [PDF]Prerequisite(s):EE340Corequisite(s): -
EE441ELECTRICAL MACHINES
Lecture+Lab: 3+0
Credit(s): 3
Fundamentals of transformers and rotating machines; dc, induction, synchronous and variable-reluctance machines. (Formerly EE 463/663; implemented Spring 2005.)
Syllabus: EE 441 [PDF]Prerequisite(s):EE340Corequisite(s): -
EE442POWER ELECTRONICS
Lecture+Lab: 3+0
Credit(s): 3
Semiconductor power switches. Rectifiers, AC voltage controllers, cycloconverters, choppers, inverters. Applications. (Formerly EE 466/666; implemented Spring 2005.)
Syllabus: EE 442 [PDF]Prerequisite(s):EE320 R, EE340Corequisite(s): -
EE443ELECTRIC POWER DISTRIBUTION
Lecture+Lab: 3+0
Credit(s): 3
Distribution components, load characteristics, voltage calculations, primary and secondary systems, transformers, capacitor applications. (Formerly EE 467/667; implemented Spring 2005.)
Prerequisite(s):EE340Corequisite(s): -
EE444POWER SYSTEM PROTECTION
Lecture+Lab: 3+0
Credit(s): 3
Elements of protective systems, relays, relaying schemes circuit interrupting devices, fault protection of radial feeders, network protective schemes and protective system reliability. (Formerly EE 468/668; implemented Spring 2005.)
Syllabus: EE444 [PDF] Prerequisite(s):EE340Corequisite(s): -
EE445 RPOWER SYSTEM OPERATION WITH RENEWABLE ENERGY SOURCES
Lecture+Lab: 3+0
Credit(s): 3
Renewable energy, distributed generation, impacts of renewable energy based generation on power system operation, electrical energy markets, deregulated power systems, hybrid power generation.
Syllabus: EE445 [PDF]
Prerequisite(s):EE440Corequisite(s): -
EE461 RSTOCHASTIC SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Introduction to stochastic systems. Includes review of concepts of random variable theory, functions of two random variables, mean square estimation, nonstationary process applications. (Formerly EE 481/681; implemented Spring 2005.)
Prerequisite(s):EE 362; MATH/STAT 352.Corequisite(s): -
EE463COMMUNICATIONS SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Basic electrical communication systems including modulation, transmission, demodulation, channel distortion and loss, bandwidth limitations, digital signaling, information theory and coding, digital transmission and reception. (Formerly EE 464/664; implemented Spring 2005.)
Prerequisite(s):EE 362Corequisite(s): -
EE465WIRELESS SENSOR SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Design of networks consisting of small in size, low-power sensor devices using various protocols that are application specific, data centric, and energy efficient.
Syllabus: EE 465 [PDF]Prerequisite(s):EE 330 RCorequisite(s): -
EE471CONTROL SYSTEMS II
Lecture+Lab: 3+0
Credit(s): 3
State-space models, controllability, observability, classical design using frequency response and root locus, state feedback, observer design.
Syllabus :EE471 [PDF] Prerequisite(s):EE 370 RCorequisite(s): -
EE472DIGITAL CONTROL ENGINEERING
Lecture+Lab: 3+0
Credit(s): 3
Difference equations and the Z-transform, digital control system modeling, digital controller design, introduction to state-space methods. (Formerly EE 476/676; implemented Spring 2005.)
Syllabus: EE472 [PDF]Prerequisite(s):EE 370 RCorequisite(s): -
EE480DIGITAL SIGNAL PROCESSING
Lecture+Lab: 3+0
Credit(s): 3
Discrete signals and systems. The Z transform. Digital filter design techniques. The Fast Fourier Transform. Modeling, analysis, and simulation of discrete random signals and systems. (Formerly EE 484/684; implemented Spring 2005.)
Prerequisite(s): EE 362; MATH/STAT 352.Corequisite(s): -
EE490ELECTRICAL PROJECTS LABORATORY
Lecture+Lab: 3+0
Credit(s): 3
Design principles and dynamic signal processing techniques used for the design and integration of modern complex systems. (Major capstone course.) (Offered fall semesters.)
Syllabus: EE490 {PDF]
Prerequisite(s): EE 320 R; EE 330 R; EE 362; EE 370 RCorequisite(s): -
EE491ENGINEERING DESIGN/ANALYSIS
Lecture+Lab: 3+4
Credit(s): 4
Innovation, entrepreneurship and design of products. Proposal writing and design and fabrication procedures used by industry. For electrical engineering majors only. (Major capstone course.) (Offered spring semesters.)
Syllabus: EE491 [PDF}
Prerequisite(s):EE 221; EE 320 R; EE490Corequisite(s): -
EE492SEMINAR
Lecture+Lab:
Credit(s): 1 TO 4
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE493 INDEPENDANT STUDY
Lecture+Lab:
Credit(s): EACH TOPIC 1 TO 3
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics
Prerequisite(s):Corequisite(s): -
EE496INTERNSHIP III
Lecture+Lab: 1 + 0
Credit(s): 1
Preparation of written reports based on cooperative program assignments. Required of all students in cooperative programs during the summer or other semesters when on work assignments with cooperative program employers. (Formerly EE 498; implemented Spring 2005.)
Prerequisite(s):Corequisite(s):
Graduate Courses
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EE610 LOPTICAL FIBER COMMUNICATION LABORATORY
Lecture+Lab: 0 + 3
Credit(s): 1
Measurements of optical fiber propagation characteristics, losses, source characteristics and transmission information. (Formerly EE 445/645; implemented Spring 2005.)
Syllabus: EE 410 L [PDF]Prerequisite(s):EE330 RCorequisite(s):EE610 -
EE620ELECTRONICS II
Lecture+Lab: 3 + 0
Credit(s): 3
Examines circuit design and integrated circuit use with emphasis on operational amplifiers, active filters and analog applications. (Formerly EE 422/622; implemented Spring 2005.)
Syllabus: EE 420 [PDF]Prerequisite(s):EE320 RCorequisite(s): -
EE621DIGITAL ELECTRONICS
Lecture+Lab: 3 + 0
Credit(s): 3
Hardware-related design considerations for combinatorial and sequential logic using integrated circuits. Includes TTL, CMOS, shift registers, arithmetic units, RAM, ROM and edge-triggered devices. (Formerly EE 427/627; implemented Spring 2005.)
Syllabus: EE 421 [PDF]Prerequisite(s):EE320 R, CPE 301Corequisite(s): -
EE621INTEGRATED CIRCUIT ENGINEERING
Lecture+Lab: 3 + 0
Credit(s): 3
Introduction to the design and fabrication of integrated circuits. Factors limiting integrated circuits specifications are considered and new technologies are studied.
Prerequisite(s):EE320 RCorequisite(s): -
EE624BIOMEDICAL INSTRUMENTATION
Lecture+Lab: 3 + 0
Credit(s): 3
Principles of modern electronic design including microcomputer applications, transducer technology, digital design, interface design, biomedical information systems. (Formerly EE 426/626; implemented Spring 2005.)
(Same as BME 426/626.)
Prerequisite(s):EE320 R, EE362Corequisite(s): -
EE626MICROPROCESSOR APPLICATIONS
Lecture+Lab: 3 + 1
Credit(s): 3
Students implement an embedded application of their choice. Design and analysis, communication, and ability to complete a working project on time, within budget. (Formerly EE 439/639; implemented Spring 2005.)
Prerequisite(s):CPE 301 RCorequisite(s): -
EE633DISTRIBUTED SYSTEMS AND ANTENNA DESIGN
Lecture+Lab: 3 + 0
Credit(s): 3
Introduction to concepts of distributed systems, wave propagation and antenna design. (Formerly EE 451/651; implemented Spring 2005.)
Prerequisite(s):EE 330 RCorequisite(s): -
EE634ELECTROMAGNETIC COMPATIBILITY
Lecture+Lab: 3 + 0
Credit(s): 3
Electronic design to minimize electromagnetic coupling and crosstalk. Topics include grounding and shielding, conducted and radiated emissions, susceptibility and EMC regulations. (Formerly EE 453/653; implemented Spring 2005.)
Prerequisite(s):EE 320 R, EE330 RCorequisite(s): -
EE635 RELECTROACOUSTICS
Lecture+Lab: 3 + 0
Credit(s): 3
Theory of sonic and ultrasonic vibrations and acoustics, including electromechanical transducers. (Formerly EE 456/656; implemented Spring 2005.)
Prerequisite(s):EE330 RCorequisite(s): -
EE636 LMICROWAVE ENGINEERING LABORATORY
Lecture+Lab: 0 + 3
Credit(s): 1
Basic microwave measurements including slotted lines, stub tuners, power meters, directional couplers, spectrum analyzer, network analyzer, filter design using commercially available software. (Formerly EE 450/650; implemented Spring 2005.)
Prerequisite(s):EE433Corequisite(s):EE436 R -
EE636 RMICROWAVE ENGINEERING
Lecture+Lab: 3+0
Credit(s): 3
Microwave network analysis, passive components, impedance matching, striplines and microstriplines, power dividers, directional couplers, filter and amplifier design. (Formerly EE 452/652; implemented Spring 2005.)
Prerequisite(s):EE433Corequisite(s):EE436 L -
EE640POWER SYSTEMS ANALYSIS
Lecture+Lab: 3+0
Credit(s): 3
Power flow, symmetrical components, faulted system analysis, protection, stability. (Formerly EE 461/661; implemented Spring 2005.)
Syllabus: EE 440 [PDF]Prerequisite(s):EE340Corequisite(s): -
EE641ELECTRICAL MACHINES
Lecture+Lab: 3+0
Credit(s): 3
Fundamentals of transformers and rotating machines; dc, induction, synchronous and variable-reluctance machines. (Formerly EE 463/663; implemented Spring 2005.)
Syllabus: EE 441 [PDF]Prerequisite(s):EE340Corequisite(s): -
EE642POWER ELECTRONICS
Lecture+Lab: 3+0
Credit(s): 3
Semiconductor power switches. Rectifiers, AC voltage controllers, cycloconverters, choppers, inverters. Applications. (Formerly EE 466/666; implemented Spring 2005.)
Syllabus: EE 442 [PDF] Prerequisite(s):EE320 R, EE340Corequisite(s): -
EE643ELECTRIC POWER DISTRIBUTION
Lecture+Lab: 3+0
Credit(s): 3
Distribution components, load characteristics, voltage calculations, primary and secondary systems, transformers, capacitor applications. (Formerly EE 467/667; implemented Spring 2005.)
Prerequisite(s):EE340Corequisite(s): -
EE644POWER SYSTEM PROTECTION
Lecture+Lab: 3+0
Credit(s): 3
Elements of protective systems, relays, relaying schemes circuit interrupting devices, fault protection of radial feeders, network protective schemes and protective system reliability. (Formerly EE 468/668; implemented Spring 2005.)
Prerequisite(s):EE340Corequisite(s): -
EE645 RPOWER SYSTEM OPERATION WITH RENEWABLE ENERGY SOURCES
Lecture+Lab: 3+0
Credit(s): 3
Renewable energy, distributed generation, impacts of renewable energy based generation on power system operation, electrical energy markets, deregulated power systems, hybrid power generation.
Syllabus: EE645 [PDF]
Prerequisite(s):EE440Corequisite(s): -
EE661 RSTOCHASTIC SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Introduction to stochastic systems. Includes review of concepts of random variable theory, functions of two random variables, mean square estimation, nonstationary process applications. (Formerly EE 481/681; implemented Spring 2005.)
Prerequisite(s):EE 362; MATH/STAT 352.Corequisite(s): -
EE663COMMUNICATIONS SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Basic electrical communication systems including modulation, transmission, demodulation, channel distortion and loss, bandwidth limitations, digital signaling, information theory and coding, digital transmission and reception. (Formerly EE 464/664; implemented Spring 2005.)
Prerequisite(s):EE 362Corequisite(s): -
EE665WIRELESS SENSOR SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Design of networks consisting of small in size, low-power sensor devices using various protocols that are application specific, data centric, and energy efficient.
Syllabus: EE 465 [PDF]Prerequisite(s):EE 330 RCorequisite(s): -
EE671CONTROL SYSTEMS II
Lecture+Lab: 3+0
Credit(s): 3
State-space models, controllability, observability, classical design using frequency response and root locus, state feedback, observer design.
Prerequisite(s):EE 370 RCorequisite(s): -
EE672DIGITAL CONTROL ENGINEERING
Lecture+Lab: 3+0
Credit(s): 3
Difference equations and the Z-transform, digital control system modeling, digital controller design, introduction to state-space methods. (Formerly EE 476/676; implemented Spring 2005.)
Syllabus: EE672 [PDF]Prerequisite(s):EE 370 RCorequisite(s): -
EE680DIGITAL SIGNAL PROCESSING
Lecture+Lab: 3+0
Credit(s): 3
Discrete signals and systems. The Z transform. Digital filter design techniques. The Fast Fourier Transform. Modeling, analysis, and simulation of discrete random signals and systems. (Formerly EE 484/684; implemented Spring 2005.)
Prerequisite(s): EE 362; MATH/STAT 352.Corequisite(s): -
EE692SEMINAR
Lecture+Lab:
Credit(s): 1 TO 4
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE693SEMINAR
Lecture+Lab:
Credit(s): 1 TO 3
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics
Prerequisite(s):Corequisite(s): -
EE721ADVANCED ELECTRONICS
Lecture+Lab: 3+0
Credit(s): 3
(a) Low noise, wide band, and fast, amplifiers, active filters, (b) pulse, wave shaping and computing circuits. These courses are not sequential.
Prerequisite(s):Corequisite(s): -
EE733MACHINE INTELLIGENCE
Lecture+Lab: 3 + 0
Credit(s): 3
(a) Intelligent systems, (b) neural computing, (c) advanced applications. Self-organizing, self-adapting systems; cybernetics; neural networks; automated decision making and control; learning automata; expert systems application; knowledge and data engineering; pattern recognition, image processing
(SAME AS CS773)
Prerequisite(s):CPE 301 RCorequisite(s): -
EE741OPTICAL FIBER COMMUNICATIONS
Lecture+Lab: 3+0
Credit(s): 3
Review of optical fibers, optical receivers, detectors, amplifiers, sources, transmission links, noise considerations, optical fiber communication systems, coherent communication, applications and future developments
Prerequisite(s):EE410, EE410LCorequisite(s): -
EE742OPTICAL FIBER SENSORS AND APPLICATIONS
Lecture+Lab:
Credit(s): 1 TO 3
Basic concept; integrated optics for sensors; interferometric-, intensity- and wavelength-based sensors; optical actuators; sensor multiplexing principles; distributed optical fiber sensors; various applications.
Prerequisite(s):EE410, EE410LCorequisite(s): -
EE743OPTICAL FIBER NETWORKING
Lecture+Lab: 0+3
Credit(s): 3
Fiber transport system and components; switching techniques; system architecture; ISDN, WAN, MAN, LAN topology; SONET technology; network survivability; residential fiber networks.
Prerequisite(s):EE410, EE410LCorequisite(s): -
EE751ANTENNA THEORY AND DESIGN
Lecture+Lab: 3+ 0
Credit(s): 3
Antenna fundamentals; theory, design of dipole, loop, wire, broadband, aperture, microstrip antennas; arrays, method of moments, antenna synthesis; CAD analysis, measurements performed in anechoic chamber.
Prerequisite(s):EE433/633Corequisite(s): -
EE752SEMINAR
Lecture+Lab: 3+0
Credit(s): 3
Electromagnetic wave propagation in nonhomogeneous media, dielectric wave guides, propagation in anisotropic materials, mode coupling in multimode dielectric wave guides, radiation from microstrip patches on ferrite substrates
Prerequisite(s):EE433/633Corequisite(s): -
EE753 RCOMPUTATIONAL ELECTROMAGNETICS
Lecture+Lab: 3+0
Credit(s): 3
Analytical methods, finite difference methods, method of moments, finite difference time domain technique, finite element technique, applications of these methods.
Prerequisite(s):EE433/633Corequisite(s): -
EE754MICROWAVE SEMICONDUCTOR DEVICES
Lecture+Lab:3+0
Credit(s): 3
Microwave diodes, junction transistors, field effect transistors, transferred electron devices and avalanche transit-time devices. Device and circuit design are considered with special emphasis on amplifier design
Prerequisite(s):EE436/636Corequisite(s): -
EE756MICROWAVE INTEGRATED CIRCUITS (MICS)
Lecture+Lab: 3+0
Credit(s): 3
Development of MlCs, analysis of microstrip lines, coupled microstrip lines, microstrip, discontinuities, slot lines and coplanar lines, MIC fabrication and design of microstrip components.
Prerequisite(s):EE436/636Corequisite(s): -
EE757 RMICROWAVE COMMUNICATIONS SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Basics of microwave communication systems, microwave transmitters, receivers, modulation and amplification, system noise consideration, microwave links and terrestrial communications, cellular radios, satellite systems, DBS
Prerequisite(s):EE436/636; EE436L/636LCorequisite(s): -
EE763ELECTRIC DRIVE SYSTEMS
Lecture+Lab: 2+1
Credit(s): 3
Design and control of adjustable speed and positioning electric drive systems with DC and AC motors.
Prerequisite(s):EE436/636; EE436L/636LCorequisite(s): -
EE766ADVANCED POWER SYSTEMS ANALYSIS
Lecture+Lab: 3+0
Credit(s): 3
(a) Computer solution of power system, (b) power system stability, (c) power system planning. Each topic may be taken for 3 credits..
Syllabus: EE766 [PDF}
Prerequisite(s):EE440Corequisite(s): -
EE776NONLINEAR CONTROL SYSTEMS
Lecture+Lab: 3+0
Credit(s): 3
Nonlinear state equations, phase plane analysis, describing function, Liapunov stability, circle criterion, introduction to nonlinear control systems design.
Prerequisite(s):Corequisite(s): -
EE778OPTIMAL CONTROL
Lecture+Lab: 3+0
Credit(s): 3
Parameter optimization, optimal control of continuous and discrete systems, introduction to numerical methods.
Prerequisite(s):EE 471 OR EE 472Corequisite(s): -
EE782RANDOM SIGNAL ANALYSIS AND ESTIMATION THEORY
Lecture+Lab: 3+0
Credit(s): 3
Random variables and random signals, auto-correlation and cross-correlation functions. Power spectral density functions, minimum mean-squared estimation, maximum likelihood estimation, linear and extended Kalman filtering -
Syllabus:EE782 [pdf]
Prerequisite(s):EE 362, MATH/STAT 352Corequisite(s): -
EE783 RADVANCED SIGNAL PROCESSING
Lecture+Lab: 3+0
Credit(s): 3
Parametric, adaptive, and model-based signal processing. Detection/estimation of signals in noise. Multidimensional discrete systems. Adaptive array processing. Introduction to intelligent signal processing systems
Prerequisite(s):EE 480/680Corequisite(s): -
EE784INFORMATION AND COMMUNICATION THEORY
Lecture+Lab: 3+0
Credit(s): 3
(a) Information theory and coding, (b) continuous and pulsed communication systems, (c) optimum transmission and propagation techniques. Each topic may be taken for 3 credits.
Prerequisite(s):Corequisite(s): -
EE790SEMINAR
Lecture+Lab:
Credit(s): 1 TO 3
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE791SPECIAL TOPICS
Lecture+Lab:
Credit(s): 1 TO 3
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE792SPECIAL TOPICS
Lecture+Lab:
Credit(s): 1 TO 2
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE793INDEPENDANT STUDY
Lecture+Lab:
Credit(s): 1 TO 3
(a) Acoustics, (b) biomedical electronics, (c) communications and networks, (d) computer engineering, (e) control systems, (f) electronics, (g) image processing, (h) machine intelligence, (j) microwave systems, (k) modeling and simulation, (m) parallel distributed processing, (n) power systems, (p) signal processing, (q) stochastic systems, (r) systems science, (s) optical fibers, (t) power electronics.
Prerequisite(s):Corequisite(s): -
EE795 RCOMPREHENSIVE EXAMINATION
Lecture+Lab:
Credit(s): 1 S/U ONLY
Course is used by graduate programs to administer comprehensive examinations either as an end of program comprehensive examination or as a qualifying examination for doctoral candidates prior to being advanced to candidacy.
Prerequisite(s):Corequisite(s): -
EE796PROFESSIONAL PAPER
Lecture+Lab:
Credit(s): 2 S/U ONLY
Prerequisite(s):Corequisite(s): -
EE797PROFESSIONAL PAPER
Lecture+Lab:
Credit(s): 1 TO 6
Prerequisite(s):Corequisite(s): -
EE799DISSERTATION
Lecture+Lab:
Credit(s): 1 TO 24
Prerequisite(s):Corequisite(s): -
EE899GRADUATE ADVISEMENT
Lecture+Lab:
Credit(s): 1 TO 4
Provides access to faculty for continued consultation and advisement. No grade is filed and credits may not be applied to any degree requirements. Limited to 8 credits (2 semester) enrollment. For non-thesis master's degree students only.
Prerequisite(s):Corequisite(s):