Chair: Yehia Massoud
The Electrical Engineering program in the Department of Electrical and Computer Engineering at UAB embodies a curriculum of 128 semester hours that is accredited by the Engineering Accreditation Commission (EAC) of ABET, http://www.abet.org. In addition to courses in pre-engineering, mathematics, calculus-based physics, chemistry, and the humanities/social sciences, students take a core of fundamental engineering coursework outside of electrical engineering, a core of courses in the breadth of electrical engineering, and electrical engineering elective courses. A bachelor’s degree in electrical engineering (B.S.E.E.) can provide the foundation that a student will need in any of the areas of electrical engineering, including advanced analog and digital electronics, microprocessor applications, biomedical instrumentation, digital computer systems, software systems, electric utility power systems, industrial power systems, digital control, industrial electronics, and machinery control.
Each student must complete a senior design team project that comprises three ( EE 497 Team Design Project) or six ( EE 498 Team Design Project I and EE 499 Team Design Project II) semester hours of coursework.
Back To TopVision
The Vision of the department is to be a nationally recognized Department of Electrical and Computer Engineering: a first choice for undergraduate and graduate education.
Back To TopMission
The Mission of the Department of Electrical and Computer Engineering is to prepare graduates to be immediately productive and able to adapt to a rapidly changing environment while also creating and applying knowledge for the benefit of Birmingham, the state, and beyond.
Back To TopElectrical Engineering Program Objectives
The Electrical Engineering undergraduate program prepares graduates to
- Succeed in a career in electrical engineering or in further education.
- Approach problem solving with an engineering mind set.
- Grow professionally.
Lower Division Requirements For Electrical Engineering
| Requirements | Hours | |
|---|---|---|
| General Chemistry Requirement | ||
| CH 115
& CH 116 | General Chemistry I and General Chemistry I Laboratory | 4 |
| Required Courses | ||
| CE 210 | Statics | 3 |
| EE 312 | Electrical Systems | 3 |
| EGR 110
& EGR 111 | Introduction to Engineering I and Introduction to Engineering II | 2 |
| or EGR 200 | Introduction to Engineering Design | |
| EGR 150 | Computer Methods in Engineering | 3 |
| EGR 265 | Math Tools for Engineering Problem Solving | 4 |
| MA 126 | Calculus II | 4 |
| ME 102 | Engineering Graphics | 2 |
| ME 251 | Introduction to Thermal Sciences | 2 |
| Total Hours | 27 | |
Major Requirements For Electrical Engineering
| Requirements | Hours | |
|---|---|---|
| Required Electrical Engineering Courses | ||
| EE 210 | Digital Logic | 3 |
| EE 233 | Engineering Programming Methods | 3 |
| EE 254 | Applied Numerical Methods | 3 |
| EE 300 | Engineering Problem Solving II | 3 |
| EE 316
& 316L | Electrical Networks and Electrical Networks Laboratory | 4 |
| EE 318 | Methods of System Analysis | 3 |
| EE 333 | Engineering Programming Using Objects | 3 |
| EE 337
& 337L | Introduction to Microprocessors and Introduction to Microprocessors Laboratory | 4 |
| EE 341 | Electromagnetics | 3 |
| EE 351
& 351L | Electronics and Electronics Laboratory | 4 |
| EE 361
& 361L | Machinery I and Machinery I Laboratory | 4 |
| EE 421 | Communication Systems | 3 |
| EE 426 | Control Systems | 3 |
| EE 431 | Analog Integrated Electronics | 4 |
| EE 485 | Engineering Operations | 3 |
| EE 497 | Team Design Project | 3 |
| or EE 499 | Team Design Project II | |
| Electrical Engineering Electives | ||
| Select four courses from the following: | 12 | |
| Wireless Communications | ||
| Digital Signal Processing | ||
| Industrial Control | ||
| Introduction to Computer Networking | ||
| Engineering Software Solutions | ||
| Microprocessor Applications | ||
| Computer Networking Protocols | ||
| Internet/Intranet Application Development | ||
| Software Engineering Projects | ||
| VHDL Digital Systems Design | ||
| Medical Instrumentation | ||
| Machinery II | ||
| Power Systems I | ||
| Power Systems II | ||
| Protective Relaying of Power Systems | ||
| Special Topics in (Area) | ||
| Special Problems in (Area) | ||
| Team Design Project I (Only for students who take EE 499 to fulfill senior design requirement) | ||
| Total Hours | 65 | |
School of Engineering Guidelines for Admission, Academic Progress, and Academic Conduct
Students are required to follow the most up-to-date set of guidelines as detailed in the most current School of Engineering Guidelines for Admission, Academic Progress, and Academic Conduct.
School of Engineering Reasonable Progress Requirement
All students in the School of Engineering must maintain a Institutional GPA of 2.0 in all UAB courses and all UAB Engineering courses applicable to the degree.
School of Engineering Graduation Requirements
Students must have a 2.0 GPA in all UAB coursework and all UAB engineering coursework applicable to degree in order to graduate with a degree from the School of Engineering. All required courses failed at UAB must be repeated at UAB in order for a student to receive credit.
Department of Electrical and Computer Engineering Residency Requirement
Students are required to take the following at UAB:
| Requirements | Hours | |
|---|---|---|
| EE 421 | Communication Systems | 3 |
| EE 426 | Control Systems | 3 |
| EE 431 | Analog Integrated Electronics | 4 |
| EE 497 | Team Design Project | 3 |
| or EE 499 | Team Design Project II | |
| Twelve hours of EE 400-level electives | 12 | |
| Total Hours | 25 | |
Curriculum for the Bachelor of Science in Electrical Engineering (B.S.E.E.)
| Freshman | |||
|---|---|---|---|
| First Term | Hours | Second Term | Hours |
| CH 115
& CH 116 | 4 | EE 210 | 3 |
| EH 101 | 3 | EGR 1111 | 1 |
| EGR 1101 | 1 | EH 102 | 3 |
| MA 125 | 4 | MA 126 | 4 |
| ME 102 | 2 | PH 221
& 221L | 4 |
| EGR 150 | 3 | ||
| 14 | 18 | ||
| Sophomore | |||
| First Term | Hours | Second Term | Hours |
| EE 312 | 3 | EE 233 | 3 |
| EGR 2652 | 4 | EE 316
& 316L | 4 |
| CE 210 | 3 | EE 300 | 3 |
| PH 222
& 222L | 4 | ME 251 | 2 |
| Core Curriculum Area II or IV3 | 3 | Core Curriculum Area II or IV3 | 3 |
| 17 | 15 | ||
| Junior | |||
| First Term | Hours | Second Term | Hours |
| EE 318 | 3 | EE 2542 | 3 |
| EE 333 | 3 | EE 337
& 337L | 4 |
| EE 351
& 351L | 4 | EE 361
& 361L | 4 |
| EE 485 | 3 | EE 341 | 3 |
| Core Curriculum Area II or IV3 | 3 | Core Curriculum Area II or IV3 | 3 |
| 16 | 17 | ||
| Senior | |||
| First Term | Hours | Second Term | Hours |
| EE 426 | 3 | EE 421 | 3 |
| Electrical Engineering Elective (400 level)4 | 9 | EE 431 | 4 |
| Core Curriculum Area II or IV3 | 3 | EE 497 or 499 | 3 |
| Electrical Engineering Elective (400 level)4 | 3 | ||
| Core Curriculum Area II or IV3 | 3 | ||
| 15 | 16 | ||
| Total credit hours: 128 | |||
1
Only first term freshman take EGR 110/ EGR 111. All others take EGR 200 (a 2-hour course).
2Curriculum change in 2008: Students can substitute MA 227 and MA 252 for EGR 265 and EE 254.
3Core Curriculum Area II: Humanities & Fine Art or Area IV: Social & Behavioral Science. Please refer to the Core Curriculum as specified for Engineering majors.
4Must be chosen from the approved list of electives.
Courses
EE 011. Coop/Internship in EE. 0 Hours.
Engineering workplace experience in preparation for the student's intended career.
EE 210. Digital Logic. 3 Hours.
Number systems and codes. Boolean algebra and combinational logic. Arithmetic and logic circuits. Memory elements. Synchronous sequential logic. Lecture and computer laboratory.
Prerequisite: MA 106 [Min Grade: C] Or MA 107 [Min Grade: C] Or MA 125 [Min Grade: C] Or MA 126 [Min Grade: C]
EE 233. Engineering Programming Methods. 3 Hours.
Program design techniques, data structures, coding and documentation standards. File I/O. Product design and life cycles. Testing and software tools. Lecture and computer laboratory.
Prerequisite: ( MA 106 [Min Grade: C] Or MA 107 [Min Grade: C] Or MA 125 [Min Grade: C]) Or ( MA 126 [Min Grade: C], EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C])
EE 254. Applied Numerical Methods. 3 Hours.
Selected mathematical and computational topics appropriate to the numerical solution of engineering problems.
Prerequisite: MA 125 [Min Grade: C], MA 126 [Min Grade: C], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D]), ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C])
EE 300. Engineering Problem Solving II. 3 Hours.
Selected mathematical and computational topics appropriate to the solution of engineering problems, including probability and statistics.
Prerequisite: MA 125 [Min Grade: C], MA 126 [Min Grade: C], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D])
EE 305. Fundamentals of Electrical Engineering. 2 Hours.
Survey of topics fundamental to field of electrical engineering. For non-engineering majors. Not available for credit toward engineering major.
Prerequisite: MA 109 [Min Grade: C]
EE 312. Electrical Systems. 3 Hours.
Introduction to DC circuit analysis, AC steady-state analysis, first-order transient analysis, ideal transformers, and electrical safety.
Prerequisite: MA 125 [Min Grade: C], MA 126 [Min Grade: C], PH 221 [Min Grade: C]
EE 316. Electrical Networks. 4 Hours.
Analysis of circuits using classical differential/integral techniques, Laplace transforms, and two-port network parameters. Circuit solution using simulation. EE 316L must be taken concurrently. Quantitative Literacy is a significant component of this course (QEP).
Prerequisite: EH 101 [Min Grade: C], PH 222 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), MA 125 [Min Grade: C], MA 126 [Min Grade: C], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D])
EE 316L. Electrical Networks Laboratory. 0 Hours.
Electrical Networks laboratory component. EE 316 must be taken concurrently.
EE 318. Methods of System Analysis. 3 Hours.
Time-domain and frequency-domain methods for modeling and analyzing continuous and discrete-time signals and systems. Fourier, Laplace, and Z transform methods.
Prerequisite: EE 300 [Min Grade: D], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D]), ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 333. Engineering Programming Using Objects. 3 Hours.
Software development emphasizing object-oriented methods. Students design and develop programs using existing classes and create their own classes. Graphical user interface framework will be used as an extensive example of an object-oriented system. Lecture and computer laboratory.
Prerequisite: EE 233 [Min Grade: D]
EE 337. Introduction to Microprocessors. 4 Hours.
Application of microcomputers to engineering problems such as data acquisition and control. Topics include CPU architecture, assembly language, and input/output interfacing. EE 337L must be taken concurrently.
Prerequisite: EE 210 [Min Grade: C], EE 233 [Min Grade: D]
EE 337L. Introduction to Microprocessors Laboratory. 0 Hours.
Introduction to Microprocessors laboratory component. EE 337 must be taken concurrently.
EE 341. Electromagnetics. 3 Hours.
Mathematical techniques used to solve electromagnetics problems. Fundamental concepts and applications for dynamic and static problems. Electromagnetic wave propagation and transmission. Transmission lines.
Prerequisite: PH 222 [Min Grade: D], EE 300 [Min Grade: D], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D]), ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 351. Electronics. 4 Hours.
Solid-state electronics, bipolar junction and field-effect transistor (FET) properties, biasing, frequency response, single and multistage amplifier circuits. EE 351L must be taken concurrently.
Prerequisite: EE 210 [Min Grade: C], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D]), PH 222 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 351L. Electronics Laboratory. 0 Hours.
Electronics laboratory component. EE 351 must be taken concurrently.
EE 361. Machinery I. 4 Hours.
Fundamentals and applications of polyphase circuits, magnetic circuits, transformers, polyphase synchronous and asynchronous machines. EE 361L must be taken concurrently.
Prerequisite: ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], ( MA 227 [Min Grade: C], MA 252 [Min Grade: D] Or EGR 265 [Min Grade: D]), PH 222 [Min Grade: D]
EE 361L. Machinery I Laboratory. 0 Hours.
Machinery I laboratory component. EE 361 must be taken concurrently.
EE 418. Wireless Communications. 3 Hours.
Wireless communication system topics such as propagation, modulation techniques, multiple access techniques, channel coding, speech and video coding, and wireless computer networks.
Prerequisite: EE 300 [Min Grade: C], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D]
EE 421. Communication Systems. 3 Hours.
Signal and system representation in time and frequency domains. Autocorrelation and spectral density. Amplitude and angle modulation. Sampling. Noise. Lecture and laboratory.
Prerequisite: EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D]
EE 423. Digital Signal Processing. 3 Hours.
Digital filter analysis and design. FFT algorithms. Applications of digital signal processing in engineering problems such as data acquisition and control. Lecture and computer laboratory.
Prerequisite: EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D]
EE 426. Control Systems. 3 Hours.
Theory of linear feedback control systems using complex frequency techniques. Block diagram manipulation, performance measures, and stability. Analysis and design using root locus and frequency response methods. Z-transform methods and z-plane root locus.
Prerequisite: EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D]
EE 427. Industrial Control. 3 Hours.
Power control devices and applications. Relay logic and translation to other forms. Programmable logic controllers. Proportional-integral-derivative and other methods for process control. Modern laboratory instrumentation and man-machine interface software. Lecture and laboratory.
Prerequisite: EE 233 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D], EE 351 [Min Grade: D], ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C])
EE 431. Analog Integrated Electronics. 4 Hours.
Advanced analysis and design using op-amps, with emphasis on error analysis and compensation. Applications include signal conditioning for instrumentation, instrumentation amplifiers, nonlinear and computational circuits, Butterworth and Chebyshev filter design, power amplifier design, voltage regulator design, and oscillators. A-to-D and D-to-A conversion methods. Laboratory exercises emphasize design techniques. Lecture and laboratory.
Prerequisite: EE 210 [Min Grade: C], EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D], EE 351 [Min Grade: D]
EE 432. Introduction to Computer Networking. 3 Hours.
Computer networking and engineering standards related to networking. Networking hardware, software, and protocols including TCP/IP protocol suite. Internetworking, LANS, and typical applications.
Prerequisite: EE 210 [Min Grade: C], ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C] Or EE 134 [Min Grade: C])
EE 433. Engineering Software Solutions. 3 Hours.
Project planning, specification, design, implementation, and testing of software solutions for engineers. Waterfall model of development and agile development methods. Lecture and computer laboratory.
Prerequisite: EE 233 [Min Grade: D], EE 333 [Min Grade: D], ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C] Or EE 134 [Min Grade: C])
EE 437. Microprocessor Applications. 3 Hours.
Applications of microprocessors in engineering problems such as data acquisition, control, and real-time input/output. Lecture and laboratory.
Prerequisite: ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C]), EE 210 [Min Grade: C], EE 233 [Min Grade: D], EE 337 [Min Grade: D]
EE 442. Computer Networking Protocols. 3 Hours.
Hands-on laboratory course covering topics in networking. TCP/IP, routing, LAN configurations, Windows and Linux configurations and protocol analysis. Lecture and computer laboratory.
Prerequisite: EE 210 [Min Grade: C], EE 432 [Min Grade: D], ( EGR 150 [Min Grade: C] Or EE 130 [Min Grade: C] Or ME 130 [Min Grade: C])
EE 444. Real-Time Process & Protocols. 3 Hours.
Hands-on laboratory course covering topics in real-time computer systems such as algorithms, state-machine implementations, communication protocols, instrumentation, hardware interfaces, multitasking, and interrupt handling.
Prerequisite: EE 233 [Min Grade: D], EE 337 [Min Grade: D]
EE 447. Internet/Intranet Application Development. 3 Hours.
Development of models and applications using Internet/Intranet technologies such as Java, JavaScript, Dynamic HTML, server side scripting, multi-tier models, and XML. Lecture and computer laboratory.
Prerequisite: EE 233 [Min Grade: D]
EE 448. Software Engineering Projects. 3 Hours.
Object-oriented concepts and design. Unified Modeling Language and design patterns. Provides a project environment for implementation of systems using object-oriented techniques. Lecture and computer laboratory.
Prerequisite: EE 233 [Min Grade: D], EE 333 [Min Grade: D]
EE 452. VHDL Digital Systems Design. 3 Hours.
Digital system design, verification, and simulation using VHDL. Lecture and laboratory.
Prerequisite: EE 337 [Min Grade: D], EE 210 [Min Grade: C], EE 233 [Min Grade: D]
EE 458. Medical Instrumentation. 3 Hours.
Fundamental operating principles, applications, and design of electronic instrumentation used in measurement of physiological parameters.
Prerequisite: EE 351 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 461. Machinery II. 3 Hours.
Physical principles of DC machines. Mathematical analysis of generator designs using equivalent circuits and magnetization curves. Calculation of motor speed, torque, power, efficiency, and starting requirements. Solid-state speed control systems.
Prerequisite: EE 361 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 471. Power Systems I. 3 Hours.
Components of power systems. Performance of modern interconnected power systems under normal and abnormal conditions. Calculation of inductive and capacitive reactances of three-phase transmission lines in steady state.
Prerequisite: EE 361 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C]
EE 472. Power Systems II. 3 Hours.
Modeling of generators, transformers, and transmission lines for system studies. Introduction to symmetrical components. Calculation of short-circuit currents due to balanced and unbalanced faults. Determination of interrupting ratings of circuit breakers. Transient stability of power systems. Derivation of swing equation and solution by numerical method. Equal area criterion.
Prerequisite: EE 471 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 361 [Min Grade: D]
EE 473. Protective Relaying of Power Systems. 3 Hours.
Operating principles of protective relays. Protection of transmission lines, generators, motors, transformers, and buses.
Prerequisite: ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 361 [Min Grade: D]
EE 485. Engineering Operations. 3 Hours.
Economic, procedural, planning, and control aspects of engineering projects. Ethics and Civic Responsibility are significant components of this course (QEP).
EE 489. Undergraduate Engineering Research. 0 Hours.
Undergraduate research experiences in electrical engineering.
Prerequisite: ( EGR 110 [Min Grade: C], EGR 111 [Min Grade: C] Or EGR 200 [Min Grade: C]), MA 125 [Min Grade: C], PH 221 [Min Grade: C]
EE 490. Special Topics in (Area). 3 Hours.
Topic assigned with course.
EE 491. Special Problems in (Area). 3 Hours.
Topic assigned with course.
EE 492. Honors Research I. 4 Hours.
Departmental honors students work closely with faculty to develop research skills.
Prerequisite: EGR 301 [Min Grade: P]
EE 493. Honors Research II. 4 Hours.
Departmental honors students work closely with faculty to develop research skills.
Prerequisite: EGR 301 [Min Grade: P]
EE 497. Team Design Project. 3 Hours.
Senior Design Team Project Course. Analysis, design, and implementation of assigned team project, including design review, demonstration, and documentation. Must have an approved Application for Degree on file and must be in final year of his/her program.
Prerequisite: EE 485 [Min Grade: D], EE 210 [Min Grade: C], EE 233 [Min Grade: D], EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D], EE 337 [Min Grade: D], EE 351 [Min Grade: D], EE 333 [Min Grade: D], EE 341 [Min Grade: D], EE 361 [Min Grade: D], EE 421 [Min Grade: D], EE 426 [Min Grade: D], EE 431 [Min Grade: D]
EE 498. Team Design Project I. 3 Hours.
Senior Design Team Project Course Part I. Analysis and design of assigned team project, including design review and documentation. Must have an approved Application for Degree on file and must be in final year of his/her program.
Prerequisite: EE 210 [Min Grade: C], EE 233 [Min Grade: D], EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D], EE 337 [Min Grade: D], EE 485 [Min Grade: D], EE 351 [Min Grade: D]
EE 499. Team Design Project II. 3 Hours.
Senior Design Project Course Part II. Design and implementation of assigned team project, including design review, demonstration, and documentation. Must have an approved Application for Degree on file and must be in final year of his/her program.
Prerequisite: EE 210 [Min Grade: C], EE 233 [Min Grade: D], EE 300 [Min Grade: D], ( EE 312 [Min Grade: C] Or EE 314 [Min Grade: C]), EE 316 [Min Grade: C], EE 318 [Min Grade: D], EE 337 [Min Grade: D], EE 485 [Min Grade: D], EE 351 [Min Grade: D], EE 498 [Min Grade: D], EE 333 [Min Grade: D], EE 341 [Min Grade: D], EE 361 [Min Grade: D], EE 421 [Min Grade: D], EE 426 [Min Grade: D], EE 431 [Min Grade: D]
Faculty
Callahan, Dale, Associate Professor of Electrical and Computer Engineering; Director, Information Engineering and Management, 2000, B.E.E. (Auburn), M.B.A. (Auburn-Montgomery), M.S.E.E. (UAB), Ph.D. (Alabama), P.E. (Alabama)Conner, David A., Professor and Chair Emeritus of Electrical and Computer Engineering, 1978, B.E.E., (Auburn), Ph.D. (Georgia Institute of Technology), P.E. (Alabama, Georgia, Tennessee, Kentucky)
Franklin, Gregory A., Assistant Professor of Electrical and Computer Engineering, 2007, B.S.E.E., M.S.E.E., Ph.D. (UAB), P.E. (Alabama)
Green, David G., Instructional Associate Professor of Electrical and Computer Engineering, 1981, B.S.E., M.S.E (UAH)
Haider, Mohammad, Assistant Professor of Electrical and Computer Engineering, 2011, Ph.D. (Tennessee-Knoxville)
Jannett, Thomas C., Professor of Electrical and Computer Engineering, 1984, B.S.E., M.S.E. (UAB), Ph.D. (Auburn)
Lingasubramanian, Karthikeyan, Assistant Professor of Electrical and Computer Engineering, 2011, Ph.D. (South Florida)
Lokey, Larry H., Instructor of Electrical and Computer Engineering, 2009, B.S.E., M.S.E.E. (UAB)
Marstrander, Jon, Instructor of Electrical and Computer Engineering, 2005, B.S.E.E., M.S.E.E. (UAB), P.E. (Alabama)
Massoud, Yehia, Professor of Electrical and Computer Engineering; Chair, Department of Electrical and Computer Engineering, 2011, Ph.D. (MIT)
Nelson, Dalton S., Assistant Professor of Electrical and Computer Engineering, 1994, B.S.E.E., M.S.E.E., (UAB), Ph.D. (UAH), P.E. (Alabama)
Tanik, Murat M., Professor of Electrical and Computer Engineering, 1998, B.S. (Middle East Technical), M.C.S., Ph.D. (Texas A&M)
Tannenbaum, Allen R., Professor of Electrical and Computer Engineering, 2012, B.A. (Columbia), Ph.D. (Harvard)
Vaughn, Gregg L., Professor of Electrical and Computer Engineering, 1979, B.S.E.E., M.S.E.E, Ph.D. (Alabama), P.E. (Alabama)
