Graduate Program in Telecommunications Engineering

http://www.te.utdallas.edu/

 

Faculty

Professors: Naofal M. Al-Dhahir, Farokh B. Bastani, Cyrus D. Cantrell III, Andras Farago, Andrea F. Fumagalli, Philipos C. Loizou, Duncan MacFarlane, Aria Nosratinia, William J. Pervin, Balaji Raghavachari, Lakshman S Tamil, I-Ling Yen, Si Q. Zheng

Associate Professors: Jorge A. Cobb, Jason P. Jue, Latifur R. Khan, Hlaing Minn, Won Namgoong, Balakrishnan Prabhakaran, Ravi Prakash, Mohammad Saquib, Murat Torlak, Subbarayan Venkatesan, Yuke Wang, W. Eric Wong

Assistant Professors: Neeraj Mittal, Kamil Sarac

Senior Lecturers: C. P. Bernardin, Nathan Dodge, Muhammad Kalam, P. K. Rajasekaran, Marco Tacca

Objectives

The Graduate Program in Telecommunications Engineering provides intensive preparation for professional practice in the design, programming, theory, and applications of telecommunications networks. It is designed to serve the needs of engineers who wish to continue their education. The Telecommunications Engineering Program offers courses of study leading to the M. S. and a Ph.D. degree in Telecommunications Engineering. Education and training is provided to both academically oriented students and students with professional goals in industrial or governmental occupations requiring advanced knowledge of telecommunications and related technology. A comprehensive program of evening courses is also offered, which enables part-time students to earn the M.S. and Ph.D. degree or to select individual courses of interest. Courses and research are both offered in a variety of sub fields of telecommunications engineering, including, fault-tolerant networks, digital communications, modulation and coding, electromagnetic-wave propagation, fiber and integrated optics, lasers, wireless communications, mobile computing, wireless multimedia, DWDM networks, QoS assurance protocols, network design and optimization, telecommunications software, performance of systems, ad-hoc and PCS wireless networks, network security and high speed transmission protocols.

Facilities

The Erik Jonsson School of Engineering and Computer Science has developed a state-of-the-art computational facility consisting of a network of Sun servers and Sun Engineering Workstations. All systems are connected via an extensive fiber-optic Ethernet and, through the Texas Higher Education Network, have direct access to most major national and international networks. In addition, many personal computers are available for student use.

The Engineering and Computer Science Buildings provide extensive facilities for research in telecommunications, microelectronics, and computer science. The TARGET Laboratory has state-of-the-art telecommunications equipment, which includes a number of transport nodes, data packet routers, voice over IP gears, and a cluster of Linux workstations for protocols development and testing. The Wireless Information Systems (WISLAB) and Antenna Measurement Laboratories at UT Dallas have a wealth of experimental equipment with a unique reconfigurable multiple antenna testbed. Having this testbed allows wireless researchers to integrate and to demonstrate radio functions (i.e. WiFi and WiMAX) in geographically different regions under different frequency usage characteristics. With the aid of the Antenna Measurement Lab located in the Waterview Science and Technology Center (WSTC), the researchers can design, build, and test many type of antennas. The Optical Communications Laboratory includes attenuators, optical power meters, lasers, APD/p-i-n photodetectors, optical tables, and couplers and is available to support system level research in optical communications.

The Center for Systems, Communications, and Signal Processing, with the purpose of promoting research and education in general communications, signal processing, control systems, medical and biological systems, circuits and systems and related software, is located in the Erik Jonsson School. The Photonic Technology and Engineering Center (PhoTEC) has produced more than thirty Ph.D. graduates. The PhoTEC faculty carry out research in enabling technologies for microelectronics and telecommunications.

The Digital Systems Laboratory includes a network of workstations, personal computers, FPGA development systems, and a wide spectrum of state-of-the-art commercial and academic design tools to support graduate research in VLSI design and computer architecture. In the Digital Signal Processing Laboratory several multi-CPU workstations are available in a network configuration for simulation experiments. Hardware development facilities for real time experimental systems are available and include microphone arrays, active noise controllers, speech compressors and echo cancellers. The Nonlinear Optics Laboratory has a dedicated network of Sun workstations for the development of simulation methods and software for optical transmission and communication systems, optical routers and all-optical networks. The Broadband Communication Laboratory has design and modeling tools for fiber and wireless transmission systems and networks, and all-optical packet routing and switching. The Advanced Communications Technologies (ACT) Laboratory provides a design and evaluation environment for the study of telecommunication systems and wireless and optical networks. ACT has facilities for designing network hardware, software, components, and applications.

In addition to the aforementioned facilities, a Class 1000 microelectronics clean room facility, including optical lithography, sputter deposition and evaporation, is available for student projects and research. An electron beam lithography pattern generator capable of sub-micron resolution is also available for microelectronics research. The Plasma Applications Laboratory has state-of-the-art facilities for mass spectrometry, microwave interferometry, optical spectroscopy, and optical detection. In addition, a Gaseous Electronics Conference Reference Reactor has been installed for plasma processing and particulate generation studies. The Optical Measurements Laboratory has dual wavelength (visible and near infrared) Gaertner Ellipsometer for optical inspection of material systems, a variety of interferometric configurations, high precision positioning devices, and supporting optical and electrical components. The Electronic Materials Processing laboratory has extensive facilities for fabricating and characterizing semiconductor and optical devices. The Laser Electronics Laboratory houses graduate research projects centered on the characterization, development and application of ultrafast dye and diode lasers. Research in characterization and fabrication of nanoscale materials and devices is performed in the Nanoelectronics Laboratory.

In addition to the facilities on campus, cooperative arrangements have been established with many local industries to make their facilities available to U.T. Dallas graduate engineering students.

Master of Science in Telecommunications Engineering

Admission Requirements

The Universityís general admission requirements are discussed here.

A student lacking undergraduate prerequisites for graduate courses in electrical engineering must complete these prerequisites or receive approval from the graduate adviser and the course instructor. A diagnostic examination may be required. Specific admission requirements follow.

A student entering the M.S.T.E. program should meet the following guidelines:

         An undergraduate preparation equivalent to a baccalaureate in electrical engineering from an accredited engineering program,

Applicants must submit three letters of recommendation from individuals who are able to judge the candidateís probability of success in pursuing a program of study leading to the masterís degree.

Applicants must also submit an essay outlining the candidateís background, education and professional goals.

Students from other engineering disciplines or from other areas of science or mathematics may be considered for admission to the program; however, some additional course work may be necessary before starting the masterís program.

Degree Requirements

The Universityís general degree requirements are discussed here.

The M.S.T.E. degree requires a minimum of 33 semester hours.

All students must have an academic adviser and an approved degree plan. Courses taken without adviser approval will not count toward the 33 semester-hour requirement. Successful completion of the approved course of studies leads to the M.S.T.E. degree.

The M.S.T.E. program has both a thesis and a non-thesis option. All part-time M.S.T.E. students will be assigned initially to the non-thesis option. Those wishing to elect the thesis option may do so by obtaining the approval of a faculty thesis supervisor.

All full-time, supported students are required to participate in the thesis option. The thesis option requires six semester hours of research, a written thesis submitted to the graduate school, and a formal public defense of the thesis. Research and thesis hours cannot be counted in a M.S.T.E. degree plan unless a thesis is written and successfully defended. A supervising committee, which must be chosen in consultation with the studentís thesis adviser prior to enrolling for thesis credit, administers the defense. Full-time students at UTD who receive financial assistance are required to enroll in 9 semester credit hours during the Fall, Spring and Summer semesters. Students enrolled in the thesis option should meet with individual faculty members to discuss research opportunities and to choose a research advisor during the first or second semester that the student is enrolled. After the second semester of study, course selection should be made in consultation with the research adviser. Part-time students are encouraged to enroll in only one course during their first semester and in no more than two courses during any semester they are also working full-time.

To receive a Master of Science degree in Telecommunications Engineering, a student must meet the following minimum set of requirements:

Completion of a minimum of 33 semester hours of graduate level lecture courses including the required core courses. With adviser approval, these may include some 5000 level courses.

Students must take the following five core courses and make a grade of B or better:


CS/TE 6385 Algorithmic Aspects of Telecommunication Networks
EE 6349 Random Processes
EE 6352 Digital Communication Systems
CS 6352 Performance of Computer Systems
CS 6390 Advanced Computer Networks

Students will take additional courses from those described in the following pages.

Recommended Elective Courses: Choose any 18 hours of 6000 level courses or higher with approval of the adviser.

RECOMMENDED ELECTRICAL ENGINEERING ELECTIVES:

EE 6310 Optical Communication Systems
EE 6316 Fields and Waves
EE 6340 Introduction to Telecommunications Networks
EE 6341 Information Theory I
EE 6343 Detection and Estimation theory
EE 6344 Coding Theory
EE 6345 Engineering of Packet-Switched Networks
EE 6355 RF and Microwave Communications Circuits
EE 6360 Digital Signal Processing I
EE 6361 Digital Signal Processing II
EE 6362 Speech Signal Processing
EE 6365 Adaptive Signal Processing
EE 6390 Introduction to Wireless Communications Systems
EE 6391 Signal and Coding for Wireless Communication Systems
EE 6392 Propagation and Devices for Wireless Communication
EE 6394 Antenna Engineering for Wireless Communications
EE 6395 Advanced Radio Frequency Engineering
EE 7340 Optical Network Architectures and Protocols

RECOMMENDED COMPUTER SCIENCE ELECTIVES:

CS 6354 Software Engineering
CS 6360 Database Design
CS 6363 Design and Analysis of Computer Algorithms
CS 6368 Telecommunication Network Management
CS 6378 Advanced Operating Systems
CS 6381 Combinatorics and Graph Algorithms
CS 6386 Telecommunication Software Design
CS 6392 Mobile Computing Systems
CS 6394 Digital Telephony
CS 6396 Real Time Systems

Doctor of Philosophy in Telecommunications Engineering

Each doctoral degree program is tailored to the student. The student must arrange a course program with the guidance and approval of a faculty member chosen as his/her graduate adviser. Adjustments can be made as the studentís interests develop and a specific dissertation topic is chosen.

Admission Requirements

The Universityís general admission requirements are discussed here.

The Ph.D. degree in Telecommunications engineering is awarded primarily to acknowledge the student success in an original research project, the description of which is a significant contribution to the literature of the discipline. Applications for the doctoral program are therefore selected by the Telecommunications Engineering Graduate Committee on the basis of research aptitude, as well as academic record. Applications for the doctoral program are considered on the individual basis.

The following are guidelines for admission to the Ph.D. program in Telecommunications Engineering.

A masterís degree in Telecommunications Engineering, or Electrical Engineering or Computer Science or a closely associated discipline from an accredited U.S institution or from an acceptable foreign university. Consideration will be given to highly qualified students wishing to pursue the doctorate without satisfying all of the requirements for a masterís degree.

         A grade point average in graduate course work of 3.5 or better or a better on a 4-point scale

                                 Scores on the GRE examination of 500 and 700 for the verbal and quantitative sections, respectively, or 1200 for the total score.

                                 Applicants must submit three letters of recommendation on official school or business letterhead or the UTD Letter of Recommendation form from individuals who are familiar with the student record and able to judge the candidateís probability of success in purchasing doctoral study in electrical engineering.

Applicants must also submit a narrative describing their motivation for doctoral study in telecommunications engineering.

Applicants must also submit a narrative describing their motivation for doctoral study and how it relates to their professional goals.

For students who are interested in a Ph.D., but are unable to attend school full-time, there is a part-time option. The guidelines for admission to the program and the degree requirements are the same as for full-time Ph.D., students. All students must have an academic adviser and an approved plan of study.

Degree Requirements

The Universityís general degree requirements are discussed here.

The Ph.D. requires a minimum of 75 semester hours.

Each program for doctoral study is individually tailored to the studentís background and research objectives by the studentís supervisory committee. The program will require a minimum of 90 semester credit hours beyond the bachelorís degree. These credits must include:

1. Course Work

At least 30 semester hours of graduate level courses beyond the bachelorís level in the major concentration. Students choose 30 hours from the following courses with the approval of the TE Graduate Committee.

Core Courses (choose any 5 of the following)

CS/TE 6385 Algorithmic Aspects of Telecommunication Networks
EE 6349 Random Processes
EE 6352 Digital Communication Systems
CS 6352 Performance of Computer Systems
CS 6390 Advanced Computer Networks
CS 6354 Software Engineering
EE 6390 Wireless Communication Systems
EE/CE 6304 Computer Architecture
EE/TE 7V81 Network Security

Recommended Electrical Engineering Electives

EE 6310 Optical Communication Systems
EE 6316 Fields and Waves
EE 6340 Introduction to Telecommunications Networks
EE 6341 Information Theory
EE 6343 Detection and Estimation theory
EE 6344 Coding Theory
EE 6345 Engineering of Packet Switched Networks
EE 6355 RF and microwave communication circuits
EE 6360 Digital Signal Processing I
EE 6361 Digital Signal Processing II
EE 6365 Adaptive Signal Processing
EE 6390 Introduction to Wireless Communication Systems
EE 6391 Signal and Coding for Wireless Communication Systems
EE 6392 Propagation and Devices for Wireless Communication
EE 6394 Antenna Engineering for Wireless Communication
EE 6395 Advanced Radio Frequency Engineering
EE 7340 Optical Network Architecture and Protocols
TE/EE 7V81 Network Security

Recommended Computer Science Electives

CS 6354 Software Engineering
CS 6360 Database Design
CS 6363 Design and Analysis of Algorithms
CS 6368 Telecommunication Network Management
CS 6378 Advanced Operating Systems
CS 6381 Combinatorics and Graph Algorithms
CS 6386 Telecommunications Software Design
CS 6392 Mobile Computing Systems
CS 6394 Digital Telephony
CS 6396 Real time Systems
CS 6390 Advance Computer Networks
CS 8302 Personal Communication Systems

2. Supervising Committee

At least 4 members, with at least 3 from the Erik Jonsson school faculty.

3. Qualifying Examination

The student must pass a qualifying exam approved by the TE graduate committee.

4. Dissertation

Completion of a major research project culminating in a dissertation demonstrating an original contribution to a scientific knowledge and engineering practice. The dissertation will be defended publicly. The rules for this defense are specified by the Office of the Dean of Graduate Studies.

Neither a foreign language nor a minor is required for Ph.D. However, the studentís supervisory committee may impose these or other requirements that it feels are necessary and appropriate to the studentís degree program.

Areas of Research

The principal concentration areas for the Telecommunications Engineering graduate program are:

ē†††††††††† Core and wireless networks

ē†††††††††† Communications and signal processing

ē†††††††††† Network design and protocols

ē†††††††††† Embedded and reconfigurable systems

ē†††††††††† Optical and photonic devices, materials and systems

ē†††††††††† Fault-tolerant data networks

Doctoral level research opportunities include: VLSI design, reconfigurable systems, system architecture, fault-tolerant computing, digital signal processing, digital communications, modulation and coding, electromagnetic-wave propagation, fiber and integrated optics, lasers and optoelectronic devices, optical transmission systems, optical networks, wireless communications, mobile IP, wireless multimedia, DWDM networks, QoS assurance protocols, network design and optimization, ad-hoc and PCS wireless networks, network security and high speed transmission protocols.

Interdisciplinary Opportunities

In keeping with the established tradition of research at UT-Dallas, the Telecommunications Engineering Program encourages students to interact with researchers in other strong programs, including computer science, electrical engineering, computer engineering, and business management.