UT Dallas 2022 Graduate Catalog

Erik Jonsson School of Engineering and Computer Science

Department of Mechanical Engineering

Objectives

The program leading to the Master of Science in Mechanical Engineering prepares both recent baccalaureate graduates and experienced mechanical engineers for the design and development of advanced mechanical and thermal systems at nano-, micro-, meso- and macro-scales. Designed to accommodate the needs of working engineers who wish to continue their education, the program offers courses at times convenient for students employed on a full-time basis grad student.

The MS program in Mechanical Engineering (ME) provides advanced studies for both recent baccalaureate graduates and experienced engineers in the following concentration areas: dynamic systems and control, manufacturing and design innovation, mechanics and materials, and thermal and fluid sciences.

The program is designed to provide advanced skills in mechanical engineering. The program also provides the foundation for a PhD degree in mechanical engineering or closely related disciplines.

The PhD program in Mechanical Engineering prepares talented doctoral students for careers in which they will create new technologies and processes for the design, manufacture, control and operation of components and systems in such fields as energy, health care, security, defense, and transportation.

Given the key enabling role of mechanical engineering in all areas of technology, the graduates of this program will have the preparation to become technical leaders in emerging and existing scientific and industrial fields in Texas, the nation, and the rest of the world.

Facilities

The Engineering and Computer Science Building, Bioengineering Science Building, and the Natural Science and Engineering Research Laboratory provide extensive facilities for teaching and research. These include wind tunnels, materials test systems, nanoindenter, high impact facilities, ultra-high speed camera, DMA, XPS, FTIR, NMR, TGA, DSC, XRD, µ-Raman, Fluorescence Spectrometer, con-focal microscopes, AFM, FIB/SEM, and atomic resolution TEM. A Class 10000 microelectronics clean room facility, including e-beam lithography, sputter deposition, PECVD, LPCVD, etch, and evaporation, is available for student projects and research.

Concentration Areas

There are four technical areas of concentration for the graduate degree programs in Mechanical Engineering. They are:

  • Dynamic Systems and Control (DSC)
  • Manufacturing and Design Innovation (MDI)
  • Mechanics and Materials (MM)
  • Thermal and Fluid Sciences (TFS)

All graduate students must select a concentration area within the first two semesters in the program.

Scholarship Opportunities

The Erik Jonsson School of Engineering and Computer Science offers competitive scholarships for highly qualified students. Interested students should request application materials by contacting the Department of Mechanical Engineering (ME).

 

Master of Science in Mechanical Engineering

33 semester credit hours minimum

Department Faculty

Professors: Fatemeh Hassanipour, Stefano Leonardi, Yaoyu Li, Hongbing Lu, Dong Qian, Mario A. Rotea, Joshua Summers, Seung M. You

Associate Professors: William Anderson, D. Todd Griffith, Giacomo (Valerio) Iungo, Golden Kumar, Arif Malik, Kristin Miller, Majid Minary, Zhenpeng Qin, Tyler Summers, Yonas Tadesse, Jie Zhang

Assistant Professors: Rodrigo Bernal Montoya, Shuang (Cynthia) Cui, Xianming Dai, Yaqing Jin, Justin Koeln, Wei Li, Hui Ouyang, Justin Ruths, Ill Ryu, Guoping Xiong, Kianoosh Yousefi, Armin Zare, Yue Zhou

Associate Professors of Instruction: Wooram Park, Oziel Rios, P.L. Stephan Thamban

Professor of Practice: Dani Fadda

Associate Professor of Practice: Robert Hart

UT Dallas Affiliated Faculty: Kyeongjae (KJ) Cho, Babak Fahimi, Matthew J. Goeckner, Jiyoung Kim, Moon J. Kim, Jeong-Bong Lee, S.O. Reza Moheimani, Mehrdad Nourani, Mark W. Spong, Robert M. Wallace, Steve Yurkovich

Admission Requirements

The University's general admission requirements are discussed on the Graduate Admission page.

The student entering the MS ME program should meet the following guidelines:

  • A bachelor's degree in engineering or one of the natural sciences from an institution of higher education in the U.S. or from a comparable institution abroad,
  • A grade point average (GPA) in upper-division quantitative coursework of 3.0 or better on a 4.0 point scale, and
  • GRE scores of 150, 160, and 4 for the verbal, quantitative, and analytical writing components, respectively, are advisable based on our experience with student success in the program.
  • Three letters of recommendation from individuals who are able to judge the candidate's potential for success in the master's degree program.
  • An essay outlining the candidate's background, education, and professional goals.
  • A detailed resume of all education and work history.

Students from other engineering disciplines or from other areas of science or mathematics may be considered for admission to the program; however, additional coursework may be necessary to complete the master's program.

A student lacking undergraduate prerequisites for graduate courses in mechanical engineering must complete these prerequisites or receive approval from the faculty advisor and the course instructor.

Degree Requirements

The University's general degree requirements are discussed on the Graduate Policies and Procedures page.

The MS degree in Mechanical Engineering requires a minimum of 33 semester credit hours of graduate level coursework.  A student must maintain a grade point average (GPA) of at least 3.0 to remain in good standing and satisfy the degree requirements.

All students must have a faculty advisor and an approved plan of study within the first two consecutive long semesters in the program. The plan of study is based upon the student's choice of concentration area.

Courses taken without advisor's approval will not be counted towards the 33 semester credit hour requirement. Successful completion of an approved plan of study leads to the MS ME degree.

The MS ME program has both a thesis and a non-thesis option. All 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.

Non-Thesis Degree Requirements

Required Major Courses: 12 semester credit hours

A MS student in ME must take a total of four core courses, selected from two or more concentration areas from the list of the four concentration areas below, and must receive a grade of B- or better in the four core courses. A student must maintain a grade point average (GPA) of at least 3.0 to remain in good standing and satisfy the degree requirements.

Dynamic Systems and Control

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6309 Intermediate Dynamics

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

Manufacturing and Design Innovation

MECH 6303 Computer Aided Design

MECH 6318 Engineering Optimization

MECH 6333 Materials Design and Manufacturing

Mechanics and Materials

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

Thermal and Fluid Sciences

MECH 6370 Incompressible Fluid Mechanics

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

Prescribed Electives within Concentration Areas: 9 semester credit hours

The following is a list of prescribed elective courses. Students must take at least three prescribed graduate-level elective courses from one concentration area. Courses counted towards satisfying requirements on Required Major Courses cannot be counted towards satisfying requirements on Prescribed Electives. All electives must be approved by faculty advisor.

Note: the presence of a course number in parentheses indicates that this course is cross-listed in another department.

Dynamic Systems and Controls (DSC)

MS students must take at least 3 courses from one concentration area.

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6308 Haptics and Teleoperated Systems

MECH 6309 Intermediate Dynamics

MECH 6311 Advanced Mechanical Vibrations

MECH 6312 (EESC 6349) Probability, Random Variables, and Statistics

MECH 6313 (EECS 6336 or BMEN 6388 or SYSE 6324) Nonlinear Systems

MECH 6314 (SYSM 6306 or BMEN 6372) Engineering Systems: Modeling and Simulation

MECH 6316 (SYSE 6322) Digital Control of Automotive Powertrain Systems

MECH 6317 (EECS 6302 or SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6323 (SYSE 6323 or EECS 6323) Robust Control Systems

MECH 6324 (BMEN 6324 or EECS 6324) Robot Control

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

MECH 6327 Convex Optimization in Systems and Controls

MECH 6328 Frequency-Domain Analysis and Design of Control Systems

MECH 6V29 Special Topics in Dynamic Systems and Control

Manufacturing and Design Innovation (MDI)

MS students must take at least 3 courses from one concentration area.

MECH 6303 Computer Aided Design

MECH 6311 Advanced Mechanical Vibrations

MECH 6314 (BMEN 6372 or SYSM 6306) Engineering Systems: Modeling and Simulation

MECH 6317 (EECS 6302 or SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6330 Multiscale Design and Optimization

MECH 6333 Materials Design and Manufacturing

MECH 6334 Smart Materials and Structures

MECH 6335 (OPRE 6340) Flexible Manufacturing Strategies

MECH 6337 (SYSM 6301) Systems Engineering, Architecture and Design

MECH 6338 Reliability-Based Design

MECH 6339 Multidisciplinary Design Optimization

MECH 6341 (EEMF 6348 or MSEN 6348) Lithography and Nanofabrication

MECH 6342 Renewable Energy and Grid Integration

MECH 6347 (EEMF 6382 or MSEN 6382) Introduction to MEMS

MECH 6348 (EEMF 6322 or MSEN 6322) Semiconductor Processing Technology

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6V49 Special Topics in Manufacturing and Design Innovation

Mechanics and Materials (MM)

MS students must take at least 3 courses from one concentration area.

MECH 5300 (MSEN 5300 or PHYS 5376) Introduction to Materials Science

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6355 Viscoelasticity

MECH 6356 Fracture Mechanics

MECH 6357 (MSEN 6380) Phase Transformations and Kinetic Processes in Materials

MECH 6358 (MSEN 6381) Advanced Ceramic Materials

MECH 6359 (MSEN 6383) Modern Physical Metallurgy

MECH 6367 (MSEN 6310) Mechanical Properties of Materials

MECH 6368 Imperfections in Crystalline Solids

MECH 6V69 Special Topics in Mechanics and Materials

Thermal and Fluid Sciences (TFS)

MS students must take at least 3 courses from one concentration area.

MECH 5370 Wind Energy Fluid Mechanics

MECH 5371 Extreme Applications in Fluid Mechanics

MECH 5373 Thermal Management of Microelectronics

MECH 6370 Incompressible Fluid Mechanics

MECH 6371 Computational Thermal Fluid Science

MECH 6372 Turbulent Flows

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

MECH 6375 Phase Change Heat Transfer

MECH 6376 Experimental Thermal and Fluid Dynamics

MECH 6377 Advanced Thermodynamics

MECH 6378 Introduction to Compressible Fluid Mechanics

MECH 6383 (EEMF 6383 or PHYS 6383) Plasma Science

MECH 6V89 Special Topics in Thermal and Fluid Sciences

Students participating in the non-thesis option must also take four graduate level electives. These courses can be selected from 5000-level and above offered by the Erik Jonsson School of Engineering and Computer Science. Students in the non-thesis option may apply up to three semester credit hours of research as a graduate elective.

Students can satisfy six semester credit hours of graduate level electives through the completion of a graduate capstone project. The graduate capstone project will consist of solving a mechanical engineering design problem sponsored by industry.

Graduate Capstone Project Design (6 semester credit hours)

All electives must be approved by the faculty advisor.

Thesis Degree Requirements

Required Major Courses: 9 semester credit hours

A MS-Thesis student in ME must take a total of three core courses, selected from two or more concentration areas from the list of the four concentration areas below, and must receive a grade of B- or better in the three core courses. A student must maintain a grade point average (GPA) of at least 3.0 to remain in good standing and satisfy the degree requirements.

Dynamic Systems and Control

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6309 Intermediate Dynamics

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

Manufacturing and Design Innovation

MECH 6303 Computer Aided Design

MECH 6318 Engineering Optimization

MECH 6333 Materials Design and Manufacturing

Mechanics and Materials

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

Thermal and Fluid Sciences

MECH 6370 Incompressible Fluid Mechanics

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

Prescribed Electives within Concentration Areas: 6 semester credit hours

The following is a list of prescribed elective courses. Students must take at least two prescribed graduate-level elective courses from one concentration area. Courses counted towards satisfying requirements on Required Major Courses cannot be counted towards satisfying requirements on Prescribed Electives. All electives must be approved by faculty advisor.

Note: the presence of a course number in parentheses indicates that this course is cross-listed in another department.

Dynamic Systems and Controls (DSC)

MS students must take at least 2 courses from one concentration area.

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6308 Haptics and Teleoperated Systems

MECH 6309 Intermediate Dynamics

MECH 6311 Advanced Mechanical Vibrations

MECH 6312 (EESC 6349) Probability, Random Variables, and Statistics

MECH 6313 (EECS 6336 or BMEN 6388 or SYSE 6324) Nonlinear Systems

MECH 6314 (SYSM 6306 or BMEN 6372) Engineering Systems: Modeling and Simulation

MECH 6316 (SYSE 6322) Digital Control of Automotive Powertrain Systems

MECH 6317 (EECS 6302 or SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6323 (SYSE 6323 or EECS 6323) Robust Control Systems

MECH 6324 (BMEN 6324 or EECS 6324) Robot Control

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

MECH 6327 Convex Optimization in Systems and Controls

MECH 6328 Frequency-Domain Analysis and Design of Control Systems

MECH 6V29 Special Topics in Dynamic Systems and Control

Manufacturing and Design Innovation (MDI)

MS students must take at least 2 courses from one concentration area.

MECH 6303 Computer Aided Design

MECH 6311 Advanced Mechanical Vibrations

MECH 6314 (BMEN 6372 or SYSM 6306) Engineering Systems: Modeling and Simulation

MECH 6317 (EECS 6302 or SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6330 Multiscale Design and Optimization

MECH 6333 Materials Design and Manufacturing

MECH 6334 Smart Materials and Structures

MECH 6335 (OPRE 6340) Flexible Manufacturing Strategies

MECH 6337 (SYSM 6301) Systems Engineering, Architecture and Design

MECH 6338 Reliability-Based Design

MECH 6339 Multidisciplinary Design Optimization

MECH 6341 (EEMF 6348 or MSEN 6348) Lithography and Nanofabrication

MECH 6342 Renewable Energy and Grid Integration

MECH 6347 (EEMF 6382 or MSEN 6382) Introduction to MEMS

MECH 6348 (EEMF 6322 or MSEN 6322) Semiconductor Processing Technology

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6V49 Special Topics in Manufacturing and Design Innovation

Mechanics and Materials (MM)

MS students must take at least 2 courses from one concentration area.

MECH 5300 (MSEN 5300 or PHYS 5376) Introduction to Materials Science

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6355 Viscoelasticity

MECH 6356 Fracture Mechanics

MECH 6357 (MSEN 6380) Phase Transformations and Kinetic Processes in Materials

MECH 6358 (MSEN 6381) Advanced Ceramic Materials

MECH 6359 (MSEN 6383) Modern Physical Metallurgy

MECH 6367 (MSEN 6310) Mechanical Properties of Materials

MECH 6368 Imperfections in Crystalline Solids

MECH 6V69 Special Topics in Mechanics and Materials

Thermal and Fluid Sciences (TFS)

MS students must take at least 2 courses from one concentration area.

MECH 5370 Wind Energy Fluid Mechanics

MECH 5371 Extreme Applications in Fluid Mechanics

MECH 5373 Thermal Management of Microelectronics

MECH 6370 Incompressible Fluid Mechanics

MECH 6371 Computational Thermal Fluid Science

MECH 6372 Turbulent Flows

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

MECH 6375 Phase Change Heat Transfer

MECH 6376 Experimental Thermal and Fluid Dynamics

MECH 6377 Advanced Thermodynamics

MECH 6378 Introduction to Compressible Fluid Mechanics

MECH 6383 (EEMF 6383 or PHYS 6383) Plasma Science

MECH 6V89 Special Topics in Thermal and Fluid Sciences

Students participating in the thesis option must take three graduate level electives and the following courses to fulfill the research and thesis requirements of the MS ME degree program:

MECH 6V97 Research in Mechanical Engineering (6 semester credit hours)

MECH 6V98 Thesis (3 semester credit hours minimum)

The thesis is required to be submitted to the graduate school and presented in a formal public defense. The supervising committee administers this defense and is chosen in consultation with the student's thesis advisor prior to enrolling for thesis credit. Thesis semester credit hours cannot be counted in a MS ME degree plan unless a thesis is written and successfully defended.

Students can satisfy six semester credit hours of graduate level electives through the completion of a graduate capstone project. The graduate capstone project will consist of solving a mechanical engineering design problem sponsored by industry.

Graduate Capstone Project Design (6 semester credit hours)

All electives must be approved by the faculty advisor

 

Doctor of Philosophy in Mechanical Engineering

78 semester credit hours minimum beyond the baccalaureate degree

Department Faculty

Professors: Fatemeh Hassanipour, Stefano Leonardi, Yaoyu Li, Hongbing Lu, Dong Qian, Mario A. Rotea, Joshua Summers, Seung M. You

Associate Professors: William Anderson, D. Todd Griffith, Giacomo (Valerio) Iungo, Golden Kumar, Arif Malik, Kristin Miller, Majid Minary, Zhenpeng Qin, Tyler Summers, Yonas Tadesse, Jie Zhang

Assistant Professors: Rodrigo Bernal Montoya, Shuang (Cynthia) Cui, Xianming Dai, Yaqing Jin, Justin Koeln, Wei Li, Hui Ouyang, Justin Ruths, Ill Ryu, Guoping Xiong, Kianoosh Yousefi, Armin Zare, Yue Zhou

Associate Professors of Instruction: Wooram Park, Oziel Rios, P.L. Stephan Thamban

Professor of Practice: Dani Fadda

Associate Professor of Practice: Robert Hart

UT Dallas Affiliated Faculty: Kyeongjae (KJ) Cho, Babak Fahimi, Matthew J. Goeckner, Jiyoung Kim, Moon J. Kim, Jeong-Bong Lee, S.O. Reza Moheimani, Mehrdad Nourani, Mark W. Spong, Robert M. Wallace, Steve Yurkovich

Admission Requirements

The University's general admission requirements are discussed on the Graduate Admission page.

The PhD in Mechanical Engineering is awarded primarily to acknowledge the student's success in an original research project, the description of which is a significant contribution to the scholarly literature. Applicants for the doctoral program are therefore selected by the Mechanical Engineering Graduate Committee on the basis of research aptitude as well as academic record.

The following are guidelines for admission to the PhD program in Mechanical Engineering:

  • A master's or bachelor's degree in engineering or one of the natural sciences from an institution of higher education in the U.S. or from a comparable institution abroad.
  • A grade point average (GPA) of 3.3 or better on a 4.0 point scale.
  • GRE scores of 150, 160, and 4 for the verbal, quantitative and analytical components, respectively, are advisable based on our experience with student success. (See also UT Dallas requirements for English proficiency).
  • Three letters of recommendation from individuals who are familiar with the student's record, and are able to judge the candidate's preparation and ability to succeed in doctoral study in Mechanical Engineering.
  • An essay describing motivation for doctoral study and how it relates to the student's professional goals.
  • A detailed resume of all education and work history.

Students from other engineering disciplines or from other areas of science or mathematics may be considered for admission to the program; however, additional coursework may be necessary to complete the PhD program.

For students who are interested in pursuing a PhD 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 PhD students.

Degree Requirements

The University's general degree requirements are discussed on the Graduate Policies and Procedures page.

Doctoral students must have a faculty advisor and an approved plan of study within the first two consecutive long semesters in the program. The faculty advisor shall be a faculty member, or affiliated faculty member, in Mechanical Engineering (ME). The plan of study is based upon the student's choice of concentration area. Each doctoral student must conduct original research in the area of Mechanical Engineering, under the direction of the faculty advisor. A supervisory committee will be formed once the faculty advisor accepts the student for a research project. The student must complete and defend a dissertation on the research project. A student must maintain a grade point average (GPA) of at least 3.0 to remain in good standing and satisfy the degree requirements.

The PhD program in Mechanical Engineering requires a minimum of 78 semester credit hours beyond the baccalaureate degree.

Transfer of graduate level credit into a doctoral program in mechanical engineering is limited to a maximum of 33 semester credit hours of graduate course work upon approval by the graduate committee based on the recommendation by dissertation advisor.

Required Major Courses: 12 semester credit hours

A PhD student in ME must take a total of four core courses, selected from two or more concentration areas from the list of the four concentration areas below, and must receive a grade of B- or better in the four core courses.

Dynamic Systems and Control

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6309 Intermediate Dynamics

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

Manufacturing and Design Innovation

MECH 6303 Computer Aided Design

MECH 6318 Engineering Optimization

MECH 6333 Materials Design and Manufacturing

Mechanics and Materials

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

Thermal and Fluid Sciences

MECH 6370 Incompressible Fluid Mechanics

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

Prescribed Electives within Concentration Areas: 12 semester credit hours

The following is a list of prescribed graduate-level elective courses. A PhD student in Mechanical Engineering must take at least four courses from the list of prescribed elective courses in one of the four areas of concentration.

Courses counted towards satisfying requirements on Required Major Courses cannot be counted towards satisfying requirements on Prescribed Electives. Upon approval from the student's faculty advisor and the Mechanical Engineering Graduate Committee, a qualified student can take other courses offered by UT Dallas to satisfy the requirements on prescribed electives.

Note: the presence of a course number in parentheses indicates that this course is cross-listed in another department.

Dynamic Systems and Controls (DSC)

PhD students must take at least 4 courses from one concentration area.

MECH 6300 (EECS 6331 or SYSM 6307) Linear Systems

MECH 6308 Haptics and Teleoperated Systems

MECH 6309 Intermediate Dynamics

MECH 6311 Advanced Mechanical Vibrations

MECH 6312 (EESC 6349) Probability, Random Variables, and Statistics

MECH 6313 (EECS 6336 or BMEN 6388 or SYSE 6324) Nonlinear Systems

MECH 6314 (SYSM 6306 or BMEN 6372) Engineering Systems: Modeling and Simulation

MECH 6316 (SYSE 6322) Digital Control of Automotive Powertrain Systems

MECH 6317 (SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6323 (SYSE 6323 or EECS 6323) Robust Control Systems

MECH 6324 (BMEN 6324 or EECS 6324) Robot Control

MECH 6325 Optimal Estimation and Kalman Filter

MECH 6326 Optimal Control and Dynamic Programming

MECH 6327 Convex Optimization in Systems and Controls

MECH 6328 Frequency-Domain Analysis and Design of Control Systems

MECH 6V29 Special Topics in Dynamic Systems and Control

MECH 7V29 Advanced Special Topics in Dynamic Systems and Control

Manufacturing and Design Innovation (MDI)

PhD students must take at least 4 courses from one concentration area.

MECH 6303 Computer Aided Design

MECH 6311 Advanced Mechanical Vibrations

MECH 6314 (BMEN 6372 or SYSM 6306) Engineering Systems: Modeling and Simulation

MECH 6317 (EECS 6302 or SYSM 6302) Dynamics of Complex Networks and Systems

MECH 6318 Engineering Optimization

MECH 6319 Dynamics and Control of MEMS

MECH 6330 Multiscale Design and Optimization

MECH 6333 Materials Design and Manufacturing

MECH 6334 Smart Materials and Structures

MECH 6335 (OPRE 6340) Flexible Manufacturing Strategies

MECH 6337 (SYSM 6301) Systems Engineering, Architecture and Design

MECH 6338 Reliability-Based Design

MECH 6339 Multidisciplinary Design Optimization

MECH 6341 (EEMF 6348 or MSEN 6348) Lithography and Nanofabrication

MECH 6342 Renewable Energy and Grid Integration

MECH 6347 (EEMF 6382 or MSEN 6382) Introduction to MEMS

MECH 6348 (EEMF 6322 or MSEN 6322) Semiconductor Processing Technology

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6V49 Special Topics in Manufacturing and Design Innovation

MECH 7V49 Advanced Special Topics in Manufacturing and Design Innovation

Mechanics and Materials (MM)

PhD students must take at least 4 courses from one concentration area.

MECH 6306 Continuum Mechanics

MECH 6350 Advanced Solid Mechanics

MECH 6351 Finite Element Techniques I

MECH 6353 Computational Mechanics

MECH 6354 Experimental Mechanics

MECH 6355 Viscoelasticity

MECH 6356 Fracture Mechanics

MECH 6357 (MSEN 6380) Phase Transformations and Kinetic Processes in Materials

MECH 6358 (MSEN 6381) Advanced Ceramic Materials

MECH 6359 (MSEN 6383) Modern Physical Metallurgy

MECH 6367 (MSEN 6310) Mechanical Properties of Materials

MECH 6368 Imperfections in Crystalline Solids

MECH 6V69 Special Topics in Mechanics and Materials

MECH 7V69 Advanced Special Topics in Mechanics and Materials

Thermal and Fluid Sciences (TFS)

PhD students must take at least 4 courses from one concentration area.

MECH 6370 Incompressible Fluid Mechanics

MECH 6371 Computational Thermal Fluid Science

MECH 6372 Turbulent Flows

MECH 6373 Convective Heat Transfer

MECH 6374 Conductive and Radiative Heat Transfer

MECH 6375 Phase Change Heat Transfer

MECH 6376 Experimental Thermal and Fluid Dynamics

MECH 6377 Advanced Thermodynamics

MECH 6378 Introduction to Compressible Fluid Mechanics

MECH 6383 (EEMF 6383 or PHYS 6383) Plasma Science

MECH 6V89 Special Topics in Thermal and Fluid Sciences

MECH 7V89 Advanced Special Topics in Thermal and Fluid Sciences

Mathematics Electives: 6 semester credit hours

The following is a list of suggested elective courses in mathematics.

Two courses are required for mathematics electives.

MATH 6303 Theory of Complex Functions I

MATH 6313 Numerical Analysis

MATH 6315 Ordinary Differential Equations

MATH 6318 Numerical Analysis of Differential Equations

MATH 6319 Principles and Techniques in Applied Mathematics I

MATH 6320 Principles and Techniques in Applied Mathematics II

MATH 6308 Inverse Problems and Applications

MATH 6321 Optimization

MATH 6340 Numerical Linear Algebra

MECH 6391 (EEGR 6381) Computational Methods in Engineering

MECH 7392 Advanced Mathematics for Mechanical Engineers I

MECH 7393 Advanced Mathematics for Mechanical Engineers II

STAT 6331 Statistical Inference I

STAT 6337 Advanced Statistical Methods I

and STAT 6338 Advanced Statistical Methods II

STAT 6339 Linear Statistical Models

STAT 6341 Numerical Linear Algebra and Statistical Computing

MATH 7313 Partial Differential Equations I

Upon the approval of a student's faculty advisor, a qualified student can request to take other graduate courses in mathematics not listed above.

In addition to course requirements, the PhD students need to complete the following:

  • Qualifying Exam (QE): It tests fundamental knowledge in mathematics and one concentration area of mechanical engineering. A student entering the PhD program with an MS ME must take this exam within three long semesters. A student has at most two attempts made within two consecutive semesters at this qualifying exam. The exam is given during the fall and spring semesters.
  • Comprehensive Exam (CE): Written dissertation proposal and an exam are given by the candidate's supervisory committee.
  • Final Exam: Completion of a major research project culminating in a dissertation demonstrating an original contribution to the body of knowledge. The dissertation is defended publicly. The rules for this defense are specified by the Office of the Dean of Graduate Education.

A student who has passed the QE and maintained the GPA requirements in PhD level organized courses will be admitted to the PhD candidacy.

The following courses are required to fulfill the research and dissertation requirements of the PhD degree program:

MECH 8V70 Advanced Research in Mechanical Engineering (30 semester credit hours minimum)

MECH 8V99 Dissertation (6 semester credit hours minimum)

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

 

Non-Degree Seeking Students in Mechanical Engineering

"Non-Degree Seeking" is a term which applies to students who are taking selected courses and who have not applied to, or been accepted into, a degree program. A student may be taking classes for various reasons; i.e., personal or professional enhancement, to transfer courses to another university, to correct a grade deficiency. Students who have not taken the GRE or GMAT, or who are awaiting results, may also be classified non- degree seeking.

A non-degree seeking student must meet the same academic eligibility requirements and English proficiency requirements as ME graduate degree seeking students. Non-degree seeking students who are ultimately admitted to a MS graduate degree program may transfer no more than 15 non-degree semester credit hours to the ME graduate degree program. A new application must be submitted when transferring from non-degree to degree seeking status.

Updated: 2022-03-30 11:49:48 v15.aa62eb