A primary goal of the MAE degree program is to provide an educational experience and training that will prepare its graduates to excel within the broad scope of the mechanical and aerospace engineering profession. Our Program Educational Objectives are to enable our graduates to attain the following professional and career accomplishments during the first few years following graduation:
- Be employed in a professional mechanical, aerospace or related engineering organization, or be admitted to graduate programs in engineering or other professional areas,
- Become an active participant in professional society activities,
- Demonstrate the initiative, motivation and ability to grow professionally in their chosen endeavor.
Future Undergraduate Students
The Department of Mechanical and Aerospace Engineering (MAE) offers three programs of study leading to the bachelor's degree. They are the Bachelor of Science in Aerospace Engineering, the Bachelor of Science in Mechanical Engineering, and a double degree of Bachelor of Science in Aerospace Engineering and Bachelor of Science in Mechanical Engineering. The Aerospace and Mechanical Engineering programs have been accredited since 1968 and 1967, respectively, by the Engineering Accreditation Commission of ABET, http://www.abet.org.
"Explore MAE" is an event held in September that welcomes our new undergraduates. Students are encouraged to talk with professors, visit MAE research and teaching labs, and join student organizations. The event is by invitation only to new students. Pizza and event t-shirts are provided. Look for your electronic invitation. See what students had to say:
Future Graduate Students
- AE Master's Graduate Handbook
- AE Ph.D. Graduate Handbook
- ME Master's Graduate Handbook
- ME Ph.D. Graduate Handbook
- Graduate Admissions Checklist - International Students
- Graduate Admissions Checklist - Domestic Students
The overall objective of the graduate program in Aerospace Engineering is to develop in a student the ability to define a technical problem, establish an appropriate mathematical or experimental model based on a firm understanding of the physical nature of the problem, analyze the problem by theoretical, numerical, or experimental techniques, and evaluate the results. Although this ability is developed in the context of aerospace problems, it is applicable to the engineering of any physical system. The program is designed for a student with any of the following specific objectives:
- A sound foundation in advanced mathematics, science, and engineering which will equip the student well for research and development work or for further advanced study toward a doctoral degree in engineering.
- A program of advanced study which allows specialization in one of the following areas:
- Fluid dynamics, aerodynamics and propulsion (theoretical and applied aerodynamics, gas dynamics, viscous fluid mechanics, turbulence, computational and experimental fluid dynamics, bio-fluidics, hypersonic flow theory, high-temperature gas dynamics, V/STOL and rotorcraft aerodynamics, air-breathing and rocket propulsion);
- Structural mechanics and structures (solid mechanics, aerospace structures, structural dynamics, composite structures and material characterization, damage tolerance and durability, smart structures, structure optimization, sensor technology, high-temperature structures and materials, aeroelasticity);
- Flight mechanics and controls (atmospheric and space flight mechanics, orbital mechanics, guidance, navigation and control);
- Vehicle design (conceptual aircraft design, atmospheric flight vehicle design, spacecraft design, computer-aided engineering).
- A balanced but non-specialized program of advanced study in aerodynamics, astronautics, flight dynamics, structural analysis, propulsion, and fluid mechanics, with emphasis on experimental techniques and modern mathematical analysis.