The evolution of our technology into the computer age has reinforced the importance of the broad technical and professional training of both the mechanical and the aerospace engineer. Each may make his or her professional contribution in many diverse industries, ranging from the automobile and aerospace industries to the manufacture of computers and the automation and control of systems.
Regardless of the particular product involved, mechanical and aerospace engineers rely upon knowledge of matter and energy conversions, motions, and forces obtained from computer simulations and experimental investigations of processes and systems. Each type of engineer is able to design mechanisms, machines, and structures to serve a specific purpose, such as the manufacture of high-tech materials, including ceramics and composites, and high-tech equipment, i.e., advanced automation and control systems. They also are trained to determine, both experimentally and theoretically, the heat and energy transfer rates that occur within engineering devices, for example, internal combustion engines, electronic equipment, robots, solar energy systems, rocket engines, steam and gas turbines, and nuclear reactors. The curriculum in mechanical and aerospace engineering provides these skills and prepares students for graduate study and research.
The undergraduate program in mechanical and aerospace engineering trains students in a technically sound, challenging, and professional manner, laying the foundation for a productive career and enabling graduates to make positive contributions to their profession and society. This is achieved with a thorough preparation in the humanities, mathematics, and basic sciences, as well as up-to-date mechanical and aerospace engineering fundamentals and applications using the most advanced tools and methods available.
In the senior year, the capstone design and manufacturing course allows students to solve open-ended, multicriteria engineering problems. Emphasis is placed on teamwork, project management, conceptualization, detailed design, analysis, and manufacturing. At the end of the yearlong course, students will have experienced a full product development cycle from concept to construction and testing.