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Aerospace engineering is concerned with the science and technology underlying the behavior and design of vehicles and systems that operate within the atmosphere and in space. It requires knowledge of a wide range of subject areas, including the basic sciences, mathematics, and engineering sciences as well as specialized studies in aerodynamics, propulsion systems, structures, materials, flight dynamics, astronautics, and computational methods. This broad background qualifies the graduating engineer not only to handle problems that are special to the aerospace field, but also to meet challenges of an interdisciplinary nature facing society, such as those involving the environment, transportation, and energy resources.
The Aerospace Engineering curriculum provides a thorough background in fluid dynamics, structures, propulsion, controls, flight dynamics and design. The curriculum provides flexibility with regard to all areas of potential aerospace practice by emphasizing applied science, design, and technology while providing a firm foundation in mathematics and physics. Students will use symbolic and high-level mathematics tools, solid modeling and finite element analysis tools, as well as computational fluid dynamics and materials selection tools. They also have access to a state-of-the art rapid prototyping facility with numerous 3D course printers, CNC machines, laser cutters, and the like. The rapid prototyping facility can be used both for course work, as well as individual entrepreneurial initiatives. With a strong science and mathematics based education, aerospace engineers have also found employment opportunities outside of the traditional aerospace industry. Many work in oceanography, biotechnology, weather prediction, energy conservation, and in the petrochemical, nuclear or automotive industries. In addition, the aerospace design provides an excellent background for business, law or medicine. Of course, people with the ambition to become pilots, either military or commercial, find the aerospace degree very attractive.
Aerospace engineering principles are reinforced and integrated through design assignments and significant “hands-on” experience with the latest in test equipment and modern experimental methods. A three-semester lab sequence builds on a basic skills and science background to develop an appreciation for measurement techniques and apparatus as well as to demonstrate aerodynamic concepts. Students also develop communications skills and learn about the complex cultural, legal, ethical and economic factors which influence the engineering profession. Students who wish to may select courses that satisfy the requirements of a minor area of study (e.g., materials science, computer science, physics and engineering business, economics).
Graduates of the Aerospace Engineering program at the University of Virginia have the knowledge, skills, and attitudes that allow them to make tangible contributions, meet new technical challenges, contribute effectively as team members, and be innovators in the analysis and design of aerospace vehicle systems. They communicate effectively and interact responsibly with colleagues, clients, employers and society.
Aerospace Engineering Curriculum (128 credits)
First Semester Credits: 15
Second Semester Credits: 17
Third Semester Credits: 17
Fourth Semester Credits: 17
Fifth Semester Credits: 17
Sixth Semester Credits: 15
Seventh Semester Credits: 15
Eighth Semester Credits: 15
- MAE 4XXX - Aerospace Design II (See Footnote 6 below) Credits / Units: 3
- STS 4600 - The Engineer, Ethics, and Professional Responsibility Credits: 3
- Math-Science/Technical Elective (See footnote 2 below) Credits / Units: 3
- HSS Elective 3 (See footnote 4 below) Credits / Units: 3
- Unrestricted Elective 3 (See Footnote 1 below)
(1) Unrestricted electives may be chosen from any graded course in the University except mathematics courses below MATH 1310 and courses that substantially duplicate any others offered for the degree, including PHYS 2010, 2020; CS 1010, 1020; or any introductory programming course. Students in doubt as to what is acceptable to satisfy a degree requirement should get the approval of their advisor and the dean’s office, located in A122 Thornton Hall.
(2) Chosen from the MAE Department’s approved Math-Science/Technical Electives List (see website).
(3) Chosen from: BIOL 2100, 2200; CHEM 1420; EVSC 2800, EVSC 3200, EVSC 3300, MSE 2090; PHYS 2620; and any approved APMA course 2000 or higher not already required by a student’s major and does not duplicate material from another APMA course.
(4) Chosen from the approved Humanities and Social Science list available in A122 Thornton Hall.
(5) Chosen from ECE 2200 (4 credits) or PHYS 2415 (3 credits) and PHYS 2419 (1 credit).
(6) Chosen from the sequence 4650-4660 or 4690-4700.
Public Professional Licensure Disclosure
As a member of the State Authorizations Reciprocity Agreement, the University of Virginia (UVA) is authorized to provide curriculum in a distance learning environment to students located in all states in the United States except for California. (34 CFR 668.43(a)(6)& 34 CFR 668.72(n)).
Upon completion of the Bachelor of Science in Aerospace Engineering at the UVA School of Engineering, graduates may be eligible for initial professional licensure in another U.S. state by applying to the licensing board or agency in that state.
Please visit the University’s state authorization web pages to make an informed decision regarding which states’ educational requirements for initial licensure are met by this program. (668.43(a)(5) (v)(A) - (C))
Enrolled students who change their current (or mailing) address to a state other than Virginia should update this information immediately in the Student Information System as it may impact their ability to complete internship, practicum, or clinical hours, use Title IV funds, or meet licensure or certification requirements in the new state. (34 CFR 668.402).