2009-10 Undergraduate Catalog
Majors
Aerospace engineers are called upon to solve exciting problems of design, construction and operation of aircraft and spacecraft to meet the ever-increasing requirement for improved performance at lower unit cost. These challenges mean that aerospace engineers work at the continuously changing forefront of science, technology and systems management.
The undergraduate curriculum in aerospace engineering is a fully accredited baccalaureate program that provides a broad education with a strong foundation in mathematics, science and basic engineering sciences. Advanced courses in aeronautics and astronautics complete the degree. Graduates will be prepared to work in the aerospace and related industries or to pursue graduate study.
There is great overlap between the aerospace engineering and mechanical engineering curriculum. The first six semesters of the two degree programs are identical. Through proper selection of electives, students can earn dual mechanical engineering/aerospace engineering B.S. degrees with one semester of additional work. Interested students should contact the mechanical and aerospace engineering department or its website for more information.
The department's active research programs are sponsored by private industry, the National Science Foundation, Department of Defense, NASA, National Institutes of Health and other agencies. These programs keep faculty at the leading edge of technology and provide opportunities for students to participate in research through classroom assignments, individual studies, undergraduate research scholarships and employment as research assistants.
The mission of the undergraduate program is to serve the state of Florida, the United States and the engineering profession by providing quality educational programs in aerospace engineering; conduct a nationally recognized research program; and foster ongoing professional development of students and faculty.
Within three to five years of obtaining a bachelor's degree in aerospace engineering at the University of Florida, a graduate is expected to achieve one or more of the following milestones:
To graduate with this major, students must complete all university, college and major requirements.
* Completed with a grade of C or better
1 May substitute CGS 2420 Computer Programming Using FORTRAN, CIS 3022 Programming Fundamentals for CIS Majors 1, EEL 4834 C++ Programming for Electrical Engineers, or other programming courses approved by the department.
2 May substitute EEL 3111C.
Aerospace Engineering |
College: Engineering |
Degree: Bachelor of Science in Aerospace Engineering |
Hours for Degree: 128 |
Minor: Yes, BioMechanics |
Dual Degree: Mechanical Engineering / Aerospace Engineering |
Combined-Degree Program: Yes |
Website: www.mae.ufl.edu/mae-undergrad/ |
Aerospace engineers are called upon to solve exciting problems of design, construction and operation of aircraft and spacecraft to meet the ever-increasing requirement for improved performance at lower unit cost. These challenges mean that aerospace engineers work at the continuously changing forefront of science, technology and systems management.
The undergraduate curriculum in aerospace engineering is a fully accredited baccalaureate program that provides a broad education with a strong foundation in mathematics, science and basic engineering sciences. Advanced courses in aeronautics and astronautics complete the degree. Graduates will be prepared to work in the aerospace and related industries or to pursue graduate study.
Dual-Degree Programs
There is great overlap between the aerospace engineering and mechanical engineering curriculum. The first six semesters of the two degree programs are identical. Through proper selection of electives, students can earn dual mechanical engineering/aerospace engineering B.S. degrees with one semester of additional work. Interested students should contact the mechanical and aerospace engineering department or its website for more information.
Research Programs
The department's active research programs are sponsored by private industry, the National Science Foundation, Department of Defense, NASA, National Institutes of Health and other agencies. These programs keep faculty at the leading edge of technology and provide opportunities for students to participate in research through classroom assignments, individual studies, undergraduate research scholarships and employment as research assistants.
Mission
The mission of the undergraduate program is to serve the state of Florida, the United States and the engineering profession by providing quality educational programs in aerospace engineering; conduct a nationally recognized research program; and foster ongoing professional development of students and faculty.
Educational Objectives
Within three to five years of obtaining a bachelor's degree in aerospace engineering at the University of Florida, a graduate is expected to achieve one or more of the following milestones:
- Advance professionally as a result of his/her ability to solve complex technical problems and to work in multidisciplinary teams on problems whose solutions lead to significant societal benefits;
- Demonstrate professional engineering competence via promotions and/or positions of increasing responsibility, or successfully transition from the traditional aerospace engineering career path into business, government or education;
- Make scholarly contributions to knowledge as demonstrated by publishing papers and/or technical reports, applying for patents, delivering effective conference presentations and/or contributing to innovative leadership articles;
- Demonstrate a commitment to the community and the profession through involvement with community and/or professional organizations and/or make contributions towards society's greater good and prosperity; and
- Demonstrate an understanding of the need for life-long learning via progress toward, or successful completion of an advanced degree, professional development and/or industrial training course(s), and/or engineering certification.
To graduate with this major, students must complete all university, college and major requirements.
Critical Tracking and Recommended Semester Plan
Semester 1:
- 2.0 UF GPA required for semesters 1-5
- 2.5 GPA on all critical-tracking coursework for semesters 1-5
- Complete 1 of 8 tracking courses with a minimum grade of C within two attempts: CHM 2045, approved science elective, MAC 2311, MAC 2312, MAC 2313, MAP 2302, PHY 2048, PHY 2049
Semester 2:
- Complete 1 additional course with a minimum grade of C within two attempts
Semester 3:
- Complete 2 additional courses with a minimum grade of C within two attempts
Semester 4:
- Complete 2 additional courses with a minimum grade of C within two attempts
Semester 5:
- Complete all 8 critical-tracking courses with a minimum grade of C within two attempts
To remain on track, students must complete the appropriate critical-tracking courses, which appear in bold.
Recommended semester plan
Semester 1 | Credits |
CHM 2045 General Chemistry 1 (GE-P) | 3 |
CHM 2045L General Chemistry 1 Laboratory (GE-P) | 1 |
EML 2920 Department and Professional Orientation | 1 |
MAC 2311 Analytic Geometry and Calculus 1 (GE-M) | 4 |
English composition (CE-C, WR; placement scores on ACT/SAT do not exempt this requirement) | 3 |
Social and Behavioral Sciences (GE-S) | 3 |
Total | 15 |
Semester 2 | Credits |
EML 2023 Computer Aided Graphics and Design | 3 |
ENC 3254 Professional Writing in the Discipline (GE-C, WR) | 3 |
MAC 2312 Analytic Geometry and Calculus 2 (GE-M) | 4 |
PHY 2048 Physics with Calculus 1 (GE-P) | 3 |
PHY 2048L Laboratory for PHY 2048 (GE-P) | 1 |
Total | 14 |
Semester 3 | Credits |
CGS 2421 Computer Programming for Engineers1 | 2 |
EGM 2511 Engineering Mechanics - Statics * | 3 |
EML 2322L Design and Manufacturing Laboratory | 2 |
MAC 2313 Analytic Geometry and Calculus 3 (GE-M) | 4 |
PHY 2049 Physics with Calculus 2 (GE-P) | 3 |
PHY 2049L Laboratory for PHY 2049 (GE-P) | 1 |
Total | 15 |
Semester 4 | Credits |
EEL 3003 Elements of Electrical Engineering and Circuits2 | 3 |
EGM 3344 Numerical Methods of Engineering Analysis | 3 |
EGM 3520 Mechanics of Materials | 3 |
EML 3100 Thermodynamics * | 3 |
MAP 2302 Elementary Differential Equations | 3 |
Total | 15 |
Semester 5 | Credits |
EMA 3010 Materials | 3 |
Humanities (GE-H) | 3 |
Science elective (AST 3018, BSC 2010, CHM 2046 or PHY 3101) | 3 |
Total | 9 |
Semester 6 | Credits |
EGM 3401 Engineering Mechanics – Dynamics * | 3 |
EGM 4313 Intermediate Engineering Analysis | 3 |
EGN 3353C Fluid Mechanics | 3 |
EML 3301C Mechanics of Materials Laboratory | 3 |
Social and Behavioral Sciences (GE-S) | 3 |
Total | 15 |
Semester 7 | Credits |
EAS 4101 Aerodynamics | 3 |
EAS 4510 Astrodynamics | 3 |
EML 4304C Thermo/Fluids Design and Laboratory | 3 |
EML 4312 Control of Mechanical Engineering Systems | 3 |
Aerospace elective: EML 4500, EML 4220, EML 4140 or EAS 4132 | 3 |
Total | 15 |
Semester 8 | Credits |
EAS 4200C Aerospace Structures | 3 |
EAS 4400 Stability and Control of Aircraft | 3 |
EAS 4700 Aerospace Design 1 | 3 |
Aerospace elective: EML 4500, EML 4220, EML 4140 or EAS 4132 | 3 |
Humanities (GE-H) | 3 |
Total | 15 |
Semester 9 | Credits |
EAS 4300 Aerospace Propulsion | 3 |
EAS 4710 Aerospace Design 2 | 3 |
Humanities (GE-H) or Social and Behavioral Sciences (GE-S) | 3 |
Technical electives (see approved list) | 6 |
Total | 15 |
* Completed with a grade of C or better
1 May substitute CGS 2420 Computer Programming Using FORTRAN, CIS 3022 Programming Fundamentals for CIS Majors 1, EEL 4834 C++ Programming for Electrical Engineers, or other programming courses approved by the department.
2 May substitute EEL 3111C.