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Aerospace Engineering, B.S.

The Â鶹ÊÓƵÏÂÔØ Department of Aerospace and Mechanical Engineering offers an undergraduate program in aerospace engineering that equips students to shape the future by incorporating the latest industry trends and immersive experiential coursework.

A robust foundation in aerospace engineering concepts coupled with cross-disciplinary teamwork sets Â鶹ÊÓƵÏÂÔØ students apart not only as problem solvers but also as ethical innovators and leaders by becoming aware of the impact of engineering decisions in the context of the environment and society.ÌýOur program provides students with a comprehensive education in aerospace engineering with a focus on systems design.

Program Highlights

  • Celebrating 90 years of aerospace engineering excellence.

  • Curriculum: Strong foundation in engineering sciences, followed by structures, thermal fluids, dynamics, and controls, aeronautical, astronautical, and design courses with flexible elective courses in cutting-edge disciplines and technologies.

  • Career focus: Preparation for careers in aerospace engineering, both in aeronautics and astronautics, and graduate studies.

  • Global reach: The campus in Madrid provides students with a unique international experience and opportunities for study abroad. These opportunities are available anytime during the first two years.

  • Experiential learning: Our curriculum emphasizes hands-on learning from day one with a focus on practical experience and proactive engagement through design projects and research endeavors. A commitment to innovation, entrepreneurship, service learning, diversity, equity, inclusion and teamwork is a part of the student experience.

  • Capstone design experience: Two-semester capstone experience focusing on aerospace vehicle design from requirement development to prototyping.

  • Research opportunities: Students can access a wide range of funded and voluntary research opportunities, collaborating closely with dedicated faculty members on diverse research projects.

  • Cutting-edge facilities: State-of-the-art labs and equipment, including the WIND wind tunnel lab, AirCRAFT lab, and Space Systems Research lab.

  • Student engagement that fosters diversity and inclusion: Our students have an opportunity to join active student organizations, participate in national and international competitions, and collaborate with faculty on research projects. Student organizations actively lead initiatives, organizing outreach events to promote the involvement of underrepresented groups in engineering.

  • Dedicated faculty and staff: Faculty, staff and students form a learning community that supports individual excellence and shared accomplishment.

Curriculum Overview

We take pride in our innovative aerospace engineering curriculum, carefully crafted to offer students a holistic education that seamlessly integrates theoretical knowledge with experiential learning. Our program stands out for its exceptional faculty, dedicated staff, and access to a wide range of cutting-edge equipment and facilities, creating an immersive environment where students can immediately apply their knowledge to real-world scenarios.

Fieldwork and Research Opportunities

Â鶹ÊÓƵÏÂÔØ's aerospace engineering program benefits include summer internships and cooperative education programs available with industry, and federal labs in the St. Louis area and nationwide. These sites include NASA, the U.S. Department of Defense, the Boeing Company, Lockheed Martin Corporation and Northrop Grumman. Further, students can count the internship experience toward a technical elective by documenting their learning.


Funded undergraduate and graduate research opportunities with faculty members in the program are available for qualified students. Funded opportunities range from private industries to federal government research laboratories. Initiatives like SURGE and FIRE offer undergraduates hands-on research experiences, allowing them to work in university labs and apply their learning in practical settings, thereby enhancing their academic journey.

Careers

Corporations and government agencies where successful Â鶹ÊÓƵÏÂÔØ aerospace engineering alumni can be found include:

  • Boeing
  • General Dynamics
  • General Electric
  • Hughes
  • Lockheed Martin
  • NASA
  • Northrop Grumman
  • Pratt-Whitney
  • Raytheon
  • SpaceX
  • Spirit AeroSystems
  • Stratolaunch
  • U.S. Air Force, Navy, and Army research centers

Admission Requirements

Begin Your Application

Â鶹ÊÓƵÏÂÔØ also accepts the Common Application.

Freshman

All applications are thoroughly reviewed with the highest degree of individual care and consideration to all credentials that are submitted. Solid academic performance in college preparatory coursework is a primary concern in reviewing a freshman applicant’s file.

To be considered for admission to any Â鶹ÊÓƵÏÂÔØ undergraduate program, applicants must be graduating from an accredited high school, have an acceptable HiSET exam score or take the General Education Development (GED) test.Ìý

Transfer

Applicants must be a graduate of an accredited high school or have an acceptable score on the GED.

Students who have attempted fewer than 24 semester credits (or 30 quarter credits) of college credit must follow the above freshmen admission requirements. Students who have completed 24 or more semester credits (or 30 quarter credits) of college credit mustÌýsubmit transcripts from all previously attended college(s).

In reviewing a transfer applicant’s file, the Office of Admission holistically examines the student’s academic performance in college-level coursework as an indicator of the student’s ability to meet the academic rigors of Â鶹ÊÓƵÏÂÔØ. Where applicable, transfer students will be evaluated on any courses outlined in the continuation standards of their preferred major.

International Applicants

All admission policies and requirements for domestic students apply to international students along with the following:

  • Demonstrate English Language Proficiency
  • Proof of financial support must include:
    • A letter of financial support from the person(s) or sponsoring agency funding the time at Â鶹ÊÓƵÏÂÔØ
    • A letter from the sponsor's bank verifying that the funds are available and will be so for the duration of study at the University
  • Academic records, in English translation, of students who have undertaken post-secondary studies outside the United States must include the courses taken and/or lectures attended, practical laboratory work, the maximum and minimum grades attainable, the grades earned or the results of all end-of-term examinations, and any honors or degrees received. WES and ECE transcripts are accepted.

Additional Admission Requirements

In addition to the general admission and matriculation requirements of the University, applicants to Â鶹ÊÓƵÏÂÔØ’s engineering programs must meet the following requirements:

  • GPA: Minimum cumulative 3.00 high school GPA for freshmen applicants and 2.70 college GPA for transfer applicants.
  • Coursework: Fifteen total units of high school work are required: three or four units of English; four or more units of mathematics, including algebra I and II, geometry and precalculus (Algebra II with Trigonometry is not sufficient). Students should be prepared to start the first semester of freshmen year in Calculus I or higher; three or four units of science, including general science, introduction to physical science, earth science, biology, physics or chemistry; two or three units of social sciences including history, psychology or sociology; and three units of electives.

Admission to the School of Science and Engineering’s degree programs is based on a combination of secondary school grades, college admission test scores, co-curricular activities and attempted college coursework, as well as other indicators of the applicant’s ability, career focus and character. This process respects the non-discrimination policy of the University and is designed to select a qualified, competent and diverse student body with high standards of scholarship and character, consistent with the mission of the University.

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Tuition Cost Per Year
Undergraduate Tuition $54,760

Additional charges may apply. Other resources are listed below:

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Information on Tuition and Fees

Miscellaneous Fees

Information on Summer Tuition

Scholarships and Financial Aid

There are two principal ways to help finance a Â鶹ÊÓƵÏÂÔØ education:

  • Scholarships: Scholarships are awarded based on academic achievement, service, leadership and financial need.
  • Financial Aid: Financial aid is provided through grants and loans, some of which require repayment.

Â鶹ÊÓƵÏÂÔØ makes every effort to keep our education affordable. In fiscal year 2023, 99% of first-time freshmen and 92% of all students received financial aid and students received more than $459 million in aid University-wide.

For priority consideration for merit-based scholarships, apply for admission by December 1 and complete a Free Application for Federal Student Aid (FAFSA) by March 1.

For more information on scholarships and financial aid, visit the Office of Student Financial Services.

Accreditation

The Aerospace Engineering, B.S. is accredited by the Engineering Accreditation Commission ofÌýABET,Ìý, under the commission's General Criteria and Program Criteria for Aerospace and Similarly Named Engineering Programs.

Enrollment and Graduation Data for Aerospace Engineering

The Aerospace Engineering, B.S. is accredited by the Engineering Accreditation Commission ofÌýABET, , under the commission's General Criteria and Program Criteria for Aerospace and Similarly Named Engineering Programs.

ProgramÌýEducational Objectives

The undergraduate program is designed to meet the following specific objectives in order to fulfill the departmental and institutional missions.

  • To practice the principles of engineering in aerospace or allied organizations
  • To pursue further learning in aerospace engineering or in allied disciplinesÌý
  • To function as effective engineers with professional knowledge, skills and values

Student OutcomesÌý

Graduates of the aerospace engineering program at Â鶹ÊÓƵÏÂÔØ will have an ability to:

  1. Identify, formulate, and solve complex engineering problems by applying principles of engineering, science and mathematics.
  2. Apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors.
  3. Communicate effectively with a range of audiences.
  4. Recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts.
  5. Function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
  6. Develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
  7. Acquire and apply new knowledge as needed, using appropriate learning strategies.
University Undergraduate Core32-35
Basic Engineering
°ä³§°ä±õÌý1060Introduction to Computer Science: Scientific Programming3
·¡°ä·¡Ìý1100Electrical Engineering 1012
·¡°ä·¡Ìý1200Computer Engineering 1012
³§·¡Ìý1700
&²¹³¾±è;Ìý³§·¡Ìý1701
Engineering Fundamentals
and Engineering Fundamentals Studio
3
General Engineering Courses
²Ñ·¡±·³ÒÌý1011Prototyping1
²Ñ·¡±·³ÒÌý2100³ÝStatics3
²Ñ·¡±·³ÒÌý2150Dynamics3
²Ñ·¡±·³ÒÌý2310Thermodynamics3
²Ñ·¡±·³ÒÌý3105Mechanics of Solids3
²Ñ·¡±·³ÒÌý3110Linear Vibrations3
²Ñ·¡±·³ÒÌý3111Mechanics Laboratory1
²Ñ·¡±·³ÒÌý3200Fluid Dynamics3
´¡·¡±·³ÒÌý3410Analysis and Control of Linear Systems3
²Ñ·¡±·³ÒÌý3510³ÝMaterials Science3
Aerospace Engineering Courses
´¡·¡±·³ÒÌý2020Introduction to Aero and Astro Engineering1
´¡·¡±·³ÒÌý3000Performance3
´¡·¡±·³ÒÌý3050Design of Space Missions3
´¡·¡±·³ÒÌý3150Astrodynamics3
´¡·¡±·³ÒÌý3230Compressible Flow3
´¡·¡±·³ÒÌý3240Aerodynamics and Boundary Layer Flow3
´¡·¡±·³ÒÌý4004Flight Vehicle Analysis and Design I3
´¡·¡±·³ÒÌý4014Flight Vehicle Analysis and Design II3
´¡·¡±·³ÒÌý4110Flight Vehicle Structures3
´¡·¡±·³ÒÌý4111Aerospace Laboratory1
´¡·¡±·³ÒÌý4210Propulsion3
´¡·¡±·³ÒÌý4400Stability and Control3
Technical Electives
Select 9 credits from an approved AE list 19
Basic Science & Mathematics
°ä±á·¡²ÑÌý1110
&²¹³¾±è;Ìý°ä±á·¡²ÑÌý1115
General Chemistry 1
and General Chemistry 1 Laboratory
4
±Ê±á³Û³§Ìý1610
&²¹³¾±è;Ìý±Ê±á³Û³§Ìý1620
University Physics I
and University Physics I Laboratory
4
±Ê±á³Û³§Ìý1630
&²¹³¾±è;Ìý±Ê±á³Û³§Ìý1640
University Physics II
and University Physics II Laboratory
4
²Ñ´¡°Õ±áÌý1510Calculus I4
²Ñ´¡°Õ±áÌý1520Calculus II4
²Ñ´¡°Õ±áÌý2530Calculus III4
²Ñ´¡°Õ±áÌý3550Differential Equations3
²Ñ´¡°Õ±áÌý3270Advanced Mathematics for Engineers3
Total Credits131-134

Non-Course Requirements

All Science and Engineering B.A. and B.S. students must complete an exit interview/survey near the end of their bachelor's program.Ìý

ÌýContinuation Standards

Students must maintain a minimum 2.00 GPA.

1

Acceptable technical electives are courses at the 4000 level in the area of program major or the 3000 level or above in allied disciplines. (Allied disciplines include courses in engineering other than student’s major, Mathematics – MATH, Computer Science – CSCI, Management – MGT, Pre-Law – PLS, Physics – PHYS, Chemistry – CHEM, and Biology – BIOL.) The student may also do an approved project or research independent study with a faculty member, or an approved internship with industry.

Ìý
Ìý

Roadmaps are recommended semester-by-semester plans of study for programs and assume full-time enrollmentÌýunless otherwise noted. Ìý

Courses and milestones designated as critical (marked with !) must be completed in the semester listed to ensure a timely graduation. Transfer credit may change the roadmap.

This roadmap should not be used in the place of regular academic advising appointments. All students are encouraged to meet with their advisor/mentor each semester. Requirements, course availability and sequencing are subject to change.

Plan of Study Grid
Year One
FallCredits
³§·¡Ìý1700
&²¹³¾±è;Ìý³§·¡Ìý1701
Engineering Fundamentals
and Engineering Fundamentals Studio
3
°ä±á·¡²ÑÌý1110
&²¹³¾±è;Ìý°ä±á·¡²ÑÌý1115
General Chemistry 1
and General Chemistry 1 Laboratory
4
COREÌý1500 Cura Personalis 1: Self in Community 1
COREÌý1600 Ultimate Questions: Theology 3
²Ñ´¡°Õ±áÌý1510 Calculus I (Critical course: Ìýrequires proficiency exam; must earn a grade of C- or above) 4
COREÌý1900 Eloquentia Perfecta 1: Written and Visual Communication 3
ÌýCredits18
Spring
°ä³§°ä±õÌý1060 Introduction to Computer Science: Scientific Programming 3
²Ñ·¡±·³ÒÌý1011 Prototyping 1
²Ñ´¡°Õ±áÌý1520 Calculus II (must earn a grade of C- or above) 4
±Ê±á³Û³§Ìý1610
&²¹³¾±è;Ìý±Ê±á³Û³§Ìý1620
University Physics I
and University Physics I Laboratory
4
²Ñ·¡±·³ÒÌý2100³Ý Statics 3
COREÌý1200 Eloquentia Perfecta 2: Oral and Visual Communication 3
ÌýCredits18
Year Two
Fall
´¡·¡±·³ÒÌý2020 Introduction to Aero and Astro Engineering 1
²Ñ·¡±·³ÒÌý2310 Thermodynamics 3
±Ê±á³Û³§Ìý1630
&²¹³¾±è;Ìý±Ê±á³Û³§Ìý1640
University Physics II
and University Physics II Laboratory
4
²Ñ·¡±·³ÒÌý3105 Mechanics of Solids 3
COREEloquentia Perfecta: Creative Expression 1-3
²Ñ´¡°Õ±áÌý2530 Calculus III 4
ÌýCredits16-18
Spring
´¡·¡±·³ÒÌý3000 Performance 3
²Ñ·¡±·³ÒÌý2150 Dynamics 3
COREÌý3600 Ways of Thinking: Social and Behavioral Sciences 3
²Ñ·¡±·³ÒÌý3200 Fluid Dynamics 3
COREÌý2500 Cura Personalis 2: Self in Contemplation 0
²Ñ´¡°Õ±áÌý3550 Differential Equations 3
COREEquity and Global Identities: Global Interdependence 0-3
ÌýCredits15-18
Year Three
Fall
´¡·¡±·³ÒÌý3230 Compressible Flow 3
´¡·¡±·³ÒÌý3150 Astrodynamics 3
²Ñ·¡±·³ÒÌý3510³Ý Materials Science 3
²Ñ·¡±·³ÒÌý3110 Linear Vibrations 3
²Ñ·¡±·³ÒÌý3111 Mechanics Laboratory 1
²Ñ´¡°Õ±áÌý3270 Advanced Mathematics for Engineers 3
COREEquity and Global Identities:Identities in Context 0-3
ÌýCredits16-19
Spring
·¡°ä·¡Ìý1100 Electrical Engineering 101 2
·¡°ä·¡Ìý1200 Computer Engineering 101 2
´¡·¡±·³ÒÌý3240 Aerodynamics and Boundary Layer Flow 3
´¡·¡±·³ÒÌý3410 Analysis and Control of Linear Systems 3
COREÌý1700 Ultimate Questions: Philosophy 3
Technical Elective 1 3
ÌýCredits16
Year Four
Fall
´¡·¡±·³ÒÌý4004 Flight Vehicle Analysis and Design I 3
´¡·¡±·³ÒÌý4110 Flight Vehicle Structures 3
´¡·¡±·³ÒÌý4400 Stability and Control 3
´¡·¡±·³ÒÌý4210 Propulsion 3
Technical Elective 1 3
´¡·¡±·³ÒÌý4111 Aerospace Laboratory 1
COREEloquentia Perfecta: Writing Intensive 0-3
ÌýCredits16-19
Spring
´¡·¡±·³ÒÌý4014 Flight Vehicle Analysis and Design II 3
´¡·¡±·³ÒÌý3050 Design of Space Missions 3
Technical Elective 1 3
COREReflection-in-Action 0-3
COREÌý3400 Ways of Thinking: Aesthetics, History, and Culture 3
COREEquity and Global Identities: Dignity, Ethics, and a Just Society 0-3
ÌýCredits12-18
ÌýTotal Credits127-144
1

Acceptable technical electives are courses at the 4000 level in the area of program major or the 3000 level or above in allied disciplines. (Allied disciplines include courses in engineering other than student’s major, Mathematics – MATH, Computer Science – CSCI, Management – MGT, Pre-Law – PLS, Physics – PHYS, Chemistry – CHEM, and Biology – BIOL.) The student may also do an approved project or research independent study with a faculty member, or an approved internship with industry.

Ìý
Ìý

2+Â鶹ÊÓƵÏÂÔØ programs provide a guided pathway for students transferring from a partner institution.Ìý