aerospace engineering courses online free

We are constantly wonderstruck by jumbo jets, missile launchers and space shuttles; images of satellites orbiting the earth and distant planets beamed back to earth by super-intelligent probes continue to hold us in thrall. We owe it all to Aerospace Engineers – the true geniuses who put humankind and machines in space.

If you are seeking to learn about Aerospace Engineering Courses Online Free for the first time, the subject might seem overpowering for those who have not researched the subject before, but you are likely to be fascinated by the information you come across. 

Read more about Certification courses for aeronautical engineering, Mit aerospace engineering online course, Mit aerospace engineering online course, Online aerospace engineering bachelors degree . You can also find articles related to How to learn aerospace engineering on your own on collegelearners.

Aerospace Engineering Courses Online Free

Have you ever flown in an airplane and are you curious about how flying works? Are you interested in the fundamental concepts behind flying? How does a wing generate lift? And how can we fly as optimally as possible?

This course provides an introduction to the fundamentals of aeronautics, using a tour through the history of flight, starting with ballooning and continuing on to airplanes and helicopters.

Experts from the Faculty of Aerospace Engineering of Delft University of Technology will help you explore and discover the fundamentals of flight, in three blocks. First, you will explore the history of flight including ballooning and obtain a basic understanding of aircraft and the earth’s atmosphere. Topics include stability, navigation, propulsion and the structure of aircraft. Block two examines the principles of aerodynamics. You will learn for instance how the shape of an airfoil or wing impacts the amount of lift generated. Block three covers flight mechanics, including various flight phases, such as descending, climbing or cruise, and the most optimal flying conditions for each phase.

At a glance

  • Institution: DelftX
  • Subject: Engineering
  • Level: Introductory
  • Prerequisites:High school level mathematics & physics
  • Language: English
  • Video Transcript: English

What you’ll learn

  • The impact of the history of flight on aircraft today.
  • How the earth’s atmosphere can be modelled and how we can use this for aircraft design.
  • Stability, structures, navigation and propulsion of aircraft.
  • The fundamental aerodynamic concepts for flying an aircraft.
  • How airfoils and wings generate lift.
  • Flight mechanics of aircraft.
  • How aircraft can optimally climb, descend and cruise.

Taught by

Jacco M. Hoekstra

Free Online Aerospace Engineering Courses

  • Advanced Control System Design. Indian Institute of Science Bangalore. …
  • Aero elasticity. …
  • Foundation of Scientific Computing. …
  • High Speed Aero Dynamics. …
  • Instability and Transition of Fluid Flows. …
  • Introduction to Aerodynamics. …
  • Introduction to Helicopter Aerodynamics & Dynamics. …
  • Optimal Control, Guidance and Estimation.

certification courses for aeronautical engineering

Aerospace Engineering at Illinois offers specialized certificates to best fit your interests.

  • Aerodynamics and Flight Mechanics
  • Aerospace Design and Systems Engineering
  • Aerospace Materials
  • Aerospace Structural Mechanics
  • Hypersonics
  • Spaceflight Engineering

Students enrolled in University of Illinois’ online and on-campus programs may apply for the certificate program. Students not enrolled at the University of Illinois may apply to take courses non-degree. Complete information about online registration, tuition and fees, etc. may be found on the Engineering Online website.

  • Online Course Registration
  • Online MS in Aerospace Engineering
  • Aerospace Graduate Degree Programs

Application Requirements

Students who are eligible to enroll in these certificate programs are:

  • Current AE graduate students

OR

  • Nondegree students that have:
    • BS degree in engineering or science from an accredited college in the United States or an approved institution of higher learning abroad. Basic background knowledge in the area of Aerospace Engineering is required for success in this certificate. Students with a non-engineering BS must have acquired this knowledge through coursework and/or through professional experience in order to qualify.
    • GPA of 3.0/4.0 or higher for the last 60 semester hours in a BS program. Students who do not meet the 3.0/4.0 GPA criterion may still be eligible to enroll if they have significant experience outside of the classroom. Such students are encouraged to contact us at aerospace@illinois.edu to determine if they are eligible to register for online classes and to participate in the certificate program.

Program Details

  • Students wanting a certificate must fill out an application form declaring this intent before enrollment in the last course to be counted towards the certificate.
  • Please email the completed application form along with your transcripts and current cv to ae-grad@illinois.edu. Please include the courses you plan to take in your email.
  • Students must earn a B or higher in each course. Courses cannot be applied to multiple certificates. However, courses taken while pursuing certificates can be applied toward the MS AE degree. Up to 12 hours of coursework taken by non-degree students and/or those pursuing certificates can be transferred into the MS AE degree. A separate application is needed for the MS AE program.

Graduate Certificate in Aerodynamics and Flight Mechanics

Aerodynamics and Flight Mechanics are among the most basic aspect of Aerospace Engineering. The aerospace engineering faculty includes world-class experts in both theoretical and practical aspects of aerodynamics and flight mechanics. This certificate requires students to complete graduate-level courses for 12 credit hours in the area of Aerodynamics and Flight Mechanics. Courses that can be applied toward this certificate are the following:

AE 410: Computational Aerodynamics (4 credit hours)
AE 412:  Viscous Flow & Heat Transfer (4 credit hours)
AE 416: Applied Aerodynamics (4 credit hours)
AE 419: Flight Mechanics (4 credit hours)
AE 451: Aeroelasticity (4 credit hours)
AE 515: Wing Theory (4 credit hours)

Graduate Certificate in Aerospace Materials

The Aerospace Engineering Department has a long tradition in Aerospace Materials and Aerospace Structures (see the next certificate). For many years the department has housed a Composite Materials Center, which is now being expanded, and also has introduced an Autonomic Materials center housed at Beckman Institute. The Department also has strong links with Mechanical, Civil, and Theoretical and Applied Mechanics faculty in these areas. As advanced materials, especially composites and high temperature materials, become more commonplace in Aerospace Engineering the “Aerospace Materials” certificate becomes very relevant.

Certificate Requirements

This certificate requires students to complete graduate-level courses for 12 credit hours in the area of Aerospace Materials. Courses that can be applied toward this certificate are the following:

AE 427: Mechanics of Polymers (3 credit hours)
AE 428: Mechanics of Composites (3 credit hours)
AE 522: Dynamic Response of Materials (4 credit hours)
AE 525: Advanced Composite Materials (4 credit hours)
AE 526: Composites Manufacturing (4 credit hours)
AE 527: Multi-scale Modeling of Materials (4 credit hours)
AE 529: Viscoelasticity Theory (4 credit hours)
 

Graduate Certificate in Aerospace Structural Mechanics

The Certificate in Aerospace Structural Mechanics is geared towards practicing engineers who wish to gain additional technical expertise in aircraft structures. The aircraft structures group at Illinois boasts among the largest research and graduate education program of its kind in the US. This comprehensive program has world-class faculty, a broad-based, cutting-edge research portfolio, and strong ties to industry and government agencies. Our Aerospace Structural Mechanics courses are kept up-to-date with the latest developments in materials, design, specifications, and sustainability engineering practices.

Certificate Requirements

This certificate requires students to complete three graduate-level courses for 12 credit hours in the area of Aerospace Structural Mechanics. Each of the three selected courses must be taken for 4 credit hours. Courses that can be applied toward this certificate are the following:

AE 420: Finite Element Analysis (3 or 4 credit hours)
AE 451: Aeroelasticity (3 or 4 credit hours)
AE 521: Fracture and Fatigue (4 credit hours)
AE 522: Dynamic Response of Materials (4 credit hours)
AE 523: Nanoscale Contact Mechanics (4 credit hours)
AE 528: Nonlinear Continuous Media (4 credit hours)
AE 550: Nonlinear Aeroelasticity (4 credit hours)

Graduate Certificate in Spaceflight Engineering

Spaceflight Engineering is among one of the most requested certificates and concentrations for which we received requests. The Aerospace Engineering department has developed a worldwide reputation for excellence in Astrodynamics and Orbital Mechanics with pioneering studies being performed here, as well as development of widely used theories and textbooks. Thus the Aerospace Engineering faculty at Illinois offers unequalled expertise in all aspects of spaceflight engineer making this a natural certificate program to form in this department. The Certificate in Spaceflight Engineering is geared towards practicing engineers who wish to gain additional technical expertise across a wide range of Space Science topics.

Certificate Requirements

This certificate requires students to complete three or four graduate-level courses for at least 12 credit hours in the area of Spaceflight Engineering. Courses that can be applied toward this certificate are the following:

AE 402: Orbital Mechanics (3 or 4 credit hours)
AE 403: Spacecraft Attitude Control (3 or 4 credit hours)
AE 446: Cube Sat. (new AE number for ENG491) (1 to 4 credit hours)
AE 502: Advanced Orbital Mechanics (4 credit hours)
AE 504: Optimal Aerospace Systems (4 credit hours)
AE 508: Optimal Space Trajectories (4 credit hours)

Graduate Certificate in Aerospace Design and Systems Engineering

Aerospace systems are highly integrated and complex, and therefore they present unique challenges from a design perspective. It is critical that aerospace engineers are well versed in the principles of design and systems engineering in order to create and manage aircraft and space systems whose components work in synergy to provide strong performance over their full life cycle. The certificate in Aerospace Design and Systems Engineering provides students with a strong foundation in the fundamentals of engineering design methods and systems engineering for aerospace applications. Students will be introduced to the basics of this subject area, as well as emerging topics that are highly relevant to the aerospace industry such as computational design optimization, design for additive manufacturing, and machine learning. Students will be required to complete 12 credit hours from a selection of the following courses:

AE 598: Nonlinear Solid Mech Design (4 credit hours)
AE 498: Structural Design Optimization (4 credit hours)
AE 498: Comp Methods for Sys Engr (4 credit hours)
AE 504: Optimal Aerospace Systems (4 credit hours)
AE 542: Aerospace Systems Engineering I (4 credit hours)
AE 543: Aerospace Systems Engineering II (4 credit hours)

Graduate Certificate in Hypersonics

Hypersonics flight systems are at the forefront of modern national security,  transportation and space exploration. In designing hypersonic vehicles, aerospace engineers face tremendous challenges associated with extreme aerodynamics, thermochemistry, advanced high temperature materials and rapid control. The Department of Aerospace Engineering is home of the Nation’s finest scholars in hypersonics research. Two vibrant centers, the Center for Hypersonics and Entry System Studies (CHESS) and the Center for Exascale Enabled Scramjet Design (CEESD), coordinate hypersonics research and education across The Grainger College of Engineering. This certificate is designed to provide students with the fundamentals of this multidisciplinary subject area, with attention to emerging topics and advances in hypersonic science and technology.

AE 498: Hypersonic Aerothermodynamics (4 credit hours)
AE 451: Aeroelasticity (4 credit hours)
AE 510: Advanced Gas Dynamics (4 credit hours)
AE 512: Molecular Gas Dynamics (4 credit hours)
AE 514: Boundary Layer Theory (4 credit hours)
AE 598: Planetary Entry (4 credit hours)
ME 598-KS: Dynamics of Gas/Plasma-Surface Interactions (4 credit hours)

mit aerospace engineering online course

A woman and two men examine and take measurements of a model jet inside a wind tunnel.

Professors, students, and researchers come to MIT from all corners of the globe to explore their passion for air and space travel and to advance the technologies and vehicles that make such travel possible.

We build on our long tradition of scholarship and research to develop and implement reliable, safe, economically feasible, and environmentally responsible air and space travel.

Our industry contributions and collaborations are extensive. We have graduated more astronauts than any other private institution in the world. Nearly one-third of our current research collaborations are with MIT faculty in other departments, and approximately one-half are with non-MIT colleagues in professional practice, government agencies, and other universities. We work closely with scientists and scholars at NASA, Boeing, the U.S. Air Force, Stanford University, Lockheed Martin, and the U.S. Department of Transportation.

Our educational programs are organized around three overlapping areas:

Aerospace information engineering
Focuses on real-time, safety-critical systems with humans-in-the-loop. Core disciplines include autonomy, software, communications, networks, controls, and human-machine and human-software interaction.

Aerospace systems engineering
Explores the central processes in the creation, implementation, and operation of complex socio-technical engineering systems. Core disciplines include system architecture and engineering, simulation and modeling, safety and risk management, policy, economics, and organizational behavior.

Aerospace vehicles engineering
Addresses the engineering of air and space vehicles, their propulsion systems, and their subsystems. Core disciplines include fluid and solid mechanics, thermodynamics, acoustics, combustion, controls, computation, design, and simulation.

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