Mechanical Engineering

About this course

The course describes basic aeroelastic phenomena arising from the mutual interaction of elastic, aerodynamic and inertial forces on a structure, with special emphasis on problems related to fixed wing vehicles. Aeroelasticity plays a major role in the design, qualification and certification of flying vehicles, as it contributes to the definition of the flight envelope and affects various performance indicators. The course is organized according to the following plan: • Introduction: why aeroelasticity matters, basic concepts in aeroelasticity, examples (including the role of aeroelasticity beyond aeronautical engineering). • Static aeroelasticity: divergence speed; lift distribution over straight and swept flexible wings; aileron effectiveness and reversal. • Dynamic aeroelasticity: vibrations of beams and mode coalescence; flutter; transient response, including gust response.

Learning outcomes

After successfully completing the course, the student will be able to: • Comprehend typical aeroelastic problems, understanding the physical principles at play; • Appreciate the role of aeroelasticity in the design of flying vehicles; • Derive simple models for the description of basic static and dynamic aeroelastic problems, accounting for all relevant forces; • Use the models for making quantitative predictions on the insurgence of important aeroelastic phenomena, such as divergence and flutter; • Understand the limits of the simple methods used in the course, and appreciate how more sophisticated approaches for practical engineering applications are developed.


Students will be evaluated based on the final examination.

Course requirements

Mechanics and aerodynamics.


Learning method: In addition to the individual methods of the students, consolidated knowledge is aspired by repeated lessons in exercises and tutorials. Teaching method: During the lectures students are instructed in a teacher-centered style. The exercises are held in a student-centered way

Additional information

  • Credits
    ECTS 5
  • Contact hours per week
  • Instructors
    Anik Hirenkumar Shah, Johannes Schreiber, Carlo Rosario Sucameli, Carlo Bottasso, Stefano Cacciola, Marta Bertele, Andreas Vad, Emmanouil Nanos
  • Mode of instruction
If anything remains unclear, please check the FAQ of TUM (Germany).


  • Start date

    14 October 2024

    • Ends
      7 February 2025
    • Term *
      Winter 2024/2025
    • Instruction language
    • Register between
      24 May - 29 Jul 2024
    Only 7 days to enrol
    Apply now
These offerings are valid for students of DTU (Denmark)