EE-736 / 3 credits

Teacher(s): Faulwasser Timm, Jiang Yuning

Language: English

Remark: Next time: Spring 2026


Frequency

Every 2 years

Summary

This doctoral course provides an introduction to optimal control covering fundamental theory, numerical implementation and problem formulation for applications.

Content

  • Recap of finite dimensional optimization and numerical methods for optimization
  • Fundamentals of Caculus of variations and optimization in function spaces
  • Closed-loop and open loop optimal control
  • Calculus of variations and optimal control
  • Pontryagin's Maximum Principle
  • Numerical optimal control
  • Singular problems and minimum time control
  • Dissipativity and optimal control
  • Hamilton-Jacobi-Bellman equations
  • Sampled-data predictive control
  • Research outlook
  • Exercises: pen and paper, programming; depending on the individual knowledge of the students

Learning Outcomes

By the end of the course, the student must be able to:

  • Solve control problems arising in their research projects by means of optimal control approaches.

Assessment methods

Oral presentation.

Resources

Bibliography

  • LIBERZON, Daniel. Calculus of variations and optimal control theory: a concise introduction. Princeton university press, 2011

Moodle Link

In the programs

  • Number of places: 30
  • Exam form: Oral presentation (session free)
  • Subject examined: Optimal Control for Dynamic Systems
  • Lecture: 32 Hour(s)
  • Exercises: 12 Hour(s)
  • Type: optional
  • Number of places: 30
  • Exam form: Oral presentation (session free)
  • Subject examined: Optimal Control for Dynamic Systems
  • Lecture: 32 Hour(s)
  • Exercises: 12 Hour(s)
  • Type: mandatory

Reference week

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