MMF910 Numerical methods for ODEs Spring 24

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This PhD-level course is about numerical methods for solving ordinary differential equations. In addition to standard theory, such as convergence results etc., I shall put some emphasis on geometric structures and how to preserve them in the numerical solution (cf. geometric numerical integration).

The course comprises:

  • lectures/exercise sessions (about one per week),
  • mandatory exercises (to be handed in via Canvas),
  • individual course projects, handed in as a report and presented in class.

Suitable, general literature (more specific reading material will be given during the lectures and in the exercises):

  • [HLW-2006] Hairer, Wanner, and Lubich: Geometric Numerical Integration, Springer (2006)
  • [MQ-2006] McLachlan and Quispel: Geometric integrators for ODEs, J. Phys. A 39 (2006)

Program

The lectures are on Tuesdays at 13:15 in MV:H11, except: 

  • 6/2, which is left for self-studies since I'm in Pisa the whole week;
  • 13/2, where instead there is the licentiate presentation of Michael Roop at 10:00 in room Pascal.

Lectures

Day Content
16/1 Prequel to numerics: from Kepler to Poincaré
23/1 Basic ODE theory and ODE numerics
30/1 Convergence of numerical integrators
6/2, 13/2 Self-studies: Chapter II of [HLW-2006]
20/2 Review of integrators and symplecticity

 

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Exercises

Week Exercises
1 Read the paper "Kepler, Newton and numerical analysis".
2 Local existence and uniqueness
3-4 Convergence of the implicit midpoint method
4-5 Runge-Kutta exercises
6 Symplectic experiments

 

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Course summary:

Course Summary
Date Details Due