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Introduction to the calculus of variations (SoSe 25)

Description:

The calculus of variation is, to put it simply, the study of critical points of functionals (functions of functions), which is often used in minimization problems. It connects many domains of mathematics such as PDEs, functional analysis, geometry,... and finds applications in a wide variety of physical problems such as in the determination of geodesics (minimizing distances), minimal surfaces, in classical and quantum mechanics (minimizing energies) etc. In this course, we will discuss both the theory and and the applications to some (and more) of the aforementioned problems.

Content:

• Finite dimensional case (minimizing functions on a vector space or on a manifold).
• The classical method: analyzing the critical points when their exist.
• Hamiltonian formulation
• The direct method: proof of existence of critical points.

Audience:

Credits:

Schedule:

- Lectures: Wednesday 12:00-14:00 in Room B133 and Thursday 10:00-12:00 in Room B046

References:

• B. van Brunt, The Calculus of Variations, Universitext, Springer, 2004
• B. Dacorogna, Introduction to the Calculus of Variations. Imperial College Press, 2004
• P. Blanchard, E. Brüning, Variational Methods in Mathematical Physics: A unified approach, Springer, 1992
• L.C. Evans, Partial Differential Equations, AMS, 1998
• M. Lewin, Describing lack of compactness in Sobolev spaces, unpublished lecture notes "Variational Methods in Quantum Mechanics", 2010, Université de Cergy-Pontoise
• E. H. Lieb, M. Loss, Analysis, Graduate studies in mathematics, AMS, 2001
• D. Gilbarg, N.S. Trudinger, Elliptic partial differential equations of second order. Vol. 224. No. 2. Berlin: springer, 1977.
• V.I. Arnold, Mathematical Methods of Classical Mechanics, Springer, 1989
• D. Cioranescu, P. Donato, An introduction to Homogeneization, Oxford University Press, 2000