An unconditionally stable finite element scheme for anisotropic curve shortening flow

Deckelnick, Klaus; Nürnberg, Robert

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An unconditionally stable finite element scheme for anisotropic curve shortening flow. (English). Archivum Mathematicum, vol. 59 (2023), issue 3, pp. 263-274

MSC: 35K15, 53E10, 65M12, 65M60 | MR 4563038 | Zbl 07675596 | DOI: 10.5817/AM2023-3-263

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Keywords:
anisotropic curve shortening flow; finite element method; stability

Summary:
Based on a recent novel formulation of parametric anisotropic curve shortening flow, we analyse a fully discrete numerical method of this geometric evolution equation. The method uses piecewise linear finite elements in space and a backward Euler approximation in time. We establish existence and uniqueness of a discrete solution, as well as an unconditional stability property. Some numerical computations confirm the theoretical results and demonstrate the practicality of our method.

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