Open AccessAn Adaptive Moving Mesh Method for Forced Curve Shortening Flow
Author(s) -
J.A. Mackenzie,
M. Nolan,
Christopher Rowlatt,
Robert H. Insall
Publication year - 2019
Publication title -
siam journal on scientific computing
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.674
H-Index - 147
eISSN - 1095-7197
pISSN - 1064-8275
DOI - 10.1137/18m1211969
Subject(s) - equidistributed sequence , mathematics , polygon mesh , discretization , curvature , flow (mathematics) , measure (data warehouse) , adaptive mesh refinement , mathematical analysis , algorithm , geometry , computer science , computational science , database
We propose a novel adaptive moving mesh method for the numerical solution of a forced curve shortening geometric evolution equation. Control of the mesh quality is obtained using a tangential mesh velocity derived from a mesh equidistribution principle, where a positive adaptivity measure or monitor function is approximately equidistributed along the evolving curve. Central finite differences are used to discretize in space the governing evolution equation for the position vector, and a second-order implicit scheme is used for the temporal integration. Simulations are presented indicating the generation of meshes which resolve areas of high curvature and are of second-order accuracy. Furthermore, the new method delivers improved solution accuracy compared to the use of uniform arc-length meshes.
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