A contribution to the particle modeling of soap films
Applied Mathematics and Computation
Computing minimal surfaces via level set curvature flow
Journal of Computational Physics
The discrete plateau problem: algorithm and numerics
Mathematics of Computation
Accurate interface-tracking for arbitrary Lagrangian-Eulerian schemes
Journal of Computational Physics
| Hi-index | 31.45 |
We present an algorithm for finding high order numerical approximations of minimal surfaces with a fixed boundary. The algorithm employs parametrization by high order polynomials and a linearization of the weak formulation of the Laplace-Beltrami operator to arrive at an iterative procedure to evolve from a given initial surface to the final minimal surface. For the steady state solution we measure the approximation error in a few cases where the exact solution is known. In the framework of parametric interpolation, the choice of interpolation points (mesh nodes) is directly affecting the approximation error, and we discuss how to best update the mesh on the evolutionary surface such that the parametrization remains smooth. In our test cases we may achieve exponential convergence in the approximation of the minimal surface as the polynomial degree increases, but the rate of convergence greatly differs with different choices of mesh update algorithms. The present work is also of relevance to high order numerical approximation of fluid flow problems involving free surfaces.