WIAS Preprint No. 1073, (2005)

Random walk on fixed spheres method for electro- and elastostatics problems



Authors

  • Sabelfeld, Karl
  • Levykin, Alexander I.
  • Shalimova, Irina

2010 Mathematics Subject Classification

  • 65C05 65F10 65Z05

Keywords

  • Random Walk methods, stochastic iterative pprocedures, Lame equation, systems of spherical integral equations

DOI

10.20347/WIAS.PREPRINT.1073

Abstract

Stochastic algorithms for solving Dirichlet boundary value problems for the Laplace and Lame equations governing 2D elasticity problems are developed. The approach presented is based on the Poisson integral formula written for each disc of a domain consisting of a family of overlapping discs. The original differential boundary value problem is reformulated in the form of equivalent system of integral equations defined on the intersection surfaces, i.e., arcs in 2D. A Random Walk algorithm can be applied then directly to the obtained system of integral equations where the random walks are living on the intersecting surfaces. We develop also a discrete random walk technique for solving the system of linear equations approximating the system of integral equations. We construct a randomized version of the successive over relaxation (SOR) method. In [6] we have demonstrated that in the case of classical potential theory our method considerably improves the convergence rate of the standard Random Walk on Spheres method. In this paper we extend the algorithm to the system of Lame equations which cannot be solved by the conventional Random Walk on Spheres method. Illustrating computations for 2D Laplace and Lame equations, and comparative analysis of different stochastic algorithms are presented.

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