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Second-order LOD multigrid method for multidimensional Riesz fractional diffusion equation

Numerical Analysis 2014-09-22 v1

Abstract

We propose a locally one dimensional (LOD) finite difference method for multidimensional Riesz fractional diffusion equation with variable coefficients on a finite domain. The numerical method is second-order convergent in both space and time directions, and its unconditional stability is strictly proved. Comparing with the popular first-order finite difference method for fractional operator, the form of obtained matrix algebraic equation is changed from (IA)uk+1=uk+bk+1(I-A)u^{k+1}=u^k+b^{k+1} to (IA~)uk+1=(I+B~)uk+b~k+1/2(I-{\widetilde A})u^{k+1}=(I+{\widetilde B})u^k+{\tilde b}^{k+1/2}; the three matrices AA, A~{\widetilde A} and B~{\widetilde B} are all Toeplitz-like, i.e., they have completely same structure and the computational count for matrix vector multiplication is O(NlogN)\mathcal{O}(N {log} N); and the computational costs for solving the two matrix algebraic equations are almost the same. The LOD-multigrid method is used to solve the resulting matrix algebraic equation, and the computational count is O(NlogN)\mathcal{O}(N {log} N) and the required storage is O(N)\mathcal{O}(N), where NN is the number of grid points. Finally, the extensive numerical experiments are performed to show the powerfulness of the second-order scheme and the LOD-multigrid method.

Keywords

Cite

@article{arxiv.1301.2643,
  title  = {Second-order LOD multigrid method for multidimensional Riesz fractional diffusion equation},
  author = {Minghua Chen and Yantao Wang and Xiao Cheng and Weihua Deng},
  journal= {arXiv preprint arXiv:1301.2643},
  year   = {2014}
}

Comments

26 pages

R2 v1 2026-06-21T23:08:11.831Z