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

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 (I-A)uk+1=uk+bk+1 to (I- A)uk+1=(I+ B)uk+ bk+1/2; the three matrices A, A and B are all Toeplitz-like, i.e., they have completely same structure and the computational count for matrix vector multiplication is 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(N log N) and the required storage is O(N), where N 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.