A fast solver for spectral element approximation applied to fractional differential equations using hierarchical matrix approximation

We develop a fast solver for the spectral element method (SEM) applied to the two-sided fractional diffusion equation on uniform, geometric and graded meshes. By approximating the singular kernel with a degenerate kernel, we construct a hierarchical matrix (H-matrix) to represent the stiffness matrix of the SEM and provide error estimates verified numerically. We can solve efficiently the H-matrix approximation problem using a hierarchical LU decomposition method, which reduces the computational cost to $O(R^2 N_d \log^2N) +O(R^3 N_d \log N)$, where $R$ it is the rank of submatrices of the H-matrix approximation, $N_d$ is the total number of degrees of freedom and $N$ is the number of elements. However, we lose the high accuracy of the SEM. Thus, we solve the corresponding preconditioned system by using the H-matrix approximation problem as a preconditioner, recovering the high order accuracy of the SEM. The condition number of the preconditioned system is independent of the polynomial degree $P$ and grows with the number of elements, but at modest values of the rank $R$ is below order 10 in our experiments, which represents a reduction of more than 11 orders of magnitude from the unpreconditioned system; this reduction is higher in the two-sided fractional derivative compared to one-sided fractional derivative. The corresponding cost is $O(R^2 N_d \log^2 N)+O(R^3 N_d \log N)+O(N_d^2)$. Moreover, by using a structured mesh (uniform or geometric mesh), we can further reduce the computational cost to $O(R^2 N_d\log^2 N) +O(R^3 N_d \log N)+ O(P^2 N\log N)$ for the preconditioned system. We present several numerical tests to illustrate the proposed algorithm using $h$ and $p$ refinements.