MULTILEVEL TAU PRECONDITIONERS FOR SYMMETRIZED MULTILEVEL TOEPLITZ SYSTEMS WITH APPLICATIONS TO SOLVING SPACE FRACTIONAL DIFFUSION EQUATIONS

In this work, we develop a novel multilevel Tau matrix-based preconditioned method for a class of nonsymmetric multilevel Toeplitz systems. This method not only accounts for but also improves upon an ideal preconditioner pioneered by Pestana [SIAM J. Matrix Anal. Appl., 40 (2019), pp. 870--887]. The ideal preconditioning approach was primarily examined numerically in that study, and an effective implementation was not included. To address these issues, we first rigorously show in this study that this ideal preconditioner can indeed achieve optimal convergence when employing the minimal residual (MINRES) method, with a convergence rate that is independent of the mesh size. Then, building on this preconditioner, we develop a practical and optimal preconditioned MINRES method. To further illustrate its applicability and develop a fast implementation strategy, we consider solving Riemann--Liouville fractional diffusion equations as an application. Specifically, following standard discretization on the equation, the resultant linear system is a nonsymmetric multilevel Toeplitz system, affirming the applicability of our preconditioning method. Through simple symmetrization strategy, we transform the original linear system into a symmetric multilevel Hankel system. Subsequently, we propose a symmetric positive definite multilevel Tau preconditioner for the symmetrized system, which can be efficiently implemented using discrete sine transforms. Theoretically, we demonstrate that mesh-independent convergence can be achieved. In particular, we prove that the eigenvalues of the preconditioned matrix are bounded within disjoint intervals containing \pm 1, without any outliers. Numerical examples are provided to critically discuss the results, showcase the spectral distribution, and support the efficacy of our preconditioning strategy.