Numerical Approximation of Fractional Powers of Elliptic Operators

Abstract

In this paper, we develop and study algorithms for approximately solving the linear algebraic systems: Ahαuh = fh, 0< α<1, for uh, fh ∈ Vh with Vh a finite element approximation space. Such problems arise in finite element or finite difference approximations of the problem Aαu=f with A, for example, coming from a second order elliptic operator with homogeneous boundary conditions. The algorithms are motivated by the recent method of Vabishchevich, 2015, that relates the algebraic problem to a solution of a time-dependent initial value problem on the interval [0,1]. Here we develop and study two time stepping schemes based on diagonal Padé approximation to (1+x)-α. The first one uses geometrically graded meshes in order to compensate for the singular behavior of the solution for t close to 0. The second algorithm uses uniform time stepping but requires smoothness of the data fh in discrete norms. For both methods, we estimate the error in terms of the number of time steps, with the regularity of fh playing a major role for the second method. Finally, we present numerical experiments for Ah coming from the finite element approximations of second order elliptic boundary value problems in one and two spatial dimensions.