Exponential quadrature rules for problems with time-dependent fractional source

Abstract

In this manuscript, we propose newly-derived exponential quadrature rules for stiff linear differential equations with time-dependent fractional sources in the form h(tr), with 0<r<1 and h a sufficiently smooth function. To construct the methods, the source term is interpolated at collocation points by a suitable non-polynomial function, yielding to time marching schemes that we call Exponential Quadrature Rules for Fractional sources (EQRF). The error analysis is done in the framework of strongly continuous semigroups. Compared to classical exponential quadrature rules, which in our case of interest converge with order 1+r at most, we prove that the new methods may reach order 1+ r for proper choices of the collocation points. We also show that the proposed integrators can be written in terms of special instances of the Mittag--Leffler functions that we call fractional functions. Several numerical experiments demonstrate the theoretical findings and highlight the effectiveness of the approach.