Error Profile for Discontinuous Galerkin Time Stepping of Parabolic PDEs

Abstract

We consider the time discretization of a linear parabolic problem by the discontinuous Galerkin (DG) method using piecewise polynomials of degree at most r-1 in t, for r1 and with maximum step size~k. It is well known that the spatial L2-norm of the DG error is of optimal order kr globally in time, and is, for r2, superconvergent of order k2r-1 at the nodes. We show that on the nth subinterval (tn-1,tn), the dominant term in the DG error is proportional to the local right Radau polynomial of degree r. This error profile implies that the DG error is of order kr+1 at the right-hand Gauss--Radau quadrature points in each interval. We show that the norm of the jump in the DG solution at the left end point tn-1 provides an accurate a posteriori estimate for the maximum error over the subinterval (tn-1,tn). Furthermore, a simple post-processing step yields a continuous piecewise polynomial of degree r with the optimal global convergence rate of order kr+1. We illustrate these results with some numerical experiments.