A square entropy stable flux limiter for PNPM schemes

Abstract

We study some theoretical aspects of PNPM schemes, which are a novel class of high order accurate reconstruction based discontinuous Galerkin (DG) schemes for hyperbolic conservation laws. The PNPM schemes store and evolve the discrete solution uh under the form of piecewise polynomials of degree N, while piecewise polynomials wh of degree M ≥ N are used for the computation of the volume and boundary fluxes. The piecewise polynomials wh are obtained from uh via a suitable reconstruction or recovery operator. The PNPM approach contains high order finite volume methods (N=0) as well as classical DG schemes (N=M) as special cases of a more general framework. Furthermore, for N ≠ M and N>0, it leads to a new intermediate class of methods, which can be denoted either as Hermite finite volume or as reconstructed DG methods. We show analytically why PNPM methods for N ≠ M are, in general, not L2-diminishing. To this end, we extend the well-known cell entropy inequality and the following L2 stability result of Jiang and Shu for DG methods (i.e. for N=M) to the general PNPM case and identify which part in the reconstruction step may cause the instability. With this insight we design a flux limiter that enforces a cell square entropy inequality and thus an L2 stability condition for PNPM schemes for scalar conservation laws in one space dimension. Furthermore, in this paper we prove existence and uniqueness of the solution of the PNPM reconstruction operator.