Summation by parts methods for the spherical harmonic decomposition of the wave equation in arbitrary dimensions

Abstract

We investigate numerical methods for wave equations in n+2 spacetime dimensions, written in spherical coordinates, decomposed in spherical harmonics on Sn, and finite-differenced in the remaining coordinates r and t. Such an approach is useful when the full physical problem has spherical symmetry, for perturbation theory about a spherical background, or in the presence of boundaries with spherical topology. The key numerical difficulty arises from lower-order 1/r terms at the origin r=0. As a toy model for this, we consider the flat space linear wave equation in the form π=ψ'+pψ/r, ψ=π', where p=2l+n, and l is the leading spherical harmonic index. We propose a class of summation by parts (SBP) finite differencing methods that conserve a discrete energy up to boundary terms, thus guaranteeing stability and convergence in the energy norm. We explicitly construct SBP schemes that are second and fourth-order accurate at interior points and the symmetry boundary r=0, and first and second-order accurate at the outer boundary r=R.