A multi-domain spectral method for scalar and vectorial Poisson equations with non-compact sources

Abstract

We present a spectral method for solving elliptic equations which arise in general relativity, namely three-dimensional scalar Poisson equations, as well as generalized vectorial Poisson equations of the type N + λ ∇(∇· N) = S with λ = -1. The source can extend in all the Euclidean space R3, provided it decays at least as r-3. A multi-domain approach is used, along with spherical coordinates (r,θ,φ). In each domain, Chebyshev polynomials (in r or 1/r) and spherical harmonics (in θ and φ) expansions are used. If the source decays as r-k the error of the numerical solution is shown to decrease at least as N-2(k-2), where N is the number of Chebyshev coefficients. The error is even evanescent, i.e. decreases as (-N), if the source does not contain any spherical harmonics of index l≥ k -3 (scalar case) or l≥ k-5 (vectorial case).

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