English

An adaptive fast multipole accelerated Poisson solver for complex geometries

Numerical Analysis 2017-05-24 v1

Abstract

We present a fast, direct and adaptive Poisson solver for complex two-dimensional geometries based on potential theory and fast multipole acceleration. More precisely, the solver relies on the standard decomposition of the solution as the sum of a volume integral to account for the source distribution and a layer potential to enforce the desired boundary condition. The volume integral is computed by applying the FMM on a square box that encloses the domain of interest. For the sake of efficiency and convergence acceleration, we first extend the source distribution (the right-hand side in the Poisson equation) to the enclosing box as a C0C^0 function using a fast, boundary integral-based method. We demonstrate on multiply connected domains with irregular boundaries that this continuous extension leads to high accuracy without excessive adaptive refinement near the boundary and, as a result, to an extremely efficient "black box" fast solver.

Keywords

Cite

@article{arxiv.1610.00823,
  title  = {An adaptive fast multipole accelerated Poisson solver for complex geometries},
  author = {Travis Askham and Antoine J Cerfon},
  journal= {arXiv preprint arXiv:1610.00823},
  year   = {2017}
}

Comments

31 pages

R2 v1 2026-06-22T16:09:36.465Z