Angular Multigrid Preconditioner for Krylov-Based Solution Techniques Applied to the S n Equations with Highly Forward-Peaked Scattering

Bruno Turcksin, Jean C. Ragusa, Jim E. Morel

Research output: Contribution to journalArticlepeer-review

16 Scopus citations

Abstract

It is well known that the diffusion synthetic acceleration (DSA) methods for the S n equations become ineffective in the Fokker-Planck forward-peaked scattering limit. In response to this deficiency, Morel and Manteuffel (1991) developed an angular multigrid method for the 1-D S n equations. This method is very effective, costing roughly twice as much as DSA per source iteration, and yielding a maximum spectral radius of approximately 0.6 in the Fokker-Planck limit. Pautz, Adams, and Morel (PAM) (1999) later generalized the angular multigrid to 2-D, but it was found that the method was unstable with sufficiently forward-peaked mappings between the angular grids. The method was stabilized via a filtering technique based on diffusion operators, but this filtering also degraded the effectiveness of the overall scheme. The spectral radius was not bounded away from unity in the Fokker-Planck limit, although the method remained more effective than DSA. The purpose of this article is to recast the multidimensional PAM angular multigrid method without the filtering as an S n preconditioner and use it in conjunction with the Generalized Minimal RESidual (GMRES) Krylov method. The approach ensures stability and our computational results demonstrate that it is also significantly more efficient than an analogous DSA-preconditioned Krylov method.

Original languageEnglish
Pages (from-to)1-22
Number of pages22
JournalTransport Theory and Statistical Physics
Volume41
Issue number1-2
DOIs
StatePublished - Jan 2012
Externally publishedYes

Keywords

  • S equation
  • angular multigrid method
  • highly forward-peaked scattering
  • preconditioned Krylov techniques

Fingerprint

Dive into the research topics of 'Angular Multigrid Preconditioner for Krylov-Based Solution Techniques Applied to the S n Equations with Highly Forward-Peaked Scattering'. Together they form a unique fingerprint.

Cite this