English

Lagrange Discrete Ordinates: a new angular discretization for the three dimensional linear Boltzmann equation

Computational Physics 2014-05-16 v1

Abstract

The classical SnS_n equations of Carlson and Lee have been a mainstay in multi-dimensional radiation transport calculations. In this paper, an alternative to the SnS_n equations, the "Lagrange Discrete Ordinate" (LDO) equations are derived. These equations are based on an interpolatory framework for functions on the unit sphere in three dimensions. While the LDO equations retain the formal structure of the classical SnS_n equations, they have a number of important differences. The LDO equations naturally allow the angular flux to be evaluated in directions other than those found in the quadrature set. To calculate the scattering source in the LDO equations, no spherical harmonic moments are needed--only values of the angular flux. Moreover, the LDO scattering source preserves the eigenstructure of the continuous scattering operator. The formal similarity of the LDO equations with the SnS_n equations should allow easy modification of mature 3D SnS_n codes such as PARTISN or PENTRAN to solve the LDO equations. Numerical results are shown that demonstrate the spectral convergence (in angle) of the LDO equations for smooth solutions and the ability to mitigate ray effects by increasing the angular resolution of the LDO equations.

Keywords

Cite

@article{arxiv.1405.3968,
  title  = {Lagrange Discrete Ordinates: a new angular discretization for the three dimensional linear Boltzmann equation},
  author = {Cory D. Ahrens},
  journal= {arXiv preprint arXiv:1405.3968},
  year   = {2014}
}

Comments

Submitted to Nuclear Science and Engineering

R2 v1 2026-06-22T04:15:21.738Z