Integrating angular and domain decomposition with space-angle discontinuous Galerkin methods in 2D radiative transfer

A space-angle discontinuous Galerkin (saDG) method is used to solve the steady-state radiative transfer equation (RTE) for 2D problems involving absorption, emission, and scattering for a semitransparent medium. This approach discretizes both spatial and angular domains. Parallel computing is based...

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Bibliographic Details
Published in:Journal of quantitative spectroscopy & radiative transfer 2024-12, Vol.329, p.109208, Article 109208
Main Authors: Wang, Hang, Haque, Md Ershadul, Abedi, Reza, Mudaliar, Saba
Format: Article
Language:English
Subjects:
Angular decomposition
Discontinuous Galerkin method
Domain decomposition
MUMPS
Parallel computing
Radiative transfer equation
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Summary:A space-angle discontinuous Galerkin (saDG) method is used to solve the steady-state radiative transfer equation (RTE) for 2D problems involving absorption, emission, and scattering for a semitransparent medium. This approach discretizes both spatial and angular domains. Parallel computing is based on angular decomposition (AD), and domain decomposition (DD) techniques. The DD technique directly solves the entire domain using the MUMPS library, whereas the AD technique results in an iterative approach for scattering media. This study proposes a novel hybrid AD-DD method, combining the best aspects of both techniques. Numerical results investigate the scalability, performance, and efficiency of AD and DD techniques. It is shown that a hybrid AD-DD technique is superior to these individual techniques by taking advantage of their strengths. Numerical methods demonstrate the applicability of the method of the best combination of hybrid AD-DD to 2D scattering gray media with complex geometries or enclosures with circular and square obstacles. •RTE fully discretizes both spatial and angular domains.•Proposed a parallel implementations of a saDG formulation for AD and DD.•Developed an innovative hybrid AD-DD technique.•Investigated the strong scaling performance for AD, DD and hybrid AD-DD.•The hybrid technique is more efficient than the individual technique.
ISSN:0022-4073
DOI:10.1016/j.jqsrt.2024.109208