Experimenting with the p4est library for AMR simulations of two-phase flows

Experimenting with the p4est library for AMR simulations of two-phase flows

Many physical problems involve spatial and temporal inhomogeneities that require a very fine discretization in order to be accurately simulated. Using an adaptive mesh, a high level of resolution is used in the appropriate areas while keeping a coarse mesh elsewhere. This idea allows to save time an...

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Veröffentlicht in:ESAIM. Proceedings and surveys 2016-03, Vol.53, p.232-247
Hauptverfasser: Drui, Florence, Fikl, Alexandru, Kestener, Pierre, Kokh, Samuel, Larat, Adam, Le Chenadec, Vincent, Massot, Marc
Format: Artikel
Sprache:eng
Schlagworte:
Computer memory
Computer Science
Computer simulation
Discrete Mathematics
Distributed memory
Distributed, Parallel, and Cluster Computing
Finite element method
Fluid Dynamics
Libraries
Mathematical Physics
Mathematical Software
Mathematics
Modeling and Simulation
Multiphase
Numerical Analysis
Physics
Simulation
Two phase flow
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Zusammenfassung:Many physical problems involve spatial and temporal inhomogeneities that require a very fine discretization in order to be accurately simulated. Using an adaptive mesh, a high level of resolution is used in the appropriate areas while keeping a coarse mesh elsewhere. This idea allows to save time and computations, but represents a challenge for distributed-memory environments. The MARS project (for Multiphase Adaptative Refinement Solver) intends to assess the parallel library p4est for adaptive mesh, in a case of a finite volume scheme applied to two-phase flows. Besides testing the library’s performances, particularly for load balancing, its user-friendliness in use and implementation are also exhibited here. First promising 3D simulations are even presented. De nombreux problmes physiques mettent en jeu des inhomognits spatiales et temporelles, qui pour tre simules correctement requièrent une discrtisation très fine. Utiliser un maillage adaptatif pour obtenir ce niveau de rsolution dans les zones o elle est requise, et garder un maillage grossier en-dehors, permet d’intressantes conomies en temps et ressources de calcul, mais représente un défi pour le calcul distribué. Le projet MARS (Multiphase Adaptative Refinement Solver) a pour objectif d’évaluer la librairie parallèle de maillage adaptatif p4est, appliqueun schma de volumes finis pour un modèle bifluide d’écoulement diphasique. Outre les performances de cette librairie, en particulier en terme d’équilibrage de charge, sa facilit d’utilisation et d’implmentation sont mises en avant. Des premires simulations 3D prometteuses sont prsentes.
ISSN:2267-3059
2267-3059
DOI:10.1051/proc/201653014