Optimization-based fluid simulation on unstructured meshes

Marek Krzysztof Misztal; Robert Bridson; Kenny Erleben; Jakob Andreas Bærentzen; Francois Anton

doi:10.2312/PE/vriphys/vriphys10/011-020

Optimization-based fluid simulation on unstructured meshes

Marek Krzysztof Misztal, Robert Bridson, Kenny Erleben, Jakob Andreas Bærentzen, Francois Anton

Datalogisk Institut

24 Citationer (Scopus)

Abstract

We present a novel approach to fluid simulation, allowing us to take into account the surface energy in a pre- cise manner. This new approach combines a novel, topology-adaptive approach to deformable interface track- ing, called the deformable simplicial complexes method (DSC) with an optimization-based, linear finite element method for solving the incompressible Euler equations. The deformable simplicial complexes track the surface of the fluid: the fluid-air interface is represented explicitly as a piecewise linear surface which is a subset of tetra- hedralization of the space, such that the interface can be also represented implicitly as a set of faces separating tetrahedra marked as inside from the ones marked as outside. This representation introduces insignificant and con- trollable numerical diffusion, allows robust topological adaptivity and provides both a volumetric finite element mesh for solving the fluid dynamics equations as well as direct access to the interface geometry data, making in- clusion of a new surface energy term feasible. Furthermore, using an unstructured mesh makes it straightforward to handle curved solid boundaries and gives us a possibility to explore several fluid-solid interaction scenarios.

Originalsprog	Engelsk
Titel	Workshop in Virtual Reality Interactions and Physical Simulation "VRIPHYS" (2010)
Redaktører	Kenny Erleben, Jan Bender, Matthias Teschner
Antal sider	10
Forlag	Eurographics Association
Publikationsdato	2010
Sider	11-20
ISBN (Trykt)	978-3-905673-78-4
DOI	https://doi.org/10.2312/PE/vriphys/vriphys10/011-020
Status	Udgivet - 2010
Begivenhed	7th Workshop on Virtual Reality Interaction and Physical Simulation - Københavns Universitet, København, Danmark Varighed: 11 nov. 2010 → 12 nov. 2010 Konferencens nummer: 7

Konference

Konference	7th Workshop on Virtual Reality Interaction and Physical Simulation
Nummer	7
Lokation	Københavns Universitet
Land/Område	Danmark
By	København
Periode	11/11/2010 → 12/11/2010

Adgang til dokumentet

10.2312/PE/vriphys/vriphys10/011-020

Misztal_2010_Optimization-based_fluidForlagets udgivne version, 2,6 MB

Citationsformater

Optimization-based fluid simulation on unstructured meshes. / Misztal, Marek Krzysztof; Bridson, Robert; Erleben, Kenny et al.

Workshop in Virtual Reality Interactions and Physical Simulation "VRIPHYS" (2010). red. / Kenny Erleben; Jan Bender; Matthias Teschner. Eurographics Association, 2010. s. 11-20.

Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › peer review

Misztal, MK, Bridson, R, Erleben, K, Bærentzen, JA & Anton, F 2010, Optimization-based fluid simulation on unstructured meshes. i K Erleben, J Bender & M Teschner (red), Workshop in Virtual Reality Interactions and Physical Simulation "VRIPHYS" (2010). Eurographics Association, s. 11-20, 7th Workshop on Virtual Reality Interaction and Physical Simulation, København, Danmark, 11/11/2010. https://doi.org/10.2312/PE/vriphys/vriphys10/011-020

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abstract = "We present a novel approach to fluid simulation, allowing us to take into account the surface energy in a pre- cise manner. This new approach combines a novel, topology-adaptive approach to deformable interface track- ing, called the deformable simplicial complexes method (DSC) with an optimization-based, linear finite element method for solving the incompressible Euler equations. The deformable simplicial complexes track the surface of the fluid: the fluid-air interface is represented explicitly as a piecewise linear surface which is a subset of tetra- hedralization of the space, such that the interface can be also represented implicitly as a set of faces separating tetrahedra marked as inside from the ones marked as outside. This representation introduces insignificant and con- trollable numerical diffusion, allows robust topological adaptivity and provides both a volumetric finite element mesh for solving the fluid dynamics equations as well as direct access to the interface geometry data, making in- clusion of a new surface energy term feasible. Furthermore, using an unstructured mesh makes it straightforward to handle curved solid boundaries and gives us a possibility to explore several fluid-solid interaction scenarios. ",

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