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Conference paper

Mathematical foundation of the optimization-based fluid animation method

In Sca '11 Proceedings of the 2011 Acm Siggraph/eurographics Symposium on Computer Animation — 2011, pp. 101-110

By Erleben, Kenny1; Misztal, Marek Krzysztof2,3; Bærentzen, Jakob Andreas2,3

Edited by Bargteil, A.; van de Panne, M.

From

University of Copenhagen1

Image Analysis and Computer Graphics, Department of Informatics and Mathematical Modeling, Technical University of Denmark2

Department of Informatics and Mathematical Modeling, Technical University of Denmark3

We present the mathematical foundation of a fluid animation method for unstructured meshes. Key contributions not previously treated are the extension to include diffusion forces and higher order terms of non-linear force approximations. In our discretization we apply a fractional step method to be able to handle advection in a numerically simple Lagrangian approach.

Following this a finite element method is used for the remaining terms of the fractional step method. The key to deriving a discretization for the diffusion forces lies in restating the momentum equations in terms of a Newtonian stress tensor. Rather than applying a straightforward temporal finite difference method followed by a projection method to enforce incompressibility as done in the stable fluids method, the last step of the fractional step method is rewritten as an optimization problem to make it easy to incorporate non-linear force terms such as surface tension.

Language: English
Publisher: ACM
Year: 2011
Pages: 101-110
Proceedings: 34th International Conference and Exhibition on Computer Graphics and Interactive Techniques
ISBN: 1450309232 and 9781450309233
Types: Conference paper
DOI: 10.1145/2019406.2019420
ORCIDs: 0000-0001-6808-4747 and Bærentzen, Jakob Andreas
Keywords

Computational Fluid Dynamics Deformable Simplicial Complexes Diffusion Forces Finite Element Method Optimizationbased Fluid Animation Unstructured Meshes

Other keywords

Animation Computer graphics Computing methodologies Continuous mathematics Design and analysis of algorithms Geometric topology Mathematical analysis Mathematical optimization Mathematics of computing Physical simulation Shape modeling Theory of computation Topology computational fluid dynamics computational fluid dynamics, deformable simplicial complexes, diffusion forces, finite element method, optimization-based fluid animation, unstructured meshes deformable simplicial complexes diffusion forces finite element method optimization-based fluid animation unstructured meshes

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