Constraint Fluids

Author

Bodin, Kenneth ; Lacoursié, Claude ; Servin, Martin

Author_Institution

Umed Univ., Umea, Sweden

Volume

18

Issue

3

fYear

2012

fDate

3/1/2012 12:00:00 AM

Firstpage

516

Lastpage

526

Abstract

We present a fluid simulation method based on Smoothed Particle Hydrodynamics (SPH) in which incompressibility and boundary conditions are enforced using holonomic kinematic constraints on the density. This formulation enables systematic multiphysics integration in which interactions are modeled via similar constraints between the fluid pseudoparticles and impenetrable surfaces of other bodies. These conditions embody Archimede´s principle for solids and thus buoyancy results as a direct consequence. We use a variational time stepping scheme suitable for general constrained multibody systems we call SPOOK. Each step requires the solution of only one Mixed Linear Complementarity Problem (MLCP) with very few inequalities, corresponding to solid boundary conditions. We solve this MLCP with a fast iterative method. Overall stability is vastly improved in comparison to the unconstrained version of SPH, and this allows much larger time steps, and an increase in overall performance by two orders of magnitude. Proof of concept is given for computer graphics applications and interactive simulations.

Keywords

computational fluid dynamics; computer graphics; digital simulation; hydrodynamics; iterative methods; Archimedes principle; SPOOK; boundary conditions; buoyancy; computer graphics applications; constraint fluids; fast iterative method; fluid pseudoparticles; fluid simulation method; holonomic kinematic constraints; incompressibility conditions; interactive simulations; mixed linear complementarity problem; smoothed particle hydrodynamics; systematic multiphysics integration; Approximation methods; Computational modeling; Computer graphics; Equations; Force; Mathematical model; Stability analysis; SPH; constraints; fluid simulation; incompressible; variational integrator.; Algorithms; Computer Graphics; Computer Simulation; Hydrodynamics; Models, Theoretical;

fLanguage

English

Journal_Title

Visualization and Computer Graphics, IEEE Transactions on

Publisher

ieee

ISSN

1077-2626

Type

jour

DOI

10.1109/TVCG.2011.29

Filename

5708198