Published August 2015
| public
Journal Article
Power particles: an incompressible fluid solver based on power diagrams
Abstract
This paper introduces a new particle-based approach to incompressible fluid simulation. We depart from previous Lagrangian methods by considering fluid particles no longer purely as material points, but also as volumetric parcels that partition the fluid domain. The fluid motion is described as a time series of well-shaped power diagrams (hence the name power particles), offering evenly spaced particles and accurate pressure computations. As a result, we circumvent the typical excess damping arising from kernel-based evaluations of internal forces or density without having recourse to auxiliary Eulerian grids. The versatility of our solver is demonstrated by the simulation of multiphase flows and free surfaces.
Additional Information
© 2015 ACM. We thank Chris Rydalch for his help with Houdini, Chris Rycroft for sharing the VORO++ library, Jiong Chen for rendering Fig. 6, and Santiago V. Lombeyda for help with figures and video. MD gratefully acknowledges the TITANE team and the INRIA International Chair program for their support. Partial funding was provided by NSF grant CCF-1011944 and a Google PhD Fellowship.Additional details
- Eprint ID
- 59566
- Resolver ID
- CaltechAUTHORS:20150814-150739482
- INRIA International Chair Program
- CCF-1011944
- NSF
- Google PhD Fellowship
- Created
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2015-08-14Created from EPrint's datestamp field
- Updated
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2021-11-10Created from EPrint's last_modified field