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Eulerian-Lagrangian Fluid Simulation on Particle Flow Maps

Graphics 2024-05-17 v1

Abstract

We propose a novel Particle Flow Map (PFM) method to enable accurate long-range advection for incompressible fluid simulation. The foundation of our method is the observation that a particle trajectory generated in a forward simulation naturally embodies a perfect flow map. Centered on this concept, we have developed an Eulerian-Lagrangian framework comprising four essential components: Lagrangian particles for a natural and precise representation of bidirectional flow maps; a dual-scale map representation to accommodate the mapping of various flow quantities; a particle-to-grid interpolation scheme for accurate quantity transfer from particles to grid nodes; and a hybrid impulse-based solver to enforce incompressibility on the grid. The efficacy of PFM has been demonstrated through various simulation scenarios, highlighting the evolution of complex vortical structures and the details of turbulent flows. Notably, compared to NFM, PFM reduces computing time by up to 49 times and memory consumption by up to 41%, while enhancing vorticity preservation as evidenced in various tests like leapfrog, vortex tube, and turbulent flow.

Keywords

Cite

@article{arxiv.2405.09672,
  title  = {Eulerian-Lagrangian Fluid Simulation on Particle Flow Maps},
  author = {Junwei Zhou and Duowen Chen and Molin Deng and Yitong Deng and Yuchen Sun and Sinan Wang and Shiying Xiong and Bo Zhu},
  journal= {arXiv preprint arXiv:2405.09672},
  year   = {2024}
}
R2 v1 2026-06-28T16:28:46.528Z