A Grid-Free Fluid Solver based on Gaussian Spatial Representation

We present a grid-free fluid solver featuring a novel Gaussian representation. Drawing inspiration from the expressive capabilities of 3D Gaussian Splatting in multi-view image reconstruction, we model the continuous flow velocity as a weighted sum of multiple Gaussian functions. Leveraging this representation, we derive differential operators for the field and implement a time-dependent PDE solver using the traditional operator splitting method. Compared to implicit neural representations as another continuous spatial representation with increasing attention, our method with flexible 3D Gaussians presents enhanced accuracy on vorticity preservation. Moreover, we apply physics-driven strategies to accelerate the optimization-based time integration of Gaussian functions. This temporal evolution surpasses previous work based on implicit neural representation with reduced computational time and memory. Although not surpassing the quality of state-of-the-art Eulerian methods in fluid simulation, experiments and ablation studies indicate the potential of our memory-efficient representation. With enriched spatial information, our method exhibits a distinctive perspective combining the advantages of Eulerian and Lagrangian approaches.