Daria Nogina, Silvia Sellán
Smoothed Particle Hydrodynamics (SPH) simulations rely on accurately and efficiently modeling fluid-solid interactions. However, particle-based coupling strategies introduce non-deterministic discretization errors, and implicit methods achieve high accuracy at the cost of expensive numerical integration. We introduce Tube Maps, a drop-in replacement for SPH boundary density computation that achieves accuracy comparable to implicit methods while dramatically reducing their computational cost. Our key observation is that the boundary density integral is fully determined by the local surface geometry near a fluid particle’s closest point. By expressing this geometry in tubular coordinates, we reduce the original three-dimensional integral to a one-dimensional closed-form expression that can be evaluated in constant time. We thus eliminate numerical quadrature and reduce boundary handling costs by one to three orders of magnitude, enabling fast and accurate SPH simulations with time-varying curved solids.
Tube Maps: Fast SPH Boundary Handling in Tubular Coordinates