English

M-PhyGs: Multi-Material Object Dynamics from Video

Computer Vision and Pattern Recognition 2025-12-19 v1

Abstract

Knowledge of the physical material properties governing the dynamics of a real-world object becomes necessary to accurately anticipate its response to unseen interactions. Existing methods for estimating such physical material parameters from visual data assume homogeneous single-material objects, pre-learned dynamics, or simplistic topologies. Real-world objects, however, are often complex in material composition and geometry lying outside the realm of these assumptions. In this paper, we particularly focus on flowers as a representative common object. We introduce Multi-material Physical Gaussians (M-PhyGs) to estimate the material composition and parameters of such multi-material complex natural objects from video. From a short video captured in a natural setting, M-PhyGs jointly segments the object into similar materials and recovers their continuum mechanical parameters while accounting for gravity. M-PhyGs achieves this efficiently with newly introduced cascaded 3D and 2D losses, and by leveraging temporal mini-batching. We introduce a dataset, Phlowers, of people interacting with flowers as a novel platform to evaluate the accuracy of this challenging task of multi-material physical parameter estimation. Experimental results on Phlowers dataset demonstrate the accuracy and effectiveness of M-PhyGs and its components.

Keywords

Cite

@article{arxiv.2512.16885,
  title  = {M-PhyGs: Multi-Material Object Dynamics from Video},
  author = {Norika Wada and Kohei Yamashita and Ryo Kawahara and Ko Nishino},
  journal= {arXiv preprint arXiv:2512.16885},
  year   = {2025}
}
R2 v1 2026-07-01T08:32:08.390Z