English

Differentiable Contact Dynamics for Stable Object Placement Under Geometric Uncertainties

Robotics 2025-12-02 v2

Abstract

From serving a cup of coffee to positioning mechanical parts during assembly, stable object placement is a crucial skill for future robots. It becomes particularly challenging under geometric uncertainties, e.g., when the object pose or shape is not known accurately. This work leverages a differentiable simulation model of contact dynamics to tackle this challenge. We derive a novel gradient that relates force-torque sensor readings to geometric uncertainties, thus enabling uncertainty estimation by minimizing discrepancies between sensor data and model predictions via gradient descent. Gradient-based methods are sensitive to initialization. To mitigate this effect, we maintain a belief over multiple estimates and choose the robot action based on the current belief at each timestep. In experiments on a Franka robot arm, our method achieved promising results on multiple objects under various geometric uncertainties, including the in-hand pose uncertainty of a grasped object, the object shape uncertainty, and the environment uncertainty.

Keywords

Cite

@article{arxiv.2409.17725,
  title  = {Differentiable Contact Dynamics for Stable Object Placement Under Geometric Uncertainties},
  author = {Linfeng Li and Gang Yang and Lin Shao and David Hsu},
  journal= {arXiv preprint arXiv:2409.17725},
  year   = {2025}
}
R2 v1 2026-06-28T18:57:57.155Z