English

Safe Dynamic Motion Generation in Configuration Space Using Differentiable Distance Fields

Robotics 2024-12-24 v1

Abstract

Generating collision-free motions in dynamic environments is a challenging problem for high-dimensional robotics, particularly under real-time constraints. Control Barrier Functions (CBFs), widely utilized in safety-critical control, have shown significant potential for motion generation. However, for high-dimensional robot manipulators, existing QP formulations and CBF-based methods rely on positional information, overlooking higher-order derivatives such as velocities. This limitation may lead to reduced success rates, decreased performance, and inadequate safety constraints. To address this, we construct time-varying CBFs (TVCBFs) that consider velocity conditions for obstacles. Our approach leverages recent developments on distance fields for articulated manipulators, a differentiable representation that enables the mapping of objects' position and velocity into the robot's joint space, offering a comprehensive understanding of the system's interactions. This allows the manipulator to be treated as a point-mass system thus simplifying motion generation tasks. Additionally, we introduce a time-varying control Lyapunov function (TVCLF) to enable whole-body contact motions. Our approach integrates the TVCBF, TVCLF, and manipulator physical constraints within a unified QP framework. We validate our method through simulations and comparisons with state-of-the-art approaches, demonstrating its effectiveness on a 7-axis Franka robot in real-world experiments.

Keywords

Cite

@article{arxiv.2412.16456,
  title  = {Safe Dynamic Motion Generation in Configuration Space Using Differentiable Distance Fields},
  author = {Xuemin Chi and Yiming Li and Jihao Huang and Bolun Dai and Zhitao Liu and Sylvain Calinon},
  journal= {arXiv preprint arXiv:2412.16456},
  year   = {2024}
}

Comments

8 pages, 5 figures

R2 v1 2026-06-28T20:44:40.459Z