English

An End-to-End Differentiable Framework for Contact-Aware Robot Design

Robotics 2021-08-25 v2 Artificial Intelligence Graphics

Abstract

The current dominant paradigm for robotic manipulation involves two separate stages: manipulator design and control. Because the robot's morphology and how it can be controlled are intimately linked, joint optimization of design and control can significantly improve performance. Existing methods for co-optimization are limited and fail to explore a rich space of designs. The primary reason is the trade-off between the complexity of designs that is necessary for contact-rich tasks against the practical constraints of manufacturing, optimization, contact handling, etc. We overcome several of these challenges by building an end-to-end differentiable framework for contact-aware robot design. The two key components of this framework are: a novel deformation-based parameterization that allows for the design of articulated rigid robots with arbitrary, complex geometry, and a differentiable rigid body simulator that can handle contact-rich scenarios and computes analytical gradients for a full spectrum of kinematic and dynamic parameters. On multiple manipulation tasks, our framework outperforms existing methods that either only optimize for control or for design using alternate representations or co-optimize using gradient-free methods.

Keywords

Cite

@article{arxiv.2107.07501,
  title  = {An End-to-End Differentiable Framework for Contact-Aware Robot Design},
  author = {Jie Xu and Tao Chen and Lara Zlokapa and Michael Foshey and Wojciech Matusik and Shinjiro Sueda and Pulkit Agrawal},
  journal= {arXiv preprint arXiv:2107.07501},
  year   = {2021}
}

Comments

Robotics: Science and Systems

R2 v1 2026-06-24T04:14:24.344Z