English

Manipulation via Force Distribution at Contact

Robotics 2026-02-04 v1

Abstract

Efficient and robust trajectories play a crucial role in contact-rich manipulation, which demands accurate mod- eling of object-robot interactions. Many existing approaches rely on point contact models due to their computational effi- ciency. Simple contact models are computationally efficient but inherently limited for achieving human-like, contact-rich ma- nipulation, as they fail to capture key frictional dynamics and torque generation observed in human manipulation. This study introduces a Force-Distributed Line Contact (FDLC) model in contact-rich manipulation and compares it against conventional point contact models. A bi-level optimization framework is constructed, in which the lower-level solves an optimization problem for contact force computation, and the upper-level optimization applies iLQR for trajectory optimization. Through this framework, the limitations of point contact are demon- strated, and the benefits of the FDLC in generating efficient and robust trajectories are established. The effectiveness of the proposed approach is validated by a box rotating task, demonstrating that FDLC enables trajectories generated via non-uniform force distributions along the contact line, while requiring lower control effort and less motion of the robot.

Keywords

Cite

@article{arxiv.2602.03350,
  title  = {Manipulation via Force Distribution at Contact},
  author = {Haegu Lee and Yitaek Kim and Casper Hewson Rask and Christoffer Sloth},
  journal= {arXiv preprint arXiv:2602.03350},
  year   = {2026}
}
R2 v1 2026-07-01T09:33:53.013Z