English

Learning-based Optoelectronically Innervated Tactile Finger for Rigid-Soft Interactive Grasping

Robotics 2021-02-01 v1

Abstract

This paper presents a novel design of a soft tactile finger with omni-directional adaptation using multi-channel optical fibers for rigid-soft interactive grasping. Machine learning methods are used to train a model for real-time prediction of force, torque, and contact using the tactile data collected. We further integrated such fingers in a reconfigurable gripper design with three fingers so that the finger arrangement can be actively adjusted in real-time based on the tactile data collected during grasping, achieving the process of rigid-soft interactive grasping. Detailed sensor calibration and experimental results are also included to further validate the proposed design for enhanced grasping robustness.

Keywords

Cite

@article{arxiv.2101.12379,
  title  = {Learning-based Optoelectronically Innervated Tactile Finger for Rigid-Soft Interactive Grasping},
  author = {Linhan Yang and Xudong Han and Weijie Guo and Fang Wan and Jia Pan and Chaoyang Song},
  journal= {arXiv preprint arXiv:2101.12379},
  year   = {2021}
}

Comments

8 pages,9 figures, Submitted to RAL and ICRA2021

R2 v1 2026-06-23T22:38:40.555Z