Feel Robot Feels: Tactile Feedback Array Glove for Dexterous Manipulation
Abstract
Teleoperation is a key approach for collecting high-quality, physically consistent demonstrations for robotic manipulation. However, teleoperation for dexterous manipulation remains constrained by: (i) inaccurate hand-robot motion mapping, which limits teleoperated dexterity, and (ii) limited tactile feedback that forces vision-dominated interaction and hinders perception of contact geometry and force variation. To address these challenges, we present TAG, a low-cost glove system that integrates precise hand motion capture with high-resolution tactile feedback, enabling effective tactile-in-the-loop dexterous teleoperation. For motion capture, TAG employs a non-contact magnetic sensing design that provides drift-free, electromagnetically robust 21-DoF joint tracking with joint angle estimation errors below 1 degree. Meanwhile, to restore tactile sensation, TAG equips each finger with a 32-actuator tactile array within a compact 2 cm^2 module, allowing operators to directly feel physical interactions at the robot end-effector through spatial activation patterns. Through real-world teleoperation experiments and user studies, we show that TAG enables reliable real-time perception of contact geometry and dynamic force, improves success rates in contact-rich teleoperation tasks, and increases the reliability of demonstration data collection for learning-based manipulation.
Keywords
Cite
@article{arxiv.2603.28542,
title = {Feel Robot Feels: Tactile Feedback Array Glove for Dexterous Manipulation},
author = {Feiyu Jia and Xiaojie Niu and Sizhe Yang and Qingwei Ben and Tao Huang and Feng zhao and Jingbo Wang and Jiangmiao Pang},
journal= {arXiv preprint arXiv:2603.28542},
year = {2026}
}
Comments
13 pages, 16 figures