Closed-Loop Sim-to-Real Reinforcement Learning for Deformable Microfiber Shape Control
Abstract
Autonomous contact-based micromanipulation is challenging because surface and interfacial interactions at the microscale are difficult to model accurately, limiting the use of conventional model-based control and sim-to-real learning. We present a closed-loop sim-to-real reinforcement learning (RL) approach for microfiber shape control on a surface. The central idea is to train geometric shape regulation in a simplified frictionless simulator and rely on real-time visual feedback during deployment to iteratively correct the observed effects of unmodeled surface interactions. An RL policy trained entirely in simulation is transferred directly to a physical dual-gripper micromanipulation system operating at 40 Hz, without retraining or domain adaptation. Using silk microfibers as a testbed, the policy achieves a mean point-wise shape error of 270 80 m across twenty-four diverse initial configurations. Across nine specimens covering all combinations of three fiber diameters (50, 80, and 120 m) and three manipulated lengths (10 mm, 15mm, and 20 mm), the same policy achieves sub-millimeter final shape error without any retraining or retuning. These results show that a policy learned in a simplified simulator can achieve repeatable real-world microfiber shape regulation under surface contact, provided that the task-relevant effects of the sim-to-real mismatch remain observable and correctable within the closed feedback loop.
Cite
@article{arxiv.2605.21688,
title = {Closed-Loop Sim-to-Real Reinforcement Learning for Deformable Microfiber Shape Control},
author = {Alessandro Amici and Houari Bettahar and Veeti Jaakkola and Quan Zhou},
journal= {arXiv preprint arXiv:2605.21688},
year = {2026}
}
Comments
7 pages,7 figures