Robotic manipulators are essential for precise industrial pick-and-place operations, yet planning collision-free trajectories in dynamic environments remains challenging due to uncertainties such as sensor noise and time-varying delays. Conventional control methods often fail under these conditions, motivating the development of Robust MPC (RMPC) strategies with constraint tightening. In this paper, we propose a novel RMPC framework that integrates phase-based nominal control with a robust safety mode, allowing smooth transitions between safe and nominal operations. Our approach dynamically adjusts constraints based on real-time predictions of moving obstacles\textemdash whether human, robot, or other dynamic objects\textemdash thus ensuring continuous, collision-free operation. Simulation studies demonstrate that our controller improves both motion naturalness and safety, achieving faster task completion than conventional methods.
@article{arxiv.2505.24209,
title = {Safety-Aware Robust Model Predictive Control for Robotic Arms in Dynamic Environments},
author = {Sanghyeon Nam and Dongmin Kim and Seung-Hwan Choi and Chang-Hyun Kim and Hyoeun Kwon and Hiroaki Kawamoto and Suwoong Lee},
journal= {arXiv preprint arXiv:2505.24209},
year = {2025}
}
Comments
This paper has been accepted to the CASE 2025 conference