Robust Data-Driven Receding-Horizon Control for LQR with Input Constraints
Abstract
This letter presents a robust data-driven receding-horizon control framework for the discrete time linear quadratic regulator (LQR) with input constraints. Unlike existing data-driven approaches that design a controller from initial data and apply it unchanged throughout the trajectory, our method exploits all available execution data in a receding-horizon manner, thereby capturing additional information about the unknown system and enabling less conservative performance. Prior data-driven LQR and model predictive control methods largely rely on Willem's fundamental lemma, which requires noise-free data, or use regularization to address disturbances, offering only practical stability guarantees. In contrast, the proposed approach extends semidefinite program formulations for the data-driven LQR to incorporate input constraints and leverages duality to provide formal robust stability guarantees. Simulation results demonstrate the effectiveness of the method.
Cite
@article{arxiv.2510.06117,
title = {Robust Data-Driven Receding-Horizon Control for LQR with Input Constraints},
author = {Jian Zheng and Mario Sznaier},
journal= {arXiv preprint arXiv:2510.06117},
year = {2025}
}
Comments
This work has been submitted to IEEE L-CSS for possible publication