Data-driven $H_{\infty}$ predictive control for constrained systems: a Lagrange duality approach
Abstract
This article proposes a data-driven control scheme for time-domain constrained systems based on model predictive control formulation. The scheme combines control and minimax model predictive control, enabling more effective handling of external disturbances and time-domain constraints. First, by leveraging input-output-disturbance data, the scheme ensures performance of the closed-loop system. Then, a minimax optimization problem is converted into a more manageable minimization problem employing Lagrange duality, which reduces conservatism typically associated with ellipsoidal evaluations of time-domain constraints. The study examines key closed-loop properties, including stability, disturbance attenuation, and constraint satisfaction, achieved by the proposed data-driven moving horizon predictive control algorithm. The effectiveness and advantages of the proposed method are demonstrated through numerical simulations involving a batch reactor system, confirming its robustness and feasibility under noisy conditions.
Cite
@article{arxiv.2412.18831,
title = {Data-driven $H_{\infty}$ predictive control for constrained systems: a Lagrange duality approach},
author = {Wenhuang Wu and Lulu Guo and Nan Li and Hong Chen},
journal= {arXiv preprint arXiv:2412.18831},
year = {2025}
}
Comments
11 pages, 4 figures