中文

Data-Driven Linear Quadratic Control Using Output-Feedback via Non-Minimal Realization

最优化与控制 2026-05-19 v1

摘要

In this paper, we investigate a continuous-time linear quadratic control problem for systems with unknown matrices, where only input-output data are available. We propose an output-feedback learning framework based on a canonical nonminimal realization constructed through Kreisselmeier's adaptive filter. The filter admits an observer interpretation, which leads to an augmented system that preserves the input-output response of the realization and provides accessible state trajectories. We show that the optimal gain of this augmented system explicitly recovers the optimal gain associated with the canonical non-minimal realization, and hence achieves the optimal state-feedback solution of the original plant. Exploiting this relation and the known structure of the augmented input matrix, we develop a data-driven value iteration algorithm within the adaptive dynamic programming framework. The resulting controller is implementable from input-output data, and its performance is validated via simulations.

关键词

引用

@article{arxiv.2605.16752,
  title  = {Data-Driven Linear Quadratic Control Using Output-Feedback via Non-Minimal Realization},
  author = {Weijian Li and Bowen Yi and Panos J. Antsaklis and Hai Lin},
  journal= {arXiv preprint arXiv:2605.16752},
  year   = {2026}
}