English

Performance-Robustness Tradeoffs in Adversarially Robust Linear-Quadratic Control

Systems and Control 2022-03-22 v1 Systems and Control

Abstract

While H\mathcal{H}_\infty methods can introduce robustness against worst-case perturbations, their nominal performance under conventional stochastic disturbances is often drastically reduced. Though this fundamental tradeoff between nominal performance and robustness is known to exist, it is not well-characterized in quantitative terms. Toward addressing this issue, we borrow from the increasingly ubiquitous notion of adversarial training from machine learning to construct a class of controllers which are optimized for disturbances consisting of mixed stochastic and worst-case components. We find that this problem admits a stationary optimal controller that has a simple analytic form closely related to suboptimal H\mathcal{H}_\infty solutions. We then provide a quantitative performance-robustness tradeoff analysis, in which system-theoretic properties such as controllability and stability explicitly manifest in an interpretable manner. This provides practitioners with general guidance for determining how much robustness to incorporate based on a priori system knowledge. We empirically validate our results by comparing the performance of our controller against standard baselines, and plotting tradeoff curves.

Keywords

Cite

@article{arxiv.2203.10763,
  title  = {Performance-Robustness Tradeoffs in Adversarially Robust Linear-Quadratic Control},
  author = {Bruce D. Lee and Thomas T. C. K. Zhang and Hamed Hassani and Nikolai Matni},
  journal= {arXiv preprint arXiv:2203.10763},
  year   = {2022}
}
R2 v1 2026-06-24T10:20:02.692Z