English

On real structured controllability/stabilizability/stability radius: Complexity and unified rank-relaxation based methods

Systems and Control 2023-07-07 v3 Systems and Control

Abstract

This paper addresses the real structured controllability, stabilizability, and stability radii (RSCR, RSSZR, and RSSR, respectively) of linear systems, which involve determining the distance (in terms of matrix norms) between a (possibly large-scale) system and its nearest uncontrollable, unstabilizable, and unstable systems, respectively, with a prescribed affine structure. This paper makes two main contributions. First, by demonstrating that determining the feasibilities of RSCR and RSSZR is NP-hard when the perturbations have a general affine parameterization, we prove that computing these radii is NP-hard. Additionally, we prove the NP-hardness of a problem related to the RSSR. These hardness results are independent of the matrix norm used. Second, we develop unified rank-relaxation based algorithms for these problems, which can handle both the Frobenius norm and the 22-norm based problems and share the same framework for the RSCR, RSSZR, and RSSR problems. These algorithms utilize the low-rank structure of the original problems and relax the corresponding rank constraints with a regularized truncated nuclear norm term. Moreover, a modified version of these algorithms can find local optima with performance specifications on the perturbations, under appropriate conditions. Finally, simulations suggest that the proposed methods, despite being in a simple framework, can find local optima as good as several existing methods.

Keywords

Cite

@article{arxiv.2201.01112,
  title  = {On real structured controllability/stabilizability/stability radius: Complexity and unified rank-relaxation based methods},
  author = {Yuan Zhang and Yuanqing Xia and Yufeng Zhan},
  journal= {arXiv preprint arXiv:2201.01112},
  year   = {2023}
}

Comments

To appear in System & Control Letters

R2 v1 2026-06-24T08:39:44.630Z