English

Combinatorics-Based Approaches to Controllability Characterization for Bilinear Systems

Optimization and Control 2020-09-09 v1

Abstract

The control of bilinear systems has attracted considerable attention in the field of systems and control for decades, owing to their prevalence in diverse applications across science and engineering disciplines. Although much work has been conducted on analyzing controllability properties, the mostly used tool remains the Lie algebra rank condition. In this paper, we develop alternative approaches based on theory and techniques in combinatorics to study controllability of bilinear systems. The core idea of our methodology is to represent vector fields of a bilinear system by permutations or graphs, so that Lie brackets are represented by permutation multiplications or graph operations, respectively. Following these representations, we derive combinatorial characterization of controllability for bilinear systems, which consequently provides novel applications of symmetric group and graph theory to control theory. Moreover, the developed combinatorial approaches are compatible with Lie algebra decompositions, including the Cartan and non-intertwining decomposition. This compatibility enables the exploitation of representation theory for analyzing controllability, which allows us to characterize controllability properties of bilinear systems governed by semisimple and reductive Lie algebras.

Keywords

Cite

@article{arxiv.2009.03430,
  title  = {Combinatorics-Based Approaches to Controllability Characterization for Bilinear Systems},
  author = {Gong Cheng and Wei Zhang and Jr-Shin Li},
  journal= {arXiv preprint arXiv:2009.03430},
  year   = {2020}
}

Comments

Keywords: Bilinear systems, Lie groups, graph theory, symmetric groups, representation theory, Cartan decomposition

R2 v1 2026-06-23T18:22:38.406Z