English

On converse Lyapunov theorems for fluid network models

Dynamical Systems 2011-11-09 v1

Abstract

We consider the class of closed generic fluid networks (GFN) models, which provides an abstract framework containing a wide variety of fluid networks. Within this framework a Lyapunov method for stability of GFN models was proposed by Ye and Chen. They proved that stability of a GFN model is equivalent to the existence of a functional on the set of paths that is decaying along paths. This result falls short of a converse Lyapunov theorem in that no state dependent Lyapunov function is constructed. In this paper we construct state-dependent Lyapunov functions in contrast to path-wise functionals. We first show by counterexamples that closed GFN models do not provide sufficient information that allow for a converse Lyapunov theorem. To resolve this problem we introduce the class of strict GFN models by forcing the closed GFN model to satisfy a concatenation and a semicontinuity condition of the set of paths in dependence of initial condition. For the class of strict GFN models we define a state-dependent Lyapunov and show that a converse Lyapunov theorem holds. Finally, it is shown that common fluid network models, like general work-conserving and priority fluid network models as well as certain linear Skorokhod problems define strict GFN models.

Keywords

Cite

@article{arxiv.1111.1990,
  title  = {On converse Lyapunov theorems for fluid network models},
  author = {Michael Schönlein and Fabian Wirth},
  journal= {arXiv preprint arXiv:1111.1990},
  year   = {2011}
}
R2 v1 2026-06-21T19:32:54.458Z