English

Structural classification of continuous time Markov chains with applications

Probability 2021-12-24 v3 Dynamical Systems

Abstract

This paper is motivated by examples from stochastic reaction network theory. The QQ-matrix of a stochastic reaction network can be derived from the reaction graph, an edge-labelled directed graph encoding the jump vectors of an associated continuous time Markov chain on the invariant space N0d\mathbb{N}^d_0. An open question is how to decompose the space N0d\mathbb{N}^d_0 into neutral, trapping, and escaping states, and open and closed communicating classes, and whether this can be done from the reaction graph alone. Such general continuous time Markov chains can be understood as natural generalizations of birth-death processes, incorporating multiple different birth and death mechanisms. We characterize the structure of N0d\mathbb{N}^d_0 imposed by a general QQ-matrix generating continuous time Markov chains with values in N0d\mathbb{N}^d_0, in terms of the set of jump vectors and their corresponding transition rate functions. Thus the setting is not limited to stochastic reaction networks. Furthermore, we define structural equivalence of two QQ-matrices, and provide sufficient conditions for structural equivalence. Examples are abundant in applications. We apply the results to stochastic reaction networks, a Lotka-Volterra model in ecology, the EnvZ-OmpR system in systems biology, and a class of extended branching processes, none of which are birth-death processes.

Keywords

Cite

@article{arxiv.2006.09802,
  title  = {Structural classification of continuous time Markov chains with applications},
  author = {Chuang Xu and Mads Christian Hansen and Carsten Wiuf},
  journal= {arXiv preprint arXiv:2006.09802},
  year   = {2021}
}
R2 v1 2026-06-23T16:24:06.209Z