English

Homeostasis Patterns

Dynamical Systems 2024-09-26 v2

Abstract

Homeostasis is a regulatory mechanism that keeps a specific variable close to a set value as other variables fluctuate. The notion of homeostasis can be rigorously formulated when the model of interest is represented as an input-output network, with distinguished input and output nodes, and the dynamics of the network determines the corresponding input-output function of the system. In this context, homeostasis can be defined as an 'infinitesimal' notion, namely, the derivative of the input-output function is zero at an isolated point. Combining this approach with graph-theoretic ideas from combinatorial matrix theory provides a systematic framework for calculating homeostasis points in models and classifying the different homeostasis types in input-output networks. In this paper we extend this theory by introducing the notion of a homeostasis pattern, defined as a set of nodes, in addition to the output node, that are simultaneously infinitesimally homeostatic. We prove that each homeostasis type leads to a distinct homeostasis pattern. Moreover, we describe all homeostasis patterns supported by a given input-output network in terms of a combinatorial structure associated to the input-output network. We call this structure the homeostasis pattern network.

Keywords

Cite

@article{arxiv.2306.15145,
  title  = {Homeostasis Patterns},
  author = {William Duncan and Fernando Antoneli and Janet Best and Martin Golubitsky and Jiaxin Jin and H. Frederik Nijhout and Mike Reed and Ian Stewart},
  journal= {arXiv preprint arXiv:2306.15145},
  year   = {2024}
}

Comments

36 pages, 10 figures, 2 tables

R2 v1 2026-06-28T11:15:14.419Z