Natural Models for Evolution on Networks

TL;DR

This paper introduces a new undirected network model for evolutionary dynamics that acts as a suppressor of selection, provides bounds on fixation probabilities, and demonstrates convergence properties and control mechanisms.

Contribution

It presents the first class of undirected suppressor graphs, introduces a mutual influence model with a potential function, and analyzes convergence and control in network-based evolution.

Findings

Identified undirected graphs that suppress selection effectively.

Proved convergence of the mutual influence model for any graph topology.

Bounded the time to stabilize to healthy states in control scenarios.

Abstract

Evolutionary dynamics have been traditionally studied in the context of homogeneous populations, mainly described my the Moran process. Recently, this approach has been generalized in \cite{LHN} by arranging individuals on the nodes of a network. Undirected networks seem to have a smoother behavior than directed ones, and thus it is more challenging to find suppressors/amplifiers of selection. In this paper we present the first class of undirected graphs which act as suppressors of selection, by achieving a fixation probability that is at most one half of that of the complete graph, as the number of vertices increases. Moreover, we provide some generic upper and lower bounds for the fixation probability of general undirected graphs. As our main contribution, we introduce the natural alternative of the model proposed in \cite{LHN}, where all individuals interact simultaneously and the result is a compromise between aggressive and non-aggressive individuals. That is, the behavior of the individuals in our new model and in the model of \cite{LHN} can be interpreted as an "aggregation" vs. an "all-or-nothing" strategy, respectively. We prove that our new model of mutual influences admits a \emph{potential function}, which guarantees the convergence of the system for any graph topology and any initial fitness vector of the individuals. Furthermore, we prove fast convergence to the stable state for the case of the complete graph, as well as we provide almost tight bounds on the limit fitness of the individuals. Apart from being important on its own, this new evolutionary model appears to be useful also in the abstract modeling of control mechanisms over invading populations in networks. We demonstrate this by introducing and analyzing two alternative control approaches, for which we bound the time needed to stabilize to the "healthy" state of the system.