Walk This Way: Modeling Foraging Ant Dynamics in Multiple Food Source Environments

Overview

Journal J Math Biol

Date 2024 Sep 12

PMID 39266783

Authors

Sean Hartman

Shawn D Ryan

Bhargav R Karamched

Affiliations

Soon will be listed here.

Abstract

Foraging for resources is an essential process for the daily life of an ant colony. What makes this process so fascinating is the self-organization of ants into trails using chemical pheromone in the absence of direct communication. Here we present a stochastic lattice model that captures essential features of foraging ant dynamics inspired by recent agent-based models while forgoing more detailed interactions that may not be essential to trail formation. Nevertheless, our model's results coincide with those presented in more sophisticated theoretical models and experiments. Furthermore, it captures the phenomenon of multiple trail formation in environments with multiple food sources. This latter phenomenon is not described well by other more detailed models. We complement the stochastic lattice model by describing a macroscopic PDE which captures the basic structure of lattice model. The PDE provides a continuum framework for the first-principle interactions described in the stochastic lattice model and is amenable to analysis. Linear stability analysis of this PDE facilitates a computational study of the impact various parameters impart on trail formation. We also highlight universal features of the modeling framework that may allow this simple formation to be used to study complex systems beyond ants.

Citing Articles

Walk this way: modeling foraging ant dynamics in multiple food source environments.

Hartman S, Ryan S, Karamched B J Math Biol. 2024; 89(4):41.

PMID: 39266783 PMC: 11392994. DOI: 10.1007/s00285-024-02136-2.

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