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Main Authors: Cummings, Joseph, Dahlin, Kyle J. -M., Gross, Elizabeth, Hauenstein, Jonathan D.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.00128
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author Cummings, Joseph
Dahlin, Kyle J. -M.
Gross, Elizabeth
Hauenstein, Jonathan D.
author_facet Cummings, Joseph
Dahlin, Kyle J. -M.
Gross, Elizabeth
Hauenstein, Jonathan D.
contents Changes in environmental or system parameters often drive major biological transitions, including ecosystem collapse, disease outbreaks, and tumor development. Analyzing the stability of steady states in dynamical systems provides critical insight into these transitions. This paper introduces an algebraic framework for analyzing the stability landscapes of ecological models defined by systems of first-order autonomous ordinary differential equations with polynomial or rational rate functions. Using tools from real algebraic geometry, we characterize parameter regions associated with steady-state feasibility and stability via three key boundaries: singular, stability (Routh-Hurwitz), and coordinate boundaries. With these boundaries in mind, we employ routing functions to compute the connected components of parameter space in which the number and type of stable steady states remain constant, revealing the stability landscape of these ecological models. As case studies, we revisit the classical Levins-Culver competition-colonization model and a recent model of coral-bacteria symbioses. In the latter, our method uncovers complex stability regimes, including regions supporting limit cycles, that are inaccessible via traditional techniques. These results demonstrate the potential of our approach to inform ecological theory and intervention strategies in systems with nonlinear interactions and multiple stable states.
format Preprint
id arxiv_https___arxiv_org_abs_2505_00128
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Routing functions for parameter space decomposition to describe stability landscapes of ecological models
Cummings, Joseph
Dahlin, Kyle J. -M.
Gross, Elizabeth
Hauenstein, Jonathan D.
Populations and Evolution
Algebraic Geometry
92D40, 92D25
Changes in environmental or system parameters often drive major biological transitions, including ecosystem collapse, disease outbreaks, and tumor development. Analyzing the stability of steady states in dynamical systems provides critical insight into these transitions. This paper introduces an algebraic framework for analyzing the stability landscapes of ecological models defined by systems of first-order autonomous ordinary differential equations with polynomial or rational rate functions. Using tools from real algebraic geometry, we characterize parameter regions associated with steady-state feasibility and stability via three key boundaries: singular, stability (Routh-Hurwitz), and coordinate boundaries. With these boundaries in mind, we employ routing functions to compute the connected components of parameter space in which the number and type of stable steady states remain constant, revealing the stability landscape of these ecological models. As case studies, we revisit the classical Levins-Culver competition-colonization model and a recent model of coral-bacteria symbioses. In the latter, our method uncovers complex stability regimes, including regions supporting limit cycles, that are inaccessible via traditional techniques. These results demonstrate the potential of our approach to inform ecological theory and intervention strategies in systems with nonlinear interactions and multiple stable states.
title Routing functions for parameter space decomposition to describe stability landscapes of ecological models
topic Populations and Evolution
Algebraic Geometry
92D40, 92D25
url https://arxiv.org/abs/2505.00128