English

Persistence for stochastic difference equations: A mini-review

Dynamical Systems 2015-12-16 v1 Probability Populations and Evolution

Abstract

Understanding under what conditions populations, whether they be plants, animals, or viral particles, persist is an issue of theoretical and practical importance in population biology. Both biotic interactions and environmental fluctuations are key factors that can facilitate or disrupt persistence. One approach to examining the interplay between these deterministic and stochastic forces is the construction and analysis of stochastic difference equations Xt+1=F(Xt,ξt+1)X_{t+1}=F(X_t,\xi_{t+1}) where XtRkX_t \in \R^k represents the state of the populations and ξ1,ξ2,...\xi_1,\xi_2,... is a sequence of random variables representing environmental stochasticity. In the analysis of these stochastic models, many theoretical population biologists are interested in whether the models are bounded and persistent. Here, boundedness asserts that asymptotically XtX_t tends to remain in compact sets. In contrast, persistence requires that XtX_t tends to be "repelled" by some "extinction set" S0RkS_0\subset \R^k. Here, results on both of these proprieties are reviewed for single species, multiple species, and structured population models. The results are illustrated with applications to stochastic versions of the Hassell and Ricker single species models, Ricker, Beverton-Holt, lottery models of competition, and lottery models of rock-paper-scissor games. A variety of conjectures and suggestions for future research are presented.

Keywords

Cite

@article{arxiv.1109.5967,
  title  = {Persistence for stochastic difference equations: A mini-review},
  author = {Sebastian J. Schreiber},
  journal= {arXiv preprint arXiv:1109.5967},
  year   = {2015}
}

Comments

Accepted for publication in the Journal of Difference Equations and Applications

R2 v1 2026-06-21T19:11:11.830Z