Quasi-stationary distributions and diffusion models in population dynamics

Quasi-stationary distributions and diffusion models in population dynamics

Patrick Cattiaux, Pierre Collet, Amaury Lambert, Servet Martínez, Sylvie Méléard, and Jaime San Martín

Source: Ann. Probab. Volume 37, Number 5 (2009), 1926-1969.

Abstract

In this paper we study quasi-stationarity for a large class of Kolmogorov diffusions. The main novelty here is that we allow the drift to go to −∞ at the origin, and the diffusion to have an entrance boundary at +∞. These diffusions arise as images, by a deterministic map, of generalized Feller diffusions, which themselves are obtained as limits of rescaled birth–death processes. Generalized Feller diffusions take nonnegative values and are absorbed at zero in finite time with probability 1. An important example is the logistic Feller diffusion.

We give sufficient conditions on the drift near 0 and near +∞ for the existence of quasi-stationary distributions, as well as rate of convergence in the Yaglom limit and existence of the Q-process. We also show that, under these conditions, there is exactly one quasi-stationary distribution, and that this distribution attracts all initial distributions under the conditional evolution, if and only if +∞ is an entrance boundary. In particular, this gives a sufficient condition for the uniqueness of quasi-stationary distributions. In the proofs spectral theory plays an important role on L² of the reference measure for the killed process.

Primary Subjects: 92D25

Secondary Subjects: 37A30, 60K35, 60J60, 60J85, 60J70

Keywords: Quasi-stationary distribution; birth–death process; population dynamics; logistic growth; generalized Feller diffusion; Yaglom limit; convergence rate; Q-process; entrance boundary at infinity

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Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aop/1253539860
Digital Object Identifier: doi:10.1214/09-AOP451
Zentralblatt MATH identifier: 05625056

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