From random Poincar\'e maps to stochastic mixed-mode-oscillation patterns
Abstract
We quantify the effect of Gaussian white noise on fast--slow dynamical systems with one fast and two slow variables, which display mixed-mode oscillations owing to the presence of a folded-node singularity. The stochastic system can be described by a continuous-space, discrete-time Markov chain, recording the returns of sample paths to a Poincar\'e section. We provide estimates on the kernel of this Markov chain, depending on the system parameters and the noise intensity. These results yield predictions on the observed random mixed-mode oscillation patterns. Our analysis shows that there is an intricate interplay between the number of small-amplitude oscillations and the global return mechanism. In combination with a local saturation phenomenon near the folded node, this interplay can modify the number of small-amplitude oscillations after a large-amplitude oscillation. Finally, sufficient conditions are derived which determine when the noise increases the number of small-amplitude oscillations and when it decreases this number.
Cite
@article{arxiv.1312.6353,
title = {From random Poincar\'e maps to stochastic mixed-mode-oscillation patterns},
author = {Nils Berglund and Barbara Gentz and Christian Kuehn},
journal= {arXiv preprint arXiv:1312.6353},
year = {2015}
}
Comments
56 pages, 14 figures; revised version