A dynamical systems approach for most probable escape paths over periodic boundaries

Analyzing when noisy trajectories, in the two dimensional plane, of a stochastic dynamical system exit the basin of attraction of a fixed point is specifically challenging when a periodic orbit forms the boundary of the basin of attraction. Our contention is that there is a distinguished Most Probab...

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Bibliographic Details
Published in:Physica. D 2023-11, Vol.454, p.133860, Article 133860
Main Authors: Fleurantin, Emmanuel, Slyman, Katherine, Barker, Blake, Jones, Christopher K.R.T.
Format: Article
Language:English
Subjects:
Dynamics of ordinary differential equations
Friedlin–Wentzell functional
Most Probable Escape Paths
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Summary:Analyzing when noisy trajectories, in the two dimensional plane, of a stochastic dynamical system exit the basin of attraction of a fixed point is specifically challenging when a periodic orbit forms the boundary of the basin of attraction. Our contention is that there is a distinguished Most Probable Escape Path (MPEP) crossing the periodic orbit which acts as a guide for noisy escaping paths in the case of small noise slightly away from the limit of vanishing noise. It is well known that, before exiting, noisy trajectories will tend to cycle around the periodic orbit as the noise vanishes, but we observe that the escaping paths are stubbornly resistant to cycling as soon as the noise becomes at all significant. Using a geometric dynamical systems approach, we isolate a subset of the unstable manifold of the fixed point in the Euler–Lagrange system, which we call the River. Using the Maslov index we identify a subset of the River which is comprised of local minimizers. The Onsager–Machlup (OM) functional, which is treated as a perturbation of the Friedlin–Wentzell functional, provides a selection mechanism to pick out a specific MPEP. Much of the paper is focused on the system obtained by reversing the van der Pol Equations in time (so-called IVDP). Through Monte-Carlo simulations, we show that the prediction provided by OM-selected MPEP matches closely the escape hatch chosen by noisy trajectories at a certain level of small noise. •Noise-induced escape over periodic boundaries for small noise is analyzed.•A geometric approach and the Maslov index are employed to identify local minimizers.•The Onsager–Machlup functional is utilized for most probable escape path selection.•Simulations are compared with theoretical predictions to confirm exit distribution.
ISSN:0167-2789
1872-8022
DOI:10.1016/j.physd.2023.133860