Noise corrections to stochastic trace formulas

We review studies of an evolution operator ${\cal L}$ for a discrete Langevin equation with a strongly hyperbolic classical dynamics and a Gaussian noise. The leading eigenvalue of ${\cal L}$ yields a physically measurable property of the dynamical system, the escape rate from the repeller. The spec...

Full description

Saved in:
Bibliographic Details
Published in:Foundations of physics 2001, Vol.31, p.641-657
Main Authors: Palla, G., Vattay, G., Voros, André, Søndergaard, N., Dettmann, C.P.
Format: Article
Language:English
Subjects:
Chaotic Dynamics
General Physics
Nonlinear Sciences
Physics
Citations: Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We review studies of an evolution operator ${\cal L}$ for a discrete Langevin equation with a strongly hyperbolic classical dynamics and a Gaussian noise. The leading eigenvalue of ${\cal L}$ yields a physically measurable property of the dynamical system, the escape rate from the repeller. The spectrum of the evolution operator ${\cal L}$ in the weak noise limit can be computed in several ways. A method using a local matrix representation of the operator allows to push the corrections to the escape rate up to order eight in the noise expansion parameter. These corrections then appear to form a divergent series. Actually, via a cumulant expansion, they relate to analogous divergent series for other quantities, the traces of the evolution operators ${\cal L}^n$. Using an integral representation of the evolution operator ${\cal L},$ we then investigate the high order corrections to the latter traces. Their asymptotic behavior is found to be controlled by sub-dominant saddle points previously neglected in the perturbative expansion, and to be ultimately described by a kind of trace formula.
ISSN:0015-9018
1572-9516
DOI:10.1023/A:1017569010085