English

First exit times for L\'evy-driven diffusions with exponentially light jumps

Probability 2009-06-10 v2

Abstract

We consider a dynamical system described by the differential equation Y˙t=U(Yt)\dot{Y}_t=-U'(Y_t) with a unique stable point at the origin. We perturb the system by the L\'evy noise of intensity ε\varepsilon to obtain the stochastic differential equation dXtε=U(Xtε)dt+εdLt.dX^{\varepsilon}_t=-U'(X^{\varepsilon}_{t-}) dt+\varepsilon dL_t. The process LL is a symmetric L\'evy process whose jump measure ν\nu has exponentially light tails, ν([u,))exp(uα)\nu([u,\infty))\sim\exp(-u^{\alpha}), α>0\alpha>0, uu\to \infty. We study the first exit problem for the trajectories of the solutions of the stochastic differential equation from the interval (1,1)(-1,1). In the small noise limit ε0\varepsilon\to0, the law of the first exit time σx\sigma_x, x(1,1)x\in(-1,1), has exponential tail and the mean value exhibiting an intriguing phase transition at the critical index α=1\alpha=1, namely, lnEσεα\ln\mathbf{E}\sigma\sim\varepsilon^{-\alpha} for 0<α<10<\alpha<1, whereas lnEσε1lnε11/α\ln\mathbf{E}\sigma\sim\varepsilon^{- 1}|\ln\varepsilon|^{1-{1}/{\alpha}} for α>1\alpha>1.

Keywords

Cite

@article{arxiv.0711.0982,
  title  = {First exit times for L\'evy-driven diffusions with exponentially light jumps},
  author = {Peter Imkeller and Ilya Pavlyukevich and Torsten Wetzel},
  journal= {arXiv preprint arXiv:0711.0982},
  year   = {2009}
}

Comments

Published in at http://dx.doi.org/10.1214/08-AOP412 the Annals of Probability (http://www.imstat.org/aop/) by the Institute of Mathematical Statistics (http://www.imstat.org)

R2 v1 2026-06-21T09:40:35.635Z