Trajectory statistics of confined L\'evy flights and Boltzmann-type equilibria

Abstract

We analyze a specific class of random systems that are driven by a symmetric L\'evy stable noise, where Langevin representation is absent. In view of the L\'evy noise sensitivity to environmental inhomogeneities, the pertinent random motion asymptotically sets down at the Boltzmann-type equilibrium, represented by a probability density function (pdf) *(x) [- (x)]. Here, we infer pdf (x,t) based on numerical path-wise simulation of the underlying jump-type process. A priori given data are jump transition rates entering the master equation for (x,t) and its target pdf *(x). To simulate the above processes, we construct a suitable modification of the Gillespie algorithm, originally invented in the chemical kinetics context. We exemplified our algorithm simulating different jump-type processes and discuss the dynamics of real physical systems where it can be useful.