Continuous time random walk and diffusion with generalized fractional Poisson process
Abstract
A non-Markovian counting process, the `generalized fractional Poisson process' (GFPP) introduced by Cahoy and Polito in 2013 is analyzed. The GFPP contains two index parameters , and a time scale parameter. Generalizations to Laskin's fractional Poisson distribution and to the fractional Kolmogorov-Feller equation are derived. We develop a continuous time random walk subordinated to a GFPP in the infinite integer lattice . For this stochastic motion, we deduce a `generalized fractional diffusion equation'. In a well-scaled diffusion limit this motion is governed by the same type of fractional diffusion equation as with the fractional Poisson process exhibiting subdiffusive -power law for the mean-square displacement. In the special cases with the equations of the Laskin fractional Poisson process and for with the classical equations of the standard Poisson process are recovered. The remarkably rich dynamics introduced by the GFPP opens a wide field of applications in anomalous transport and in the dynamics of complex systems.
Cite
@article{arxiv.1907.03830,
title = {Continuous time random walk and diffusion with generalized fractional Poisson process},
author = {Thomas M. Michelitsch and Alejandro P. Riascos},
journal= {arXiv preprint arXiv:1907.03830},
year = {2020}
}
Comments
27 pages, 4 figures. Accepted for publication in Physica A. arXiv admin note: text overlap with arXiv:1906.09704