Transition to anomalous dynamics in a simple random map
Abstract
The famous Bernoulli shift (or dyadic transformation) is perhaps the simplest deterministic dynamical system exhibiting chaotic dynamics. It is a piecewise linear time-discrete map on the unit interval with a uniform slope larger than one, hence expanding, with a positive Lyapunov exponent and a uniform invariant density. If the slope is less than one the map becomes contracting, the Lyapunov exponent is negative, and the density trivially collapses onto a fixed point. Sampling from these two different types of maps at each time step by randomly selecting the expanding one with probability , and the contracting one with probability , gives a prototype of a random dynamical system. Here we calculate the invariant density of this simple random map, as well as its position autocorrelation function, analytically and numerically under variation of . We find that the map exhibits a non-trivial transition from fully chaotic to completely regular dynamics by generating a long-time anomalous dynamics at a critical sampling probability , defined by a zero Lyapunov exponent. This anomalous dynamics is characterised by an infinite invariant density, weak ergodicity breaking and power law correlation decay.
Cite
@article{arxiv.2308.09269,
title = {Transition to anomalous dynamics in a simple random map},
author = {Jin Yan and Moitrish Majumdar and Stefano Ruffo and Yuzuru Sato and Christian Beck and Rainer Klages},
journal= {arXiv preprint arXiv:2308.09269},
year = {2024}
}
Comments
22 pages, 6 figures