Long-range memory elementary 1D cellular automata: Dynamics and nonextensivity
Abstract
We numerically study the dynamics of elementary 1D cellular automata (CA), where the binary state of a cell does not only depend on the states in its local neighborhood at time , but also on the memory of its own past states . We assume that the weight of this memory decays proportionally to , with (the limit corresponds to the usual CA). Since the memory function is summable for and nonsummable for , we expect pronounced %qualitative and quantitative changes of the dynamical behavior near . This is precisely what our simulations exhibit, particularly for the time evolution of the Hamming distance of initially close trajectories. We typically expect the asymptotic behavior , where is the entropic index associated with nonextensive statistical mechanics. In all cases, the function exhibits a sensible change at . We focus on the class II rules 61, 99 and 111. For rule 61, for , and for , whereas the opposite behavior is found for rule 111. For rule 99, the effect of the long-range memory on the spread of damage is quite dramatic. These facts point at a rich dynamics intimately linked to the interplay of local lookup rules and the range of the memory. Finite size scaling studies varying system size indicate that the range of the power-law regime for typically diverges with . Similar studies have been carried out for other rules, e.g., the famous "universal computer" rule 110.
Cite
@article{arxiv.cond-mat/0604459,
title = {Long-range memory elementary 1D cellular automata: Dynamics and nonextensivity},
author = {Thimo Rohlf and Constantino Tsallis},
journal= {arXiv preprint arXiv:cond-mat/0604459},
year = {2007}
}
Comments
4 pages revtex, 6 .eps figures