Critical branching processes in digital memcomputing machines
Abstract
Memcomputing is a novel computing paradigm that employs time non-locality (memory) to solve combinatorial optimization problems. It can be realized in practice by means of non-linear dynamical systems whose point attractors represent the solutions of the original problem. It has been previously shown that during the solution search digital memcomputing machines go through a transient phase of avalanches (instantons) that promote dynamical long-range order. By employing mean-field arguments we predict that the distribution of the avalanche sizes follows a Borel distribution typical of critical branching processes with exponent . We corroborate this analysis by solving various random 3-SAT instances of the Boolean satisfiability problem. The numerical results indicate a power-law distribution with exponent , in very good agreement with the mean-field analysis. This indicates that memcomputing machines self-tune to a critical state in which avalanches are characterized by a branching process, and that this state persists across the majority of their evolution.
Cite
@article{arxiv.1904.04899,
title = {Critical branching processes in digital memcomputing machines},
author = {Sean R. B. Bearden and Forrest C. Sheldon and Massimiliano Di Ventra},
journal= {arXiv preprint arXiv:1904.04899},
year = {2020}
}
Comments
5 pages, 3 figures