Prediction in a driven-dissipative system displaying a continuous phase transition
Abstract
Prediction in complex systems at criticality is believed to be very difficult, if not impossible. Of particular interest is whether earthquakes, whose distribution follows a power law (Gutenberg-Richter) distribution, are in principle unpredictable. We study the predictability of event sizes in the Olmai-Feder-Christensen model at different proximities to criticality using a convolutional neural network. The distribution of event sizes satisfies a power law with a cutoff for large events. We find that prediction decreases as criticality is approached and that prediction is possible only for large, non-scaling events. Our results suggest that earthquake faults that satisfy Gutenberg-Richter scaling are difficult to forecast.
Cite
@article{arxiv.1907.11790,
title = {Prediction in a driven-dissipative system displaying a continuous phase transition},
author = {Chon-Kit Pun and Sakib Matin and W. Klein and Harvey Gould},
journal= {arXiv preprint arXiv:1907.11790},
year = {2020}
}
Comments
12 pages, 6 figures