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Hauptverfasser: Shen, Jianmin, Li, Wei, Deng, Shengfeng, Zhang, Tao
Format: Preprint
Veröffentlicht: 2021
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Online-Zugang:https://arxiv.org/abs/2101.06392
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author Shen, Jianmin
Li, Wei
Deng, Shengfeng
Zhang, Tao
author_facet Shen, Jianmin
Li, Wei
Deng, Shengfeng
Zhang, Tao
contents Machine learning (ML) has been well applied to studying equilibrium phase transition models, by accurately predicating critical thresholds and some critical exponents. Difficulty will be raised, however, for integrating ML into non-equilibrium phase transitions. The extra dimension in a given non-equilibrium system, namely time, can greatly slow down the procedure towards the steady state. In this paper we find that by using some simple techniques of ML, non-steady state configurations of directed percolation (DP) suffice to capture its essential critical behaviors in both (1+1) and (2+1) dimensions. With the supervised learning method, the framework of our binary classification neural networks can identify the phase transition threshold, as well as the spatial and temporal correlation exponents. The characteristic time $t_{c}$, specifying the transition from active phases to absorbing ones, is also a major product of the learning. Moreover, we employ the convolutional autoencoder, an unsupervised learning technique, to extract dimensionality reduction representations and cluster configurations of (1+1) bond DP. It is quite appealing that such a method can yield a reasonable estimation of the critical point.
format Preprint
id arxiv_https___arxiv_org_abs_2101_06392
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Supervised and unsupervised learning of directed percolation
Shen, Jianmin
Li, Wei
Deng, Shengfeng
Zhang, Tao
Statistical Mechanics
Computational Physics
Machine learning (ML) has been well applied to studying equilibrium phase transition models, by accurately predicating critical thresholds and some critical exponents. Difficulty will be raised, however, for integrating ML into non-equilibrium phase transitions. The extra dimension in a given non-equilibrium system, namely time, can greatly slow down the procedure towards the steady state. In this paper we find that by using some simple techniques of ML, non-steady state configurations of directed percolation (DP) suffice to capture its essential critical behaviors in both (1+1) and (2+1) dimensions. With the supervised learning method, the framework of our binary classification neural networks can identify the phase transition threshold, as well as the spatial and temporal correlation exponents. The characteristic time $t_{c}$, specifying the transition from active phases to absorbing ones, is also a major product of the learning. Moreover, we employ the convolutional autoencoder, an unsupervised learning technique, to extract dimensionality reduction representations and cluster configurations of (1+1) bond DP. It is quite appealing that such a method can yield a reasonable estimation of the critical point.
title Supervised and unsupervised learning of directed percolation
topic Statistical Mechanics
Computational Physics
url https://arxiv.org/abs/2101.06392