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Hauptverfasser: Tuo, Kui, Deng, Shengfeng, Yang, Yuxiang, Wang, Yanyang, Wang, Qiuping A., Li, Wei, Zhang, Wenjun
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2509.10209
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author Tuo, Kui
Deng, Shengfeng
Yang, Yuxiang
Wang, Yanyang
Wang, Qiuping A.
Li, Wei
Zhang, Wenjun
author_facet Tuo, Kui
Deng, Shengfeng
Yang, Yuxiang
Wang, Yanyang
Wang, Qiuping A.
Li, Wei
Zhang, Wenjun
contents The local rules of Wolfram cellular automata with one-dimensional three-cell neighborhoods are represented by eight-bit binary that encode deterministic update rules. These automata are widely utilized to investigate self-organization phenomena and the dynamics of complex systems. In this work, we employ numerical simulations and computational methods to investigate the asymptotic density and dynamical evolution mechanisms in Wolfram automata. We apply both supervised and unsupervised learning methods to identify the configurations associated with different Wolfram rules. Furthermore, we explore alternative initial conditions under which certain Wolfram rules generate similar fractal patterns over time, even when starting from a single active site. Our results reveal the relationship between the asymptotic density and the initial density of selected rules. The supervised learning methods effectively identify the configurations of various Wolfram rules, while unsupervised methods like principal component analysis and autoencoders can approximately cluster configurations of different Wolfram rules into distinct groups, yielding results that align well with simulated density outputs.
format Preprint
id arxiv_https___arxiv_org_abs_2509_10209
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Supervised and unsupervised learning with numerical computation for the Wolfram cellular automata
Tuo, Kui
Deng, Shengfeng
Yang, Yuxiang
Wang, Yanyang
Wang, Qiuping A.
Li, Wei
Zhang, Wenjun
Computational Physics
The local rules of Wolfram cellular automata with one-dimensional three-cell neighborhoods are represented by eight-bit binary that encode deterministic update rules. These automata are widely utilized to investigate self-organization phenomena and the dynamics of complex systems. In this work, we employ numerical simulations and computational methods to investigate the asymptotic density and dynamical evolution mechanisms in Wolfram automata. We apply both supervised and unsupervised learning methods to identify the configurations associated with different Wolfram rules. Furthermore, we explore alternative initial conditions under which certain Wolfram rules generate similar fractal patterns over time, even when starting from a single active site. Our results reveal the relationship between the asymptotic density and the initial density of selected rules. The supervised learning methods effectively identify the configurations of various Wolfram rules, while unsupervised methods like principal component analysis and autoencoders can approximately cluster configurations of different Wolfram rules into distinct groups, yielding results that align well with simulated density outputs.
title Supervised and unsupervised learning with numerical computation for the Wolfram cellular automata
topic Computational Physics
url https://arxiv.org/abs/2509.10209