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Autori principali: Berkovich, Jaime A., David, Noah S., Buehler, Markus J.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.17333
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author Berkovich, Jaime A.
David, Noah S.
Buehler, Markus J.
author_facet Berkovich, Jaime A.
David, Noah S.
Buehler, Markus J.
contents Cellular automata (CA) provide a minimal formalism for investigating how simple local interactions generate rich spatiotemporal behavior in domains as diverse as traffic flow, ecology, tissue morphogenesis and crystal growth. However, automatically discovering the local update rules for a given phenomenon and using them for quantitative prediction remains challenging. Here we present AutomataGPT, a decoder-only transformer pretrained on around 1 million simulated trajectories that span 100 distinct two-dimensional binary deterministic CA rules on toroidal grids. When evaluated on previously unseen rules drawn from the same CA family, AutomataGPT attains 98.5% perfect one-step forecasts and reconstructs the governing update rule with up to 96% functional (application) accuracy and 82% exact rule-matrix match. These results demonstrate that large-scale pretraining over wider regions of rule space yields substantial generalization in both the forward (state forecasting) and inverse (rule inference) problems, without hand-crafted priors. By showing that transformer models can faithfully infer and execute CA dynamics from data alone, our work lays the groundwork for abstracting real-world dynamical phenomena into data-efficient CA surrogates, opening avenues in biology, tissue engineering, physics and AI-driven scientific discovery.
format Preprint
id arxiv_https___arxiv_org_abs_2506_17333
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle AutomataGPT: Forecasting and Ruleset Inference for Two-Dimensional Cellular Automata
Berkovich, Jaime A.
David, Noah S.
Buehler, Markus J.
Machine Learning
Disordered Systems and Neural Networks
Materials Science
Quantitative Methods
Cellular automata (CA) provide a minimal formalism for investigating how simple local interactions generate rich spatiotemporal behavior in domains as diverse as traffic flow, ecology, tissue morphogenesis and crystal growth. However, automatically discovering the local update rules for a given phenomenon and using them for quantitative prediction remains challenging. Here we present AutomataGPT, a decoder-only transformer pretrained on around 1 million simulated trajectories that span 100 distinct two-dimensional binary deterministic CA rules on toroidal grids. When evaluated on previously unseen rules drawn from the same CA family, AutomataGPT attains 98.5% perfect one-step forecasts and reconstructs the governing update rule with up to 96% functional (application) accuracy and 82% exact rule-matrix match. These results demonstrate that large-scale pretraining over wider regions of rule space yields substantial generalization in both the forward (state forecasting) and inverse (rule inference) problems, without hand-crafted priors. By showing that transformer models can faithfully infer and execute CA dynamics from data alone, our work lays the groundwork for abstracting real-world dynamical phenomena into data-efficient CA surrogates, opening avenues in biology, tissue engineering, physics and AI-driven scientific discovery.
title AutomataGPT: Forecasting and Ruleset Inference for Two-Dimensional Cellular Automata
topic Machine Learning
Disordered Systems and Neural Networks
Materials Science
Quantitative Methods
url https://arxiv.org/abs/2506.17333