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Autori principali: Chertenkov, Vladislav, Shchur, Lev
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.13027
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author Chertenkov, Vladislav
Shchur, Lev
author_facet Chertenkov, Vladislav
Shchur, Lev
contents The main question raised in the article is whether a neural network trained on a spin lattice model in one universality class can be used to test a model in another universality class. The quantities of interest are the critical phase transition temperature and the correlation length exponent. In other words, the question of transfer learning is how ``universal'' the trained network is and under what conditions. For this purpose, we applied a supervised learning procedure to three two-dimensional models for which critical properties are precisely known: the Ising model, the four-state Potts model, and the Baxter-Wu model. We consider two datasets: one with spins configurations and one with binding energy configurations. We find that estimates of the critical temperature agree well with the known results for both datasets, but not with the results of cross-testing using the energy datasets of the two models: the four-state Potts model and the Ising model. Estimates of the critical length exponent are less regular, and appear to be more accurate for energy datasets. A good example is the cross-testing using the energy dataset between Ising model and Baxter-Wu model in both training and testing directions.12
format Preprint
id arxiv_https___arxiv_org_abs_2411_13027
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Machine Learning Domain Adaptation in Spin Models with Continuous Phase Transitions
Chertenkov, Vladislav
Shchur, Lev
Statistical Mechanics
The main question raised in the article is whether a neural network trained on a spin lattice model in one universality class can be used to test a model in another universality class. The quantities of interest are the critical phase transition temperature and the correlation length exponent. In other words, the question of transfer learning is how ``universal'' the trained network is and under what conditions. For this purpose, we applied a supervised learning procedure to three two-dimensional models for which critical properties are precisely known: the Ising model, the four-state Potts model, and the Baxter-Wu model. We consider two datasets: one with spins configurations and one with binding energy configurations. We find that estimates of the critical temperature agree well with the known results for both datasets, but not with the results of cross-testing using the energy datasets of the two models: the four-state Potts model and the Ising model. Estimates of the critical length exponent are less regular, and appear to be more accurate for energy datasets. A good example is the cross-testing using the energy dataset between Ising model and Baxter-Wu model in both training and testing directions.12
title Machine Learning Domain Adaptation in Spin Models with Continuous Phase Transitions
topic Statistical Mechanics
url https://arxiv.org/abs/2411.13027