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Autor principal: Kim, Sejin
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2511.06387
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author Kim, Sejin
author_facet Kim, Sejin
contents We study the inverse problem of holographic entanglement entropy in AdS$_3$ using a data-driven generative model. Training data consist of randomly generated geometries and their holographic entanglement entropies using the Ryu--Takayanagi formula. After training, the Transformer reconstructs the blackening function within our metric ansatz from previously unseen inputs. The Transformer achieves accurate reconstructions on smooth black hole geometries and extrapolates to horizonless backgrounds. We describe the architecture and data generation process, and we quantify accuracy on both $f(z)$ and the reconstructed $S(\ell)$. Code and evaluation scripts are available at the provided repository.
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publishDate 2025
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spellingShingle Learning the Inverse Ryu--Takayanagi Formula with Transformers
Kim, Sejin
High Energy Physics - Theory
Machine Learning
We study the inverse problem of holographic entanglement entropy in AdS$_3$ using a data-driven generative model. Training data consist of randomly generated geometries and their holographic entanglement entropies using the Ryu--Takayanagi formula. After training, the Transformer reconstructs the blackening function within our metric ansatz from previously unseen inputs. The Transformer achieves accurate reconstructions on smooth black hole geometries and extrapolates to horizonless backgrounds. We describe the architecture and data generation process, and we quantify accuracy on both $f(z)$ and the reconstructed $S(\ell)$. Code and evaluation scripts are available at the provided repository.
title Learning the Inverse Ryu--Takayanagi Formula with Transformers
topic High Energy Physics - Theory
Machine Learning
url https://arxiv.org/abs/2511.06387