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Autores principales: Kol-Namer, Harel, Goldstein, Moshe
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2411.03980
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author Kol-Namer, Harel
Goldstein, Moshe
author_facet Kol-Namer, Harel
Goldstein, Moshe
contents Neural networks has recently attracted much interest as useful representations of quantum many body ground states, which might help address the infamous sign problem. Most attention was directed at their representability properties, while possible limitations on finding the desired optimal state have not been suitably explored. By leveraging well-established results applicable in the context of infinite width, specifically regarding the renowned neural tangent kernel and conjugate kernel, a comprehensive analysis of the convergence and initialization characteristics of the method is conducted. We reveal the dependence of these characteristics on the interplay among these kernels, the Hamiltonian, and the basis used for its representation. We introduce and motivate novel performance metrics and explore the condition for their optimization. By leveraging these findings, we elucidate a substantial dependence of the effectiveness of this approach on the selected basis, demonstrating that so-called stoquastic Hamiltonians are more amenable to solution through neural networks than those suffering from a sign problem.
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spellingShingle Neural Network Ground State from the Neural Tangent Kernel Perspective: The Sign Bias
Kol-Namer, Harel
Goldstein, Moshe
Quantum Physics
Disordered Systems and Neural Networks
Neural networks has recently attracted much interest as useful representations of quantum many body ground states, which might help address the infamous sign problem. Most attention was directed at their representability properties, while possible limitations on finding the desired optimal state have not been suitably explored. By leveraging well-established results applicable in the context of infinite width, specifically regarding the renowned neural tangent kernel and conjugate kernel, a comprehensive analysis of the convergence and initialization characteristics of the method is conducted. We reveal the dependence of these characteristics on the interplay among these kernels, the Hamiltonian, and the basis used for its representation. We introduce and motivate novel performance metrics and explore the condition for their optimization. By leveraging these findings, we elucidate a substantial dependence of the effectiveness of this approach on the selected basis, demonstrating that so-called stoquastic Hamiltonians are more amenable to solution through neural networks than those suffering from a sign problem.
title Neural Network Ground State from the Neural Tangent Kernel Perspective: The Sign Bias
topic Quantum Physics
Disordered Systems and Neural Networks
url https://arxiv.org/abs/2411.03980