Saved in:
Bibliographic Details
Main Authors: Lin, Zhi, Wang, Tong, Yue, Sheng
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.14306
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917303686266880
author Lin, Zhi
Wang, Tong
Yue, Sheng
author_facet Lin, Zhi
Wang, Tong
Yue, Sheng
contents The cluster Gutzwiller method is widely used to study the strongly correlated bosonic systems, owing to its ability to provide a more precise description of quantum fluctuations. However, its utility is limited by the exponential increase in computational complexity as the cluster size grows. To overcome this limitation, we propose an artificial intelligence-based method known as $Δ$-Learning. This approach constructs a predictive model by learning the discrepancies between lower-precision (small cluster sizes) and high-precision (large cluster sizes) implementations of the cluster Gutzwiller method, requiring only a small number of training samples. Using this predictive model, we can effectively forecast the outcomes of high-precision methods with high accuracy. Applied to various Bose-Hubbard models, the $Δ$-Learning method effectively predicts phase diagrams while significantly reducing the computational resources and time. Furthermore, we have compared the predictive accuracy of $Δ$-Learning with other direct learning methods and found that $Δ$-Learning exhibits superior performance in scenarios with limited training data. Therefore, when combined with the cluster Gutzwiller approximation, the $Δ$-Learning approach offers a computationally efficient and accurate method for studying phase transitions in large, complex bosonic systems.
format Preprint
id arxiv_https___arxiv_org_abs_2408_14306
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Delta-Learning approach combined with the cluster Gutzwiller approximation for strongly correlated bosonic systems
Lin, Zhi
Wang, Tong
Yue, Sheng
Quantum Gases
The cluster Gutzwiller method is widely used to study the strongly correlated bosonic systems, owing to its ability to provide a more precise description of quantum fluctuations. However, its utility is limited by the exponential increase in computational complexity as the cluster size grows. To overcome this limitation, we propose an artificial intelligence-based method known as $Δ$-Learning. This approach constructs a predictive model by learning the discrepancies between lower-precision (small cluster sizes) and high-precision (large cluster sizes) implementations of the cluster Gutzwiller method, requiring only a small number of training samples. Using this predictive model, we can effectively forecast the outcomes of high-precision methods with high accuracy. Applied to various Bose-Hubbard models, the $Δ$-Learning method effectively predicts phase diagrams while significantly reducing the computational resources and time. Furthermore, we have compared the predictive accuracy of $Δ$-Learning with other direct learning methods and found that $Δ$-Learning exhibits superior performance in scenarios with limited training data. Therefore, when combined with the cluster Gutzwiller approximation, the $Δ$-Learning approach offers a computationally efficient and accurate method for studying phase transitions in large, complex bosonic systems.
title Delta-Learning approach combined with the cluster Gutzwiller approximation for strongly correlated bosonic systems
topic Quantum Gases
url https://arxiv.org/abs/2408.14306