通过深度学习发现玻色-爱因斯坦凝聚体中隐藏的物理机制

IF 1.5 4区 物理与天体物理 Q3 OPTICS
Xiao-Dong Bai, Hao Xu, Dongxiao Zhang
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引用次数: 0

摘要

摘要发现系统隐藏的物理机制,如潜在的偏微分方程(PDEs),是一个有趣的课题,但尚未得到充分探索。特别是,如何超越传统方法获取复杂系统的 PDEs,目前正在积极讨论之中。在这项工作中,我们提出了一种深度学习方法来发现一维玻色-爱因斯坦凝聚体(BECs)的底层格罗斯-皮塔耶夫斯基方程(GPEs)。结果表明,由于深度神经网络的优势,这种方法明显优于传统方法。前者能够获得精度高、对数据噪声不敏感的拟合模型,即使在没有知识结构的情况下,也能成功地从数据中直接发现玻色-爱因斯坦凝聚体应遵守的底层 GPE。更重要的是,我们发现这种方法即使在数据具有(15%)噪声的情况下也能很好地工作。虽然研究的案例只是概念验证,但该方法为从观测中揭示量子系统中隐藏的新物理机制提供了一种很有前途的技术。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Discovering hidden physical mechanisms in Bose–Einstein condensates via deep-learning

Discovering hidden physical mechanisms in Bose–Einstein condensates via deep-learning

Discovering hidden physical mechanisms of a system, such as underlying partial differential equations (PDEs), is an intriguing subject that has not yet been fully explored. In particular, how to go beyond the traditional method to obtain the PDEs of complex systems is currently under active debate. In this work, we propose a deep-learning approach to discover the underlying Gross-Pitaevskii equations (GPEs) of one-dimensional Bose–Einstein condensates (BECs). The results show that such method is markedly superior to the traditional method due to advantages of the deep neural network. The former possesses the ability to obtain a parsimonious model with high accuracy and insensitivity to data noise, and can successfully discover the underlying GPEs that BECs should obey directly from the data even in the absence of a knowledge structure. More importantly, we find that such method is able to work well even for data with \(15\%\) noise. Although the cases studied are proof-of-concept, the method provides a promising technique for unveiling hidden novel physical mechanisms in quantum systems from observations.

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来源期刊
The European Physical Journal D
The European Physical Journal D 物理-物理:原子、分子和化学物理
CiteScore
3.10
自引率
11.10%
发文量
213
审稿时长
3 months
期刊介绍: The European Physical Journal D (EPJ D) presents new and original research results in: Atomic Physics; Molecular Physics and Chemical Physics; Atomic and Molecular Collisions; Clusters and Nanostructures; Plasma Physics; Laser Cooling and Quantum Gas; Nonlinear Dynamics; Optical Physics; Quantum Optics and Quantum Information; Ultraintense and Ultrashort Laser Fields. The range of topics covered in these areas is extensive, from Molecular Interaction and Reactivity to Spectroscopy and Thermodynamics of Clusters, from Atomic Optics to Bose-Einstein Condensation to Femtochemistry.
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