Jorge I. Hernandez-Martinez, Gerardo Rodriguez-Hernandez, Andres Mendez-Vazquez
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引用次数: 0
摘要
我们提出了一种数据驱动的方法,利用受限玻尔兹曼机(RBM)来求解构型空间中的薛定谔方程。传统的配置交互(CI)方法虽然功能强大,但由于需要大量的行列式,因此计算成本很高。我们的方法利用 RBM 高效地识别和采样最重要的行列式,加快了收敛速度并降低了计算成本。与完整的 CI 计算相比,这种方法即使减少了四个数量级的行列式,也能实现高达 99.99% 的相关能量,比以前的技术水平低两个数量级。此外,我们的研究表明,RBM 可以学习潜在的量子特性,提供比其他方法更详细的见解。这种创新的数据驱动方法为量子化学提供了一种前景广阔的工具,既提高了效率,又加深了对复杂系统的理解。
Configuration Interaction Guided Sampling with Interpretable Restricted Boltzmann Machine
We propose a data-driven approach using a Restricted Boltzmann Machine (RBM)
to solve the Schr\"odinger equation in configuration space. Traditional
Configuration Interaction (CI) methods, while powerful, are computationally
expensive due to the large number of determinants required. Our approach
leverages RBMs to efficiently identify and sample the most significant
determinants, accelerating convergence and reducing computational cost. This
method achieves up to 99.99\% of the correlation energy even by four orders of
magnitude less determinants compared to full CI calculations and up to two
orders of magnitude less than previous state of the art works. Additionally,
our study demonstrate that the RBM can learn the underlying quantum properties,
providing more detail insights than other methods . This innovative data-driven
approach offers a promising tool for quantum chemistry, enhancing both
efficiency and understanding of complex systems.
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