Simple and efficient algorithms for training machine learning potentials to force data.

Justin S. Smith, N. Lubbers, A. Thompson, K. Barros
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引用次数: 6

Abstract

Abstract Machine learning models, trained on data from ab initio quantum simulations, are yielding molecular dynamics potentials with unprecedented accuracy. One limiting factor is the quantity of available training data, which can be expensive to obtain. A quantum simulation often provides all atomic forces, in addition to the total energy of the system. These forces provide much more information than the energy alone. It may appear that training a model to this large quantity of force data would introduce significant computational costs. Actually, training to all available force data should only be a few times more expensive than training to energies alone. Here, we present a new algorithm for efficient force training, and benchmark its accuracy by training to forces from real-world datasets for organic chemistry and bulk aluminum.
用于训练机器学习潜力以强制数据的简单有效算法。
基于从头算量子模拟数据训练的机器学习模型正在以前所未有的精度产生分子动力学势。一个限制因素是可用训练数据的数量,获得这些数据的成本可能很高。除了系统的总能量外,量子模拟通常还提供所有原子力。这些力比能量本身提供了更多的信息。训练一个模型来处理如此大量的力数据似乎会带来巨大的计算成本。实际上,训练所有可用的力数据应该只比训练单独的能量贵几倍。在这里,我们提出了一种高效力训练的新算法,并通过训练来自有机化学和大块铝的真实数据集的力来基准其准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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