A statistical learning framework for mapping indirect measurements of ergodic systems to emergent properties

IF 2.624
Nicholas Hindley , Stephen J. DeVience , Ella Zhang , Leo L. Cheng , Matthew S. Rosen
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引用次数: 0

Abstract

The discovery of novel experimental techniques often lags behind contemporary theoretical understanding. In particular, it can be difficult to establish appropriate measurement protocols without analytic descriptions of the underlying system-of-interest. Here we propose a statistical learning framework that avoids the need for such descriptions for ergodic systems. We validate this framework by using Monte Carlo simulation and deep neural networks to learn a mapping between nuclear magnetic resonance spectra acquired on a novel low-field instrument and proton exchange rates in ethanol-water mixtures. We found that trained networks exhibited normalized-root-mean-square errors of less than 1 % for exchange rates under 150 s−1 but performed poorly for rates above this range. This differential performance occurred because low-field measurements are indistinguishable from one another for fast exchange. Nonetheless, where a discoverable relationship between indirect measurements and emergent dynamics exists, we demonstrate the possibility of approximating it in an efficient, data-driven manner.

Abstract Image

将遍历系统的间接测量结果映射到突发特性的统计学习框架
新型实验技术的发现往往落后于当代的理论认识。特别是,如果没有对相关基础系统的分析描述,就很难建立适当的测量协议。在这里,我们提出了一种统计学习框架,可以避免对遍历系统进行此类描述。我们利用蒙特卡罗模拟和深度神经网络来学习新型低场仪器获取的核磁共振谱与乙醇-水混合物中质子交换率之间的映射,从而验证了这一框架。我们发现,训练有素的网络在交换率低于 150 s-1 时的归一化均方根误差小于 1%,但在交换率高于此范围时表现不佳。出现这种性能差异的原因是,在快速交换时,低场测量结果无法相互区分。尽管如此,当间接测量和突发动力学之间存在可发现的关系时,我们证明了以高效、数据驱动的方式近似处理这种关系的可能性。
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CiteScore
1.90
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0.00%
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