Collocation based training of neural ordinary differential equations.

Pub Date : 2021-07-09 DOI:10.1515/sagmb-2020-0025
Elisabeth Roesch, Christopher Rackauckas, Michael P H Stumpf
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引用次数: 17

Abstract

The predictive power of machine learning models often exceeds that of mechanistic modeling approaches. However, the interpretability of purely data-driven models, without any mechanistic basis is often complicated, and predictive power by itself can be a poor metric by which we might want to judge different methods. In this work, we focus on the relatively new modeling techniques of neural ordinary differential equations. We discuss how they relate to machine learning and mechanistic models, with the potential to narrow the gulf between these two frameworks: they constitute a class of hybrid model that integrates ideas from data-driven and dynamical systems approaches. Training neural ODEs as representations of dynamical systems data has its own specific demands, and we here propose a collocation scheme as a fast and efficient training strategy. This alleviates the need for costly ODE solvers. We illustrate the advantages that collocation approaches offer, as well as their robustness to qualitative features of a dynamical system, and the quantity and quality of observational data. We focus on systems that exemplify some of the hallmarks of complex dynamical systems encountered in systems biology, and we map out how these methods can be used in the analysis of mathematical models of cellular and physiological processes.

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基于配置的神经常微分方程训练。
机器学习模型的预测能力往往超过机械建模方法。然而,没有任何机制基础的纯数据驱动模型的可解释性通常是复杂的,并且预测能力本身可能是一个糟糕的度量标准,我们可能希望通过它来判断不同的方法。在这项工作中,我们专注于相对较新的神经常微分方程建模技术。我们将讨论它们如何与机器学习和机械模型相关联,并有可能缩小这两个框架之间的鸿沟:它们构成了一类混合模型,集成了数据驱动和动态系统方法的思想。训练神经ode作为动态系统数据的表示有其特定的要求,本文提出了一种快速有效的训练策略。这减少了对昂贵的ODE求解器的需求。我们说明了搭配方法提供的优势,以及它们对动力系统定性特征的鲁棒性,以及观测数据的数量和质量。我们专注于系统生物学中遇到的复杂动力系统的一些典型特征的系统,并且我们绘制了如何将这些方法用于细胞和生理过程的数学模型分析。
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