Physics-informed machine learning (PIML) has emerged as a promising new approach for simulating complex physical and biological systems that are governed by complex multiscale processes for which some data are also available. In some instances, the objective is to discover part of the hidden physics from the available data, and PIML has been shown to be particularly effective for such problems for which conventional methods may fail. Unlike commercial machine learning where training of deep neural networks requires big data, in PIML big data are not available. Instead, we can train such networks from additional information obtained by employing the physical laws and evaluating them at random points in the space-time domain. Such physics-informed machine learning integrates multimodality and multifidelity data with mathematical models, and implements them using neural networks or graph networks. Here, we review some of the prevailing trends in embedding physics into machine learning, using physics-informed neural networks (PINNs) based primarily on feed-forward neural networks and automatic differentiation. For more complex systems or systems of systems and unstructured data, graph neural networks (GNNs) present some distinct advantages, and here we review how physics-informed learning can be accomplished with GNNs based on graph exterior calculus to construct differential operators; we refer to these architectures as physics-informed graph networks (PIGNs). We present representative examples for both forward and inverse problems and discuss what advances are needed to scale up PINNs, PIGNs and more broadly GNNs for large-scale engineering problems.
翻译:物理知情机器学习(PIMML)是模拟复杂物理和生物系统的一种有希望的新办法,这种系统由复杂的多尺度过程管理,有些数据也可用,在某些情况下,目标是从现有数据中发现隐藏的物理部分,而PIML已证明对常规方法可能失败的问题特别有效。与商业机器学习不同,深神经网络培训需要大数据,而PIML大数据则不可用。相反,我们可以从利用物理法和在空间-时空随机点评价物理法和生物系统而获得的额外信息来培训这种网络。这种物理知情机器学习将多式联运和多纤维数据与数学模型相结合,并使用神经网络或图形网络加以实施。在这里,我们审查将物理嵌入机器学习的一些普遍趋势,使用物理智能神经网络(PNNN)主要依靠供养的神经网络和自动区分。对于更为复杂的系统或系统系统以及非结构化的数据、图形神经网络(GNNNP)来说有一些明显的优势,在这里,我们审查如何将物理学和多纤维的多纤维模型化的网络作为基础,我们如何将GNP-G-G-G-G-G-G-G-rodal-rodeal-gradeal的模型用于前进进进进进进进进的模型,我们如何将这些系统和进进进进进进进进进进进进进进进进进进进的模型,我们把这些系统和G-我们把进进进进进进进进进进的G-我们把进的G-进的G-进的系统和进进进进的G-进进进进进进进进进进进的G-进进进进进的进进进进进的进的G-进的进的G-进的G-进的G-进的G-进的G-进的进的G-进的进的进的进的进的进的进的进的进的进的进的进的进的进的进的进的进的进的研。