AMS-Net: Adaptive Multiscale Sparse Neural Network with Interpretable Basis Expansion for Multiphase Flow Problems

Yating Wang, W. Leung, Guang Lin
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引用次数: 1

Abstract

In this work, we propose an adaptive sparse learning algorithm that can be applied to learn the physical processes and obtain a sparse representation of the solution given a large snapshot space. Assume that there is a rich class of precomputed basis functions that can be used to approximate the quantity of interest. We then design a neural network architecture to learn the coefficients of solutions in the spaces which are spanned by these basis functions. The information of the basis functions are incorporated in the loss function, which minimizes the differences between the downscaled reduced order solutions and reference solutions at multiple time steps. The network contains multiple submodules and the solutions at different time steps can be learned simultaneously. We propose some strategies in the learning framework to identify important degrees of freedom. To find a sparse solution representation, a soft thresholding operator is applied to enforce the sparsity of the output coefficient vectors of the neural network. To avoid over-simplification and enrich the approximation space, some degrees of freedom can be added back to the system through a greedy algorithm. In both scenarios, that is, removing and adding degrees of freedom, the corresponding network connections are pruned or reactivated guided by the magnitude of the solution coefficients obtained from the network outputs. The proposed adaptive learning process is applied to some toy case examples to demonstrate that it can achieve a good basis selection and accurate approximation. More numerical tests are performed on two-phase multiscale flow problems to show the capability and interpretability of the proposed method on complicated applications.
基于可解释基展开的多相流问题自适应多尺度稀疏神经网络
在这项工作中,我们提出了一种自适应稀疏学习算法,该算法可用于学习物理过程,并获得给定大快照空间的解的稀疏表示。假设有丰富的一类预先计算的基函数,可以用来近似感兴趣的数量。然后,我们设计了一个神经网络架构来学习由这些基函数跨越的空间中解的系数。在损失函数中加入基函数的信息,使降阶解与参考解在多个时间步长的差异最小化。该网络包含多个子模块,可以同时学习不同时间步长的解。我们在学习框架中提出了一些策略来识别重要的自由度。为了找到稀疏解表示,采用软阈值算子来增强神经网络输出系数向量的稀疏性。为了避免过度简化和丰富近似空间,可以通过贪心算法将一些自由度添加回系统。在这两种情况下,即移除自由度和添加自由度,根据从网络输出中获得的解系数的大小,对相应的网络连接进行修剪或重新激活。将所提出的自适应学习过程应用到一些玩具案例中,证明了它可以实现良好的基选择和精确的逼近。通过对两相多尺度流动问题的数值试验,验证了该方法在复杂应用中的适用性。
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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