Quantification of Errors Generated by Uncertain Data in a Linear Boundary Value Problem Using Neural Networks

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-11-28 DOI:10.1137/22m1538855
Vilho Halonen, Ilkka Pölönen
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Abstract

SIAM/ASA Journal on Uncertainty Quantification, Volume 11, Issue 4, Page 1258-1277, December 2023.
Abstract. Quantifying errors caused by indeterminacy in data is currently computationally expensive even in relatively simple PDE problems. Efficient methods could prove very useful in, for example, scientific experiments done with simulations. In this paper, we create and test neural networks which quantify uncertainty errors in the case of a linear one-dimensional boundary value problem. Training and testing data is generated numerically. We created three training datasets and three testing datasets and trained four neural networks with differing architectures. The performance of the neural networks is compared to known analytical bounds of errors caused by uncertain data. We find that the trained neural networks accurately approximate the exact error quantity in almost all cases and the neural network outputs are always between the analytical upper and lower bounds. The results of this paper show that after a suitable dataset is used for training even a relatively compact neural network can successfully predict quantitative effects generated by uncertain data. If these methods can be extended to more difficult PDE problems they could potentially have a multitude of real-world applications.
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线性边值问题中不确定数据误差的神经网络量化
SIAM/ASA不确定度量化杂志,第11卷,第4期,1258-1277页,2023年12月。摘要。目前,即使在相对简单的偏微分方程问题中,由数据不确定性引起的量化误差在计算上也是昂贵的。有效的方法可以被证明是非常有用的,例如,用模拟完成的科学实验。在本文中,我们创建并测试了在线性一维边值问题的情况下量化不确定性误差的神经网络。训练和测试数据以数字方式生成。我们创建了三个训练数据集和三个测试数据集,并训练了四个具有不同架构的神经网络。将神经网络的性能与已知的由不确定数据引起的误差的分析界限进行了比较。我们发现,训练后的神经网络几乎在所有情况下都能准确地逼近准确的误差量,神经网络的输出总是在解析上界和下界之间。本文的结果表明,在使用合适的数据集进行训练后,即使是相对紧凑的神经网络也可以成功地预测不确定数据产生的定量效应。如果这些方法可以扩展到更困难的PDE问题,它们可能具有大量实际应用程序。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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