相干衍射成像缺陷识别的自动连续学习

2022 IEEE/ACM International Workshop on Artificial Intelligence and Machine Learning for Scientific Applications (AI4S) Pub Date : 2022-11-01 DOI:10.1109/AI4S56813.2022.00006

Orcun Yildiz, Henry Chan, Krishnan Raghavan, W. Judge, M. Cherukara, Prasanna Balaprakash, S. Sankaranarayanan, T. Peterka

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引用次数: 0

摘要

x射线布拉格相干衍射成像(BCDI)广泛应用于材料表征。然而，获得x射线衍射数据是困难和计算密集的。在这里，我们引入了一种机器学习方法来从原始相干衍射数据中识别样品中的晶线缺陷。为了实现这一过程的自动化，我们构建了一个耦合相干衍射数据生成与深度神经网络缺陷分类器的训练和推理的工作流程。特别地，我们采用持续学习的方法，我们根据缺陷分类器的准确性生成所需的训练和推理数据，而不是先验地生成所有的训练数据。结果表明，我们的方法在使用更少的数据样本的同时提高了缺陷分类器的准确性。

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Automated Continual Learning of Defect Identification in Coherent Diffraction Imaging

X-ray Bragg coherent diffraction imaging (BCDI) is widely used for materials characterization. However, obtaining X-ray diffraction data is difficult and computationally intensive. Here, we introduce a machine learning approach to identify crystalline line defects in samples from the raw coherent diffraction data. To automate this process, we compose a workflow coupling coherent diffraction data generation with training and inference of deep neural network defect classifiers. In particular, we adopt a continual learning approach, where we generate training and inference data as needed based on the accuracy of the defect classifier instead of all training data generated a priori. The results show that our approach improves the accuracy of defect classifiers while using much fewer samples of data.

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2022 IEEE/ACM International Workshop on Artificial Intelligence and Machine Learning for Scientific Applications (AI4S)

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