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一种用于定量金相学的端到端计算机视觉方法。

An end-to-end computer vision methodology for quantitative metallography.

机构信息

Scientific Computing Center, Nuclear Research Center-Negev, Be'er-Sheva, Israel.

Department of Physics, Nuclear Research Center-Negev, Be'er-Sheva, Israel.

出版信息

Sci Rep. 2022 Mar 21;12(1):4776. doi: 10.1038/s41598-022-08651-w.

DOI:10.1038/s41598-022-08651-w
PMID:35314725
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8938431/
Abstract

Metallography is crucial for a proper assessment of material properties. It mainly involves investigating the spatial distribution of grains and the occurrence and characteristics of inclusions or precipitates. This work presents a holistic few-shot artificial intelligence model for Quantitative Metallography, including Anomaly Detection, that automatically quantifies the degree of the anomaly of impurities in alloys. We suggest the following examination process: (1) deep semantic segmentation is performed on the inclusions (based on a suitable metallographic dataset of alloys and corresponding tags of inclusions), producing inclusions masks that are saved into a separated dataset. (2) Deep image inpainting is performed to fill the removed inclusions parts, resulting in 'clean' metallographic images, which contain the background of grains. (3) Grains' boundaries are marked using deep semantic segmentation (based on another metallographic dataset of alloys), producing boundaries that are ready for further inspection on the distribution of grains' size. (4) Deep anomaly detection and pattern recognition is performed on the inclusions masks to determine spatial, shape, and area anomaly detection of the inclusions. Finally, the end-to-end model recommends an expert on areas of interest for further examination. The physical result can re-tune the model according to the specific material at hand. Although the techniques presented here were developed for metallography analysis, most of them can be generalized to a broader set of microscopy problems that require automation. All source-codes as well as the datasets that were created for this work, are publicly available at https://github.com/Scientific-Computing-Lab-NRCN/MLography .

摘要

金相学对于正确评估材料性能至关重要。它主要涉及研究晶粒的空间分布以及夹杂物或沉淀物的出现和特征。这项工作提出了一种整体的少镜头人工智能模型,用于定量金相学,包括异常检测,它可以自动量化合金中杂质异常的程度。我们建议以下检查过程:(1)对夹杂物进行深度语义分割(基于适当的金相合金数据集和相应的夹杂物标签),生成夹杂物掩模,并将其保存到单独的数据集。(2)进行深度图像修复,以填充去除的夹杂物部分,生成包含晶粒背景的“干净”金相图像。(3)使用深度语义分割标记晶粒边界(基于另一组金相合金数据集),生成准备好进一步检查晶粒尺寸分布的边界。(4)对夹杂物掩模进行深度异常检测和模式识别,以确定夹杂物的空间、形状和面积异常检测。最后,端到端模型为感兴趣的区域推荐专家进行进一步检查。物理结果可以根据手头的特定材料重新调整模型。虽然这里介绍的技术是为金相分析开发的,但其中大多数技术可以推广到更广泛的需要自动化的显微镜问题。所有的源代码以及为这项工作创建的数据集都可以在 https://github.com/Scientific-Computing-Lab-NRCN/MLography 上获得。

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2
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3
Deep learning-based automatic inpainting for material microscopic images.基于深度学习的材料微观图像自动修复。
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4
Deep learning for cellular image analysis.深度学习在细胞图像分析中的应用。
Nat Methods. 2019 Dec;16(12):1233-1246. doi: 10.1038/s41592-019-0403-1. Epub 2019 May 27.
5
High Throughput Quantitative Metallography for Complex Microstructures Using Deep Learning: A Case Study in Ultrahigh Carbon Steel.基于深度学习的复杂微观结构高通量定量金相学:以超高碳钢为例
Microsc Microanal. 2019 Feb;25(1):21-29. doi: 10.1017/S1431927618015635.
6
Deep Learning in Microscopy Image Analysis: A Survey.深度学习在显微镜图像分析中的应用:综述。
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7
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8
Fully Convolutional Networks for Semantic Segmentation.全卷积网络用于语义分割。
IEEE Trans Pattern Anal Mach Intell. 2017 Apr;39(4):640-651. doi: 10.1109/TPAMI.2016.2572683. Epub 2016 May 24.
9
A Comparative Evaluation of Unsupervised Anomaly Detection Algorithms for Multivariate Data.多元数据无监督异常检测算法的比较评估
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10
A computational approach to edge detection.一种基于计算的边缘检测方法。
IEEE Trans Pattern Anal Mach Intell. 1986 Jun;8(6):679-98.