Endpoint Detection of Partially Overlapping Straight Fibers using High Positive Gaussian Curvature in 3D images

IF 0.8 4区计算机科学 Q4 IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY

Image Analysis & Stereology Pub Date : 2019-12-13 DOI:10.5566/ias.2197

Markus Kronenberger, K. Schladitz, O. Wirjadi, Christopher Weber, B. Hamann, H. Hagen

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引用次数: 0

Abstract

This paper introduces a method for detecting endpoints of partially overlapping straight fibers in three-dimensional voxel image data. The novel approach directly determines fiber endpoints without the need for more expansive single-fiber segmentation. In the context of fiber-reinforced polymers, endpoint information is of practical significance as it can indicate potential damage in endless fiber systems, or can serve as input for estimating statistical fiber length distribution. We tackle this challenge by exploiting Gaussian curvature of the surface of the fibers. Fiber endpoints have high positive curvature, allowing one to distinguish them from the rest of a structure. Accuracy data of the proposed method are presented for various data sets. For simulated fiber systems with fiber volume fractions of less than 20 %, true positive rates above 94 % and false positive rates below 5 % are observed. Two well-resolved real data sets show a reduction of the first rate to 90.3 % and an increase of the second rate to 13.1 %.

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基于高正高斯曲率的三维图像部分重叠直纤维端点检测

介绍了一种检测三维体素图像数据中部分重叠直纤维端点的方法。这种新方法直接确定光纤端点，而不需要更广泛的单光纤分割。在纤维增强聚合物的研究中，端点信息具有重要的实际意义，因为它可以指示无尽纤维系统中的潜在损伤，也可以作为估计统计纤维长度分布的输入。我们通过利用纤维表面的高斯曲率来解决这个挑战。纤维端点具有很高的正曲率，使人们能够将它们与结构的其余部分区分开来。给出了不同数据集的精度数据。对于纤维体积分数小于20%的模拟纤维系统，观察到真阳性率高于94%，假阳性率低于5%。两个分辨率良好的真实数据集显示，第一个速率降低到90.3%，第二个速率增加到13.1%。

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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来源期刊

Image Analysis & Stereology MATERIALS SCIENCE, MULTIDISCIPLINARY-MATHEMATICS, APPLIED

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Image Analysis and Stereology is the official journal of the International Society for Stereology & Image Analysis. It promotes the exchange of scientific, technical, organizational and other information on the quantitative analysis of data having a geometrical structure, including stereology, differential geometry, image analysis, image processing, mathematical morphology, stochastic geometry, statistics, pattern recognition, and related topics. The fields of application are not restricted and range from biomedicine, materials sciences and physics to geology and geography.