重叠纤维的分离计数算法

纺织学报 ›› 2011, Vol. 32 ›› Issue (5): 43-49.

重叠纤维的分离计数算法

贾立锋

广东工业大学

收稿日期:2010-04-26 修回日期:2011-01-28 出版日期:2011-05-15 发布日期:2011-05-15
通讯作者: 贾立锋

A Algorithm for Segmentation of Interlacing Fibers

Received:2010-04-26 Revised:2011-01-28 Online:2011-05-15 Published:2011-05-15

摘要/Abstract

摘要： 在用显微镜法测试纤维直径和含量时必须统计纤维根数。目前普遍采用人工计数费时费力，精度不高。为了实现计算机自动计数，除用纤维散布器使纤维尽可能分散为单根纤维外，对个别没有分散开的重叠纤维（三根以下）可利用图像处理技术分离纤维。本文首先提取纤维集合体边缘，计算边缘各点倾角曲线，并对此曲线进行小波变换，将纤维头端去除而获得纤维纵向边缘，用Hough变换提取纵向边缘的倾角，对提取的纵向边缘进行配对，从而统计出纤维根数和求取纤维直径，实验表明，本方法统计纤维根数精度高，直径测试准确，符合有关标准要求。

关键词: 小波变换, 直径, 根数, 重叠纤维分离

Abstract: The number of fibers in sample must be obtained to determine diameter of fiber and blending rate of sample. In order to do this automatically a fiber scatter should first be introduced to make fibers interlaced together as less as three. Then image process is employed to distinguish individual fiber. The paper introduced this image process method. First, the edge of interlacing fibers is extracted. Second, the slope angle of tangent at the individual point of edge is calculated to form a curve of slope angle. This curve is wavelet transformed and the dots at the end of fiber are removed because sharp change occurs in the curve. The fiber edge can be restored from the remained dots by Hough transform. These edges are sort out to figure out the amount of interlacing fiber and also diameter of fibers. Experiment shows the accurate is high enough for standards involved.

Key words: Wavelet, diameter, amount of fibers, segmentation of interlacing fibers

中图分类号:

TS101.1

贾立锋. 重叠纤维的分离计数算法[J]. 纺织学报, 2011, 32(5): 43-49.

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