A feature fusion-based line structured light 3-D imaging method.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-10-10 DOI:10.1038/s41598-025-19500-x

Jingjing Lou, Liangliang Sun, Yunhan Li, Chuan Ye, Yuhang Jiang

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引用次数: 0

Abstract

To address the challenges of uneven illumination, background noise, and low contrast in laser stripe center extraction in industrial environments such as measurement, this paper proposes a line laser 3D measurement method based on feature fusion. First, a multi-feature fusion detection model is constructed to obtain the brightness feature map and region-enhanced feature map of the laser stripe. Then, wavelet transform is used to fuse the brightness feature map and the region-enhanced feature map, followed by segmentation of the fused feature map using an adaptive maximum entropy method. Next, a gray-gravity method optimized by gradient direction and curvature is employed to determine the initial center points of the laser stripe. Finally, adaptive segmentation based on neighborhood differences is performed, and polynomial fitting is applied to the segmented stripes to obtain the final laser stripe centers. Experimental results show that, under a noise variance of 0.3, the maximum error in laser stripe extraction is less than 1.07 pixels, the width error between different rows is less than 0.24 mm, and the mean error of repeatability extraction is less than 0.13 mm.

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一种基于特征融合的线结构光三维成像方法。

针对测量等工业环境中激光条纹中心提取存在光照不均匀、背景噪声、对比度低等问题，提出了一种基于特征融合的直线激光三维测量方法。首先，构建多特征融合检测模型，得到激光条纹的亮度特征图和区域增强特征图；然后利用小波变换对亮度特征映射和区域增强特征映射进行融合，然后利用自适应最大熵法对融合后的特征映射进行分割；其次，采用梯度方向和曲率优化的灰度-重力法确定激光条纹的初始中心点；最后，基于邻域差异进行自适应分割，对分割后的条纹进行多项式拟合，得到最终的激光条纹中心。实验结果表明，在噪声方差为0.3的情况下，激光条纹提取的最大误差小于1.07像素，行间宽度误差小于0.24 mm，重复性提取的平均误差小于0.13 mm。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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