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一种新型同心圆形编码靶标及其在复杂条件下视觉测量的定位与识别方法。

A Novel Concentric Circular Coded Target, and Its Positioning and Identifying Method for Vision Measurement under Challenging Conditions.

作者信息

Liu Yan, Su Xin, Guo Xiang, Suo Tao, Yu Qifeng

机构信息

College of Physics and Optoelectronic Engineering, Shenzhen University, Shenzhen 518060, China.

Institute of Intelligent Optical Measurement and Detection, Shenzhen University, Shenzhen 518060, China.

出版信息

Sensors (Basel). 2021 Jan 28;21(3):855. doi: 10.3390/s21030855.

DOI:10.3390/s21030855
PMID:33525342
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7866129/
Abstract

Coded targets have been demarcated as control points in various vision measurement tasks such as camera calibration, 3D reconstruction, pose estimation, etc. By employing coded targets, matching corresponding image points in multi images can be automatically realized which greatly improves the efficiency and accuracy of the measurement. Although the coded targets are well applied, particularly in the industrial vision system, the design of coded targets and its detection algorithms have encountered difficulties, especially under the conditions of poor illumination and flat viewing angle. This paper presents a novel concentric circular coded target (CCCT), and its positioning and identifying algorithms. The eccentricity error has been corrected based on a practical error-compensation model. Adaptive brightness adjustment has been employed to address the problems of poor illumination such as overexposure and underexposure. The robust recognition is realized by perspective correction based on four vertices of the background area in the CCCT local image. The simulation results indicate that the eccentricity errors of the larger and smaller circles at a large viewing angle of 70° are reduced by 95% and 77% after correction by the proposed method. The result of the wing deformation experiment demonstrates that the error of the vision method based on the corrected center is reduced by up to 18.54% compared with the vision method based on only the ellipse center when the wing is loaded with a weight of 6 kg. The proposed design is highly applicable, and its detection algorithms can achieve accurate positioning and robust identification even in challenging environments.

摘要

在各种视觉测量任务中,如相机校准、三维重建、姿态估计等,编码靶标已被划定为控制点。通过使用编码靶标,可以自动实现多幅图像中对应图像点的匹配,这大大提高了测量的效率和准确性。尽管编码靶标得到了很好的应用,特别是在工业视觉系统中,但编码靶标的设计及其检测算法遇到了困难,尤其是在光照条件差和平视角度的情况下。本文提出了一种新型的同心圆编码靶标(CCCT)及其定位和识别算法。基于实际误差补偿模型对偏心误差进行了校正。采用自适应亮度调整来解决光照不足的问题,如过曝光和曝光不足。通过基于CCCT局部图像中背景区域四个顶点的透视校正实现了鲁棒识别。仿真结果表明,采用该方法校正后,在70°大视角下,大圆和小圆的偏心误差分别降低了95%和77%。机翼变形实验结果表明,当机翼加载6kg重量时,基于校正中心的视觉方法的误差比仅基于椭圆中心的视觉方法降低了18.54%。所提出的设计具有很高的适用性,其检测算法即使在具有挑战性的环境中也能实现精确定位和鲁棒识别。

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