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基于编码结构光的鱼类三维重建

3D Reconstruction of Fishes Using Coded Structured Light.

作者信息

Veinidis Christos, Arnaoutoglou Fotis, Syvridis Dimitrios

机构信息

Optical Communications Laboratory, Department of Informatics and Telecommunications, University of Athens, 15784 Athens, Greece.

"Athena" Research and Innovation Centre, Xanthi's Division, 67100 Xanthi, Greece.

出版信息

J Imaging. 2023 Sep 18;9(9):189. doi: 10.3390/jimaging9090189.

DOI:10.3390/jimaging9090189
PMID:37754953
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10532609/
Abstract

3D reconstruction of fishes provides the capability of extracting geometric measurements, which are valuable in the field of Aquaculture. In this paper, a novel method for 3D reconstruction of fishes using the Coded Structured Light technique is presented. In this framework, a binary image, called pattern, consisting of white geometric shapes, namely symbols, on a black background is projected onto the surface of a number of fishes, which belong to different species. A camera captures the resulting images, and the various symbols in these images are decoded to uniquely identify them on the pattern. For this purpose, a number of steps, such as the binarization of the images captured by the camera, symbol classification, and the correction of misclassifications, are realized. The proposed methodology for 3D reconstructions is adapted to the specific geometric and morphological characteristics of the considered fishes with fusiform body shape, something which is implemented for the first time. Using the centroids of the symbols as feature points, the symbol correspondences immediately result in point correspondences between the pattern and the images captured by the camera. These pairs of corresponding points are exploited for the final 3D reconstructions of the fishes. The extracted 3D reconstructions provide all the geometric information which is related to the real fishes. The experimentation demonstrates the high efficiency of the techniques adopted in each step of the proposed methodology. As a result, the final 3D reconstructions provide sufficiently accurate approximations of the real fishes.

摘要

鱼类的三维重建提供了提取几何测量值的能力,这在水产养殖领域具有重要价值。本文提出了一种利用编码结构光技术进行鱼类三维重建的新方法。在此框架下,一个由黑色背景上的白色几何形状(即符号)组成的二值图像(称为图案)被投影到多种不同鱼类的表面。一台相机捕捉生成的图像,这些图像中的各种符号被解码以在图案上唯一识别它们。为此,实现了多个步骤,如相机捕捉图像的二值化、符号分类以及错误分类的校正。所提出的三维重建方法适用于所考虑的具有梭形身体形状的鱼类的特定几何和形态特征,这是首次实现。以符号的质心作为特征点,符号对应关系立即导致图案与相机捕捉图像之间的点对应关系。这些对应点对被用于鱼类的最终三维重建。提取的三维重建提供了与真实鱼类相关的所有几何信息。实验证明了所提出方法各步骤中所采用技术的高效性。因此,最终的三维重建提供了对真实鱼类足够准确的近似。

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Structured-light modulation analysis technique for contamination and defect detection of specular surfaces and transparent objects.
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