An Open-Source Photogrammetry Workflow for Reconstructing 3D Models.

IF 2.2 4区 生物学 Q2 BIOLOGY
C Zhang, A M Maga
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引用次数: 1

Abstract

Acquiring accurate 3D biological models efficiently and economically is important for morphological data collection and analysis in organismal biology. In recent years, structure-from-motion (SFM) photogrammetry has become increasingly popular in biological research due to its flexibility and being relatively low cost. SFM photogrammetry registers 2D images for reconstructing camera positions as the basis for 3D modeling and texturing. However, most studies of organismal biology still relied on commercial software to reconstruct the 3D model from photographs, which impeded the adoption of this workflow in our field due the blocking issues such as cost and affordability. Also, prior investigations in photogrammetry did not sufficiently assess the geometric accuracy of the models reconstructed. Consequently, this study has two goals. First, we presented an affordable and highly flexible SFM photogrammetry pipeline based on the open-source package OpenDroneMap (ODM) and its user interface WebODM. Second, we assessed the geometric accuracy of the photogrammetric models acquired from the ODM pipeline by comparing them to the models acquired via microCT scanning, the de facto method to image skeleton. Our sample comprised 15 Aplodontia rufa (mountain beaver) skulls. Using models derived from microCT scans of the samples as reference, our results showed that the geometry of the models derived from ODM was sufficiently accurate for gross metric and morphometric analysis as the measurement errors are usually around or below 2%, and morphometric analysis captured consistent patterns of shape variations in both modalities. However, subtle but distinct differences between the photogrammetric and microCT-derived 3D models could affect the landmark placement, which in return affected the downstream shape analysis, especially when the variance within a sample is relatively small. At the minimum, we strongly advise not combining 3D models derived from these two modalities for geometric morphometric analysis. Our findings can be indictive of similar issues in other SFM photogrammetry tools since the underlying pipelines are similar. We recommend that users run a pilot test of geometric accuracy before using photogrammetric models for morphometric analysis. For the research community, we provide detailed guidance on using our pipeline for building 3D models from photographs.

用于重建3D模型的开源摄影测量工作流程。
高效、经济地获得准确的三维生物模型对于生物形态学数据的收集和分析具有重要意义。近年来,运动结构(SFM)摄影测量以其灵活性和相对较低的成本在生物研究中越来越受欢迎。SFM摄影测量注册用于重建相机位置的2D图像,作为3D建模和纹理的基础。然而,大多数生物体研究仍然依赖于商业软件从照片中重建三维模型,由于成本和负担能力等阻塞问题,阻碍了该工作流程在我们领域的采用。此外,先前的摄影测量研究没有充分评估重建模型的几何精度。因此,本研究有两个目标。首先,我们提出了一个价格合理且高度灵活的SFM摄影测量管道,该管道基于开源软件包OpenDroneMap (ODM)及其用户界面WebODM。其次,我们评估了从ODM管道获得的摄影测量模型的几何精度,并将其与通过微ct扫描获得的模型进行比较,微ct扫描是一种实际的骨骼成像方法。我们的样本包括15个阿plodontia rufa(山狸)头骨。通过对样品进行微ct扫描得出的模型作为参考,我们的研究结果表明,ODM得出的模型的几何形状对于总体度量和形态计量分析来说是足够精确的,因为测量误差通常在2%左右或以下,并且形态计量分析捕获了两种模式下形状变化的一致模式。然而,摄影测量和微ct衍生的3D模型之间细微但明显的差异可能会影响地标的放置,从而影响下游的形状分析,特别是当样本内的方差相对较小时。至少,我们强烈建议不要将这两种模式的3D模型结合起来进行几何形态分析。我们的发现可以指示其他SFM摄影测量工具中的类似问题,因为底层管道是相似的。我们建议用户在使用摄影测量模型进行形态测量分析之前先进行几何精度的试点测试。对于研究界,我们提供了使用我们的管道从照片中构建3D模型的详细指导。
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
CiteScore
3.70
自引率
6.70%
发文量
48
审稿时长
20 weeks
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