Intelligent crack identification method for high‐rise buildings aided by synthetic environments

Ziluo Yao, Sheng Jiang, Shuo Wang, Jingjing Wang, Hai Liu, Yasutaka Narazaki, Jie Cui, Billie F. Spencer
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Abstract

SummaryCracks can develop in high‐rise buildings because of long‐term environmental changes and extreme loading events such as strong winds or earthquakes. Although deep learning‐based identification methods can efficiently identify cracks, the accuracy of crack identification in high‐rise buildings needs to be improved due to the lack of crack datasets specifically related to high‐rise structures. Moreover, the number of available images of cracks in high‐rise is limited. To this end, this paper establishes an intelligent crack identification method based on a photorealistic synthetic modeling technique. First, a computer graphics (CG) model of a high‐rise building with assumed damage is constructed. Subsequently, the CG model is utilized to generate a dataset that includes photorealistic images of the high‐rise building as well as corresponding labels for various components and types of damage. The generated dataset is then used to train a DeepLabv3 + neural network for structural component and damage identification, followed by validation by employing images of both synthetic and full‐scale high‐rise buildings. The trained network can accurately identify different components in images of the full‐scale, high‐rise building and identify cracks that are intentionally synthesized in those images. The results show that the synthetic dataset generated by the CG model not only allows for fast and efficient labeling for the purpose of neural network training but also outperforms methods that do not consider any application‐specific context in crack identification.
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合成环境辅助下的高层建筑智能裂缝识别方法
摘要由于长期的环境变化以及强风或地震等极端荷载事件,高层建筑可能会出现裂缝。虽然基于深度学习的识别方法可以有效识别裂缝,但由于缺乏专门与高层建筑结构相关的裂缝数据集,高层建筑裂缝识别的准确性还有待提高。此外,现有的高层建筑裂缝图像数量有限。为此,本文建立了一种基于逼真合成建模技术的智能裂缝识别方法。首先,构建一个具有假定损伤的高层建筑计算机图形(CG)模型。随后,利用该计算机图形模型生成一个数据集,其中包括高层建筑的逼真图像以及各种组件和损坏类型的相应标签。生成的数据集随后用于训练 DeepLabv3 + 神经网络,以识别结构部件和损坏,然后使用合成和全尺寸高层建筑的图像进行验证。经过训练的网络可以准确识别全尺寸高层建筑图像中的不同组件,并识别这些图像中有意合成的裂缝。结果表明,CG 模型生成的合成数据集不仅可以快速有效地标记神经网络训练,而且优于在裂缝识别中不考虑任何特定应用背景的方法。
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