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通过红外热成像与深度学习相结合检测纤维增强塑料(FRP)加固混凝土结构中的内部缺陷

Detecting Internal Defects in FRP-Reinforced Concrete Structures through the Integration of Infrared Thermography and Deep Learning.

作者信息

Pan Pengfei, Zhang Rongpeng, Zhang Yi, Li Hongbo

机构信息

Xinhua College, Ningxia University, Yinchuan 750021, China.

College of Civil and Hydraulic Engineering, Ningxia University, Yinchuan 750021, China.

出版信息

Materials (Basel). 2024 Jul 6;17(13):3350. doi: 10.3390/ma17133350.

Abstract

This study represents a significant advancement in structural health monitoring by integrating infrared thermography (IRT) with cutting-edge deep learning techniques, specifically through the use of the Mask R-CNN neural network. This approach targets the precise detection and segmentation of hidden defects within the interfacial layers of Fiber-Reinforced Polymer (FRP)-reinforced concrete structures. Employing a dual RGB and thermal camera setup, we captured and meticulously aligned image data, which were then annotated for semantic segmentation to train the deep learning model. The fusion of the RGB and thermal imaging significantly enhanced the model's capabilities, achieving an average accuracy of 96.28% across a 5-fold cross-validation. The model demonstrated robust performance, consistently identifying true negatives with an average specificity of 96.78% and maintaining high precision at 96.42% in accurately delineating damaged areas. It also showed a high recall rate of 96.91%, effectively recognizing almost all actual cases of damage, which is crucial for the maintenance of structural integrity. The balanced precision and recall culminated in an average 1 of 96.78%, highlighting the model's effectiveness in comprehensive damage assessment. Overall, this synergistic approach of combining IRT and deep learning provides a powerful tool for the automated inspection and preservation of critical infrastructure components.

摘要

本研究通过将红外热成像(IRT)与前沿的深度学习技术相结合,特别是使用Mask R-CNN神经网络,在结构健康监测方面取得了重大进展。这种方法旨在精确检测和分割纤维增强聚合物(FRP)增强混凝土结构界面层内的隐藏缺陷。采用RGB和热成像双相机设置,我们捕获并精心对齐了图像数据,然后对其进行语义分割标注以训练深度学习模型。RGB和热成像的融合显著增强了模型的能力,在五折交叉验证中平均准确率达到96.28%。该模型表现出强大的性能,始终以96.78%的平均特异性识别真阴性,并在准确描绘受损区域时保持96.42%的高精度。它还显示出96.91%的高召回率,有效地识别了几乎所有实际损坏情况,这对于维持结构完整性至关重要。平衡的精度和召回率最终平均达到96.78%,突出了该模型在综合损伤评估中的有效性。总体而言,这种将IRT与深度学习相结合的协同方法为关键基础设施组件的自动检测和维护提供了一个强大的工具。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f639/11243370/2842c07e38b4/materials-17-03350-g001.jpg

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