Attention-enhanced deep learning framework for automated concrete crack depth prediction using infrared thermography

热成像 深度学习 残余物 人工智能 计算机科学 无损检测 结构工程 突出 嵌入 热的 桥(图论) 红外线的 梁(结构) 残余应力 机器学习 钥匙(锁) 基础(证据) 人工神经网络 结构健康监测 表征(材料科学) 财产(哲学) 温度测量 计算机视觉 断裂(地质) 有限元法 边界(拓扑) 地质学 断裂力学 可靠性(半导体) 材料科学
作者
Wangrui Wan,Jiqiao Zhang,Gongfa Chen,Xiaomei Yang,Fangsen Cui
出处
期刊:International Journal of Computational Methods [World Scientific]
标识
DOI:10.1142/s0219876226500234
摘要

Traditional manual methods for measuring concrete crack depth are inefficient, time-consuming, and heavily reliant on operator experience, often resulting in inconsistent and subjective outcomes. Moreover, most existing studies on crack characterization primarily emphasize surface-level parameters such as crack length, width, and area. The crack depth, a key indicator of structural integrity and residual load-bearing capacity, remains insufficiently addressed. To bridge this gap, this study proposes an automated crack depth prediction framework that integrates infrared thermography (IRT) with an enhanced SE-ResNet-18 deep learning model. Concrete beam specimens with precisely calibrated crack depths were fabricated under controlled laboratory conditions, and corresponding thermal images were acquired to establish a robust training dataset. By embedding a squeeze-and-excitation (SE) attention mechanism into the conventional ResNet-18 architecture, the model’s capacity to capture and emphasize salient thermal features was significantly improved, resulting in more accurate and stable depth predictions. Experimental results demonstrate that the proposed SE-ResNet-18 achieves 93.77% accuracy within a ±1 mm tolerance, outperforming the baseline ResNet-18 network by a substantial margin. This solution is fully automated in its predictive analysis and non-contact in its sensing modality. It shows strong potential for practical implementation in real-world structural health monitoring and provides a foundation for future research on field-scale applications and model generalisation under varying environmental conditions.
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