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一种基于新型 CNN-LSTM 混合模型的电-机械阻抗信号预测粘结强度监测方法

A Novel CNN-LSTM Hybrid Model for Prediction of Electro-Mechanical Impedance Signal Based Bond Strength Monitoring.

机构信息

Department of Civil Engineering, Shiv Nadar University, Greater Noida 201314, India.

RISCO, Department of Civil Engineering, University of Aveiro, 3810-193 Aveiro, Portugal.

出版信息

Sensors (Basel). 2022 Dec 16;22(24):9920. doi: 10.3390/s22249920.

DOI:10.3390/s22249920
PMID:36560293
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9781742/
Abstract

The recent application of deep learning for structural health monitoring systems for damage detection has potential for improvised structure performance and maintenance for long term durability, and reliable strength. Advancements in electro-mechanical impedance (EMI) techniques have sparked attention among researchers to develop novel monitoring techniques for structural monitoring and evaluation. This study aims to determine the performance of EMI techniques using a piezo sensor to monitor the development of bond strength in reinforced concrete through a pull-out test. The concrete cylindrical samples with embedded steel bars were prepared, cured for 28 days, and a pull-out test was performed to measure the interfacial bond between them. The piezo coupled signatures were obtained for the PZT patch bonded to the steel bar. The damage qualification is performed through the statistical indices, i.e., were obtained for different displacements recorded for axial pull. Furthermore, this study utilizes a novel Convolutional Neural Network-Long Short-Term Memory (CNN-LSTM)-based hybrid model, an effective regression model to predict the EMI signatures. These results emphasize the efficiency and potential application of the deep learning-based hybrid model in predicting EMI-based structural signatures. The findings of this study have several implications for structural health diagnosis using a deep learning-based model for monitoring and conservation of building heritage.

摘要

深度学习在结构健康监测系统中的应用,为损伤检测提供了改进结构性能和长期耐久性、可靠性的潜力。机电阻抗(EMI)技术的进步引起了研究人员的关注,促使他们开发用于结构监测和评估的新型监测技术。本研究旨在通过拔出试验,使用压电传感器来监测钢筋混凝土中粘结强度的发展,确定 EMI 技术的性能。制备了嵌入钢筋的混凝土圆柱试样,养护 28 天,然后进行拔出试验,以测量它们之间的界面粘结。获得了粘贴在钢筋上的 PZT 贴片的压电耦合特征。通过统计指标进行损伤定性,即获得了记录的不同轴向拉伸位移的特征。此外,本研究利用了一种新颖的卷积神经网络-长短期记忆(CNN-LSTM)混合模型,这是一种有效的回归模型,用于预测 EMI 特征。这些结果强调了基于深度学习的混合模型在预测基于 EMI 的结构特征方面的效率和潜在应用。本研究的结果对使用基于深度学习的模型进行结构健康诊断、监测和保护建筑遗产具有重要意义。

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