Damage detection in truss bridges using transmissibility and machine learning algorithm : application to Nam O bridge

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2020-01-01 DOI:10.12989/SSS.2020.26.1.035
Duong H. Nguyen, H. Tran-Ngoc, T. Bui-Tien, G. Roeck, M. Wahab
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引用次数: 10

Abstract

This paper proposes the use of transmissibility functions combined with a machine learning algorithm, Artificial Neural Networks (ANNs), to assess damage in a truss bridge. A new approach method, which makes use of the input parameters calculated from the transmissibility function, is proposed. The network not only can predict the existence of damage, but also can classify the damage types and identity the location of the damage. Sensors are installed in the truss joints in order to measure the bridge vibration responses under train and ambient excitations. A finite element (FE) model is constructed for the bridge and updated using FE software and experimental data. Both single damage and multiple damage cases are simulated in the bridge model with different scenarios. In each scenario, the vibration responses at the considered nodes are recorded and then used to calculate the transmissibility functions. The transmissibility damage indicators are calculated and stored as ANNs inputs. The outputs of the ANNs are the damage type, location and severity. Two machine learning algorithms are used; one for classifying the type and location of damage, whereas the other for finding the severity of damage. The measurements of the Nam O bridge, a truss railway bridge in Vietnam, is used to illustrate the method. The proposed method not only can distinguish the damage type, but also it can accurately identify damage level.
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基于传递率和机器学习算法的桁架桥梁损伤检测:在南澳大桥上的应用
本文提出使用传递率函数结合机器学习算法,人工神经网络(ANNs)来评估桁架桥梁的损伤。提出了一种利用传递率函数计算输入参数的新逼近方法。该网络不仅可以预测损伤的存在,还可以对损伤类型进行分类,识别损伤的位置。传感器安装在桁架节点上,以测量列车和环境激励下桥梁的振动响应。建立了桥梁的有限元模型,并利用有限元软件和实验数据进行了更新。在桥梁模型中分别模拟了不同场景下的单损伤和多损伤情况。在每种情况下,记录所考虑节点的振动响应,然后用于计算传递率函数。传递率损伤指标被计算并存储为人工神经网络的输入。人工神经网络的输出是损伤类型、位置和严重程度。使用了两种机器学习算法;一个用于对损害的类型和位置进行分类,而另一个用于发现损害的严重程度。以越南南澳铁路桁架桥的测量结果为例说明了该方法。该方法不仅能区分损伤类型,而且能准确识别损伤等级。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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