Extreme state prediction of long-span bridges using extended ACER method

IF 5.7 2区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY
Liping Zhang, Liming Zhou, Jianqing Bu, Fei Xu, Bin Wei, Zhaofeng Xu, Cunbao Zhao, Yiqiang Li, Wei Chai, Shuanglin Guo, Yongding Tian
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引用次数: 0

Abstract

An accurate prediction of the future service state of long-span bridges is crucial for the structural reliability evaluation, maintenance planning, and further life-cycle cost analysis. By extending the average conditional exceedance rate (ACER) statistical model and applying input–output data collected through a structural health monitoring (SHM) system, this paper proposes a novel methodology for predicting the future service state of long-span bridges. The advantages lie in the consideration of the main excitation load as the structural input and the strain response of the bridge as the output. Therefore, a mapping relationship between the extreme excitation load and extreme strain could be established, and the future service state of long-span bridges could be predicted. The proposed method comprises three steps: (1) extraction of the ambient temperature-induced strain and vehicle-induced strain from the measured strain series through the SHM system using the baseline estimation and denoising with sparsity (BEADS) method, (2) establishing statistical models of the extreme values of different excitations (input) and structural strains (output) using a cascade of conditioning approximations and the ACER to obtain the tail trend of the data and extrapolating it, and (3) establishing a functional relationship between the input and output extreme values based on the same conditions of the regression period at the target prediction level, after which the future service state of long-span bridges can be predicted. The proposed method is applied to a case study of the Jinchao Bridge in Guangdong Province, China, and the results are expected to provide a scientific reference for the design of new bridges and in the maintenance of existing ones in service.
基于扩展ACER方法的大跨度桥梁极端状态预测
准确预测大跨度桥梁的未来使用状态,对结构可靠性评估、维修计划和寿命周期成本分析具有重要意义。通过扩展平均条件超限率(ACER)统计模型,并应用结构健康监测(SHM)系统收集的输入-输出数据,提出了一种预测大跨度桥梁未来使用状态的新方法。其优点在于将主激励荷载作为结构的输入,将桥梁的应变响应作为输出。因此,可以建立极端激励荷载与极端应变之间的映射关系,预测大跨度桥梁未来的使用状态。建议的方法包括三个步骤:(1)利用基线估计和稀疏度去噪(BEADS)方法,通过SHM系统从实测应变序列中提取环境温度诱发应变和车辆诱发应变;(2)利用条件近似级联和ACER建立不同激励(输入)和结构应变(输出)极值的统计模型,得到数据的尾部趋势并进行外推;(3)在目标预测水平上,在回归周期相同的条件下,建立输入与输出极值之间的函数关系,进而对大跨度桥梁的未来使用状态进行预测。并以广东金潮大桥为例进行了分析,结果可为新桥的设计和现役桥梁的维护提供科学参考。
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来源期刊
CiteScore
12.80
自引率
12.10%
发文量
181
审稿时长
4.8 months
期刊介绍: Structural Health Monitoring is an international peer reviewed journal that publishes the highest quality original research that contain theoretical, analytical, and experimental investigations that advance the body of knowledge and its application in the discipline of structural health monitoring.
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