Optimization of Sensor Placement in a Bridge Structural Health Monitoring System

2021 IEEE International Systems Conference (SysCon) Pub Date : 2021-04-15 DOI:10.1109/SysCon48628.2021.9447077

Juan C. Avendano, L. D. Otero, C. Otero

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引用次数: 4

Abstract

This paper presents an optimal sensor placement (OSP) technique designed to be implemented on Structural Health Monitoring (SHM) systems. A steel bridge was modeled in ANSYS environment and four load values were applied at pre-identified locations to generate data. Each experiment yielded an array of data that contains the location, as well as corresponding deformation and safety factors. Measurements were taken at 1,000,000 positions on the bridge and a library of a similar number of failure modes was created for each experiment. Each data library was processed as a multi-dimensional matrix by applying the average filtering algorithm. Local extrema were identified in terms of the corresponding deformation and safety factors by removing repeated values at nearby locations. The results provided a list of 100 locations with maximum deformation or minimum safety factors, containing the optimized positions on the bridge for placement of sensors. The final developed system that includes this placement algorithm capable of simulating multiple load conditions on structures, identifying possible failure points, and detecting and predicting failure scenarios. Both hardware and software implementations of a model of a bridge were performed as a pilot project to validate the proposed system.

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桥梁结构健康监测系统中传感器布置的优化

本文提出了一种用于结构健康监测(SHM)系统的传感器优化布置(OSP)技术。在ANSYS环境中对一座钢桥进行了建模，并在预先确定的位置施加了四个荷载值来生成数据。每次实验都会产生一组数据，其中包含位置，以及相应的变形和安全系数。在桥上的1,000,000个位置进行了测量，并为每个实验创建了一个相似数量的失效模式库。每个数据库采用平均滤波算法作为一个多维矩阵进行处理。通过去除邻近位置的重复值，根据相应的变形和安全系数识别出局部极值。结果提供了100个最大变形或最小安全系数的位置列表，其中包含桥上传感器放置的最佳位置。最终开发的系统包括这种放置算法，能够模拟结构上的多种载荷条件，识别可能的故障点，并检测和预测故障场景。一个桥梁模型的硬件和软件实现作为一个试点项目来验证所提出的系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE International Systems Conference (SysCon)

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