Multi-objective SHM sensor path optimisation for damage detection in large composite stiffened panels

Structural Health Monitoring Pub Date : 2024-03-11 DOI:10.1177/14759217241231701

L. Morse, Ilias N. Giannakeas, Vincenzo Mallardo, Z. Sharif-Khodaei, M. Aliabadi

{"title":"Multi-objective SHM sensor path optimisation for damage detection in large composite stiffened panels","authors":"L. Morse, Ilias N. Giannakeas, Vincenzo Mallardo, Z. Sharif-Khodaei, M. Aliabadi","doi":"10.1177/14759217241231701","DOIUrl":null,"url":null,"abstract":"This work proposes a novel methodology for the automatic multi-objective optimisation of sensor paths in structural health monitoring (SHM) sensor networks using archived multi-objective simulated annealing. Using all of the sensor paths within a sensor network may not always be beneficial during damage detection. Many sensor paths may experience significant signal noise, attenuation, and wave mode conversion due to the presence of features, such as stiffeners, and hence impair the detection accuracy of the overall system. Many paths will also contribute little to the overall coverage level or damage detection accuracy of the network and can be ignored, reducing complexity. Knowing which paths to include, and which to exclude, can require significant prior expert knowledge, which may not always be available. Furthermore, even when expert knowledge is considered, the optimum path selection might not be achieved. Therefore, this work proposes a novel automatic procedure for optimising the sensor paths of an SHM sensor network to maximise coverage level, maximise damage detection accuracy and minimise the overall signal noise in the network due to geometric features. This procedure was tested on a real-world large composite stiffened panel with many geometric features in the form of frames and stiffeners. Compared to using all of the available sensor pairs, the optimised network exhibits superior performance in terms of detection accuracy and overall noise. It was also found to provide very similar performance, in terms of coverage level and overall signal noise, to a sensor path network designed based on prior expert knowledge but provided up to 35% higher damage detection accuracy. As a result, the novel procedure proposed in this work has the capability to design high-performing SHM sensor path networks for structures with complex geometries but without the need for prior expert knowledge, making SHM more accessible to the engineering community.","PeriodicalId":515545,"journal":{"name":"Structural Health Monitoring","volume":"84 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-03-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Structural Health Monitoring","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1177/14759217241231701","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

This work proposes a novel methodology for the automatic multi-objective optimisation of sensor paths in structural health monitoring (SHM) sensor networks using archived multi-objective simulated annealing. Using all of the sensor paths within a sensor network may not always be beneficial during damage detection. Many sensor paths may experience significant signal noise, attenuation, and wave mode conversion due to the presence of features, such as stiffeners, and hence impair the detection accuracy of the overall system. Many paths will also contribute little to the overall coverage level or damage detection accuracy of the network and can be ignored, reducing complexity. Knowing which paths to include, and which to exclude, can require significant prior expert knowledge, which may not always be available. Furthermore, even when expert knowledge is considered, the optimum path selection might not be achieved. Therefore, this work proposes a novel automatic procedure for optimising the sensor paths of an SHM sensor network to maximise coverage level, maximise damage detection accuracy and minimise the overall signal noise in the network due to geometric features. This procedure was tested on a real-world large composite stiffened panel with many geometric features in the form of frames and stiffeners. Compared to using all of the available sensor pairs, the optimised network exhibits superior performance in terms of detection accuracy and overall noise. It was also found to provide very similar performance, in terms of coverage level and overall signal noise, to a sensor path network designed based on prior expert knowledge but provided up to 35% higher damage detection accuracy. As a result, the novel procedure proposed in this work has the capability to design high-performing SHM sensor path networks for structures with complex geometries but without the need for prior expert knowledge, making SHM more accessible to the engineering community.

查看原文本刊更多论文

多目标 SHM 传感器路径优化，用于大型复合加劲板的损伤检测

本研究提出了一种新方法，利用归档多目标模拟退火法对结构健康监测（SHM）传感器网络中的传感器路径进行自动多目标优化。在损伤检测过程中，使用传感器网络中的所有传感器路径并不总是有益的。由于加劲件等特征的存在，许多传感器路径可能会出现明显的信号噪声、衰减和波模转换，从而影响整个系统的检测精度。许多路径对网络的整体覆盖水平或损坏检测精度的贡献也很小，可以忽略不计，从而降低复杂性。要知道哪些路径应包括在内，哪些路径应排除在外，可能需要大量的专家知识，而这些知识并不总是可用的。此外，即使考虑了专家知识，也可能无法实现最佳路径选择。因此，这项工作提出了一种新的自动程序，用于优化 SHM 传感器网络的传感器路径，以最大限度地提高覆盖水平，最大限度地提高损坏检测精度，并最大限度地降低网络中因几何特征而产生的整体信号噪声。该程序在真实世界的大型复合加劲板上进行了测试，该加劲板具有许多几何特征，如框架和加劲件。与使用所有可用传感器对相比，优化后的网络在检测精度和总体噪声方面表现出更优越的性能。研究还发现，就覆盖水平和总体信号噪声而言，优化网络的性能与根据专家知识设计的传感器路径网络非常相似，但损坏检测精度却高出 35%。因此，这项工作中提出的新程序有能力为具有复杂几何形状的结构设计高性能的 SHM 传感器路径网络，而无需先验的专家知识，从而使 SHM 更容易为工程界所接受。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Structural Health Monitoring

自引率

0.00%

发文量