An Evaluation Framework for Deep Learning-Based Anomaly Detection in Structural Health Monitoring.

e-Journal of Nondestructive Testing Pub Date : 2024-07-01 DOI:10.58286/29573

Yacine Bel-Hadj, W. Weijtjens, C. Devriendt

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Abstract

The task of evaluating deep learning algorithms in the context of Structural Health Monitoring (SHM) for damage detection is made particularly challenging by the limited availability of empirical data from damaged structures. Making it impossible to assert whether the trained algorithm would be able to pick up changes due to (unseen) damage. This study puts forth a methodology that employs synthesized anomalies to advance our understanding of the specific conditions under which deep learning algorithms for anomaly detection are succesfull and when they prove to be insensitive to damage. This research aims to develop a comprehensive deep learning model that utilizes raw data as its input, negating the need for specialized preprocessing or the development of anomaly indices that are constrained to specific types of anomalies. Central to our methodology is the introduction of simulated damage into the data set through various manipulations. This evaluation method could be generalized across diverse sensor types, such as accelerometer data (ACCs) and Fiber Bragg Sensors (FBGs). As a case study, we focus on accelerometer data, utilizing Power Spectral Density (PSD) as the input for a deep learning-based anomaly detection algorithm. The study employs both attenuation and the addition of harmonics at varying levels and frequencies to mimic anomalies, thereby investigation the model's areas of sensitivity. To empirically validate the approach, an 8-degree-of-freedom simulated system is used, and environmental effect is modelled by a linear stiffness reduction across all degrees of freedom (DOFs). Structural damage is then simulated by altering the stiffness of a specific DOF. Our results demonstrate a robust correlation between the model’s success in identifying these synthesized anomalies and its capability to detect actual structural damage. This correlation serves as a valuable guide for hyperparameter optimization.

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基于深度学习的结构健康监测异常检测评估框架。

在结构健康监测（SHM）中评估深度学习算法以进行损伤检测的任务，由于从受损结构中获得的经验数据有限而变得尤其具有挑战性。因此，无法断言训练有素的算法是否能够捕捉到（看不见的）损坏所导致的变化。本研究提出了一种采用合成异常的方法，以推进我们对异常检测深度学习算法在哪些特定条件下能够成功以及何时被证明对损坏不敏感的理解。这项研究旨在开发一种全面的深度学习模型，利用原始数据作为输入，无需进行专门的预处理，也无需开发受限于特定异常类型的异常指数。我们方法的核心是通过各种操作将模拟损害引入数据集。这种评估方法可以推广到各种类型的传感器，如加速度计数据（ACC）和光纤布拉格传感器（FBG）。作为案例研究，我们将重点放在加速度计数据上，利用功率谱密度（PSD）作为基于深度学习的异常检测算法的输入。研究采用了衰减和添加不同级别和频率的谐波来模拟异常，从而调查模型的敏感区域。为了对该方法进行经验验证，使用了一个 8 自由度模拟系统，并通过降低所有自由度 (DOF) 的线性刚度来模拟环境影响。然后通过改变特定 DOF 的刚度来模拟结构损伤。我们的研究结果表明，该模型在成功识别这些合成异常与检测实际结构损坏的能力之间存在很强的相关性。这种相关性为超参数优化提供了宝贵的指导。

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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e-Journal of Nondestructive Testing

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