Fatigue Damage Diagnostics of Composites Using Data Fusion and Data Augmentation With Deep Neural Networks

S. Dabetwar, S. Ekwaro-Osire, J. Dias
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引用次数: 9

Abstract

Composite materials can be modified according to the requirements of applications, and hence, their applications are increasing significantly with time. Due to the complex nature of the aging of composites, it is equally challenging to establish structural health monitoring techniques. One of the most applied non-destructive techniques for this class of materials is using Lamb waves to quantify the damage. Another important advancement in damage detection is the application of deep neural networks. The data-driven methods have proven to be most efficient for damage detection in composites. For both of these advanced methods, the burning question always has been the requirement of data and quality of data. In this paper, these measurements were used to create a framework based on a deep neural network for efficient fault diagnostics. The research question developed for this paper was as follows: Can data fusion techniques used along with data augmentation improve the damage diagnostics using the convolutional neural network? The specific aims developed to answer this research question were: (1) highlighting the importance of data fusion methods, (2) underlining the importance of data augmentation techniques, (3) generalization abilities of the proposed framework, and (4) sensitivity of the size of the dataset. The results obtained through the analysis concluded that the artificial intelligence techniques along with the Lamb wave measurements can efficiently improve the fault diagnostics of complex materials such as composites.
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基于数据融合和深度神经网络数据增强的复合材料疲劳损伤诊断
复合材料可以根据应用的要求进行改性,因此,随着时间的推移,它们的应用正在显著增加。由于复合材料老化的复杂性,建立结构健康监测技术同样具有挑战性。这类材料最常用的非破坏性技术之一是使用兰姆波来量化损伤。损伤检测的另一个重要进展是深度神经网络的应用。数据驱动的方法已被证明是最有效的复合材料损伤检测方法。对于这两种先进的方法来说,最迫切的问题一直是对数据和数据质量的要求。在本文中,这些测量被用来创建一个基于深度神经网络的框架,用于有效的故障诊断。本文的研究问题是:数据融合技术和数据增强技术是否可以提高卷积神经网络的损伤诊断?为回答这一研究问题而开发的具体目标是:(1)强调数据融合方法的重要性;(2)强调数据增强技术的重要性;(3)所提出框架的泛化能力;(4)数据集大小的敏感性。分析结果表明,人工智能技术与兰姆波测量相结合,可以有效提高复合材料等复杂材料的故障诊断水平。
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来源期刊
CiteScore
3.80
自引率
9.10%
发文量
25
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