一种数据驱动的混合方法,用于超声导波监测焊接轨道不可用损伤情景生成合成数据

IF 5.7 2区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY Structural Health Monitoring-An International Journal Pub Date : 2023-10-10 DOI:10.1177/14759217231197265
Dineo A Ramatlo, Daniel N Wilke, Philip W Loveday
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引用次数: 0

摘要

开发可靠的超声导波监测系统需要为每个应用场景提供大量的检测数据。实验调查是基础,但需要长时间和昂贵的,特别是对现实生活中的测试。由于缺乏包括损伤在内的实验数据,这种情况更加严重。在一些导波应用中,例如管道,可以引入人工损伤并对测试结构进行实验室实验。然而,在轨道应用中,实验室实验要么是不可能的,要么是没有意义的。因此,利用建模能力生成合成数据变得越来越重要。提出了一种基于变分自编码器(VAE)的深度学习方法,用于合成焊接轨道超声检测数据。主要目的是使用VAE模型生成包含沿轨道长度指定位置的损坏特征的合成数据。训练VAE对输入的无损伤基线信号进行编码,并通过指定到损伤信号的距离作为潜在空间中的附加变量,在换能器的两侧添加损伤信号,从而解码重建带有损伤的检测信号。训练数据来自基于物理的模型,该模型使用半解析有限元和传统有限元程序计算虚拟实验响应信号。包含损伤特征的VAE重构响应信号与基于物理模型模拟的原始目标信号几乎相同。VAE能够捕获由多不连续波导中多个传播模式相互作用产生的信号中的复杂特征。VAE模型通过融合焊缝反射和裂纹模型反射,成功地生成了综合检测数据,这些反射位于距离传感器指定距离的左右两侧。在某些情况下,VAE并没有准确地重建反射的峰值振幅。该研究展示了使用VAE生成具有损伤特征的合成数据的潜力和优势,而不是使用叠加将包含焊缝反射的无损伤响应与损伤特征融合。结果表明,该方法可以在不可用损伤情况下生成真实的检测数据。
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A data-driven hybrid approach to generate synthetic data for unavailable damage scenarios in welded rails for ultrasonic guided wave monitoring
Developing reliable ultrasonic-guided wave monitoring systems requires a significant amount of inspection data for each application scenario. Experimental investigations are fundamental but require a long period and are costly, especially for real-life testing. This is exacerbated by a lack of experimental data that includes damage. In some guided wave applications, such as pipelines, it is possible to introduce artificial damage and perform lab experiments on the test structure. However, in rail track applications, laboratory experiments are either not possible or meaningful. The generation of synthetic data using modelling capabilities thus becomes increasingly important. This paper presents a variational autoencoder (VAE)-based deep learning approach for generating synthetic ultrasonic inspection data for welded railway tracks. The primary aim is to use a VAE model to generate synthetic data containing damage signatures at specified positions along the length of a rail track. The VAE is trained to encode an input damage-free baseline signal and decode to reconstruct an inspection signal with damage by adding a damage signature on either side of the transducer by specifying the distance to the damage signature as an additional variable in the latent space. The training data was produced from a physics-based model that computes virtual experimental response signals using the semi-analytical finite element and the traditional finite element procedures. The VAE reconstructed response signals containing damage signatures were almost identical to the original target signals simulated using the physics-based model. The VAE was able to capture the complex features in the signals resulting from the interaction of multiple propagating modes in a multi-discontinuous waveguide. The VAE model successfully generated synthetic inspection data by fusing reflections from welds with the reflection from a crack model at specified distances from the transducer on either the right or left side. In some cases, the VAE did not exactly reconstruct the peak amplitude of the reflections. This study demonstrated the potential and highlighted the benefit of using a VAE to generate synthetic data with damage signatures as opposed to using superposition to fuse the damage-free responses containing reflections from welds with a damage signature. The results show that it is possible to generate realistic inspection data for unavailable damage scenarios.
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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.
期刊最新文献
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