Automatic Air-Coupled Ultrasound Detection of Impact Damages in Fiber-Reinforced Composites Based on One-Dimension Deep Learning Models

被引:0
作者
Yuxia Duan
Tiantian Shao
Yuntao Tao
Hongbo Hu
Bingyang Han
Jingwen Cui
Kang Yang
Stefano Sfarra
Fabrizio Sarasini
Carlo Santulli
Ahmad Osman
Andrea Mross
Mingli Zhang
Dazhi Yang
Hai Zhang
机构
[1] Central South University,School of Physics and Electronics
[2] University of L’Aquila,Department of Industrial and Information Engineering and Economics (DIIIE)
[3] University of Rome Sapienza,Department of Chemical Engineering Materials Environment (DICMA)
[4] Università degli Studi di Camerino,School of Science and Technology
[5] Fraunhofer Institute for Nondestructive Testing - IZFP,McGill Centre for Integrative Neuroscience, Montreal Neurological Institute
[6] Saarland University of Applied Sciences,School of Electrical Engineering and Automation
[7] McGill University,Centre for Composite Materials and Structures (CCMS)
[8] Shandong Technology and Business University,undefined
[9] Harbin Institute of Technology,undefined
[10] Harbin Institute of Technology,undefined
来源
Journal of Nondestructive Evaluation | 2023年 / 42卷
关键词
Air-coupled ultrasound; Fiber-reinforced polymer; Deep learning; A-scan signals;
D O I
暂无
中图分类号
学科分类号
摘要
Impact damage constitutes a major threat to the performance and safety of fiber-reinforced composites. In this regard, transmission air-coupled ultrasound inspection technology has been identified as an ideal method for detection of common structural defects in modern multilayer composites. However, traditional machine learning algorithms and ultrasonic signal analysis methods are limited in terms of efficiency and accuracy. To remedy the situation, four one-dimensional deep learning models based on A-scan signals obtained from air-coupled ultrasound, which can automatically detect the impact damage in fiber-reinforced polymer composites, are constructed in this paper. Remarkably, all four models have attained high accuracy and recall on the testing sets, even though the training data and test data correspond to different materials and even structures. Among the four models, the long short-term memory recurrent neural network outperforms the other three models, which demonstrates its robustness and effectiveness.
引用
收藏
相关论文
共 67 条
[1]  
Rajak DK(2019)Fiber-Reinforced Polymer Composites: Manufacturing, Properties, and Applications[J] Polymers 11 1667-332
[2]  
Pagar DD(2013)Application of Fiber-Reinforced Composites for Sports Instruments[J] Adv. Mater. Res. 641 329-313
[3]  
Menezes PL(2009)An experimental investigation of the impact response of composite laminates[J] Compos. Struct. 87 307-106
[4]  
Shi BQ(2017)Three-dimensional thermography for non-destructive testing and evaluation[J] Quant. InfraRed Thermography J. 14 79-79
[5]  
Cai YT(2015)Fiber orientation assessment in complex shaped parts reinforced with carbon fiber using infrared thermography[J] Quant. InfraRed Thermography J. 12 64-248
[6]  
Aktaş M(2020)Comparative study of active infrared thermography, ultrasonic laser vibrometry and laser ultrasonics in application to the inspection of graphite/epoxy composite parts[J] Quant. InfraRed Thermography J. 17 235-28
[7]  
Atas C(2022)Deep learning-based anomaly detection from ultrasonic images[J] Ultrasonics 124 106737-1111
[8]  
İçten BM(2021)Augmented Ultrasonic Data for Machine Learning[J] J. Nondestr. Eval. 40 4-197
[9]  
Akhloufi MA(2011)Automatic defect classification in Ultrasonic NDT using Artificial Intelligence[J] J. Nondestr. Eval. 30 20-148
[10]  
Guyon Y(2013)Decision support system for ultrasound inspection of fiber metal laminates using statistical signal processing and neural networks[J] Ultrasonics 53 1104-199
1234567