A novel physically interpretable end-to-end network for stress monitoring in laser shock peening

IF 8.2 1区 计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Computers in Industry Pub Date : 2023-12-15 DOI:10.1016/j.compind.2023.104060
Rui Qin , Zhifen Zhang , Jing Huang , Zhengyao Du , Xianwen Xiang , Jie Wang , Guangrui Wen , Weifeng He
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Abstract

The data-driven method based on acoustic emission signals is gradually becoming a hot topic in the field of laser shock peening quality monitoring. Although some existing deep learning methods do provide excellent monitoring accuracy and speed, they lack physical interpretability in nature, and the opacity of these decisions poses a great challenge to their credibility. The weak interpretability of deep learning models has become the biggest obstacle to the landing of artificial intelligence projects. To overcome this drawback, this paper proposes a monitoring strategy that can achieve physical interpretability in feature extraction, selection and classification, namely, jointly generating monitoring results and explanations. Specifically, it is an end-to-end model that combines convolutional neural units, gated recurrent units, and attention mechanisms. Firstly, a wavelet analysis with physical meaning that can be autonomously learned is performed on the acoustic emission. Then, the contribution of features is distinguished based on the correlation of information in different frequency bands, and redundant and noisy features are removed. Finally, the interpretability evaluation of processing quality is realized by using gated recurrent units with attention mechanisms. The effectiveness and reliability of the proposed method are confirmed by the experimental data of both laser shock peening at small and large gradient energies compared to state-of-the-art feature methods, CNN- and LSTM-based models. Most importantly, the physical interpretation of acoustic emission signals during the processing can increase the credibility of decisions and provide a basic logic for on-site judgments by professionals.

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用于激光冲击强化应力监测的新型物理可解释端到端网络
基于声发射信号的数据驱动方法正逐渐成为激光冲击强化质量监测领域的研究热点。尽管现有的一些深度学习方法确实提供了出色的监测准确性和速度,但它们本质上缺乏物理可解释性,并且这些决策的不透明性对其可信度构成了巨大挑战。深度学习模型的弱可解释性已经成为人工智能项目落地的最大障碍。为了克服这一缺点,本文提出了一种监测策略,在特征提取、选择和分类中实现物理可解释性,即监测结果与解释共同生成。具体来说,它是一个结合了卷积神经单元、门控循环单元和注意机制的端到端模型。首先,对声发射进行具有可自主学习物理意义的小波分析;然后,根据不同频带信息的相关性区分特征的贡献,去除冗余和噪声特征;最后,利用带注意机制的门控循环单元实现了加工质量的可解释性评价。通过小梯度能量和大梯度能量下的激光冲击强化实验数据,对比目前最先进的特征方法、基于CNN和基于lstm的模型,验证了该方法的有效性和可靠性。最重要的是,声发射信号在处理过程中的物理解释可以增加决策的可信度,并为专业人员的现场判断提供基本逻辑。
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来源期刊
Computers in Industry
Computers in Industry 工程技术-计算机:跨学科应用
CiteScore
18.90
自引率
8.00%
发文量
152
审稿时长
22 days
期刊介绍: The objective of Computers in Industry is to present original, high-quality, application-oriented research papers that: • Illuminate emerging trends and possibilities in the utilization of Information and Communication Technology in industry; • Establish connections or integrations across various technology domains within the expansive realm of computer applications for industry; • Foster connections or integrations across diverse application areas of ICT in industry.
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