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探索刀具状态监测中端到端深度学习输入数据的处理范式。

Exploring the Processing Paradigm of Input Data for End-to-End Deep Learning in Tool Condition Monitoring.

作者信息

Wang Chengguan, Wang Guangping, Wang Tao, Xiong Xiyao, Ouyang Zhongchuan, Gong Tao

机构信息

Institute of Intelligent Manufacturing Technology, Shenzhen Polytechnic University, Shenzhen 518055, China.

AVIC Changhe Aircraft Industry (Group) Corporation Ltd., Jingdezhen 333002, China.

出版信息

Sensors (Basel). 2024 Aug 15;24(16):5300. doi: 10.3390/s24165300.

DOI:10.3390/s24165300
PMID:39204994
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11360168/
Abstract

Tool condition monitoring technology is an indispensable part of intelligent manufacturing. Most current research focuses on complex signal processing techniques or advanced deep learning algorithms to improve prediction performance without fully leveraging the end-to-end advantages of deep learning. The challenge lies in transforming multi-sensor raw data into input data suitable for direct model feeding, all while minimizing data scale and preserving sufficient temporal interpretation of tool wear. However, there is no clear reference standard for this so far. In light of this, this paper innovatively explores the processing methods that transform raw data into input data for deep learning models, a process known as an input paradigm. This paper introduces three new input paradigms: the downsampling paradigm, the periodic paradigm, and the subsequence paradigm. Then an improved hybrid model that combines a convolutional neural network (CNN) and bidirectional long short-term memory (BiLSTM) was employed to validate the model's performance. The subsequence paradigm demonstrated considerable superiority in prediction results based on the PHM2010 dataset, as the newly generated time series maintained the integrity of the raw data. Further investigation revealed that, with 120 subsequences and the temporal indicator being the maximum value, the model's mean absolute error (MAE) and root mean square error (RMSE) were the lowest after threefold cross-validation, outperforming several classical and contemporary methods. The methods explored in this paper provide references for designing input data for deep learning models, helping to enhance the end-to-end potential of deep learning models, and promoting the industrial deployment and practical application of tool condition monitoring systems.

摘要

刀具状态监测技术是智能制造中不可或缺的一部分。当前大多数研究都集中在复杂的信号处理技术或先进的深度学习算法上,以提高预测性能,却没有充分利用深度学习的端到端优势。挑战在于将多传感器原始数据转换为适合直接输入模型的数据,同时尽量减小数据规模并保留对刀具磨损足够的时间解释。然而,目前尚无明确的参考标准。鉴于此,本文创新性地探索了将原始数据转换为深度学习模型输入数据的处理方法,这一过程称为输入范式。本文介绍了三种新的输入范式:下采样范式、周期范式和子序列范式。然后采用一种改进的混合模型,该模型结合了卷积神经网络(CNN)和双向长短期记忆网络(BiLSTM)来验证模型的性能。基于PHM2010数据集,子序列范式在预测结果中表现出相当大的优势,因为新生成的时间序列保持了原始数据的完整性。进一步研究发现,在有120个子序列且时间指标为最大值的情况下,经过三倍交叉验证后,该模型的平均绝对误差(MAE)和均方根误差(RMSE)最低,优于几种经典和当代方法。本文探索的方法为深度学习模型的输入数据设计提供了参考,有助于增强深度学习模型的端到端潜力,并推动刀具状态监测系统的工业部署和实际应用。

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