Bearing fault diagnosis based on a multiple-constraint modal-invariant graph convolutional fusion network

Zhongmei Wang , Pengxuan Nie , Jianhua Liu , Jing He , Haibo Wu , Pengfei Guo
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Abstract

Multisensor data fusion method can improve the accuracy of bearing fault diagnosis, in order to address the problems of single-sensor data types and the insufficient exploration of redundancy and complementarity between different modal data in most existing multisensor data fusion methods for bearing fault diagnosis, a bearing fault diagnosis method based on a Multiple-Constraint Modal-Invariant Graph Convolutional Fusion Network (MCMI-GCFN) is proposed in this paper. Firstly, a Convolutional Autoencoder (CAE) and Squeeze-and-Excitation Block (SE block) are used to extract features of raw current and vibration signals. Secondly, the model introduces source domain classifiers and domain discriminators to capture modal invariance between different modal data based on domain adversarial training, making use of the redundancy and complementarity between multimodal data. Then, the spatial aggregation property of Graph Convolutional Neural Networks (GCN) is utilized to capture the dependency relationship between current and vibration modes with similar time step features for accurately fusing contextual semantic information. Finally, the validation is conducted on the public bearing damage current and vibration dataset from Paderborn University. The experimental results showed that the delivered fusion method achieved a bearing fault diagnosis accuracy of 99.6 %, which was about 9 %–11.4 % better than that with nonfusion methods.

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基于多约束模态不变图卷积融合网络的轴承故障诊断
多传感器数据融合方法可以提高轴承故障诊断的准确性,针对现有轴承故障诊断多传感器数据融合方法中存在的数据类型单一、不同模态数据之间的冗余性和互补性挖掘不足等问题,本文提出了一种基于多约束模态不变图卷积融合网络(MCMI-GCFN)的轴承故障诊断方法。首先,利用卷积自动编码器(CAE)和挤压激励块(SE 块)提取原始电流和振动信号的特征。其次,该模型引入了源域分类器和域判别器,利用多模态数据之间的冗余性和互补性,在域对抗训练的基础上捕捉不同模态数据之间的模态不变性。然后,利用图卷积神经网络(GCN)的空间聚合特性,捕捉具有相似时间步长特征的电流模态和振动模态之间的依赖关系,从而准确融合上下文语义信息。最后,在帕德博恩大学的公开轴承损坏电流和振动数据集上进行了验证。实验结果表明,融合方法的轴承故障诊断准确率达到 99.6%,比非融合方法高出约 9%-11.4%。
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