A physical knowledge-based extreme learning machine approach to fault diagnosis of rolling element bearing from small datasets

Tianyun Liu, Li Kou, Le Yang, Wenhui Fan, Cheng Wu
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引用次数: 1

Abstract

The learning-based methods have been widely applied to design a fault diagnosis model for rolling element bearing. However, the mainstream methods can only deal with the large training dataset, which is always violated in practical application. In this paper, we propose a physical knowledge-based hierarchical extreme learning machine(H-ELM) approach to adapt the problem of fault diagnosis for bearing with the small and imbalanced dataset. First, the proposed method uses the simple feature extraction algorithm to build a knowledge base for sample selection from the historical database, and the given training dataset is augmented with knowledge base. Second, a modified H-ELM algorithm is developed to identify fault location and recognize fault severity ranking based on the augmented dataset. Third, we design a self-optimizing module to optimize the sample selection and improve the performance of the H-ELM network. To evaluate the effectiveness of the proposed approach, the H-ELM without knowledge base and data augmentation-based support vector machine(SVM), back propagation neuron networks(BPNN) and deep belief networks(DBN) are tested in the numerical experiments to present a comprehensive comparison. The experimental results demonstrate that our approach outperforms in accuracy than other counterparts when dealing with the small and imbalanced datasets.
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基于物理知识的极限学习机小数据集滚动轴承故障诊断方法
基于学习的方法已被广泛应用于滚动轴承故障诊断模型的设计。然而,主流方法只能处理大型训练数据集,这在实际应用中经常被违反。在本文中,我们提出了一种基于物理知识的层次极限学习机(H-ELM)方法来适应小而不平衡数据集的轴承故障诊断问题。该方法首先利用简单的特征提取算法从历史数据库中建立样本选择知识库,并对给定的训练数据集进行知识库扩充;其次,基于增强数据集,提出改进的H-ELM算法进行故障定位和故障严重等级识别;第三,设计自优化模块,优化样本选择,提高H-ELM网络的性能。为了评估该方法的有效性,在数值实验中对无知识库的H-ELM和基于数据增强的支持向量机(SVM)、反向传播神经元网络(BPNN)和深度信念网络(DBN)进行了全面比较。实验结果表明,在处理小数据集和不平衡数据集时,我们的方法的准确性优于其他同类方法。
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