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用于滚动轴承故障诊断的贝叶斯优化混合核支持向量机

Bayesian-Optimized Hybrid Kernel SVM for Rolling Bearing Fault Diagnosis.

作者信息

Song Xinmin, Wei Weihua, Zhou Junbo, Ji Guojun, Hussain Ghulam, Xiao Maohua, Geng Guosheng

机构信息

College of Engineering, Nanjing Agricultural University, Nanjing 210031, China.

College of Mechanical and Electronic Engineering, Nanjing Forestry University, Nanjing 210037, China.

出版信息

Sensors (Basel). 2023 May 28;23(11):5137. doi: 10.3390/s23115137.

DOI:10.3390/s23115137
PMID:37299863
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10255357/
Abstract

We propose a new fault diagnosis model for rolling bearings based on a hybrid kernel support vector machine (SVM) and Bayesian optimization (BO). The model uses discrete Fourier transform (DFT) to extract fifteen features from vibration signals in the time and frequency domains of four bearing failure forms, which addresses the issue of ambiguous fault identification caused by their nonlinearity and nonstationarity. The extracted feature vectors are then divided into training and test sets as SVM inputs for fault diagnosis. To optimize the SVM, we construct a hybrid kernel SVM using a polynomial kernel function and radial basis kernel function. BO is used to optimize the extreme values of the objective function and determine their weight coefficients. We create an objective function for the Gaussian regression process of BO using training and test data as inputs, respectively. The optimized parameters are used to rebuild the SVM, which is then trained for network classification prediction. We tested the proposed diagnostic model using the bearing dataset of the Case Western Reserve University. The verification results show that the fault diagnosis accuracy is improved from 85% to 100% compared with the direct input of vibration signal into the SVM, and the effect is significant. Compared with other diagnostic models, our Bayesian-optimized hybrid kernel SVM model has the highest accuracy. In laboratory verification, we took sixty sets of sample values for each of the four failure forms measured in the experiment, and the verification process was repeated. The experimental results showed that the accuracy of the Bayesian-optimized hybrid kernel SVM reached 100%, and the accuracy of five replicates reached 96.7%. These results demonstrate the feasibility and superiority of our proposed method for fault diagnosis in rolling bearings.

摘要

我们提出了一种基于混合核支持向量机(SVM)和贝叶斯优化(BO)的滚动轴承故障诊断新模型。该模型使用离散傅里叶变换(DFT)从四种轴承故障形式的时域和频域振动信号中提取十五个特征,解决了由于其非线性和非平稳性导致的故障识别模糊问题。然后将提取的特征向量分为训练集和测试集,作为SVM进行故障诊断的输入。为了优化SVM,我们使用多项式核函数和径向基核函数构建了一个混合核SVM。BO用于优化目标函数的极值并确定其权重系数。我们分别使用训练数据和测试数据作为输入,为BO的高斯回归过程创建一个目标函数。将优化后的参数用于重建SVM,然后对其进行训练以进行网络分类预测。我们使用凯斯西储大学的轴承数据集对所提出的诊断模型进行了测试。验证结果表明,与将振动信号直接输入SVM相比,故障诊断准确率从85%提高到了100%,效果显著。与其他诊断模型相比,我们的贝叶斯优化混合核SVM模型具有最高的准确率。在实验室验证中,我们对实验中测量的四种故障形式中的每一种都取了六十组样本值,并重复了验证过程。实验结果表明,贝叶斯优化混合核SVM的准确率达到100%,五次重复的准确率达到96.7%。这些结果证明了我们所提出的滚动轴承故障诊断方法的可行性和优越性。

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3
Modified multiscale weighted permutation entropy and optimized support vector machine method for rolling bearing fault diagnosis with complex signals.
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4
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基于改进多尺度加权排列熵和优化支持向量机的复杂信号滚动轴承故障诊断方法
ISA Trans. 2021 Aug;114:470-484. doi: 10.1016/j.isatra.2020.12.054. Epub 2021 Jan 1.
4
Challenges in representation learning: a report on three machine learning contests.表示学习中的挑战:三个机器学习竞赛的报告。
Neural Netw. 2015 Apr;64:59-63. doi: 10.1016/j.neunet.2014.09.005. Epub 2014 Dec 29.