Fault Diagnosis Method of Rolling Bearing Combining VMD with t-SNE
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摘要: 滚动轴承故障诊断普遍采用有监督学习的方式,针对有标签数据难以获取的问题,提出一种VMD分解与t-SNE流形学习相结合的滚动轴承故障诊断方法。利用VMD分解将滚动轴承原始振动信号分解为若干本征模态分量(IMF);计算每个模态分量的时频特性指标组成高维故障特征,通过t-SNE对故障进行二次特征提取,获取低维敏感特征并将其作为K-means分类器的输入,实现故障类型的识别。将该方法应用到滚动轴承故障诊断中并与VMD + PCA、原始时频特征+ t-SNE两种方法进行对比,结果表明VMD + t-SNE方法以无监督学习的方式实现了故障诊断的去标签化和自适应性,同时提高了故障诊断的准确性。Abstract: Aiming at the problem that the supervised learning is commonly adopted in fault diagnosis for rolling bearing, while the labeled data are often difficult to obtain, a fault diagnosis method of rolling bearing combining VMD (Variational Mode Decomposition) with t-SNE (t-distributed Stochastic Neighbor Embedding) is proposed. The original vibration signal of the rolling bearing is decomposed into the several intrinsic mode functions (IMF) by VMD decomposition; the time-frequency characteristics of each IMF is calculated to form high-dimensional fault features, and the secondary feature extraction is performed by t-SNE to form low-dimensional sensitive features; low-dimensional sensitive features are input to the K-means classifier for fault type identification. The method is applied to the fault diagnosis of rolling bearing and compared with VMD + PCA, original time-frequency features + t-SNE. The results show that the VMD + t-SNE method realizes the de-labeling and adaptability of fault diagnosis in the form of unsupervised learning, while improving the accuracy of fault diagnosis.
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Key words:
- VMD /
- t-SNE /
- rolling bearing /
- feature extraction /
- fault diagnosis
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图 2 机械故障模拟实验台[16]
表 1 滚动轴承信号原始特征向量
特征维数 时频特性 特征维数 时频特性 1 最大值 11 中心频率 2 均值 12 频率方差 3 峰峰值 13 E30/E 4 均方根 14 E31/E 5 波形因子 15 E32/E 6 峰值因子 16 E33/E 7 裕度因子 17 E34/E 8 脉冲因子 18 E35/E 9 峭度因子 19 E36/E 10 歪度因子 20 E37/E 表 2 不同K值下IMF分量中心频率
K 中心频率/Hz 2 1 624 3 820 3 1 600 2 760 3 831 4 1 506 1 774 3 315 3 848 5 1 554 1 674 2 756 3 758 3 895 6 1 546 1 664 2 740 3 376 3 804 3 929 表 3 不同方法分类结果对比
诊断方法 DBI 准确率 原始特征+t-SNE 0.374 93.75% VMD+PCA 0.309 96.25% VMD+t-SNE 0.157 99.37% -
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