Journal of Jilin University(Engineering and Technology Edition) ›› 2025, Vol. 55 ›› Issue (2): 494-502.doi: 10.13229/j.cnki.jdxbgxb.20230530

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Rolling bearing fault diagnosis method via wavelet packet logarithmic-energy map

Na WANG1,2(),Yue-lei CUI1,Yang LI1,Zi-cong WANG1   

  1. 1.School of Control Science and Engineering,Tiangong University,Tianjin 300387,China
    2.Key Laboratory of Intelligent Control of Electrical Equipment,Tianjin 300387,China
  • Received:2023-05-27 Online:2025-02-01 Published:2025-04-16

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Abstract:

For the fault diagnosis on rolling bearing, a method via wavelet packet logarithmic-energy map is proposed. Firstly, a new wavelet packet node logarithmic energy formula is improved and presented to overcome the complexity and subjectivity of parameters in the traditional ones. Thus the high-frequency faults and the low-frequency faults are easily identified. As a result, the initial time-frequency features are extracted adequately. Secondly, the idea of Gramian angular summation field is used to transform the features from one-dimension data to two-dimension picture. Therefore the features via wavelet packet logarithmic-energy map are constructed. In them, the space information among the adjacent features are considered further. So the optimization for the initial time-frequency features is completed and their significance are increased. On this basis, the residual network is applied to enhance the accuracy of the presented approach. Finally, the higher accuracy of diagnosis and the greater generalization ability of the proposed method is verified by the standard rolling bearing data set of Case Western Reserve University.

Key words: fault diagnosis, feature extraction, rolling bearing, Gramian angular summation field, wavelet packet logarithmic-energy map, residual network

CLC Number: 

  • TH113.1

Fig.1

Time domain waveform of four state signals"

Fig.2

Schematic diagram of four-layer wavelet packet decomposition"

Fig.3

Schematic diagram of mapping one-dimensional logarithmic energy in Gram angle and field to two-dimensional image"

Fig.4

Basic structure of residual block"

Fig.5

Basic structure of residual network"

Table 1

Data parameters of rolling bearing"

序号类型工况损伤程度/mm损伤位置数量
1OR20.355 63点钟100
0.533 46点钟100
2IR20.355 6100
0.533 4100
3B20.355 6100
0.533 4100
4N2200

Fig.6

Comparison of features extraction effect between the logarithmic energy maps and the ordinary energy maps"

Table 2

Structural parameters of residual network"

网络层输入通道输出通道卷积核大小步长
Conv2d1165*51
ReLU1616
MaxPool2d16162*2
Conv2d(RB1)16163*3
ReLU(RB1)1616
Conv2d(RB1)16163*31
ReLU(RB1)1616
Conv2d16325*51
ReLU3232
MaxPool2d32322*2
Conv2d(RB2)32323*31
ReLU(RB2)3232
Conv2d(RB2)32323*31
ReLU(RB2)3232
Linear321

Fig.7

Comparison of training accuracy among CNN, E-CNN, EI-Res and LEI-Res models"

Fig.8

Comparison of training loss among CNN, E-CNN, EI-Res and LEI-Res models"

Table 3

Comparison of diagnosis accuracy and computation complexity on test dataset among CNN, E-CNN, EI-Res and LEI-Res models"

方法CNNE-CNNEI-ResLEI-Res
测试准确率/%92.0896.6699.16100
运行时间/s48.7445.9157.1056.88
时间复杂度O(105O(103O(106O(106
空间复杂度O(104O(102O(104O(104

Table 4

Ablation experiments"

方法CNNCNN+RB1CNN+RB2CNN+RB1+RB2
测试准确率/%99.58100100100
测试损失值0.010 20.004 20.004 70.001 3
运行时间/s54.9156.2554.8156.88
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