Abstract

The working environment of seawater axial piston hydraulic pump is harsh, and it is difficult to diagnose due to insufficient fault database. In contrast, pumps of the same type but using hydraulic oil have an adequate fault database and are easy to diagnose. In view of the above situation, a fault diagnosis method of seawater hydraulic piston pump based on transfer learning is proposed. The method decomposes the original sampled fault signal by complementary ensemble empirical mode decomposition (CEEMD) to obtain the intrinsic mode function (IMF) that can characterize the original signal. The singular value decomposition (SVD) is performed on the IMF. Then, the obtained singular value is used as a feature parameter to construct a feature vector. The feature data of seawater hydraulic pump and oil pump are used as target data and auxiliary data to form training data. The training data is trained based on the iterative adjustment of the weight through the TrAdaBoost transfer learning algorithm. Finally, the results of diagnosis and classification are compared with traditional machine learning. When the number of training data is 5 groups, the accuracy of transfer learning is 30.5% higher than that of traditional machine learning. The results show that transfer learning has great advantages in the case of a small number of samples.

Highlights

  • Machine learning is a hot topic in today’s scientific research, and it is widely used in the field of fault diagnosis

  • Singular value decomposition (SVD) is applied to IMF. en, the singular value obtained by decomposition is used as the characteristic parameter. e characteristic data of seawater hydraulic pump and oil pump are used as target data and auxiliary data for training. e training data is trained by TrAdaBoost transfer learning algorithm based on iterative adjustment of weights

  • All the sample data are decomposed by complementary ensemble empirical mode decomposition (CEEMD) and SVD to form the training dataset. e data of seawater hydraulic pump is the target data, and the data of oil hydraulic pump is used as auxiliary data

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Summary

Theory of Algorithm

The complementary ensemble empirical mode decomposition (CEEMD) is used to decompose and select the original fault signal, and IMF representing the original signal is obtained. Singular value decomposition (SVD) is applied to IMF. En, the singular value obtained by decomposition is used as the characteristic parameter. E signal x(t) is decomposed using the CEEMD and the result is as follows:. Due to the influence of background noise and the insufficiency of the algorithm, the IMF obtained by CEEMD decomposition has false components and noise components. Singular value decomposition (SVD) is widely used in signal processing and fault diagnosis [26,27,28]. E singular value obtained by decomposition has stability invariance and can describe the intrinsic characteristics of the original signal. Orthogonal transformation is the essence of singular value decomposition (SVD).

Result
Transfer Learning
Experimentation
Findings
Result and Discussion
Conclusion

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