Abstract
Machinery fault diagnosis tasks have been well addressed when sufficient and abundant data are available. However, the data imbalance problem widely exists in real-world scenarios, which leads to the performance deterioration of fault diagnosis markedly. To solve this problem, we present a novel imbalanced fault diagnosis method based on the enhanced generative adversarial networks (GAN). By artificially generating fake samples, the proposed method can mitigate the loss caused by the lack of real fault data. Specifically, in order to improve the quality of generated samples, a new discriminator is designed using spectrum normalization (SN) strategy and a two time-scale update rule (TTUR) method is used to stabilize the training process of GAN. Then, an enhanced Wasserstein GAN with gradient penalty is developed to generate high-quality synthetic samples for the fault samples set. Finally, a deep convolutional classifier is constructed to carry out fault classification. The performance and effectiveness of the proposed method are validated on the Case Western Reserve University bearing dataset and rolling bearing dataset acquired from our laboratory. The simulation results show that the proposed method has a superior performance than other methods for imbalanced fault diagnosis tasks.
Highlights
As one of the most important components for rotating machinery, rolling bearing is widely used in manufacturing system, electric system, and other mechanical equipment
The testing accuracy of our approach for each dataset is greater than 99%, which suggests that the proposed method
4) ANALYSIS AND DISCUSSION In order to explain why our approach can achieve excellent performance on rolling bearing fault diagnosis with imbalanced data, we provide a visual insight for the training process of enhanced Wasserstein generative adversarial networks (WGAN)-GP method, including the similarity between generated samples and real samples, and the highlevel representations extracted by the discriminator
Summary
As one of the most important components for rotating machinery, rolling bearing is widely used in manufacturing system, electric system, and other mechanical equipment. Rolling bearing is subject to unexpected failures under complex operating conditions, which causes huge economic loss and casualties in engineering practice [1], [2]. It is of great significance to study rolling bearing fault diagnosis to ensure the safety and reliability of facilities. Traditional fault diagnosis algorithms can extract fault features from raw vibrational signal to recognize fault types. Feature extraction methods in the time and frequency domains, such as wavelet transform [3], variational mode decomposition [4], permutation entropy [5], have been widely used to improve fault diagnosis performance in existing research.
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