Abstract
In recent years, deep learning methods which promote the accuracy and efficiency of fault diagnosis task without any extra requirement of artificial feature extraction have elicited the attention of researchers in the field of manufacturing industry as well as aerospace. However, the problems that data in source and target domains usually have different probability distributions because of different working conditions and there are insufficient labeled or even unlabeled data in target domain significantly deteriorate the performance and generalization of deep fault diagnosis models. To address these problems, we propose a novel Wasserstein Generative Adversarial Network with Gradient Penalty- (WGAN-GP-) based deep adversarial transfer learning (WDATL) model in this study, which exploits a domain critic to learn domain invariant feature representations by minimizing the Wasserstein distance between the source and target feature distributions through adversarial training. Moreover, an improved one-dimensional convolutional neural network- (CNN-) based feature extractor which utilizes exponential linear units (ELU) as activation functions and wide kernels is designed to automatically extract the latent features of raw time-series input data. Then, the fault model classifier trained in one working condition (source domain) with sufficient labeled samples could be generalized to diagnose data in other working conditions (target domain) with insufficient labeled samples. Experiments on two open datasets demonstrate that our proposed WDATL model outperforms most of the state-of-the-art approaches on transfer diagnosis tasks under diverse working circumstances.
Highlights
Fault diagnosis utilizing the data acquired by monitoring the equipment is a technology which aims to detect the potential anomalies as early as possible and identify the root causes of failures and help make maintenance decision to avoid catastrophic breakdown
We propose a new Wasserstein GAN (WGAN)-GP-based deep adversarial transfer learning (WDATL) model to tackle the problems of spacecraft fault diagnosis under various working conditions
The main contributions of this paper can be summarized as follows: (1) We propose a novel WGAN-GP-based deep adversarial transfer learning (WDATL) model, which could learn domain-invariant features and promote diagnosis performance under multiple working conditions
Summary
Fault diagnosis utilizing the data acquired by monitoring the equipment is a technology which aims to detect the potential anomalies as early as possible and identify the root causes of failures and help make maintenance decision to avoid catastrophic breakdown. With the rapid increase of test data and fast development in data-driven technology, deep learning models, such as Deep Belief Network (DBN) [9, 10], Sparse Auto-Encoder (SAE) [11, 12], convolutional neural network (CNN) [8, 13,14,15], and Recurrent Neural Network (RNN) [16, 17], can extract effective features and show superior learning capability in fault diagnosis These deep models are becoming research hotspots in the fault diagnosis of industrial equipment and spacecraft [8, 18, 19].
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