Abstract
Data augmentation has become a hot topic in the field of mechanical intelligent fault diagnosis. It can expand the limited training dataset by generating simulated samples, but there is still no effective method augmenting the resolution of low resolution sample. In this paper, a simple algorithm, namely, efficient subpixel convolutional neural network (ESPCN), is proposed to solve this deficiency. The ESPCN model performs the arrange operation on the raw low resolution data through the subpixel layer and outputs the result of four‐channel multifeature maps. Then, the sample resolution is increased to four times compared with the raw low resolution sample. Finally, the generated high resolution dataset is employed to train the stacked autoencoders (SAE) for fault classification, and the raw high resolution dataset is used for testing. Two fault diagnosis cases with different sample dimensions and rotating speeds are set up to simulate the low resolution situation, and the experimental results verify the feasibility of the proposed algorithm.
Highlights
Mechanical fault diagnosis has entered the age of artificial intelligence as technology rapidly increases [1, 2]
The raw low resolution dataset is input into the efficient subpixel convolutional neural network (ESPCN) network, and the generated high resolution dataset is used as the training set of the stacked autoencoders (SAE)
Since ESPCN can enhance the resolution of low resolution dataset by 4 times, the sample owns much more effective features, which helps the classification network to identify samples with different health conditions
Summary
Mechanical fault diagnosis has entered the age of artificial intelligence as technology rapidly increases [1, 2]. High resolution samples are generally employed in the study of fault diagnosis [15, 16]. For a set of mechanical devices rotating at high speed, it is difficult to collect enough feature information by a signal collector with a low sampling frequency. (1) The proposed ESPCN model can learn features from a low resolution sample and enhance the sample resolution by four times compared to raw signal (2) The generated high resolution dataset is employed to train the SAE model for fault classification and the raw high resolution dataset are used for testing (3) Two experimental cases (different sample dimensions and rotating speeds) are set to simulate the low resolution situation and verify the effectiveness of the propose method.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
