Abstract
Extracting robust fault sensitive features of vibration signals remains a challenge for rotating machinery fault diagnosis under variable operating conditions. Most existing fault diagnosis methods based on the convolutional neural network (CNN) can only extract single-scale features, which not only loss fault sensitive information on other scales, but also suffer from the domain shift problem. In this work, a novel end-to-end deep learning network named adaptive weighted multiscale convolutional neural network (AWMSCNN) is proposed to adaptively extract robust and discriminative multiscale fusion features from raw vibration signals. The AWMSCNN consists of three main components: the denoising layer, the adaptive weighted multiscale convolutional (AWMSC) block, and the multiscale feature fusion layer. The AWMSC block can learn rich and complementary features on multiple scales in parallel. Then, an adaptive weight vector is introduced to modulate multiscale features to emphasize fault sensitive features and suppress features that are sensitive to operating conditions. The train wheelset bearing dataset and the bearing dataset provided by Case Western Reserve University (CWRU) are used to verify the superiority of the proposed model over the basic CNN and other multiscale CNN models. The experiment results show that the proposed model has strong fault discriminative ability and domain adaptive ability against variable operating conditions.
Highlights
Rotating machinery is widely used in transportation, electric equipment, and manufacturing equipment [1]
PROPOSED METHOD The proposed adaptive weighted multiscale convolutional neural network (AWMSCNN) is implemented under the assumption that labeled training datasets under at least two operating conditions are available for model training
CASE 2: EXPERIMENT RESULTS ON THE CWRU DATASET AND PERFORMANCE ANALYSIS 1) DATA DESCRIPTION The CWRU motor bearing dataset is provided by the Bearing Data Center of Case Western Reserve University [33]
Summary
Rotating machinery is widely used in transportation, electric equipment, and manufacturing equipment [1]. Rotating machinery often operates under complex conditions such as variable speed, variable load, and strong noise [2], [3]. Any small fault of the rotating machinery may evolve into a major safety accident. Effective fault diagnosis of rotating machinery under variable operating conditions is crucial to guarantee. The extracted features are sent into a shallow machine learning model, such as support vector machines (SVM), neural networks, and decision trees, to implement fault detection. It is difficult and time-consuming to determine which features should be extracted [5]. What is worse, rotating machinery typically operates under variable operating conditions in practice, especially under variable speed and
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