AI Article Synopsis
- Fault diagnosis in mechanical equipment is crucial for minimizing property damage and injuries, utilizing bearing vibration signals for effective diagnostics despite noise interference.
- The CCSDRSN method enhances traditional approaches by improving the soft threshold function in deep residual shrinkage networks, leading to better information extraction and diagnostic accuracy.
- Incorporating depthwise separable convolutions optimizes the network structure, and the method has proven effective in noisy environments and various load conditions through validation with Case Western Reserve University datasets.
Article Abstract
Fault diagnosis of mechanical equipment can effectively reduce property losses and casualties. Bearing vibration signals, as one of the effective sources of diagnostic information, are often overwhelmed by substantial environmental noise. To address this issue, we present a fault diagnosis method, CCSDRSN, which exhibits strong noise resistance. This method enhances the soft threshold function in the traditional deep residual shrinkage network, allowing it to extract useful information from the fault signal to the maximum extent, thus significantly improving diagnostic accuracy. Additionally, we have developed a novel activation function that can nonlinearly transform the time frequency map across multiple dimensions and the entire region. In pursuit of network optimization and parameter reduction, we have strategically incorporated depthwise separable convolutions, effectively replacing conventional convolutional layers. This architectural innovation streamlines the network. By verifying the effectiveness of the proposed method using Case Western Reserve University datasets, the results demonstrate that the proposed method not only possesses strong noise resistance in high noise environments but also achieves high diagnostic accuracy and good generalization performance under different load conditions.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11516171 | PMC |
| http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0307672 | PLOS |
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