变压器
计算机科学
方位(导航)
断层(地质)
电子工程
模式识别(心理学)
人工智能
工程类
电气工程
电压
地质学
地震学
作者
Yufei Han,Fan Zhang,Zhaoqi Li,Qichen Wang,Chaofan Li,Pei Ling Lai,Tianrui Li,Fei Teng,Zhenzhen Jin
标识
DOI:10.1109/tim.2024.3502821
摘要
In recent years, intelligent fault diagnosis methods for bearings, dominated by deep learning, have been widely applied. However, most current methods are still limited to diagnosing different types of faults or degrees of faults as single diagnostic targets. There is less research on methods that diagnose multiple fault tasks simultaneously, and there are difficulties in fully extracting complementary fault features, adapting to complex diagnostic environments with strong noise interference, and handling imbalanced data distribution across various working conditions. To overcome these difficulties and challenges, this article proposes an innovative multitask CNN-Transformer (MT-ConvFormer) bearing fault diagnosis method. This method consists of a shared layer responsible for learning globally shared information and several task-specific branch networks designed for different fault diagnosis tasks. First, the shared layer uses the CNN to extract local feature information and combines it with the Transformer to infer cyclic global dependencies of vibration signals, effectively mining globally shared information. Then, the task branch networks, by adopting an effective redundancy filtering mechanism, can more efficiently extract useful feature information from the shared layer and suppress the interference of irrelevant information. Experimental results show that this method exhibits significant diagnostic performance both under noisy conditions and under conditions of imbalanced data distribution across different working conditions. Moreover, comparative experiments with other existing methods further confirm the superiority of MT-ConvFormer under the same experimental setups.
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