计算机科学
人工智能
稳健性(进化)
特征提取
电子工程
工程类
变压器
航空航天
模式识别(心理学)
卷积神经网络
故障检测与隔离
状态监测
分割
降噪
执行机构
人工神经网络
极限学习机
信号处理
噪声测量
增采样
小波
小波变换
控制工程
作者
Liubing Hu,Jinghong Tian,Zhilin Dong,Lingli Cui,Chengri Lang
标识
DOI:10.1109/tase.2025.3640120
摘要
To address the critical challenges of submerged weak fault signatures and extreme operational variability in aerospace bearing diagnosis, a GADF-powered dual-branch network with KAN-Swin Transformer is proposed for fault diagnosis of aerospace bearing in this study. Firstly, the one-dimensional vibration signal is encoded into a two-dimensional time-frequency image through gramian angular difference field (GADF), employing polar coordinate mapping to preserve temporal dependencies and spectral dynamic characteristics while addressing the noise sensitivity limitations of conventional time-frequency analysis methods. Subsequently, a KAN-Swin Transformer module is developed by replacing traditional multilayer perceptron with B-spline basis functions, which enhances nonlinear mapping capability through dynamic grid adjustment strategy, effectively reducing parameter complexity while improving modeling of transient impacts and periodic patterns. Furthermore, a dual-branch parallel architecture is proposed: The KAN-Swin Transformer branch extracts local structural features through hierarchical window attention mechanisms, while the CNN-GAM branch strengthens global texture perception via multi-scale convolution integrated with channel-spatial attention fusion. Finally, cross-modal feature concatenation is combined with adaptive pooling to achieve synergistic optimization of global-local characteristics, significantly enhancing fault pattern discriminability under complex noise environments. The developed method tested on two different sets of aerospace bearing data, has achieved a classification accuracy of 100%. Meanwhile, the collaborative effect of module integration including KAN, Swin Transformer and CNN-GAM is validated through ablation experiments, showing enhanced cross-speed operational recognition rates compared to baseline models and confirming the robustness of the framework against noise and variable loading conditions. By synergistically integrating mechanism fusion and attention architectures, the proposed framework provides a reliable solution for intelligent health monitoring of aerospace bearings.
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