TY - GEN
T1 - Multiscale Wavelet-Driven Transformer for Blade Icing Detection MWT
AU - Xiang, Dong
AU - Cheng, Xu
AU - Chen, Sizhuo
AU - Liu, Mengna
AU - Shi, Fan
AU - Liu, Xiufeng
PY - 2024
Y1 - 2024
N2 - Currently, the global demand for green wind power generation is increasing day by day. However, the icing of fan blades can significantly reduce the efficiency of fan power generation, highlighting the increasing importance of efficiently detecting whether the wind turbine is icing. In the traditional approach, the operation status of wind turbines is manually collected. However, with technological advancements, the SCADA system now automatically collects the continuous operational status of wind turbines. Nevertheless, However, the monitored operational data suffers from data imbalance. In this study, we introduce a multi-level neural network built upon the Trans- former architecture. Specifically, to extract multi-level features from the time and frequency domains, we utilize discrete wavelet decomposition. By leveraging the self-attention mechanism of the Transformer, we enhance the feature extraction capabilities for predictive tasks. We investigate data resampling methods to address the data imbalance problem. Comprehensive studies demonstrate that our proposed algorithm improves F1 scores to 90.08%, 81.70%, and 76.21% on datasets processed using data resampling algorithms. The obtained icing detection results validate the applicability of our approach and demonstrate that adopting this algorithm can enhance the accuracy.
AB - Currently, the global demand for green wind power generation is increasing day by day. However, the icing of fan blades can significantly reduce the efficiency of fan power generation, highlighting the increasing importance of efficiently detecting whether the wind turbine is icing. In the traditional approach, the operation status of wind turbines is manually collected. However, with technological advancements, the SCADA system now automatically collects the continuous operational status of wind turbines. Nevertheless, However, the monitored operational data suffers from data imbalance. In this study, we introduce a multi-level neural network built upon the Trans- former architecture. Specifically, to extract multi-level features from the time and frequency domains, we utilize discrete wavelet decomposition. By leveraging the self-attention mechanism of the Transformer, we enhance the feature extraction capabilities for predictive tasks. We investigate data resampling methods to address the data imbalance problem. Comprehensive studies demonstrate that our proposed algorithm improves F1 scores to 90.08%, 81.70%, and 76.21% on datasets processed using data resampling algorithms. The obtained icing detection results validate the applicability of our approach and demonstrate that adopting this algorithm can enhance the accuracy.
KW - Deep learning
KW - Wind turbine
KW - discrete wavelet decomposition
KW - icing detection
KW - transformer
U2 - 10.1145/3653644.3653650
DO - 10.1145/3653644.3653650
M3 - Article in proceedings
T3 - ACM International Conference Proceeding Series
SP - 204
EP - 210
BT - Proceedings of the 2024 3rd International Conference on Frontiers of Artificial Intelligence and Machine Learning
ER -