Citation

Khan, MD Azam and Rahman, Arifur and Mahmud, Farhad Uddin and Bishnu, Kanchon Kumar and Nabil, Hadiur Rahman and Mridha, M. F. and Hossen, Md. Jakir (2025) A Physics-Guided Bayesian Neural Network for Sensor Fault Detection in Wind Turbines. IEEE Open Journal of the Computer Society. pp. 1-12. ISSN 2644-1268

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Abstract

Predictive maintenance is essential for ensuring the reliability and efficiency of wind energy systems. Traditional deep learning models for sensor fault detection rely solely on data-driven patterns, often lacking interpretability and robustness. This paper proposes a Physics-Guided Bayesian Neural Network (PINN-BNN) model that integrates physics-informed learning with Bayesian inference to improve fault detection in wind turbines. The proposed approach enforces domain-specific constraints to ensure physically consistent predictions while quantifying uncertainty for risk-aware decision-making. The model is evaluated using a real-world wind turbine sensor dataset, achieving an accuracy of 97.6%, a recall of 91.8%, and an AUC-ROC of 0.987. The SHapley Additive exPlanations (SHAP) analysis reveals that gearbox temperature, blade vibration, and generator torque are the most critical features influencing failure predictions. Bayesian uncertainty estimation further improves interpretability by assigning confidence levels to each prediction. A comparative study with ten baseline models, including Long Short-Term Memory (LSTM), Transformer-based models, and traditional machine learning classifiers, demonstrates that the PINN-BNN model outperforms existing approaches while maintaining computational efficiency with a training time of 39.8 minutes and an inference time of 1.7 ms per sample. The integration of physics-informed learning ensures that the model generalizes well to varying environmental conditions, reducing false negatives and minimizing unexpected system failures. The proposed methodology presents a step toward interpretable and reliable predictive maintenance in wind energy systems.

Item Type:	Article
Uncontrolled Keywords:	Predictive maintenance, wind turbines, physics-informed neural networks, Bayesian inference, uncertainty quantification, sensor fault detection, explainable AI
Subjects:	T Technology > TK Electrical engineering. Electronics Nuclear engineering > TK5101-6720 Telecommunication. Including telegraphy, telephone, radio, radar, television
Divisions:	Faculty of Engineering and Technology (FET)
Depositing User:	Ms Suzilawati Abu Samah
Date Deposited:	26 Jun 2025 06:30
Last Modified:	26 Jun 2025 06:30
URII:	http://shdl.mmu.edu.my/id/eprint/14090

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