Beyond Accuracy: Cost-Aware, Explainable Predictive Maintenance for Industrial Machine Health Monitoring Using Sensor RUL Estimation
DOI:
https://doi.org/10.66279/713yns26Keywords:
Predictive Maintenance, Remaining Useful Life (RUL), Random Forest, Cost-Sensitive LearningAbstract
Predictive maintenance in safety-critical aerospace systems requires not only accurate remaining useful life (RUL) prediction, but also decision-relevant outputs that are explainable, cost-sensitive, and operationally actionable. However, existing approaches primarily optimize metrics such as RMSE and MAE while overlooking asymmetric error costs, interpretability, and early-warning performance. This paper presents a comprehensive framework evaluated on the NASA C-MAPSS FD001 turbofan dataset, addressing these limitations. Four models, Ridge Regression, Random Forest, XGBoost, and LSTM, are trained on a 112-feature space derived from 14 sensors using rolling statistics, lag features, degradation slopes, and delta transformations. Models are evaluated using RMSE, MAE, R², and the NASA PHM asymmetric score. Results indicate that Random Forest achieves the lowest RMSE (12.13 cycles), while XGBoost attains the best PHM Score (230.02), suggesting improved robustness under asymmetric cost conditions. SHAP-based analysis identifies delta and variability features of key sensors as dominant degradation indicators, offering physically interpretable insights. Additionally, an early-warning system evaluated at a 30-cycle horizon shows that Random Forest achieves an F1-score of 0.737 with minimal missed failures, while LSTM demonstrates higher recall at the cost of increased false alarms. These findings highlight the importance of combining accuracy, cost-awareness, and explainability to support practical predictive maintenance decision-making.
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