Uncertainty-Aware Degradation Prediction of PEM Fuel Cells Using PatchTST and Weighted Quantile Random Forests

Accurate and reliable degradation prediction is essential for ensuring the long-term performance and safety of proton exchange membrane fuel cells (PEMFCs) operating under dynamic conditions. Existing data-driven approaches often struggle to capture long-range degradation dependencies, neglect non-stationary aging behavior, or provide only deterministic predictions without uncertainty information. To address these limitations, this paper proposes an uncertainty-aware degradation prediction framework that integrates a Patch-Based Transformer (PatchTST) with a degradation-aware weighted quantile random forest. PatchTST is employed to learn robust temporal degradation representations from multivariate operational data, while the proposed degradation-aware weighting strategy emphasizes late-life aging behavior and quantile regression enables probabilistic prediction with calibrated uncertainty intervals. Experimental evaluation on a publicly available PEMFC dataset demonstrates that the proposed method achieves superior performance, with an RMSE of 0.0018 , an MAE of 0.0022 , and a MAPE of 0.028 , outperforming representative deep learning and tree-based baselines. In addition, the proposed framework attains a prediction interval coverage probability of 0.91 with a narrow mean prediction interval width of 0.063 , confirming its reliability for uncertainty-aware prognostics. The results indicate that the proposed approach provides an effective and robust solution for PEM fuel cell degradation prediction and health monitoring.