What does this research mean for the field?

The proposed multi-scale bidirectional fusion network (MBFNet) significantly improves real-time degradation prediction accuracy for industrial automotive PEMFC stacks, reducing prediction error by 18.6% and requiring 36.8% fewer parameters compared to standard LSTM-attention models. Novelty: ClaimNovelty.METHODOLOGICAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to enhance degradation prediction accuracy for PEMFC stacks in automotive conditions using a novel multi-scale fusion approach.

May 20, 2026

Real-time degradation modeling for automotive PEMFC stacks: a multi-scale fusion network validated on an industrial 215-channel system

Key Points

The aim is to enhance degradation prediction accuracy for PEMFC stacks in automotive conditions using a novel multi-scale fusion approach.
Developed a multi-scale bidirectional fusion network (MBFNet) for degradation prediction in a 215-channel PEMFC stack.
Introduced a channel-joint adaptive noise correlation threshold (NCT) algorithm to address variable sensor correlations without physical modeling.
Implemented experimental comparisons with LSTM-attention and 1D-CNN methods to evaluate prediction accuracy and efficiency.
MBFNet achieved 18.6% lower prediction error and 36.8% fewer parameters compared to the LSTM-attention benchmark.
In multi-step predictions, MBFNet reduced root mean square error by 24.5% relative to LSTM-attention and by 55.2% compared to 1D-CNN across four horizons.
MBFNet demonstrated strong physical interpretability, facilitating efficient implementation for practical use.

Abstract

Accurately predicting long-term degradation patterns in proton exchange membrane fuel cell (PEMFC) stacks under automotive operating conditions remains challenging. Prediction methods are largely constrained by laboratory-scale experiments and limited stack sizes, resulting in insufficient accuracy and generalization capability. To address these limitations, in this paper we propose a multi-scale bidirectional fusion network (MBFNet) tailored for an industrial 215-channel PEMFC stack, enabling accurate degradation prediction under accelerated real-world dynamic conditions using gas-heat-electricity (GHE) co-simulation data. A channel-joint adaptive noise correlation threshold (NCT) algorithm is introduced to account for variable correlations across sensors and operating conditions without relying on prior physical modeling. A multi-scale decomposition module captures degradation dynamics at different temporal scales, while a bidirectional fusion module integrates global trends and local details into the final prediction. Experimental results show that MBFNet achieves 18.6% lower prediction error and 36.8% fewer parameters than the long short-term memory (LSTM)-attention benchmark under real operating scenarios. In multi-step prediction tasks, MBFNet reduces root mean square error by an average of 24.5% relative to LSTM-attention and 55.2% relative to a one-dimensional convolutional neural network (1D-CNN) across four prediction horizons, better satisfying automotive application requirements. Moreover, MBFNet exhibits strong physical interpretability, making it efficient to implement and promising for practical deployment.

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Real-time degradation modeling for automotive PEMFC stacks: a multi-scale fusion network validated on an industrial 215-channel system

Key Points

Abstract

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