Enhancing cell lifetime is a vital criterion in battery design and development. Because lifetime evaluation requires prolonged cycling experiments, early prediction of cell ageing can significantly accelerate both the autonomous...
Enhancing lifetime is a vital aspect in battery design and development. Lifetime evaluation requires prolonged cycling experiments. Early prediction of battery cell ageing can accelerate the development timeline as well as optimal charging schedule planning, and battery cell and pack production towards an extended lifetime. We demonstrate that an autoregressive model can be trained with limited data for early prediction capacity. Our approach robustly models the capacity degradation over the entire lifetime and outperforms previous approaches in accuracy for EOL (end of life) prediction. Our model captures the uncertainty in the prediction, allowing appropriate and reliable deployment. Explainability analysis of the proposed deep model provides cognizance of the interplay between multiple cell degradation mechanisms. Finally, we show that the model aligns with existing chemical insights into the rationale for early EOL despite not being trained for this or having received prior chemical knowledge.
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