Predicting Battery Cycle Life with Few-Shot Transfer Learning over Heterogeneous Datasets
Runyao Yu (Rimac Technology, AIT Austrian Institute of Technology, TU Delft - Intelligent Electrical Power Grids)
Jiaqi Wang (Student TU Delft)
Yongsheng Han (TU Delft - Signal Processing Systems)
Chi Zhang (Student TU Delft)
Teddy Szemberg O'Connor (Rimac Technology)
Jochen Cremer (AIT Austrian Institute of Technology, TU Delft - Intelligent Electrical Power Grids)
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Abstract
This paper presents an efficient approach to battery cycle life prediction through few-shot transfer learning, addressing the challenges of costly and limited battery aging data. Leveraging freely available datasets, a multi-layer perceptron (MLP) model was pretrained on diverse battery aging datasets to adapt to new prediction tasks with minimal training samples through few-shot fine-tuning techniques on the target data. The proposed fine-tuning strategy was validated using a heterogeneous aging dataset of 347 batteries, with cycle lives ranging from 144 to 4,052 cycles, incorporating batteries with lithium iron phosphate (LFP), lithium cobalt oxide (LCO), nickel cobalt aluminum oxide (NCA), and nickel manganese cobalt oxide (NMC) chemistries, which ensures robust validation of our methods. The results show that even with few samples of data from a target task, a comparable generalization performance to training from scratch with 100% data can be achieved, thus demonstrating its effectiveness in utilizing available resources for accurate cycle life prediction.