Unlocking Unlabeled Battery Data
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Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Volymtitel
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Sammanfattning
The transport sector is expanding rapidly and with it the use of lithium-ion batteries.
Accurately estimating a battery’s State of Health (SoH) is crucial to ensure optimal
usage and in turn optimize both the safety and the environmental impact of the
battery. Traditional machine learning relies on labeled data, which is limited in the
field of SoH estimation. Furthermore, the field holds a significant gap between laboratory
and field data. This project aims to investigate how self-supervised and semisupervised
machine learning methods can be used for SoH estimation. This is done
through upstream self-supervised learning of unlabeled data using autoencoders, and
downstream supervised estimation of SoH. Furthermore, a multi-chemistry battery
dataset containing both field and laboratory data was curated. To further bridge the
gap between field and laboratory data a fine-tuning task was performed. The proposed
semi-supervised hybrid architecture consists of a convolutional autoencoder
combined with an LSTM head. This resulted in SoH predictions with an MAE of
0.0196 and an RMSE of 0.0313. The amount of labeled training data could be significantly
reduced whilst maintaining accurate results. The model was successfully
fine-tuned to produce solid early predictions for SoH on the field data. This project
provides a machine learning pipeline which both lowers the need for labeled data
and helps bridge the laboratory-field gap in SoH estimation. Future work with a
focus on data engineering and acquiring higher quality field data could further build
on these results.
Beskrivning
Ämne/nyckelord
State of Health, Lithium-ion Batteries, Battery Degradation, Machine Learning, Self-supervised Learning, Semi-supervised Learning.
