Real-time personalized health status prediction of lithium-ion batteries using deep transfer learning

Real-time and personalized lithium-ion battery health management is conducive to safety improvement for end-users. However, personalized prognostic of the battery health status is still challenging due to diverse usage interests, dynamic operational patterns and limited historical data. We generate...

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Bibliographic Details
Published in:Energy & environmental science 2022-10, Vol.15 (1), p.483-494
Main Authors: Ma, Guijun, Xu, Songpei, Jiang, Benben, Cheng, Cheng, Yang, Xin, Shen, Yue, Yang, Tao, Huang, Yunhui, Ding, Han, Yuan, Ye
Format: Article
Language:English
Subjects:
Batteries
Customization
Datasets
Discharge
End users
Learning
Lithium
Lithium-ion batteries
Power consumption
Predictions
Real time
Rechargeable batteries
Transfer learning
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Summary:Real-time and personalized lithium-ion battery health management is conducive to safety improvement for end-users. However, personalized prognostic of the battery health status is still challenging due to diverse usage interests, dynamic operational patterns and limited historical data. We generate a comprehensive dataset consisting of 77 commercial cells (77 discharge protocols) with over 140 000 charge-discharge cycles-the largest dataset to our knowledge of its kind, and develop a transfer learning framework to realize real-time personalized health status prediction for unseen battery discharge protocols, at any charge-discharge cycle. Our method can achieve mean testing errors of 0.176% and 8.72% for capacity estimation and remaining useful life (RUL) prediction, respectively. Additionally, the proposed framework can leverage the knowledge from two other well-known battery datasets, with a variety of charge configurations and a different battery chemistry respectively, to reliably estimate the capacity (0.328%/0.193%) and predict the RUL (9.80%/9.90%) of our cells. This study allows end users to tailor battery consumption plans and motivates manufacturers to improve battery designs. We have developed a high-performance deep transfer learning framework to predict the health status of lithium-ion batteries for each end-user at any charge-discharge cycle.
ISSN:1754-5692
1754-5706
DOI:10.1039/d2ee01676a