期刊
IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS
卷 68, 期 4, 页码 3170-3180出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TIE.2020.2973876
关键词
Uncertainty; Degradation; Lithium-ion batteries; Reliability; Ground penetrating radar; Predictive models; Electric vehicles (EVs); data-driven approach; lithium-ion (Li-ion) batteries; remaining useful life (RUL); uncertainty management
资金
- EU [685716]
- National Natural Science Foundation of China [61903223]
- Shandong Provincial Key Research and Development Program (Major Scientific and Technological Innovation Project) [2019JZZY010416]
This article applies advanced machine-learning techniques to predict future capacities and RUL for lithium-ion batteries with uncertainty quantification. The combined LSTM+GPR model outperforms other counterparts and provides accurate results for both 1-step and multistep ahead capacity predictions, demonstrating good adaptability and reliable uncertainty quantification for battery health diagnosis even at the early battery cycle stage.
Predicting future capacities and remaining useful life (RUL) with uncertainty quantification is a key but challenging issue in the applications of battery health diagnosis and management. This article applies advanced machine-learning techniques to achieve effective future capacities and RUL prediction for lithium-ion (Li-ion) batteries with reliable uncertainty management. To be specific, after using the empirical mode decomposition (EMD) method, the original battery capacity data is decomposed into some intrinsic mode functions (IMFs) and a residual. Then, the long short-term memory (LSTM) submodel is applied to estimate the residual while the Gaussian process regression (GPR) submodel is utilized to fit the IMFs with the uncertainty level. Consequently, both the long-term dependence of capacity and uncertainty quantification caused by the capacity regenerations can be captured directly and simultaneously. Experimental aging data from different batteries are deployed to evaluate the performance of proposed LSTM+GPR model in comparison with the solo GPR, solo LSTM, GPR+EMD, and LSTM+EMD models. Illustrative results demonstrate the combined LSTM+GPR model outperforms other counterparts and is capable of achieving accurate results for both 1-step and multistep ahead capacity predictions. Even predicting the RUL at the early battery cycle stage, the proposed data-driven approach still presents good adaptability and reliable uncertainty quantification for battery health diagnosis.
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