TR2019-085
Online Parameter Identification for State of Power Prediction of Lithiumion Batteries in Electric Vehicles Using Extremum Seeking
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- "Online Parameter Identification for State of Power Prediction of Lithiumion Batteries in Electric Vehicles Using Extremum Seeking", International Journal of Control, Automation and Systems, DOI: 10.1007/s12555-018-0506-y, pp. 2906-2916, August 2019.BibTeX TR2019-085 PDF
- @article{Wei2019aug,
- author = {Wei, Chun and Benosman, Mouhacine and Kim, Taesic},
- title = {Online Parameter Identification for State of Power Prediction of Lithiumion Batteries in Electric Vehicles Using Extremum Seeking},
- journal = {International Journal of Control, Automation and Systems},
- year = 2019,
- pages = {2906--2916},
- month = aug,
- doi = {10.1007/s12555-018-0506-y},
- url = {https://www.merl.com/publications/TR2019-085}
- }
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- "Online Parameter Identification for State of Power Prediction of Lithiumion Batteries in Electric Vehicles Using Extremum Seeking", International Journal of Control, Automation and Systems, DOI: 10.1007/s12555-018-0506-y, pp. 2906-2916, August 2019.
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Abstract:
Accurate state-of-power (SOP) estimation is critical for building battery systems with optimized performance and longer life in electric vehicles and hybrid electric vehicles. This paper proposes a novel parameter identification method and its implementation on SOP prediction for lithium-ion batteries. The extremum seeking algorithm is developed for identifying the parameters of batteries on the basis of an electrical circuit model incorporating hysteresis effect. A rigorous convergence proof of the estimation algorithm is provided. In addition, based on the electrical circuit model with the identified parameters, a battery SOP prediction algorithm is derived, which considers both the voltage and current limitations of the battery. Simulation results for lithium-ion batteries based on real test data from urban dynamometer driving schedule (UDDS) are provided to validate the proposed parameter identification and SOP prediction methods. The proposed method is suitable for real operation of embedded battery management system due to its low complexity and numerical stability.