Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications

Daniel Jerouschek; Omer Tan; Ralph Kennel; Ahmet Taskiran

doi:10.1109/SEST50973.2021.9543225

Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications

Daniel Jerouschek, Omer Tan, Ralph Kennel, Ahmet Taskiran

Lehrstuhl für Hochleistungs-Umrichtersysteme

IAV GmbH Ingenieurgesellschaft Auto und Verkehr

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

1 Zitat (Scopus)

Abstract

The prediction of voltage levels in an automotive 48V mild hybrid power supply system is safety-relevant while also enabling greater efficiency. The high power-to-energy ratio in these power supply systems makes exact voltage prediction challenging, so that a method is established to model the behavior of the lithium-ion batteries by means of a recurrent neural network. The raw data are consequently pre-processed with over- and undersampling, normalization and sequentialization algorithms. The resulting database is used to train the constructed recurrent neural network models, while hyperparameter tuning is carried out with the optimization framework optuna. This training methodology is performed with two battery types. Validation shows a maximum error of 2.34 V for the LTO battery and a maximum error of 3.39 V for the LFP battery. The results demonstrate performance of the proposed methodology in an appropriate error range for utilization as a tool to generate a battery model based on available data.

Originalsprache	Englisch
Titel	SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies
Herausgeber (Verlag)	Institute of Electrical and Electronics Engineers Inc.
ISBN (elektronisch)	9781728176604
DOIs	https://doi.org/10.1109/SEST50973.2021.9543225
Publikationsstatus	Veröffentlicht - 6 Sept. 2021
Veranstaltung	4th International Conference on Smart Energy Systems and Technologies, SEST 2021 - Virtual, Vaasa, Finnland Dauer: 6 Sept. 2021 → 8 Sept. 2021

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Name	SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies

Konferenz

Konferenz	4th International Conference on Smart Energy Systems and Technologies, SEST 2021
Land/Gebiet	Finnland
Ort	Virtual, Vaasa
Zeitraum	6/09/21 → 8/09/21

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Jerouschek, D., Tan, O., Kennel, R., & Taskiran, A. (2021). Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications. in SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies (SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/SEST50973.2021.9543225

Jerouschek, Daniel ; Tan, Omer ; Kennel, Ralph et al. / Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications. SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies. Institute of Electrical and Electronics Engineers Inc., 2021. (SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies).

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title = "Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications",

abstract = "The prediction of voltage levels in an automotive 48V mild hybrid power supply system is safety-relevant while also enabling greater efficiency. The high power-to-energy ratio in these power supply systems makes exact voltage prediction challenging, so that a method is established to model the behavior of the lithium-ion batteries by means of a recurrent neural network. The raw data are consequently pre-processed with over- and undersampling, normalization and sequentialization algorithms. The resulting database is used to train the constructed recurrent neural network models, while hyperparameter tuning is carried out with the optimization framework optuna. This training methodology is performed with two battery types. Validation shows a maximum error of 2.34 V for the LTO battery and a maximum error of 3.39 V for the LFP battery. The results demonstrate performance of the proposed methodology in an appropriate error range for utilization as a tool to generate a battery model based on available data.",

keywords = "Lithium-ion battery (LIB), Long short-term memories (LSTM), Machine learning (ML), Modeling recurrent neural network (RNN)",

author = "Daniel Jerouschek and Omer Tan and Ralph Kennel and Ahmet Taskiran",

note = "Publisher Copyright: {\textcopyright} 2021 IEEE.; 4th International Conference on Smart Energy Systems and Technologies, SEST 2021 ; Conference date: 06-09-2021 Through 08-09-2021",

year = "2021",

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day = "6",

doi = "10.1109/SEST50973.2021.9543225",

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Jerouschek, D, Tan, O, Kennel, R & Taskiran, A 2021, Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications. in SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies. SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies, Institute of Electrical and Electronics Engineers Inc., 4th International Conference on Smart Energy Systems and Technologies, SEST 2021, Virtual, Vaasa, Finnland, 6/09/21. https://doi.org/10.1109/SEST50973.2021.9543225

Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications. / Jerouschek, Daniel; Tan, Omer; Kennel, Ralph et al.
SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies. Institute of Electrical and Electronics Engineers Inc., 2021. (SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies).

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

TY - GEN

T1 - Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications

AU - Jerouschek, Daniel

AU - Tan, Omer

AU - Kennel, Ralph

AU - Taskiran, Ahmet

PY - 2021/9/6

Y1 - 2021/9/6

N2 - The prediction of voltage levels in an automotive 48V mild hybrid power supply system is safety-relevant while also enabling greater efficiency. The high power-to-energy ratio in these power supply systems makes exact voltage prediction challenging, so that a method is established to model the behavior of the lithium-ion batteries by means of a recurrent neural network. The raw data are consequently pre-processed with over- and undersampling, normalization and sequentialization algorithms. The resulting database is used to train the constructed recurrent neural network models, while hyperparameter tuning is carried out with the optimization framework optuna. This training methodology is performed with two battery types. Validation shows a maximum error of 2.34 V for the LTO battery and a maximum error of 3.39 V for the LFP battery. The results demonstrate performance of the proposed methodology in an appropriate error range for utilization as a tool to generate a battery model based on available data.

AB - The prediction of voltage levels in an automotive 48V mild hybrid power supply system is safety-relevant while also enabling greater efficiency. The high power-to-energy ratio in these power supply systems makes exact voltage prediction challenging, so that a method is established to model the behavior of the lithium-ion batteries by means of a recurrent neural network. The raw data are consequently pre-processed with over- and undersampling, normalization and sequentialization algorithms. The resulting database is used to train the constructed recurrent neural network models, while hyperparameter tuning is carried out with the optimization framework optuna. This training methodology is performed with two battery types. Validation shows a maximum error of 2.34 V for the LTO battery and a maximum error of 3.39 V for the LFP battery. The results demonstrate performance of the proposed methodology in an appropriate error range for utilization as a tool to generate a battery model based on available data.

KW - Lithium-ion battery (LIB)

KW - Long short-term memories (LSTM)

KW - Machine learning (ML)

KW - Modeling recurrent neural network (RNN)

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Jerouschek D, Tan O, Kennel R, Taskiran A. Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications. in SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies. Institute of Electrical and Electronics Engineers Inc. 2021. (SEST 2021 - 4th International Conference on Smart Energy Systems and Technologies). doi: 10.1109/SEST50973.2021.9543225

Modeling lithium-ion batteries using machine learning algorithms for mild-hybrid vehicle applications

Abstract

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