Wear Leveling-Aware Active Battery Cell Balancing

Enrico Fraccaroli; Seongik Jang; Logan Stach; Hoeseok Yang; Sangyoung Park; Samarjit Chakraborty

doi:10.1109/VLSID60093.2024.00114

Wear Leveling-Aware Active Battery Cell Balancing

Enrico Fraccaroli, Seongik Jang, Logan Stach, Hoeseok Yang, Sangyoung Park, Samarjit Chakraborty

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Due to manufacturing variabilities and temperature gradients within an electric vehicle's battery pack, the capacities of cells in it decrease differently over time. This reduces the usable capacity of the battery - the charge levels of one or more cells might be at the minimum threshold while most of the other cells have residual charge. Active cell balancing (i.e., transferring charge among cells) can equalize their charge levels, thereby increasing the battery pack's usable capacity. But performing balancing means additional charge transfer, which can result in energy loss and cell aging, akin to memory aging in storage technologies due to writing. This paper studies when cell balancing should be optimally triggered to minimize aging while maintaining the necessary driving capability. In particular, we propose optimization strategies for cell balancing while minimizing their impact on aging. By borrowing terminology from the storage domain, we refer to this as 'wear leveling-aware' active balancing.

Original language	English
Title of host publication	Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024
Publisher	IEEE Computer Society
Pages	643-648
Number of pages	6
ISBN (Electronic)	9798350384406
DOIs	https://doi.org/10.1109/VLSID60093.2024.00114
State	Published - 2024
Externally published	Yes
Event	37th International Conference on VLSI Design, VLSID 2024 - Kolkata, West Bengal, India Duration: 6 Jan 2024 → 10 Jan 2024

Publication series

Name	Proceedings of the IEEE International Conference on VLSI Design
ISSN (Print)	1063-9667

Conference

Conference	37th International Conference on VLSI Design, VLSID 2024
Country/Territory	India
City	Kolkata, West Bengal
Period	6/01/24 → 10/01/24

Keywords

Active Cell Balancing
Battery Management
Charge Equalization
Modeling
Simulation

Access to Document

10.1109/VLSID60093.2024.00114

Cite this

Fraccaroli, E., Jang, S., Stach, L., Yang, H., Park, S., & Chakraborty, S. (2024). Wear Leveling-Aware Active Battery Cell Balancing. In Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024 (pp. 643-648). (Proceedings of the IEEE International Conference on VLSI Design). IEEE Computer Society. https://doi.org/10.1109/VLSID60093.2024.00114

Fraccaroli, Enrico ; Jang, Seongik ; Stach, Logan et al. / Wear Leveling-Aware Active Battery Cell Balancing. Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024. IEEE Computer Society, 2024. pp. 643-648 (Proceedings of the IEEE International Conference on VLSI Design).

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title = "Wear Leveling-Aware Active Battery Cell Balancing",

abstract = "Due to manufacturing variabilities and temperature gradients within an electric vehicle's battery pack, the capacities of cells in it decrease differently over time. This reduces the usable capacity of the battery - the charge levels of one or more cells might be at the minimum threshold while most of the other cells have residual charge. Active cell balancing (i.e., transferring charge among cells) can equalize their charge levels, thereby increasing the battery pack's usable capacity. But performing balancing means additional charge transfer, which can result in energy loss and cell aging, akin to memory aging in storage technologies due to writing. This paper studies when cell balancing should be optimally triggered to minimize aging while maintaining the necessary driving capability. In particular, we propose optimization strategies for cell balancing while minimizing their impact on aging. By borrowing terminology from the storage domain, we refer to this as 'wear leveling-aware' active balancing.",

keywords = "Active Cell Balancing, Battery Management, Charge Equalization, Modeling, Simulation",

author = "Enrico Fraccaroli and Seongik Jang and Logan Stach and Hoeseok Yang and Sangyoung Park and Samarjit Chakraborty",

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year = "2024",

doi = "10.1109/VLSID60093.2024.00114",

language = "English",

series = "Proceedings of the IEEE International Conference on VLSI Design",

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Fraccaroli, E, Jang, S, Stach, L, Yang, H, Park, S & Chakraborty, S 2024, Wear Leveling-Aware Active Battery Cell Balancing. in Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024. Proceedings of the IEEE International Conference on VLSI Design, IEEE Computer Society, pp. 643-648, 37th International Conference on VLSI Design, VLSID 2024, Kolkata, West Bengal, India, 6/01/24. https://doi.org/10.1109/VLSID60093.2024.00114

Wear Leveling-Aware Active Battery Cell Balancing. / Fraccaroli, Enrico; Jang, Seongik; Stach, Logan et al.
Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024. IEEE Computer Society, 2024. p. 643-648 (Proceedings of the IEEE International Conference on VLSI Design).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Fraccaroli, Enrico

AU - Jang, Seongik

AU - Stach, Logan

AU - Yang, Hoeseok

AU - Park, Sangyoung

AU - Chakraborty, Samarjit

PY - 2024

Y1 - 2024

N2 - Due to manufacturing variabilities and temperature gradients within an electric vehicle's battery pack, the capacities of cells in it decrease differently over time. This reduces the usable capacity of the battery - the charge levels of one or more cells might be at the minimum threshold while most of the other cells have residual charge. Active cell balancing (i.e., transferring charge among cells) can equalize their charge levels, thereby increasing the battery pack's usable capacity. But performing balancing means additional charge transfer, which can result in energy loss and cell aging, akin to memory aging in storage technologies due to writing. This paper studies when cell balancing should be optimally triggered to minimize aging while maintaining the necessary driving capability. In particular, we propose optimization strategies for cell balancing while minimizing their impact on aging. By borrowing terminology from the storage domain, we refer to this as 'wear leveling-aware' active balancing.

AB - Due to manufacturing variabilities and temperature gradients within an electric vehicle's battery pack, the capacities of cells in it decrease differently over time. This reduces the usable capacity of the battery - the charge levels of one or more cells might be at the minimum threshold while most of the other cells have residual charge. Active cell balancing (i.e., transferring charge among cells) can equalize their charge levels, thereby increasing the battery pack's usable capacity. But performing balancing means additional charge transfer, which can result in energy loss and cell aging, akin to memory aging in storage technologies due to writing. This paper studies when cell balancing should be optimally triggered to minimize aging while maintaining the necessary driving capability. In particular, we propose optimization strategies for cell balancing while minimizing their impact on aging. By borrowing terminology from the storage domain, we refer to this as 'wear leveling-aware' active balancing.

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Fraccaroli E, Jang S, Stach L, Yang H, Park S, Chakraborty S. Wear Leveling-Aware Active Battery Cell Balancing. In Proceedings - 37th International Conference on VLSI Design, VLSID 2024 - held concurrently with 23rd International Conference on Embedded Systems, ES 2024. IEEE Computer Society. 2024. p. 643-648. (Proceedings of the IEEE International Conference on VLSI Design). doi: 10.1109/VLSID60093.2024.00114

Wear Leveling-Aware Active Battery Cell Balancing

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Keywords

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