HIGH PRECISION STATE OF CHARGE ESTIMATION FOR LITHIUM-ION BATTERIES USING AN INTERMEDIATE OBSERVER

Dan Wang, Sicheng Zhou, Zhibo Feng, Jun Wu, and Guanjie Wang

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References

1. [1] M. Yin, “Research on rul of li-ion battery based on improved ar-pf model,” International Journal of Power and Energy Systems,vol. 41, no. 1, pp. 58–64, 2021.
2. [2] H. Obeid, R. Petrone, H. Chaoui, and H. Gualous, “Higherorder sliding-mode observers for state-of-charge and state-of-health estimation of lithium-ion batteries,” IEEE Transactionson Vehicular Technology, vol. 72, no. 4, pp. 4482–4492, 2023.
3. [3] A. Nath, R. Gupta, R. Mehta, and S. S. Bahga, “Attractiveellipsoid sliding-mode observer design for state of charge esti-7mation of lithium-ion cells,” IEEE Transactions on VehicularTechnology, vol. 69, no. 12, pp. 14701–14712, 2020.
4. [4] C. H. Hyun and S. M. Baek, “Hybrid-type intelligent state ofcharge observer of li-ion batteries,” Journal of Electrical Engi-neering & Technology, vol. 16, no. 6, pp. 3017–3024, 2021.
5. [5] S. Rout and S. Das, “Online state-of-charge estimation oflithium-ion battery using a fault-tolerant and noise-immunethreefold modified adaptive extended kalman filter,” IEEETransactions on Transportation Electrification, vol. 10, no. 4,pp. 9366–9380, 2024.
6. [6] C. Y. Pan, Z. X. Peng, and S. C. Yang, “Battery state of chargeestimation with event-triggered parameter identification,” IEEETransactions on Transportation Electrification, vol. 10, no. 4,pp. 10401–10409, 2024.
7. [7] N. Li, F. Hu, and W. Ma, “Application of multi-energy com-posite energy storage system technology in electric vehicles,”International Journal of Power and Energy Systems, vol. 44,no. 10, pp. 1–10, 2024.
8. [8] H. D. Xi, X. J. Lin, S. Zhang, and X. Luo, “A lumped distur-bance compensation scheme for unbiased state-of-charge esti-mation of lithium-ion batteries,” IEEE Transactions on PowerElectronics, vol. 40, no. 3, pp. 4569–4580, 2025.
9. [9] I. M. Monirul, L. Qiu, and R. Ruby, “Accurate state of charge es-timation for uav-centric lithium-ion batteries using customizedunscented kalman filter,” Journal of Energy Storage, vol. 107,p. 114955, 2025.
10. [10] R. Xiong, Q. Yu, W. Shen, and C. Lin, “A sensor fault diagnosismethod for a lithium-ion battery pack in electric vehicles,” IEEETransactions on Power Electronics, vol. 34, no. 10, pp. 9709–9718, 2019.
11. [11] L. Yang, T. Liu, Z. Li, and W. Zhou, “State estimation and en-ergy management of microgrid energy storage system using par-ticle filter and markov chain monte carlo,” International Journalof Power and Energy Systems, vol. 44, no. 10, 2024.
12. [12] Q. Ouyang, J. Chen, J. Zheng, and Y. Hong, “Soc estimation-based quasi-sliding mode control for cell balancing in lithium-ionbattery packs,” IEEE Transactions on Industrial Electronics,vol. 65, no. 4, pp. 3427–3436, 2018.
13. [13] M. Naguib, P. Kollmeyer, and A. Emadi, “Lithium-ion bat-tery pack robust state of charge estimation, cell inconsistency,and balancing: Review,” IEEE Access, vol. 9, pp. 50570–50582,2021.
14. [14] Z. Xi, M. Dahmardeh, B. Xia, and Y. Fu, “Learning of batterymodel bias for effective state of charge estimation of lithium-ionbatteries,” IEEE Transactions on Vehicular Technology, vol. 68,no. 9, pp. 8613–8628, 2019.
15. [15] Y. Dai, Q. Peng, T. Liu, and J. Meng, “Negative resistor-basedequivalent circuit model of lithium-ion battery energy storagesystem for grid inertia support,” IEEE Transactions on PowerElectronics, vol. 39, no. 11, pp. 15217–15230, 2024.
16. [16] W. Zhang, L. Wang, L. Wang, and C. Liao, “Joint state-of-charge and state-of-available-power estimation based on theonline parameter identification of lithium-ion battery model,”IEEE Transactions on Industrial Electronics, vol. 69, no. 4,pp. 3677–3688, 2022.
17. [17] W. Song, R. Liu, X. Jin, and W. Guo, “Soc estimation forlithium-ion batteries based on weighted multi-innovation sage-husa adaptive ekf,” Energies, vol. 18, no. 16, p. 4364, 2025.
18. [18] J. Xu, C. C. Mi, B. Cao, and J. Deng, “The state of charge esti-mation of lithium-ion batteries based on a proportional-integralobserver,” IEEE Transactions on Vehicular Technology, vol. 63,no. 4, pp. 1614–1621, 2014.
19. [19] M. Y. Zhang and X. B. Fan, “Design of battery managementsystem based on improved ampere-hour integration method,”International Journal of Electric and Hybrid Vehicles, vol. 14,no. 1-2, pp. 1–29, 2022.
20. [20] Z. L. Chen, W. J. Liao, and P. F. Li, “Lithium-ion battery stateof charge estimation strategy for industrial applications,” Pro-ceedings of the Institution of Civil Engineers - Energy, vol. 177,no. 1, pp. 14–21, 2023.
21. [21] G. Z. Dong, G. X. Gao, Y. J. Lou, and J. C. Yu, “Hybridphysics and data-driven electrochemical states estimation forlithium-ion batteries,” IEEE Transactions on Energy Conver-sion, vol. 39, no. 4, pp. 2689–2700, 2024.
22. [22] M. Savargaonkar, I. Oyewole, A. Chehade, and A. A. Hussein,“Uncorrelated sparse autoencoder with long short-term mem-ory for state-of-charge estimations in lithium-ion battery cells,”IEEE Transactions on Automation Science and Engineering,vol. 21, no. 1, pp. 15–26, 2024.
23. [23] D. D. Ge, G. Y. Jin, J. Q. Wang, and Z. D. Zhang, “A novelba-abc-elm model for estimating state of health of lithium-ionbatteries,” Energy Reports, vol. 13, pp. 465–476, 2025.
24. [24] A. Elachhab, E. Laadissi, A. Tabine, and A. Hajjaji, “Deeplearning and data augmentation for robust battery state ofcharge estimation in electric vehicles,” Electrical Engineering,vol. 107, pp. 7313–7327, 2025.
25. [25] Z. D. Lu, H. M. Chen, and F. X. Xu, “State of charge estimationof lithium-ion battery based on tscso-gru-attention,” Interna-tional Journal of Green Energy, vol. 22, no. 8, pp. 1628–1638,2024.
26. [26] A. V. Vykhodtsev, D. Jang, Q. Wang, W. Rosehart, andH. Zareipour, “Physics-aware degradation model of lithium-ionbattery energy storage for techno-economic studies in power sys-tems,” IEEE Transactions on Sustainable Energy, vol. 15, no. 1,pp. 316–327, 2024.
27. [27] C. S. Huang and M. Y. Chow, “Robust state-of-charge estima-tion for lithium-ion batteries over full soc range,” IEEE Jour-nal of Emerging and Selected Topics in Industrial Electronics,vol. 2, no. 3, pp. 305–313, 2021.
28. [28] T. Y. Meng, Z. L. Lin, Y. Wan, and Y. A. Shamash, “Nonlin-ear observer-based state-of-charge balancing of networked bat-tery energy storage systems,” Journal of Control and Decision,vol. 12, no. 1, pp. 49–64, 2025.
29. [29] F. Yang, Q. Mao, J. M. Zhang, and S. L. Hou, “Real-timestate-of-charge estimation for rechargeable batteries based on in-situ ultrasound-based battery health monitoring and extendedkalman filtering model,” Applied Energy, vol. 381, p. 125161,2025.
30. [30] Y. Feng, C. Xue, Q. L. Han, and F. L. Han, “Robust estima-tion for state-of-charge and state-of-health of lithium-ion batter-ies using integral-type terminal sliding-mode observers,” IEEETransactions on Industrial Electronics, vol. 67, no. 5, pp. 4013–4023, 2020.
31. [31] A. Clemente, A. Cecilia, and R. Costa-Castell´o, “Online stateof charge estimation for a vanadium redox flow battery with un-equal flow rates,” Journal of Energy Storage, vol. 60, p. 106503,2023.

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• Abstract
• DOI: 10.2316/J.2026.203-0655
• From Journal (203) International Journal of Power and Energy Systems - 2026

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