Loading [MathJax]/extensions/MathMenu.js
Modeling and Identification of Li-ion Cells | IEEE Journals & Magazine | IEEE Xplore
Access provided by:

MIT Libraries

Sign Out
Access provided by:

MIT Libraries

Sign Out
ADVANCED SEARCH
Journals & Magazines >IEEE Control Systems Letters >Volume: 7

Modeling and Identification of Li-ion Cells

PDF
P. Lopes dos Santos; T.-P. Azevedo Perdicoúlis; Paulo A. Salgado
All Authors

Abstract:

To develop a full battery model in view to accurate battery management, Li-ion cell dynamics is modelled by a capacitor in series with a simplified Randles circuit. The o...Show More

Metadata

Abstract:

To develop a full battery model in view to accurate battery management, Li-ion cell dynamics is modelled by a capacitor in series with a simplified Randles circuit. The open circuit voltage is the voltage at the capacitor terminals, allowing, in this way, for the dependence of the open circuit voltage on the state-of-charge to be embedded in its capacitance. The Randles circuit is recognised as a trusty description of a cell dynamics. It contains a semi-integrator of the current, known as the Warburg impedance, that is a special case of a fractional integrator. To enable the formulation of a time-domain system identification algorithm, the Warburg impedance impulse response was calculated and normalised, in order to derive a finite order state-space approximation, using the Ho-Kalman algorithm. Thus, this Warburg impedance LTI model, with known parameters (normalised impedance) in series with a gain block, is suitable for system identification, since it has only one unknown parameter. A LTI System identification Algorithm was formulated to estimate the model parameters and the initial values of both the open circuit voltage and the states of the normalised Warburg impedance. The performance of the algorithm was very satisfactory on the whole state-of-charge region and when compared with low order Thévenin models. Once it is understood the parameters variability on the state-of-charge, temperature and ageing, we envisage to continue the work using parameter-varying algorithms.
Published in: IEEE Control Systems Letters ( Volume: 7)
Page(s): 1015 - 1020
Date of Publication: 16 December 2022
Electronic ISSN: 2475-1456
DOI: 10.1109/LCSYS.2022.3230010

Funding Agency:

References is not available for this document.
Contents

I. Introduction

As the major industrialised nations are becoming more concerned about global warming and fossil fuel depletion, they outline their plans for electric vehicles (EV) development and production in detriment of combustion engines. Battery technology has been one of the bottlenecks in EV, making the research on battery management systems (BMS) extremely important, especially for the battery state-of-charge (SoC) estimation — the current capacity of a battery expressed as a percentage of the fully-charged capacity. Factors that mainly affect battery SoC are: charge/discharge rate and times, polarisation effect, temperature, self-discharge or battery ageing. In fact, batteries are very complex due to their strong time-varying and non-linear properties, what makes the accurate estimate of SoC a challenging task. During the last years EV powered by lithium batteries have become popular since significant improvements in energy density and power capability have made Li-ion batteries [4], [19] the preferred solution for nowadays low carbon mobility. The change in behaviour of the batteries throughout a vehicle lifetime can have a significant detrimental effect on the whole vehicle performance and existence. Thence, exploring the causes of battery ageing, as well as developing mitigation strategies to avoid premature degradation becomes of paramount importance to vehicle manufacturers. In [24] various representative patents and papers related to SoC estimation methods for an electric vehicle battery are reviewed. According to their theoretical and experimental characteristics, the estimation methods were divided into traditional, based on battery experiments, and modern, based on control theory, especially intelligent algorithms.

Select All
1.
G. Barbero and I. Lelidis, "Analysis of Warburg’s impedance and its equivalent electric circuits", Phys. Chem., vol. 19, no. 36, pp. 24934-24944, 2017.
CrossRef Google Scholar
2.
A. Baughman and M. Ferdowsi, "Battery charge equalisation-state of the art and future trends", SAE Trans., vol. 114, pp. 905-910, Sep. 2005.
Google Scholar
3.
S. Buller, M. Thele, R. W. A. A. De Doncker and E. Karden, "Impedance-based simulation models of supercapacitors and li-ion batteries for power electronic applications", IEEE Trans. Ind. Appl., vol. 41, no. 3, pp. 742-747, May/Jun. 2005.
View Article
Google Scholar
4.
Z. Haizhou, "Modeling of lithium-ion battery for charging/discharging characteristics based on circuit model", Int. J. Online Biomed. Eng., vol. 13, no. 6, pp. 86-95, 2017.
CrossRef Google Scholar
5.
H. Hinz, "Comparison of lithium-ion battery models for simulating storage systems in distributed power generation", Inventions, vol. 4, no. 3, pp. 41, 2019.
CrossRef Google Scholar
6.
Y. Jiang, B. Zhang, X. Shu and Z. Wei, "Fractional-order autonomous circuits with order larger than one", J. Adv. Res., vol. 25, pp. 217-225, Sep. 2020.
CrossRef Google Scholar
7.
Y. Jin, W. Zhao, Z. Li, B. Liu and L. Liu, "Modeling and simulation of lithium-ion battery considering the effect of charge-discharge state", Proc. J. Phys. Conf. Series, 2021.
CrossRef Google Scholar
8.
T. Katayama, Subspace Methods for System Identification, London, U.K.:Springer-Verlag, 2005.
Google Scholar
9.
H. Lei and Y. Y. Han , "The measurement and analysis for open circuit voltage of lithium-ion battery", Proc. J. Phys. Conf. Series, 2019.
CrossRef Google Scholar
10.
M. Li, "Li-ion dynamics and state of charge estimation", Renew. Energy, vol. 100, pp. 44-52, Jan. 2017.
CrossRef Google Scholar
11.
E. Locorotondc et al., "Modeling and simulation of constant phase element for battery electrochemical impedance spectroscopy", Proc. IEEE 5th Int. Forum Res. Tech. Society Ind. (RTSI), pp. 225-230, Sep. 2019.
View Article
Google Scholar
12.
P. L. Dos Santos et al., "Identification of optimal prediction error Thévenin models of Li-ion cells using the MOLI approach", arXiv:2212.09452, 2022.
Google Scholar
13.
B. O. Agudelo, W. Zamboni and E. Monmasson, "A comparison of time-domain implementation methods for fractional-order battery impedance models", Energies, vol. 14, no. 15, pp. 4415, 2021.
CrossRef Google Scholar
14.
I. G. Pérez, I. Gandiaga, M. Garmendia, J. F. Reynaud and U. Viscarret, "Modelling of li-ion batteries dynamics using impedance spectroscopy and pulse fitting: EVs application", World Electr. Veh. J., vol. 6, no. 3, pp. 644-652, 2013.
CrossRef Google Scholar
15.
G. L. Plett, Battery Management Systems Volume I: Battery Modeling, Norwood, MA, USA:Artech House, 2015.
Google Scholar
16.
I. Podlubny, I. Petráš, B. M. Vinagre, P. O’Leary and L. Dorcák, "Analogue realizations of fractional-order controllers", Nonlinear Dyn., vol. 29, pp. 281-296, Jul. 2002.
Google Scholar
17.
A. Rahmoun and H. Biechl, "Modelling of li-ion batteries using equivalent circuit diagrams", Przeglad Elektrotechniczny, vol. 88, no. 7, pp. 152-156, 2012.
Google Scholar
18.
J. F. Reynaud, C. E. Carrejo, O. Gantet, P. Alo’ısi, B. Estibals and C. Alonso, "Active balancing circuit for advanced lithium-ion batteries used in photovoltaic application", Renew. Energ. Power Qual., vol. 1, no. 9, pp. 1423-1428, 2011.
CrossRef Google Scholar
19.
Tutorial lithium asciitext ion battery model, Oct. 2016, [online] Available: https://powersimtech.com/resources/tutorials/lithium/ion-battery-model/.
Google Scholar
20.
K. Uddin, S. Perera, W. D. Widanage, L. Somerville and J. Marco, "Characterising lithium-ion battery degradation through the identification and tracking of electrochemical battery model parameters", Batteries, vol. 2, no. 2, pp. 13, 2016.
CrossRef Google Scholar
21.
S. Westerlund and L. Ekstam, "Capacitor theory", IEEE Trans. Dielectr. Electr. Insul., vol. 1, no. 5, pp. 826-839, Oct. 1994.
View Article
Google Scholar
22.
W. He, N. Williard, C. Chen and M. Pecht, "State of charge estimation for electric vehicle batteries using unscented Kalman filtering", Microelectron. Rel., vol. 53, no. 6, pp. 840-847, 2013.
CrossRef Google Scholar
23.
M. Yu et al., "Fractional-order modeling of lithium-ion batteries using additive noise assisted modeling and correlative information criterion", J. Adv. Res., vol. 25, pp. 49-56, Sep. 2020.
CrossRef Google Scholar
24.
M. Zhang and X. Fan, "Review on the state of charge estimation methods for electric vehicle battery", World Electr. Veh. J., vol. 11, no. 1, pp. 23, 2020.
CrossRef Google Scholar
25.
W. Zhou, Y. Zheng, Z. Pan and Q. Lu, "Review on the battery model and SoC estimation method", Processes, vol. 9, no. 9, pp. 1685, 2021.
CrossRef Google Scholar
26.
L. Zhang, X. Wang, M. Chen, F. Yu and M. Li, "A fractional-order model of lithium-ion batteries and multi-domain parameter identification method", J. Energy Storage, vol. 50, Jun. 2022.
CrossRef Google Scholar
Contact IEEE to Subscribe
More Like This
A Dual ANN Model for Estimation of Internal Impedance of Rechargeable Cell Battery

2018 53rd International Universities Power Engineering Conference (UPEC)

Published: 2018

Optimizing Experiments for Accurate Battery Circuit Parameters Estimation: Reduction and Adjustment of Frequency Set Used in Electrochemical Impedance Spectroscopy

2024 IEEE Energy Conversion Congress and Exposition (ECCE)

Published: 2024

Show More

References

References is not available for this document.

IEEE Account

Purchase Details

Profile Information

Need Help?

A not-for-profit organization, IEEE is the world's largest technical professional organization dedicated to advancing technology for the benefit of humanity.
© Copyright 2025 IEEE - All rights reserved. Use of this web site signifies your agreement to the terms and conditions.