An adaptive state of charge estimator for lithium‐ion batteries

Muhammad U. Ali; Hafiz F. Khan; Haris Masood; Karam D. Kallu; Malik M. Ibrahim; Amad Zafar; Semin Oh; Sangil Kim

doi:10.1002/ese3.1141

Energy Science & Engineering (Jul 2022)

An adaptive state of charge estimator for lithium‐ion batteries

Muhammad U. Ali,
Hafiz F. Khan,
Haris Masood,
Karam D. Kallu,
Malik M. Ibrahim,
Amad Zafar,
Semin Oh,
Sangil Kim

Affiliations

Muhammad U. Ali: Department of Unmanned Vehicle Engineering Sejong University Seoul Korea
Hafiz F. Khan: Islamabad Electric Supply Company Ltd. Islamabad Pakistan
Haris Masood: Department of Electrical Engineering University of Wah Wah Cantt Pakistan
Karam D. Kallu: School of Mechanical and Manufacturing Engineering (SMME) National University of Sciences and Technology (NUST) H‐12 Islamabad Pakistan
Malik M. Ibrahim: Department of Mathematics Pusan National University Busan Korea
Amad Zafar: Department of Electrical Engineering The Ibadat International University Islamabad Pakistan
Semin Oh: Finance Fishery Manufacture Industrial Mathematics Center on Big Data Pusan National University Busan Korea
Sangil Kim: Department of Mathematics Pusan National University Busan Korea

DOI: https://doi.org/10.1002/ese3.1141
Journal volume & issue: Vol. 10, no. 7
pp. 2333 – 2347

Abstract

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Abstract This study presents a data‐driven approach in conjunction with an adaptive extended Kalman filter (AEKF) to estimate lithium‐ion batteries' state of charge (SOC) online. The Thevenin battery model is used to evaluate the effects using battery voltage and current. The advantages of the Lagrange multiplier method are utilized to model the lithium‐ion battery. The Lagrange multiplier method continuously decreases the model error to adjust the Kalman gain of AEKF for accurate SOC estimation. Various current profiles such as hybrid pulse test, dynamic stress test, and Beijing dynamic stress test are used to verify the proposed approach's adaptability, robustness, and accuracy. It is observed that the proposed approach outperforms other methodologies (recursive least square–AEKF and forgetting factor recursive least square–AEKF) due to its high accuracy (mean average error of 0.32%). Additionally, the proposed approach exhibits robustness and high convergence speed despite deliberate erroneous initialization of parameters, thus indicating its applicability in online SOC estimation applications.

Published in Energy Science & Engineering

ISSN: 2050-0505 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology; Science
Website: https://onlinelibrary.wiley.com/journal/20500505

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