A Systematic Literature Review of State of Health and State of Charge Estimation Methods for Batteries Used in Electric Vehicle Applications

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
R. Swarnkar, Harikrishnan Ramachandran, S. Ali, Rani Jabbar
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Abstract

In recent years, artificial intelligence and machine learning have captured the attention of researchers and industrialists in order to estimate and predict the state of batteries. The quality of data must be good, and the source of data must be the same for different models’ performance comparisons. The lithium-ion battery is popularly used because of its high energy density and its compact size. Due to the non-linear and complex characteristics of lithium-ion batteries, electric vehicle users have to know about battery health conditions. Different types of state estimation methods are used, namely, electrochemical-based, equivalent circuit model (ECM) based, and data-driven approaches. This paper is a survey of electric vehicle history, different battery chemistries, battery management system (BMS) basics and key challenges and solutions in BMS, and in-depth discussions about other battery state of charge and state of health estimation methods. Research trend analysis, critical analysis of this work, limitations, and future directions of existing works are discussed. This paper also provides information on the open-access available datasets of different battery chemistry for a data-driven approach. This paper highlights the key challenges of state estimation techniques. Knowledge of accurate battery state of charge (SOC) provides critical information about remaining available energy. In comparison, battery state of health (SOH) indicates its current health condition, remaining lifetime, performance, and proper energy management of the electric vehicles.
电动汽车应用中电池的健康状态和充电状态估计方法的系统文献综述
近年来,为了估计和预测电池的状态,人工智能和机器学习引起了研究人员和实业家的注意。数据质量必须良好,不同模型的性能比较数据来源必须相同。锂离子电池由于其高能量密度和紧凑的尺寸而被广泛使用。由于锂离子电池的非线性和复杂特性,电动汽车用户必须了解电池的健康状况。使用了不同类型的状态估计方法,即基于电化学的、基于等效电路模型(ECM)的和数据驱动的方法。本文概述了电动汽车的历史、不同的电池化学成分、电池管理系统(BMS)的基本原理以及BMS中的关键挑战和解决方案,并深入讨论了其他电池充电状态和健康状态估计方法。讨论了研究趋势分析、对这项工作的批判性分析、现有工作的局限性和未来方向。本文还为数据驱动方法提供了关于不同电池化学的开放访问可用数据集的信息。本文强调了状态估计技术的关键挑战。准确的电池充电状态(SOC)的知识提供了关于剩余可用能量的关键信息。相比之下,电池健康状态(SOH)表示其当前的健康状况、剩余寿命、性能以及电动汽车的适当能量管理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
World Electric Vehicle Journal
World Electric Vehicle Journal Engineering-Automotive Engineering
CiteScore
4.50
自引率
8.70%
发文量
196
审稿时长
8 weeks
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