Joint Estimation of the SOC-SOH Based on Lithium Battery Model and Fractional Order Theory
Zhao Jingying1, Hu Jin1, Zhang Xuehui1, Zhang Wenyu2
1. State Key Laboratory for Reliability and Intelligence of Electrical Equipment Hebei University of Technology Tianjin 300130 China; 2. State Grid Hebei Zhangjiakou Scenery Storage and Transportation New Energy Co. Ltd Zhangjiakou 075000 China
Abstract:Traditional state of charge (SOC) estimation algorithm of lithium battery is often based on equivalent circuit model, which has low accuracy and too many parameters. And the application of equivalent circuit model in state of health (SOH) estimation is limited because of the disadvantages. In addition, the capacity attenuation of lithium battery is often ignored to result in poor timeliness of SOC estimation. There is a coupling relationship between SOC and SOH of lithium battery. SOC-SOH joint estimation is an effective means during life cycle, but joint estimation model is relatively complex and imperfect, which doesn't support the estimation requirements. This paper presented a joint SOC-SOH estimation model with equivalent circuit model and fractional order theory. By adaptive extended Kalman filter (AEKF) algorithm and capacity parameter modification method, the accuracy and the timeliness of the state estimation were improved. Firstly, based on the second order RC model of lithium battery, the state equation was established. Considering the time-varying characteristics of noise covariance, dynamic noise covariance parameter was obtained by calculating the cumulative error, and AEKF algorithm was proposed to estimate the SOC of lithium battery. Secondly, aiming at the of excessive parameters in integer order model, the RC series module was simplified by fractional calculus theory to acquire a fractional order model with high precision and few parameters. The parameters were identified by fuzzy controller. Based on the charging conditions and the polarization characteristics of lithium battery, the interval constant current charging time and the fractional-order model parameters were determined as health factors. Thirdly,by use of SSA to optimize BP neural network for the global optimal solution of the weight, nonlinear relationship between health factors and SOH was analyzed to design SOH estimation model. Finally,considering the capacity attenuation of lithium battery and the measurement accuracy of health factors, SOH estimation value was used to modify the capacity parameters and SOC estimation value was used to determine the initial sampling point of health factor to develop a SOC-SOH joint estimation model. Aging tests, dynamic condition tests of US06 and DST of lithium battery are designed to verify the joint SOC-SOH estimation model. In dynamic tests of US06 and DST, the results show that maximum error of SOC estimation accuracy based on AEKF algorithm and EKF algorithm is less than 1% and more than 3% respectively, which verified the effectiveness of SOC estimation model with AEKF algorithm. In aging tests, the effectiveness of health factors was verified and the influence of accuracy between SOC and SOH estimates was analyzed. The results show that the correlation coefficient between interval constant current charging time and SOH is greater than 0.96, the correlation coefficient between fractional order model parameters and SOH is greater than 0.95, which expressed the strong correlation of the health factors. The maximum errors of SOH estimation based on health factors acquired by AEKF and EKF were less than 1% and more than 2%, respectively, which showed the SOH estimation improvement with health factors acquired by AEKF. By capacity parameter modification, the maximum error of SOC estimation could decrease at less than 1%, while the maximum error of SOC estimation is more than 22% without modification. Meanwhile, with different capacity modification accuracies, the maximum errors of SOC estimation could be ensured to be less than 1.5%, which reduced the estimation errors and improved the timelines with the joint SOC-SOH estimation model. The following conclusions can be drawn from the analysis: (1) Compared with EKF, the actual dynamic noise covariance is considered in AEKF algorithm proposed. It is more appropriate to establish SOC model to effectively improve SOC estimation accuracy. (2) Fractional order model can better reflect the polarization characteristics of lithium battery. With the health factors extracted based on charging conditions and fractional order model parameters, SOH estimation model established can reduce the estimation error. (3) AEKF algorithm is used to adaptively monitor the charging and discharging state of lithium battery to acquire accurate health factors. SOH estimation value is used to modify capacity parameters instead of fixed capacity parameters because of actual capacity attenuation. The joint estimation model designed is more suitable for the actual change. It has stronger timeliness and robustness.
赵靖英, 胡劲, 张雪辉, 张文煜. 基于锂电池模型和分数阶理论的SOC-SOH联合估计[J]. 电工技术学报, 2023, 38(17): 4551-4563.
Zhao Jingying, Hu Jin, Zhang Xuehui, Zhang Wenyu. Joint Estimation of the SOC-SOH Based on Lithium Battery Model and Fractional Order Theory. Transactions of China Electrotechnical Society, 2023, 38(17): 4551-4563.
[1] 朱丽群, 张建秋. 一种联合锂电池健康和荷电状态的新模型[J]. 中国电机工程学报, 2018, 38(12): 3613-3620, 21. Zhu Liqun, Zhang Jianqiu.A new model of jointed states of charge and health for lithium batteries[J]. Proceedings of the CSEE, 2018, 38(12): 3613-3620, 21. [2] Li Chaoran, Xiao Fei, Fan Yaxiang.An approach to state of charge estimation of lithium-ion batteries based on recurrent neural networks with gated recurrent unit[J]. Energies, 2019, 12(9): 1592. [3] Dai Houde, Zhao Guangcai, Lin Mingqiang, et al.A novel estimation method for the state of health of lithium-ion battery using prior knowledge-based neural network and Markov chain[J]. IEEE Transactions on Industrial Electronics, 2019, 66(10): 7706-7716. [4] 刘芳, 马杰, 苏卫星, 等. 基于自适应回归扩展卡尔曼滤波的电动汽车动力电池全生命周期的荷电状态估算方法[J]. 电工技术学报, 2020, 35(4): 698-707. Liu Fang, Ma Jie, Su Weixing, et al.State of charge estimation method of electric vehicle power battery life cycle based on auto regression extended Kalman filter[J]. Transactions of China Electrotechnical Society, 2020, 35(4): 698-707. [5] Ramadan H S, Becherif M, Claude F.Extended Kalman filter for accurate state of charge estimation of lithium-based batteries: a comparative analysis[J]. International Journal of Hydrogen Energy, 2017, 42(48): 29033-29046. [6] 郝文美, 张立伟, 彭博, 等. 动车组钛酸锂电池荷电状态估计[J]. 电工技术学报, 2021, 36(增刊1): 362-371. Hao Wenmei, Zhang Liwei, Peng Bo, et al.State of charge estimation of lithium titanate battery for electric multiple units[J]. Transactions of China Electrotechnical Society, 2021, 36(S1): 362-371. [7] 裴磊. 基于平衡电压的电动汽车锂离子电池状态估计方法研究[D]. 哈尔滨: 哈尔滨工业大学, 2016. [8] 宫明辉, 乌江, 焦朝勇. 基于模糊自适应扩展卡尔曼滤波器的锂电池SOC估算方法[J]. 电工技术学报, 2020, 35(18): 3972-3978. Gong Minghui, Wu Jiang, Jiao Chaoyong.SOC estimation method of lithium battery based on fuzzy adaptive extended Kalman filter[J]. Transactions of China Electrotechnical Society, 2020, 35(18): 3972-3978. [9] 李超然, 肖飞, 樊亚翔, 等. 基于门控循环单元神经网络和Huber-M估计鲁棒卡尔曼滤波融合方法的锂离子电池荷电状态估算方法[J]. 电工技术学报, 2020, 35(9): 2051-2062. Li Chaoran, Xiao Fei, Fan Yaxiang, et al.A hybrid approach to lithium-ion battery SOC estimation based on recurrent neural network with gated recurrent unit and Huber-M robust Kalman filter[J]. Transactions of China Electrotechnical Society, 2020, 35(9): 2051-2062. [10] 庞辉, 郭龙, 武龙星, 等. 考虑环境温度影响的锂离子电池改进双极化模型及其荷电状态估算[J]. 电工技术学报, 2021, 36(10): 2178-2189. Pang Hui, Guo Long, Wu Longxing, et al.An improved dual polarization model of Li-ion battery and its state of charge estimation considering ambient temperature[J]. Transactions of China Electrotechnical Society, 2021, 36(10): 2178-2189. [11] Love C T, Virji M B V, Rocheleau R E, et al. State-of-health monitoring of 18650 4S packs with a single-point impedance diagnostic[J]. Journal of Power Sources, 2014, 266: 512-519. [12] 骆凡, 黄海宏, 王海欣. 基于电化学阻抗谱的退役动力电池荷电状态和健康状态快速预测[J]. 仪器仪表学报, 2021, 42(9): 172-180. Luo Fan, Huang Haihong, Wang Haixin.Rapid prediction of the state of charge and state of health of decommissioned power batteries based on electrochemical impedance spectroscopy[J]. Chinese Journal of Scientific Instrument, 2021, 42(9): 172-180. [13] Galeotti M, Cinà L, Giammanco C, et al.Performance analysis and SOH (state of health) evaluation of lithium polymer batteries through electrochemical impedance spectroscopy[J]. Energy, 2015, 89: 678-686. [14] Guo Peiyao, Cheng Ze, Yang Lei.A data-driven remaining capacity estimation approach for lithium-ion batteries based on charging health feature extraction[J]. Journal of Power Sources, 2019, 412: 442-450. [15] Tian Jinpeng, Xiong Rui, Shen Weixiang.State-of-health estimation based on differential temperature for lithium ion batteries[J]. IEEE Transactions on Power Electronics, 2020, 35(10): 10363-10373. [16] 杨胜杰, 罗冰洋, 王菁, 等. 基于容量增量曲线峰值区间特征参数的锂离子电池健康状态估算[J]. 电工技术学报, 2021, 36(11): 2277-2287. Yang Shengjie, Luo Bingyang, Wang Jing, et al.State of health estimation for lithium-ion batteries based on peak region feature parameters of incremental capacity curve[J]. Transactions of China Electrotechnical Society, 2021, 36(11): 2277-2287. [17] 李超然, 肖飞, 樊亚翔, 等. 基于卷积神经网络的锂离子电池SOH估算[J]. 电工技术学报, 2020, 35(19): 4106-4119. Li Chaoran, Xiao Fei, Fan Yaxiang, et al.An approach to lithium-ion battery SOH estimation based on convolutional neural network[J]. Transactions of China Electrotechnical Society, 2020, 35(19): 4106-4119. [18] Han Xuebing, Ouyang Minggao, Lu Languang, et al.Simplification of physics-based electrochemical model for lithium ion battery on electric vehicle. Part II: Pseudo-two-dimensional model simplification and state of charge estimation[J]. Journal of Power Sources, 2015, 278: 814-825. [19] 王萍, 弓清瑞, 张吉昂, 等. 一种基于数据驱动与经验模型组合的锂电池在线健康状态预测方法[J]. 电工技术学报, 2021, 36(24): 5201-5212. Wang Ping, Gong Qingrui, Zhang Jiang, et al.An online state of health prediction method for lithium batteries based on combination of data-driven and empirical model[J]. Transactions of China Electrotechnical Society, 2021, 36(24): 5201-5212. [20] 董明, 范文杰, 刘王泽宇, 等. 基于特征频率阻抗的锂离子电池健康状态评估[J]. 中国电机工程学报, 2022, 42(24): 9094-9105. Dong Ming, Fan Wenjie, Liu Wangzeyu, et al.Health assessment of lithium-ion batteries based on characteristic frequency impedance[J]. Proceedings of the CSEE, 2022, 42(24): 9094-9105. [21] 颜湘武, 邓浩然, 郭琪, 等. 基于自适应无迹卡尔曼滤波的动力电池健康状态检测及梯次利用研究[J]. 电工技术学报, 2019, 34(18): 3937-3948. Yan Xiangwu, Deng Haoran, Guo Qi, et al.Study on the state of health detection of power batteries based on adaptive unscented Kalman filters and the battery echelon utilization[J]. Transactions of China Electrotechnical Society, 2019, 34(18): 3937-3948. [22] Chaoui H, Ibe-Ekeocha C C. State of charge and state of health estimation for lithium batteries using recurrent neural networks[J]. IEEE Transactions on Vehicular Technology, 2017, 66(10): 8773-8783. [23] Wei Zhongbao, Zhao Jiyun, Ji Dongxu, et al.A multi-timescale estimator for battery state of charge and capacity dual estimation based on an online identified model[J]. Applied Energy, 2017, 204: 1264-1274. [24] 李超然, 肖飞, 樊亚翔, 等. 基于深度学习的锂离子电池SOC和SOH联合估算[J]. 中国电机工程学报, 2021, 41(2): 681-692. Li Chaoran, Xiao Fei, Fan Yaxiang, et al.Joint estimation of the state of charge and the state of health based on deep learning for lithium-ion batteries[J]. Proceedings of the CSEE, 2021, 41(2): 681-692. [25] Gomez J, Nelson R, Kalu E E, et al.Equivalent circuit model parameters of a high-power Li-ion battery: thermal and state of charge effects[J]. Journal of Power Sources, 2011, 196(10): 4826-4831. [26] Zou Changfu, Zhang Lei, Hu Xiaosong, et al.A review of fractional-order techniques applied to lithium-ion batteries, lead-acid batteries, and supercapacitors[J]. Journal of Power Sources, 2018, 390: 286-296. [27] 齐乃明, 秦昌茂, 王威. 分数阶系统的最优Oustaloup数字实现算法[J]. 控制与决策, 2010, 25(10): 1598-1600. Qi Naiming, Qin Changmao, Wang Wei.Optimal Oustaloup digital realization of fractional order systems[J]. Control and Decision, 2010, 25(10): 1598-1600. [28] Xue Jiankai, Shen Bo.A novel swarm intelligence optimization approach: sparrow search algorithm[J]. Systems Science & Control Engineering, 2020, 8(1): 22-34.