基于改进粒子滤波的锂电池SOH预测

doi:10.19799/j.cnki.2095-4239.2020.0159

储能科学与技术 ›› 2020, Vol. 9 ›› Issue (6): 1954-1960.doi: 10.19799/j.cnki.2095-4239.2020.0159

基于改进粒子滤波的锂电池SOH预测

徐超¹(), 李立伟²(), 杨玉新³, 王凯¹

^1.青岛大学电气工程学院
^2.青岛大学威海创新研究院
^3.青岛大学图书馆，山东青岛 266071

收稿日期:2020-04-28 修回日期:2020-05-11 出版日期:2020-11-05 发布日期:2020-10-28
通讯作者: 李立伟 E-mail:sdxuchao111@163.com;ytllw@163.com
作者简介:徐超（1995—），男，硕士研究生，研究方向为新能源汽车电控系统开发，E-mail：sdxuchao111@163.com；
基金资助:
山东省科技发展计划项目(2011GGB01123);山东省重点研发计划项目(2017GGX50114);山东省自然科学基金项目(Y2008F23)

Lithium-ion battery SOH estimation based on improved particle filter

Chao XU¹(), Liwei LI²(), Yuxin YANG³, Kai WANG¹

^1.School of Electrical Engineering, Qingdao University
^2.Weihai Innovation Institute, Qingdao Univesity
^3.Library of Qingdao University, Qingdao 266071, Shandong, China

Received:2020-04-28 Revised:2020-05-11 Online:2020-11-05 Published:2020-10-28
Contact: Liwei LI E-mail:sdxuchao111@163.com;ytllw@163.com

摘要/Abstract

摘要：

随着锂离子电池在电动汽车和微电网越来越广泛地使用，人们在保证电池管理系统(BMS)安全可靠运行和降低维护成本方面做了许多研究，电池健康状态(SOH)估计作为锂离子电池管理系统的关键功能之一，准确估计电池当前健康状态对电池管理系统有重要意义。为了提高估计准确性，首先在分析传统布谷鸟搜索优化算法的基础上，提出了一种动态布谷鸟搜索算法，该算法通过改进步长和发现概率，并将函数值变化趋势引入到步长更新方程，平衡了搜索速度和精度之间的关系。为解决传统粒子滤波自身存在的粒子退化问题，通过将粒子用布谷鸟鸟窝表示，对布谷鸟群体搜索的模拟来指导更新粒子的分布，利用改进的动态布谷鸟搜索来优化粒子滤波算法。然后从锂离子电池工作时的可测参数中提取健康指标HI，建立了HI指标与SOH之间的映射模型，并将其应用于状态空间模型的观测，提出了一种基于改进粒子滤波算法的电池SOH估计方法。实验结果表明，该方法优于传统粒子滤波算法(PF)，对锂离子电池退化过程预测具有良好的适应性和精确性。

关键词: 锂离子电池, 粒子滤波算法, 粒子退化, 改进布谷鸟算法, SOH预测, 健康指标

Abstract:

With the increasing extensive use of lithium-ion batteries in electric vehicles and microgrid, much research has been performed to ensure a safe and reliable operation and reduce the maintenance costs of the lithium-ion battery management system (BMS). As one of the key functions of the BMS, the state of health (SOH) estimation is very important. A dynamic cuckoo search algorithm is proposed based on the analysis of the traditional cuckoo search optimization algorithm to improve the estimation accuracy. The relationship between search speed and accuracy is balanced by improving the step size and the discovery probability and by introducing the change trend of the function value into the step update equation. A dynamic cuckoo search algorithm is proposed to solve the particle degradation problem existing in the traditional particle filter itself. The particles are represented by cuckoo bird's nests. Moreover, the cuckoo group search simulation is used to guide the distribution of updated particles, while the improved dynamic cuckoo search is used to optimize the particle filter algorithm. The health index (HI) is extracted from the measurable parameters of the lithium-ion battery, and the mapping model between the HI index and the SOH is established and applied to the state space model observation. A battery SOH estimation method based on the improved particle filter algorithm is proposed. The experimental results show that this method is superior to the traditional particle filter algorithm and has good adaptability and accuracy in predicting the degradation process of lithium-ion batteries.

Key words: lithium-ion battery, particle filter algorithm, particle dilution, improved cuckoo search, SOH estimation, health indicator

中图分类号:

TM 912

徐超, 李立伟, 杨玉新, 王凯. 基于改进粒子滤波的锂电池SOH预测[J]. 储能科学与技术, 2020, 9(6): 1954-1960.

Chao XU, Liwei LI, Yuxin YANG, Kai WANG. Lithium-ion battery SOH estimation based on improved particle filter[J]. Energy Storage Science and Technology, 2020, 9(6): 1954-1960.

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参考文献 21

1	严旭明, 冯光炷, 黄雪. 锂离子电池负极材料的制备及应用进展[J]. 化工新型材料, 2019, 47(7): 22-25.
	YAN Xuming, FENG Guangzhu, HUANG Xue. Research progress of preparation and application of cathode material for lithium ion battery[J]. New Chemical Materials, 2019, 47(7): 22-25.
2	HENDRICKS C, WILLIARD N, MATHEW S, et al. A failure modes, mechanisms, and effects analysis (FMMEA) of lithium-ion batteries[J]. Journal of Power Sources, 2015, 297: 113-120.
3	JAVED K, GOURIVEAU R, ZERHOUNI N. State of the art and taxonomy of prognostics approaches, trends of prognostics applications and open issues towards maturity at different technology readiness levels[J]. Mechanical Systems and Signal Processing, 2016, 94: doi: 10.1016/j.ymssp.2017.01.050.
4	CHEN L, LU Z Q, LIN W, et al. A new state-of-health estimation method for lithium-ion batteries through the intrinsic relationship between ohmic internal resistance and capacity[J]. Measurement, 2018, 116: 586-595.
5	HU X, JIANG J, CAO D, et al. Battery health prognosis for electric vehicles using sample entropy and sparse bayesian predictive modeling[J]. IEEE Transactions on Industrial Electronics, 2015, 63(4): doi: 10.1109/TIE.2015.2461523.
6	JOUIN M, GOURIVEAU R, HISSEL D, et al. Particle filter-based prognostics: Review, discussion and perspectives[J]. Mechanical Systems and Signal Processing, 2015, 72/73: 2-31.
7	王法胜, 鲁明羽, 赵清杰, 等. 粒子滤波算法[J]. 计算机学报, 2014, 37(8): 1679-1694.
	WANG Fasheng, LU Mingyu, ZHAO Qingjie, et al. Particle filtering algorithm[J]. Chinese Journal of Computers, 2014, 37(8): 1679-1694.
8	NICELY M A, WELLS B E. Improved parallel resampling methods for particle filtering[J]. IEEE Access, 2019, 7: 47593-47604.
9	CHENG F, QU L, QIAO W, et al. Enhanced particle filtering for bearing remaining useful life prediction of wind turbine drivetrain gearboxes[J]. IEEE Transactions on Industrial Electronics, 2019, 66(6): 4738-4748.
10	田梦楚, 薄煜明, 陈志敏, 等. 萤火虫算法智能优化粒子滤波[J]. 自动化学报, 2016, 42(1): 89-97.
	TIAN Mengchu, BO Yuming, CHEN Zhimin, et al. Firefly algorithm intelligence optimized particle filter[J]. Acta Automatica Sinica, 2016, 42(1): 89-97.
11	陈志敏, 吴盘龙, 薄煜明, 等. 基于自控蝙蝠算法智能优化粒子滤波的机动目标跟踪方法[J]. 电子学报, 2018, 46(4): 886-894.
	CHEN Zhimin, WU Panlong, BO Yuming, et al. Adaptive control bat algorithm intelligent optimization particle filter for maneuvering target tracking[J]. Acta Electronica Sinica, 2018, 46(4): 886-894.
12	HAN W, XU J, ZHOU M, et al. Cuckoo-search and particle-filter-based inversing approach to estimating defects via magnetic flux leakage signals[J]. IEEE Transactions on Magnetics, 2015, 52(4): 1.
13	任航. 基于拟蒙特卡洛滤波的改进式粒子滤波目标跟踪算法[J]. 电子测量与仪器学报, 2015, 29(2): 289-295.
	REN Hang. Improved particle filter target tracking algorithm based on Quasi Monte Carlo filtering[J]. Journal of Electronic Measurement and Instrumentation, 2015, 29(2): 289-295.
14	李娟, 刘晓龙, 卢长刚, 等. 改进的粒子滤波重采样算法[J]. 吉林大学学报(工学版), 2015, 45(6): 2069-2074.
	LI Juan, LIU Xiaolong, LU Changgang, et al. Improvement of resampling algorithm of particle filter[J]. Journal of Jilin University (Engineering and Technology Edition), 2015, 45(6): 2069-2074.
15	朱蓉, 靳雁霞, 范卫华. 融合优质粒子分布的粒子群优化算法[J]. 小型微型计算机系统, 2015, 36(3): 576-580.
	ZHU Rong, JIN Yanxia, FAN Weihua. Particle swarm optimization Algorithm combination with the distribution of superior quality particles[J]. Journal of Chinese Computer Systems, 2015, 36(3): 576-580.
16	YANG X S, DEB S. Cuckoo search via levy flights[J]. Mathematics, 2010: doi: doi:10.1109/NABIC.2009.5393690.
17	GANDOMI A H, YANG X S, ALAVI A H. Cuckoo search algorithm: A metaheuristic approach to solve structural optimization problems[J]. Engineering With Computers, 2013, 29(2): 245.
18	明波, 黄强, 王义民, 等. 基于改进布谷鸟算法的梯级水库优化调度研究[J]. 水利学报, 2015, 46(3): 341-349.
	MING Bo, HUANG Qiang, WANG Yimin, et al. Cascade reservoir operation optimization based-on improved Cuckoo search[J]. Journal of Hydraulic Engineering, 2015, 46(3): 341-349.
19	LIU D, ZHOU J, LIAO H, et al. A health indicator extraction and optimization framework for lithium-ion battery degradation modeling and prognostics[J]. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 2015, 45(6): 915-928.
20	GORDON N J, SALMOND D J, SMITH A F M. Novel approach to nonlinear/non-Gaussian Bayesian state estimation[J]. Radar and Signal Processing, IEE Proceedings F, 1993, 140(2): 107-113.
21	XING Y, MA E W M, TSUI K L, et al. An ensemble model for predicting the remaining useful performance of lithium-ion batteries[J]. Microelectronics Reliability, 2013, 53(6): 811-888.

评价指标	ICS-PF/%	PF/%
RMSE	0.6452	0.8240
ME	2.3615	3.0948
MRE	2.5370	3.3232
AE	0.4935	0.6528

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基于改进粒子滤波的锂电池SOH预测

Lithium-ion battery SOH estimation based on improved particle filter

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