基于卷积长短期记忆网络的锂电池寿命预测及动态建模

doi:10.3785/j.issn.1008-973X.2026.05.012

浙江大学学报(工学版)

2026, Vol. 60

Issue (5): 1027-1036 DOI: 10.3785/j.issn.1008-973X.2026.05.012

能源与动力工程

基于卷积长短期记忆网络的锂电池寿命预测及动态建模

王孝龙1,2(

),陶吉利2,*(

),朱想先3,梁建伟1,陈岱岱3,刘之涛4

1. 江西理工大学电气工程与自动化学院，江西赣州 341099
2. 浙大宁波理工学院信息科学与工程学院，浙江宁波 315100
3. 宁波均胜电子股份有限公司浙江省汽车电子智能化重点实验室，浙江宁波，315048
4. 浙江大学控制科学与工程学院，浙江杭州 310027

Convolutional long short-term memory network based lithium battery life prediction and dynamic modeling

Xiaolong WANG1,2(

),Jili TAO2,*(

),Xiangxian ZHU3,Jianwei LIANG1,Daidai CHEN3,Zhitao LIU4

1. School of Electrical Engineering and Automation, Jiangxi University of Science and Technology, Ganzhou, 341099
2. School of Information Science and Engineering, NingboTech University, Ningbo 315100
3. Key Laboratory of Automotive Electronics Intelligentization of Zhejiang Province, Ningbo Joyson Electronic Corp., Ningbo 315048
4. College of Control Science and Engineering, Zhejiang University, Hangzhou 310027

全文: PDF(5477 KB) HTML

摘要：

针对传统固定参数模型难以适应电池老化过程的问题，将数据驱动与物理模型机理深度融合，提出基于健康状态（SOH）的锂离子电池动态建模方法. 采用卷积长短期记忆网络从电池时序数据中提取多尺度特征，实现SOH高精度预测；构建二阶RC等效电路模型，采用带遗忘因子的递推最小二乘法进行参数在线识别；引入随机森林回归与卡尔曼滤波，实现模型参数随老化状态的动态更新. 实验结果表明，所提方法在电池老化各阶段均具有比传统固定参数模型更高的预测精度和更稳定的误差分布. 在电池老化后期，所提方法使动态模型的性能显著提升约80%，中位误差为0.025 V，相比传统模型具有显著优势.

关键词： 寿命预测; 卷积长短期记忆网络; 动态模型; 递推最小二乘法; 卡尔曼滤波

Abstract:

To address the problem that traditional fixed-parameter models cannot adapt to battery aging processes, data-driven approaches were deeply integrated with physical model mechanisms, and a state-of-health (SOH)-based dynamic modeling method for lithium-ion batteries was proposed. Convolutional long short-term memory networks were employed to extract multi-scale features from battery time-series data, achieving high-precision SOH prediction. A second-order RC equivalent circuit model was constructed, and a forgetting factor recursive least squares method was adopted for online parameter identification. Random forest regression and Kalman filtering were introduced to realize dynamic updating of model parameters according to aging states. Experimental results show that the proposed method achieves higher prediction accuracy and a more stable error distribution than the traditional fixed-parameter model across all battery aging stages. In the late aging stage, the proposed method improves the prediction performance of the dynamic model by approximately 80%, with a median error of 0.025 V, demonstrating significant advantages over the traditional model.

Key words: life prediction convolutional long short-term memory network dynamic model recursive least squares method Kalman filter

收稿日期: 2025-06-10 出版日期: 2026-05-06

CLC:

TM 912

基金资助: 国家自然科学基金资助项目（62373321）；浙江省自然科学基金资助项目（LMS25F030027）；浙江省汽车电子智能化重点实验室开放课题资助（J20240708）.

通讯作者: 陶吉利 E-mail: yk12090202@163.com;taojili@nbt.edu.cn

作者简介: 王孝龙（2000—），男，硕士生，电池能源管理. orcid.org/0009-0000-3663-4484. E-mail：yk12090202@163.com

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	作者相关文章
	王孝龙
	陶吉利
	朱想先
	梁建伟
	陈岱岱
	刘之涛

引用本文:

王孝龙,陶吉利,朱想先,梁建伟,陈岱岱,刘之涛. 基于卷积长短期记忆网络的锂电池寿命预测及动态建模[J]. 浙江大学学报(工学版), 2026, 60(5): 1027-1036.

Xiaolong WANG,Jili TAO,Xiangxian ZHU,Jianwei LIANG,Daidai CHEN,Zhitao LIU. Convolutional long short-term memory network based lithium battery life prediction and dynamic modeling. Journal of ZheJiang University (Engineering Science), 2026, 60(5): 1027-1036.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.05.012 或 https://www.zjujournals.com/eng/CN/Y2026/V60/I5/1027

图 1 基于电池健康状态预测的锂电池动态建模系统框架

图 2 卷积长短期记忆网络架构图

图 3 二阶RC等效电路图

图 4 卷积长短期记忆网络在训练过程中的性能参数变化曲线

表 1 不同锂电池寿命预测模型的预测性能对比

图 5 不同锂电池寿命预测模型的电池寿命预测曲线

图 6 等效电路模型参数识别结果

表 2 不同参数识别方法误差对比

表 3 等效电路模型参数对电池健康状态变化的敏感性分析

图 7 基于雷达图的等效电路模型参数对电池健康状态变化的敏感性与响应强度分析

表 4 卡尔曼滤波器参数设置

图 8 优化后的等效电路模型参数随电池健康状态的演变曲线

表 5 不同参数优化与更新策略的消融实验结果

表 6 不同预测方法在电池健康状态不同阶段的预测性能对比

图 9 传统固定参数模型与动态参数模型端电压输出对比图

图 10 不同电池健康状态下传统固定参数模型与动态参数模型预测误差对比

1	DOU W, ZHENG M, ZHANG W, et al Review on the binders for sustainable high-energy-density lithium ion batteries: status, solutions, and prospects[J]. Advanced Functional Materials, 2023, 33 (45): 2305161 doi: 10.1002/adfm.202305161
2	李秋燕, 王利利, 张艺涵, 等能源互联网多能流的耦合模型及动态优化方法综述[J]. 电力系统保护与控制, 2020, 48 (19): 179- 186 LI Qiuyan, WANG Lili, ZHANG Yihan, et al A review of coupling models and dynamic optimization methods for energy Internet multi-energy flow[J]. Power System Protection and Control, 2020, 48 (19): 179- 186
3	LIU Y, ZHU Y, CUI Y Challenges and opportunities towards fast-charging battery materials[J]. Nature Energy, 2019, 4 (7): 540- 550 doi: 10.1038/s41560-019-0405-3
4	SU L, XU Y, DONG Z State-of-health estimation of lithium-ion batteries: a comprehensive literature review from cell to pack levels[J]. Energy Conversion and Economics, 2024, 5 (4): 224- 242 doi: 10.1049/enc2.12125
5	LI P, WU X, GROSU R, et al Applying neural network to health estimation and lifetime prediction of lithium-ion batteries[J]. IEEE Transactions on Transportation Electrification, 2025, 11 (1): 4224- 4248 doi: 10.1109/TTE.2024.3457621
6	ZHANG M, YANG D, DU J, et al A review of SOH prediction of Li-ion batteries based on data-driven algorithms[J]. Energies, 2023, 16 (7): 3167 doi: 10.3390/en16073167
7	YAO Q, SONG X, XIE W State of health estimation of lithium-ion battery based on CNN–WNN–WLSTM[J]. Complex and Intelligent Systems, 2024, 10 (2): 2919- 2936 doi: 10.1007/s40747-023-01300-3
8	LI P, ZHANG Z, GROSU R, et al An end-to-end neural network framework for state-of-health estimation and remaining useful life prediction of electric vehicle lithium batteries[J]. Renewable and Sustainable Energy Reviews, 2022, 156: 111843 doi: 10.1016/j.rser.2021.111843
9	WU X, LI P, DENG Z, et al LDNet-RUL: lightweight deformable neural network for remaining useful life prognostics of lithium-ion batteries[J]. IEEE Transactions on Power Electronics, 2025, 40 (9): 13514- 13528 doi: 10.1109/TPEL.2025.3562188
10	WANG S, TAKYI-ANINAKWA P, FAN Y C, et al A novel feedback correction-adaptive Kalman filtering method for the whole-life-cycle state of charge and closed-circuit voltage prediction of lithium-ion batteries based on the second-order electrical equivalent circuit model[J]. International Journal of Electrical Power and Energy Systems, 2022, 139: 108020 doi: 10.1109/ACCESS.2021.3111927
11	TRAN M K, MATHEW M, JANHUNEN S, et al. A comprehensive equivalent circuit model for lithium-ion batteries, incorporating the effects of state of health, state of charge, and temperature on model parameters [J]. Journal of Energy Storage, 2021, 43: 103252
12	WANG F, ZHAI Z, ZHAO Z, et al Physics-informed neural network for lithium-ion battery degradation stable modeling and prognosis[J]. Nature Communications, 2024, 15: 4332 doi: 10.1038/s41467-024-48779-z
13	WU Y, BAI D, ZHANG K, et al Advancements in the estimation of the state of charge of lithium-ion battery: a comprehensive review of traditional and deep learning approaches[J]. Journal of Materials Informatics, 2025, 5: 18 doi: 10.20517/jmi.2024.84
14	WANG Q, GAO T, LI X SOC estimation of lithium-ion battery based on equivalent circuit model with variable parameters[J]. Energies, 2022, 15 (16): 5829 doi: 10.3390/en15165829
15	XU Y W, WU X L, CHEN M Y, et al Li-ion batteries state-of-charge observation method based on model with variable parameters[J]. Control Theory and Applications, 2019, 36 (3): 443- 452 doi: 10.1109/cac.2017.8243196
16	ZHANG Y, XIONG R, HE H, et al Long short-term memory recurrent neural network for remaining useful life prediction of lithium-ion batteries[J]. IEEE Transactions on Vehicular Technology, 2018, 67 (7): 5695- 5705 doi: 10.1109/TVT.2018.2805189
17	ZHAO Z, KOU F R, YANG T X, et al Fractional-order-model-based state-of-charge fusion estimation for multi-chemistry lithium-ion batteries[J]. Journal of Power Sources, 2026, 666: 239186 doi: 10.1016/j.jpowsour.2025.239186
18	CHEN Y, MENG J, MING S, et al Improved deep extreme learning machine for state of health estimation of lithium-ion battery[J]. International Journal of Energy Research, 2024, 2024 (1): 8892634 doi: 10.1155/2024/8892634
19	YANG S, ZHOU S, HUA Y, et al A parameter adaptive method for state of charge estimation of lithium-ion batteries with an improved extended Kalman filter[J]. Scientific Reports, 2021, 11: 5805 doi: 10.1038/s41598-021-84729-1
20	FANG F, MA C, JI Y A method for state of charge and state of health estimation of lithium batteries based on an adaptive weighting unscented Kalman filter[J]. Energies, 2024, 17 (9): 2145 doi: 10.3390/en17092145
21	LI X, SONG Y, REN H State of charge estimation of lithium-ion batteries based on fractional-order model with mul-ti-innovations dual cubature Kalman filter method[J]. Journal of the Electrochemical Society, 2024, 171 (9): 090510 doi: 10.1149/1945-7111/ad75bb
22	KNOX J, BLYTH M, HALES A Advancing state estimation for lithium-ion batteries with hysteresis through systematic extended Kalman filter tuning[J]. Scientific Reports, 2024, 14: 12472 doi: 10.1038/s41598-024-61596-0
23	FAHMY H M, HASANIEN H M, ALSALEH I, et al State of health estimation of lithium-ion battery using dual adaptive unscented Kalman filter and Coulomb counting approach[J]. Journal of Energy Storage, 2024, 88: 111557 doi: 10.1016/j.est.2024.111557
24	戴彦文, 于艾清基于健康特征参数的CNN-LSTM&GRU组合锂电池SOH估计[J]. 储能科学与技术, 2022, 11 (5): 1641- 1649 DAI Yanwen, YU Aiqing Combined CNN-LSTM and GRU based health feature parameters for lithium-ion batteries SOH estimation[J]. Energy Storage Science and Technology, 2022, 11 (5): 1641- 1649
25	刘伟霞, 田勋, 肖家勇, 等基于混合模型及LSTM的锂电池SOH与剩余寿命预测[J]. 储能科学与技术, 2021, 10 (2): 689- 694 LIU Weixia, TIAN Xun, XIAO Jiayong, et al Estimation of SOH and remaining life of lithium batteries based on a combination model and long short-term memory[J]. Energy Storage Science and Technology, 2021, 10 (2): 689- 694 doi: 10.19799/j.cnki.2095-4239.2020.0382
26	HO K C, KHANH D N, HSUEH Y F, et al Deep learning approach for equivalent circuit model parameter identification of lithium-ion batteries[J]. Electronics, 2025, 14 (11): 2201 doi: 10.3390/electronics14112201
27	LI P, AO Z, HOU J, et al Physics-informed mamba neural network with potential knowledge for state-of-charge estimation of lithium-ion batteries[J]. Journal of Energy Storage, 2025, 123: 116546 doi: 10.1016/j.est.2025.116546
28	刘萍, 李泽文, 蔡雨思, 等基于等效电路模型和数据驱动模型融合的SOC和SOH联合估计方法[J]. 电工技术学报, 2024, 39 (10): 3232- 3243 LIU Ping, LI Zewen, CAI Yusi, et al Joint estimation method of SOC and SOH based on fusion of equivalent circuit model and data-driven model[J]. Transactions of China Electrotechnical Society, 2024, 39 (10): 3232- 3243
29	LIU D, LI L, SONG Y, et al Hybrid state of charge estimation for lithium-ion battery under dynamic operating conditions[J]. International Journal of Electrical Power and Energy Systems, 2019, 110: 48- 61 doi: 10.1016/j.ijepes.2019.02.046
30	TANG X, ZOU C, YAO K, et al Aging trajectory prediction for lithium-ion batteries via model migration and Bayesian Monte Carlo method[J]. Applied Energy, 2019, 254: 113591 doi: 10.1016/j.apenergy.2019.113591
31	FENG J, WU L, HUANG K, et al Online SOC estimation of a lithium-ion battery based on FFRLS and AEKF[J]. Energy Storage Science and Technology, 2021, 10: 242
32	范兴明, 封浩, 张鑫最小二乘算法优化及其在锂离子电池参数辨识中的应用[J]. 电工技术学报, 2024, 39 (5): 1577- 1588 FAN Xingming, FENG Hao, ZHANG Xin Optimization of least squares method and its application in parameter identification of lithium-ion battery model[J]. Transactions of China Electrotechnical Society, 2024, 39 (5): 1577- 1588 doi: 10.19595/j.cnki.1000-6753.tces.222214
33	LAO Z, XIA B, WANG W, et al A novel method for lithium-ion battery online parameter identification based on variable forgetting factor recursive least squares[J]. Energies, 2018, 11 (6): 1358 doi: 10.3390/en11061358
34	WANG H, ZHENG Y, YU Y Lithium-ion battery SOC estimation based on adaptive forgetting factor least squares online identification and unscented Kalman filter[J]. Mathematics, 2021, 9 (15): 1733 doi: 10.3390/math9151733
35	SUN X, JI J, REN B, et al Adaptive forgetting factor recursive least square algorithm for online identification of equivalent circuit model parameters of a lithium-ion battery[J]. Energies, 2019, 12 (12): 2242 doi: 10.3390/en12122242
36	TAN X, ZHAN D, LYU P, et al Online state-of-health estimation of lithium-ion battery based on dynamic parameter identification at multi timescale and support vector regression[J]. Journal of Power Sources, 2021, 484: 229233 doi: 10.1016/j.jpowsour.2020.229233

[1]	陈宇豪,吴瑾,李懿峰,陆小霞,王奕媛. 利用改进卡尔曼滤波提高回波信号ToF精度[J]. 浙江大学学报(工学版), 2025, 59(12): 2459-2471.
[2]	李仲兴,贾英竹,耿国庆,覃夷旭,杨鑫昌. 基于多方法加权融合的矿用车质心侧偏角估计[J]. 浙江大学学报(工学版), 2025, 59(10): 2106-2114.
[3]	卢地华,周胜增,陈自强. 适用于无人水下潜航器电池管理系统的SOC-SOH联合估计[J]. 浙江大学学报(工学版), 2024, 58(5): 1080-1090.
[4]	罗钒睿,刘振宇,任佳辉,李笑宇,程阳. 基于改进卡尔曼滤波的轻量级激光惯性里程计[J]. 浙江大学学报(工学版), 2024, 58(11): 2280-2289.
[5]	王昊泽,金小军,侯聪,周立山,徐兆斌,金仲和. 基于抗差自适应估计的微纳卫星相对定位算法[J]. 浙江大学学报(工学版), 2023, 57(11): 2325-2336.
[6]	莫仁鹏,司小胜,李天梅,朱旭. 基于多尺度特征与注意力机制的轴承寿命预测[J]. 浙江大学学报(工学版), 2022, 56(7): 1447-1456.
[7]	张迅,李建胜,欧阳文,陈润泽,汲振,郑凯. 融合运动信息和跟踪评价的高效卷积算子[J]. 浙江大学学报(工学版), 2022, 56(6): 1135-1143, 1167.
[8]	王思鹏,杜昌平,宋广华,郑耀. 基于改进MSCKF的无人机室内定位方法[J]. 浙江大学学报(工学版), 2022, 56(4): 711-717.
[9]	郭承乾,马刚,梅江洲,张贵科,李宏璧,周伟. 基于InSAR与多源数据融合的堆石坝外观变形重构[J]. 浙江大学学报(工学版), 2022, 56(2): 347-355.
[10]	韩冬阳,林泽宇,郑宇,郑美妹,夏唐斌. 基于选择性深度神经网络集成的涡扇发动机剩余寿命预测[J]. 浙江大学学报(工学版), 2022, 56(11): 2109-2118.
[11]	伍川辉,廖家,熊仕勇,牛英杰,周博. 基于激光传感器的槽型轨轮廓匹配方法[J]. 浙江大学学报(工学版), 2021, 55(9): 1607-1614.
[12]	雷克兵,陈自强. 基于改进多新息扩展卡尔曼滤波的电池SOC估计[J]. 浙江大学学报(工学版), 2021, 55(10): 1978-1985.
[13]	李竟成,吴越,胡斯登,石健将. 基于递推最小二乘法与核密度估计的同步整流Boost变换器回流功率抑制[J]. 浙江大学学报(工学版), 2020, 54(1): 169-177.
[14]	王延忠,杨凯,齐荣华,陈燕燕,李菲,高浩. 航空发动机叶轮超高周疲劳寿命预测方法[J]. 浙江大学学报(工学版), 2019, 53(4): 621-627.
[15]	胡天中,余建波. 基于多尺度分解和深度学习的锂电池寿命预测[J]. 浙江大学学报(工学版), 2019, 53(10): 1852-1864.

Viewed

Full text

Abstract

Cited

Shared

Discussed