基于无迹粒子滤波改进算法的电池容量衰退预测研究

doi:10.3969/j.issn.1000-1158.2024.08.19

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摘要为了提高电池容量预测的准确性和适用性,提出一种基于无迹粒子滤波的改进算法。为了减小滤波迭代过程的观测误差,引入支持向量回归算法对其予以改进。由于支持向量回归算法中的核函数与惩罚因子较难确定,提出使用遗传算法的寻优能力对其进行求解,形成一种经遗传算法和支持向量回归改进的模型。对这种融合模型进行性能评估,并与UPF-SVR和UPF-RVR进行对比,实验结果显示,融合模型预测结果的平均绝对误差EMA和均方根误差SRMSE分别低于2.0％和2.5％,相比其它模型预测精度更高,同时预测水平和收敛性均显著优于其它模型,更具有效性和可行性。

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	郭芮君
	辛永强
	杨剑锋

关键词 ：电学计量, 电池容量预测, 无迹粒子滤波, 遗传算法, 支持向量回归, 寻优能力

Abstract：In order to improve the accuracy and applicability of battery capacity prediction, an improved algorithm based on traceless particle filtering is proposed. In order to reduce the observation error of the filtering iteration process, a support vector regression algorithm is introduced to improve it. Since the kernel function and penalty factor in the support vector regression algorithm are difficult to determine, it is proposed to use the optimization ability of the genetic algorithm to solve it, forming a model improved by the genetic algorithm and support vector regression. The performance of this fusion model is evaluated and compared with UPF-SVR and UPF-RVR, and the experimental results show that the mean absolute error EMAand root mean square error SRMSE of the fusion model prediction results are lower than 2.0% and 2.5%, respectively, and the prediction accuracy is higher compared with the other models, and at the same time, the prediction level and convergence are significantly better than other models, which is more effective and feasible.

Key words： electrical measurement battery capacity prediction traceless particle filtering genetic algorithm support vector regression optimization ability

收稿日期: 2023-11-29 发布日期: 2024-09-05

PACS:

TB971

基金资助:甘肃省自然科学基金(23JRRA868)

通讯作者: 辛永强(1979-),甘肃兰州人,甘肃省计量研究院高级工程师,从事计量与检测技术方面的工作。Email:66063103@qq.com E-mail: 13560474@qq.com

作者简介: 郭芮君(1983-),甘肃兰州人,甘肃省计量研究院高级工程师,从事电磁计量和智能控制方面的工作。Email:13560474@qq.com

引用本文:

郭芮君,辛永强,杨剑锋 . 基于无迹粒子滤波改进算法的电池容量衰退预测研究[J]. 计量学报, 2024, 45(8): 1222-1230.
GUO Ruijun,XIN Yongqiang,YANG Jianfeng . Research on Battery Capacity Decline Prediction Based on Improved Algorithm of Traceless Particle Filtering. Acta Metrologica Sinica, 2024, 45(8): 1222-1230.

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