一种基于模态分解和机器学习的锂电池寿命预测方法

doi:10.19799/j.cnki.2095-4239.2022.0341

摘要/Abstract

摘要：

锂离子电池剩余使用寿命(RUL)是电池健康管理的一个重要指标。本工作采用电池容量作为健康状况的指标，使用模态分解和机器学习算法，提出了一种CEEMDAN-RF-SED-LSTM方法去预测锂电池RUL。首先采用CEEMDAN分解电池容量数据，为了避免波动分量里的噪音对模型预测能力的影响，且又不完全抛弃波动分量里的特征信息，本工作提出使用随机森林(RF)算法得到每个波动分量的重要性排序和数值，以此作为每个分量对原始数据解释能力的权重。然后将权重值和不同波动分量构建的神经网络模型得到的预测结果进行加权重构，进而得到锂离子电池的RUL预测。文章对比了单一模型和组合模型预测精度，加入了RF的组合模型预测精度让五种神经网络的表现都有进一步的提升。最后，对表现较好的两种网络——LSTM和GRU引入了简单编码解码(SED)的机制，让其更好地学习到序列数据全局时间上的特征和远程的依赖关系。以NASA数据集作为研究对象进行该方法的性能测试。实验结果表明，CEEMDAN-RF-SED-LSTM模型对电池RUL预测表现效果好，预测结果相比单一模型具有更低的误差。

关键词: 锂离子电池, 寿命预测, 自适应白噪声完整集成经验模态分解, 随机森林, 神经网络

Abstract:

Lithium-ion battery's remaining useful life (RUL) is an important indicator of battery health management. Therefore, in this paper, using battery capacity as an indicator of health status, including modal decomposition and machine learning algorithms, a CEEMDAN-RF-SED-LSTM method was proposed to predict lithium battery RUL. First, adaptive white-noise full-ensemble empirical-mode decomposition (CEEMDAN) was used to decompose the battery capacity data. Then, to avoid the influence of the noise in the fluctuation component on the prediction ability of the model and not completely discard the characteristic information in the fluctuation component, this paper used the Random Forest algorithm to obtain important values for each fluctuation component, after which sexual ranking and numerical values were used as weights for each component's ability to explain the original data. Subsequently, the weight value and prediction result obtained by the neural network model constructed by different fluctuation components were weighted and reconstructed, resulting in the RUL prediction of the lithium-ion battery. Next, this research compared the prediction accuracy of the single model and the combined model, followed by the addition of the combined model prediction accuracy of RF, to improve the performance of the five neural networks further, after which the Simple Encoder-Decoder (SED) mechanism was introduced for the two networks with better performance, LSTM and GRU, to better learn the global temporal features and long-range dependencies of sequence data. We finally tested the method's performance using the NASA dataset as the research object. The experimental results showed that although the CEEMDAN-RF-SED-LSTM model performed well in battery RUL prediction, the prediction results had lower errors than the single model.

Key words: Li-ion battery, life prediction, adaptive white noise full ensemble empirical mode decomposition, random forest, neural network

中图分类号:

TM 912

肖浩逸, 何晓霞, 梁佳佳, 李春丽. 一种基于模态分解和机器学习的锂电池寿命预测方法[J]. 储能科学与技术, 2022, 11(12): 3999-4009.

Haoyi XIAO, Xiaoxia HE, Jiajia LIANG, Chunli LI. A lithium battery life-prediction method based on mode decomposition and machine learning[J]. Energy Storage Science and Technology, 2022, 11(12): 3999-4009.

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电池编号	拟合优度	IMF1	IMF2	IMF3
B0005	0.999284	0.023469	0.064610	0.109861
B0006	0.999052	0.072530	0.035768	0.124490
B0007	0.998983	0.027500	0.088808	0.076621
B0018	0.998613	0.025708	0.041343	0.174602

电池编号	神经网络模型	模型方法	运行时间/s	MAE	RMSE	MAPE	RE
B0005	LSTM	LSTM	18.77	0.058592	0.070959	0.043809	0.040650
		CEEMDAN-LSTM	70.65	0.043490	0.057525	0.026992	0.026260
		CEEMDAN-RF-LSTM	74.93	0.040182	0.053559	0.024962	0.024390
	RNN	RNN	38.07	0.280588	0.360674	0.180698	0.335772
		CEEMDAN-RNN	87.56	0.245580	0.332067	0.169977	0.390244
		CEEMDAN-RF-RNN	91.95	0.071269	0.087691	0.047033	0.195122
	GRU	GRU	17.84	0.060329	0.072215	0.044820	0.073171
		CEEMDAN-GRU	61.86	0.045586	0.060776	0.028049	0.028130
		CEEMDAN-RF-GRU	66.39	0.041444	0.055729	0.025512	0.024390
	CNN	CNN	13.09	0.068268	0.081806	0.039025	0.440650
		CEEMDAN-CNN	47.96	0.062904	0.073718	0.040348	0.304553
		CEEMDAN-RF-CNN	52.11	0.062832	0.073593	0.040437	0.280813
	MLP	MLP	13.02	0.070968	0.081720	0.047639	0.325203
		CEEMDAN-MLP	45.63	0.068850	0.080262	0.045182	0.329496
		CEEMDAN-RF-MLP	49.97	0.068734	0.080241	0.044737	0.305152

电池编号	神经网络模型	模型方法	运行时间/s	MAE	RMSE	MAPE	RE
B0006	LSTM	LSTM	20.72	0.054751	0.069080	0.037688	0.068037
		CEEMDAN-LSTM	64.83	0.044735	0.058687	0.028165	0.056075
		CEEMDAN-RF-LSTM	69.37	0.039161	0.049791	0.024893	0.054112
	RNN	RNN	38.66	0.207933	0.325623	0.177686	0.439252
		CEEMDAN-RNN	87.25	0.249714	0.345865	0.180759	0.355140
		CEEMDAN-RF-RNN	91.36	0.086660	0.110239	0.061186	0.196262
	GRU	GRU	17.84	0.064288	0.082282	0.044646	0.046729
		CEEMDAN-GRU	58.64	0.042328	0.052737	0.027216	0.065421
		CEEMDAN-RF-GRU	62.91	0.041394	0.051566	0.026716	0.065421
	CNN	CNN	13.19	0.083262	0.095125	0.054467	0.233645
		CEEMDAN-CNN	47.86	0.046205	0.062880	0.030333	0.029597
		CEEMDAN-RF-CNN	51.37	0.041894	0.054645	0.027848	0.028037
	MLP	MLP	13.06	0.085937	0.096994	0.064232	0.088037
		CEEMDAN-MLP	39.78	0.051744	0.066709	0.034459	0.084112
		CEEMDAN-RF-MLP	44.08	0.048342	0.063234	0.032276	0.037383

电池编号	模型方法	MAE	RMSE	MAPE	RE
B0005	CEEMDAN-RF-SED-LSTM	0.025569	0.031899	0.016515	0.018130
B0005	CEEMDAN-RF-SED-GRU	0.037491	0.044218	0.024056	0.089431
B0006	CEEMDAN-RF-SED-LSTM	0.032727	0.039157	0.021635	0.056075
B0006	CEEMDAN-RF-SED-GRU	0.041408	0.049697	0.028029	0.093458
B0007	CEEMDAN-RF-SED-LSTM	0.021852	0.026331	0.013319	0.059524
B0007	CEEMDAN-RF-SED-GRU	0.028275	0.036218	0.017499	0.061905
B0018	CEEMDAN-RF-SED-LSTM	0.025835	0.031901	0.016380	0.094737
B0018	CEEMDAN-RF-SED-GRU	0.030818	0.040062	0.019301	0.081053

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