New energy vehicle battery state of charge prediction based on XGBoost algorithm and RF fusion

Q2 Energy Energy Informatics Pub Date : 2024-11-11 DOI:10.1186/s42162-024-00424-1
Changyou Lei
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Abstract

As the most important component of new energy electric vehicles, lithium-ion batteries may suffer irreversible damage to the battery due to an abnormal state of charge. Nevertheless, the extant research on charge prediction predominantly employs a single model or an enhanced single model. However, these approaches do not fully account for the intricacies and variability of the actual driving road conditions of the vehicle. Furthermore, the prediction accuracy of the charge state in the latter phase of discharge remains suboptimal. To further improve the accuracy of predicting the state of charge, the study utilizes actual operating data of new energy vehicles and combines two proposed algorithms to build a first layer learner of a fusion prediction model. The second layer learner integrates various prediction results. The fusion model can enhance its adaptability to complex data structures by combining the gradient boosting ability of XGBoost algorithm and the diversity of Random Forest when dealing with nonlinear problems. This fusion method modifies the input features of the second layer of the fusion model, enhances the complexity of the second layer learner, effectively circumvents overfitting, and exhibits reduced error rates relative to traditional single-chip prediction models. As a result, the performance of the prediction model is significantly enhanced. The tests showed that when using the fusion model for state of charge prediction, the prediction accuracy could reach 97.6%, and the prediction accuracy was higher than the other four comparison models. When the car was driving in a 25 ℃ highway environment, the root mean square error of the fusion model was 1.3%, and the average absolute error was 1.5%. In urban road environments, the root mean square error of the fusion model was 1.5%, and the average absolute error was 1%. The experiment demonstrates that the proposed fusion prediction model can accurately predict the charging status, thereby enabling the battery to be fully utilized while simultaneously reducing energy consumption. In comparison to the traditional single model or enhanced single model, the proposed fusion model has demonstrated a notable enhancement in both prediction accuracy and computational efficiency.

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基于 XGBoost 算法和射频融合的新能源汽车电池充电状态预测
作为新能源电动汽车最重要的部件,锂离子电池可能会因异常充电状态而遭受不可逆的损坏。然而,现有的充电预测研究主要采用单一模型或增强型单一模型。然而,这些方法并不能完全考虑车辆实际行驶路况的复杂性和多变性。此外,对放电后期充电状态的预测精度仍然不够理想。为了进一步提高充电状态预测的准确性,本研究利用新能源汽车的实际运行数据,结合两种拟议算法,建立了融合预测模型的第一层学习器。第二层学习器整合了各种预测结果。在处理非线性问题时,融合模型结合了 XGBoost 算法的梯度提升能力和随机森林的多样性,从而增强了对复杂数据结构的适应性。这种融合方法修改了融合模型第二层的输入特征,增强了第二层学习器的复杂性,有效避免了过拟合,与传统的单芯片预测模型相比,误差率有所降低。因此,预测模型的性能显著提高。测试表明,使用融合模型进行充电状态预测时,预测准确率可达 97.6%,且预测准确率高于其他四个对比模型。汽车在 25 ℃ 高速公路环境中行驶时,融合模型的均方根误差为 1.3%,平均绝对误差为 1.5%。在城市道路环境中,融合模型的均方根误差为 1.5%,平均绝对误差为 1%。实验证明,所提出的融合预测模型可以准确预测充电状态,从而使电池得到充分利用,同时降低能耗。与传统的单一模型或增强型单一模型相比,所提出的融合模型在预测精度和计算效率方面都有显著提高。
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来源期刊
Energy Informatics
Energy Informatics Computer Science-Computer Networks and Communications
CiteScore
5.50
自引率
0.00%
发文量
34
审稿时长
5 weeks
期刊最新文献
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