基于频域功率分布的自适应能量管理策略

Cheng-shi Luo, Ying Huang, Xu Wang, Yongliang Li, Fen Guo
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引用次数: 0

摘要

针对重型混合动力电动汽车(hev)的特殊需求。提出了一种基于频域功率分布的自适应能量管理策略。本文利用MATLAB/Simulink建立了某重型混合动力汽车的动力学模型。首先,采用带外部输入的非线性自回归神经网络(NARX)对车辆速度进行预测;其次,根据预测的车速,采用主成分分析和K-means聚类方法对工况进行分类,根据工况类别自适应调整相应的控制参数,并在频域内进行功率分配;以一段真实车辆行驶工况数据作为仿真条件,对该策略进行了验证和分析。仿真结果表明,该策略可以快速将偏离的电池荷电状态(SoC)恢复到目标值并保持稳定。有效地降低了电池的充放电电流幅值,同时也减少了发动机的瞬态工况,使发动机能够在最佳效率曲线上工作。验证了该策略是一种有效的重型混合动力汽车实时能量管理策略。
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Adaptive Energy Management Strategy Based on Frequency Domain Power Distribution
Aiming at the special needs of heavy-duty hybrid electric vehicles(HEVs)., an adaptive energy management strategy based on frequency domain power distribution is proposed. This article uses MATLAB/Simulink to establish a dynamic model of a heavy-duty HEV. Firstly, the nonlinear autoregressive with external input(NARX) neural network is used to predict the speed of the vehicle. Secondly, according to the predicted vehicle speed, principal component analysis and K-means clustering method are used to classify the working conditions, the corresponding control parameters are adjusted adaptively according to the working conditions category, and the power is distributed in the frequency domain. A piece of real vehicle driving cycle data of the vehicle is used as the simulation condition to verify and analyze the strategy. The simulation results show that this strategy can quickly restore the deviated battery state-of-charge (SoC) to the target value and maintain it stably. The battery's charge and discharge current amplitude are effectively reduced, and meanwhile, the transient working conditions of the engine are reduced too, and therefore the engine can work on the optimal efficiency curve. It is verified that this strategy is an effective real-time energy management strategy for heavy-duty HEVs.
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