电动汽车生态自适应巡航控制策略鲁棒模型预测控制框架

Shengbin Yu, Xiao Pan, Anastasis Georgiou, Boli Chen, I. Jaimoukha, S. Evangelou
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引用次数: 1

摘要

近年来,车联网技术的发展为设计智能、可持续的车辆运动控制器提供了新的解决方案。这项工作解决了一个汽车跟踪任务,其中反馈线性化方法与鲁棒模型预测控制(RMPC)方案相结合,以安全、优化和有效地控制连接的电动汽车。特别是,非线性动力学通过反馈线性化方法进行线性化,以保持高效的计算速度并保证全局最优性。同时,通过RMPC设计处理了不可避免的模型不匹配问题。RMPC的控制目标是在满足物理约束和安全约束的前提下,考虑有界模型失配扰动,优化自我车辆的电能效率。数值结果首先通过与标称MPC的比较验证了该方法的有效性和鲁棒性。对该方法性能的进一步研究表明,与最近提出的使用空间域建模方法的基准方法相比,该方法具有更高的能源效率和乘客舒适度。
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A Robust Model Predictive Control Framework for Ecological Adaptive Cruise Control Strategy of Electric Vehicles
The recent advancement in vehicular networking technology provides novel solutions for designing intelligent and sustainable vehicle motion controllers. This work addresses a car-following task, where the feedback linearisation method is combined with a robust model predictive control (RMPC) scheme to safely, optimally and efficiently control a connected electric vehicle. In particular, the nonlinear dynamics are linearised through a feedback linearisation method to maintain an efficient computational speed and to guarantee global optimality. At the same time, the inevitable model mismatch is dealt with by the RMPC design. The control objective of the RMPC is to optimise the electric energy efficiency of the ego vehicle with consideration of a bounded model mismatch disturbance subject to satisfaction of physical and safety constraints. Numerical results first verify the validity and robustness through a comparison between the proposed RMPC and a nominal MPC. Further investigation into the performance of the proposed method reveals a higher energy efficiency and passenger comfort level as compared to a recently proposed benchmark method using the space-domain modelling approach.
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