Enhancement of energy utilization efficiency and speed control of autonomous electric vehicles (AEVs): A hybrid approach

IF 3.2 4区工程技术 Q3 ENERGY & FUELS

Energy Efficiency Pub Date : 2024-07-02 DOI:10.1007/s12053-024-10238-5

S. Raguvaran, S. Anandamurugan

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Abstract

The efficiency of energy utilization in autonomous electric vehicles greatly impacts their longitudinal motion control. However, the complexity of driving scenes poses challenges to this control. This study introduces a hybrid approach that combines the improved coot optimization algorithm with adaptive reinforcement equilibrium learning to enhance both energy efficiency and speed control in autonomous electric vehicles. The primary innovation lies in optimizing and managing the powertrain efficiency operating point distribution to increase energy utilization efficiency. In the first phase, the improved coot optimization handles vehicle energy utilization efficiency by optimizing operational point transfers. The system normalizes motor torque and velocity to maximize efficiency within constrained conditions. Subsequently, in the second phase, adaptive reinforcement equilibrium learning effectively predicts vehicle speed control on irregular pathways. The proposed technique is implemented on the PYTHON platform to evaluate performance. The analysis also investigates two specific operating conditions: New European Driving Cycle (NEDC) and World Light-Duty Vehicle Test Cycle (WLTC). The findings demonstrate that the proposed strategy effectively optimizes vehicle powertrain efficiency operating point distribution, resulting in improved energy consumption outcomes. The energy utilization efficiency of the proposed approach is 90%, 93%, 95%, 96%, and 98.4%, respectively, at time 100 s, 200 s, 300 s, 400 s, and 500 s.

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提高自动驾驶电动汽车（AEV）的能源利用效率和速度控制：混合方法

自动驾驶电动汽车的能量利用效率对其纵向运动控制有很大影响。然而，驾驶场景的复杂性给这种控制带来了挑战。本研究引入了一种混合方法，将改进的库特优化算法与自适应强化平衡学习相结合，以提高自主电动汽车的能源效率和速度控制。主要创新在于优化和管理动力总成效率工作点分布，以提高能源利用效率。在第一阶段，改进的 COOT 优化通过优化运行点转移来处理车辆的能源利用效率。系统对电机扭矩和速度进行归一化处理，以便在受限条件下实现效率最大化。随后，在第二阶段，自适应强化平衡学习可有效预测不规则路径上的车辆速度控制。我们在PYTHON平台上实施了所提出的技术，以评估其性能。分析还研究了两种特定的运行条件：新欧洲驾驶循环（NEDC）和世界轻型车辆测试循环（WLTC）。研究结果表明，所提出的策略能有效优化车辆动力总成效率工作点分布，从而改善能耗结果。在 100 秒、200 秒、300 秒、400 秒和 500 秒时，拟议方法的能量利用效率分别为 90%、93%、95%、96% 和 98.4%。

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来源期刊

Energy Efficiency ENERGY & FUELS-ENERGY & FUELS

CiteScore

5.80

自引率

6.50%

发文量

审稿时长

>12 weeks

期刊介绍： The journal Energy Efficiency covers wide-ranging aspects of energy efficiency in the residential, tertiary, industrial and transport sectors. Coverage includes a number of different topics and disciplines including energy efficiency policies at local, regional, national and international levels; long term impact of energy efficiency; technologies to improve energy efficiency; consumer behavior and the dynamics of consumption; socio-economic impacts of energy efficiency measures; energy efficiency as a virtual utility; transportation issues; building issues; energy management systems and energy services; energy planning and risk assessment; energy efficiency in developing countries and economies in transition; non-energy benefits of energy efficiency and opportunities for policy integration; energy education and training, and emerging technologies. See Aims and Scope for more details.