Dynamic Vehicle Allocation Policies for Shared Autonomous Electric Fleets

Yuxuan Dong, R. Koster, D. Roy, Yugang Yu
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引用次数: 4

Abstract

In the future, vehicle sharing platforms for passenger transport will be unmanned, autonomous, and electric. These platforms must decide which vehicle should pick up which type of customer based on the vehicle’s battery level and customer’s travel distance. We design dynamic vehicle allocation policies for matching appropriate vehicles to customers using a Markov decision process model. To obtain the model parameters, we first model the system as a semi-open queuing network (SOQN) with multiple synchronization stations. At these stations, customers with varied battery demands are matched with semi-shared vehicles that hold sufficient remaining battery levels. If a vehicle’s battery level drops below a threshold, it is routed probabilistically to a nearby charging station for charging. We solve the analytical model of the SOQN and obtain approximate system performance measures, which are validated using simulation. With inputs from the SOQN model, the Markov decision process minimizes both customer waiting cost and lost demand and finds a good heuristic vehicle allocation policy. The experiments show that the heuristic policy is near optimal in small-scale networks and outperforms benchmark policies in large-scale realistic scenarios. An interesting finding is that reserving idle vehicles to wait for future short-distance customer arrivals can be beneficial even when long-distance customers are waiting.
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共享自动驾驶电动车队的动态车辆分配策略
未来,用于客运的车辆共享平台将实现无人驾驶、自动驾驶和电动化。这些平台必须根据车辆的电池电量和客户的行驶距离来决定哪辆车应该搭载哪种类型的客户。采用马尔可夫决策过程模型设计动态车辆分配策略,为客户匹配合适的车辆。为了获得模型参数,我们首先将系统建模为具有多个同步站的半开放排队网络(SOQN)。在这些充电站,对电池有不同需求的客户可以选择有足够剩余电量的半共享汽车。如果车辆的电池电量低于阈值,它很可能会被路由到附近的充电站充电。我们求解了SOQN的解析模型,得到了近似的系统性能度量,并通过仿真验证了其有效性。利用SOQN模型的输入,马尔可夫决策过程最小化了客户等待成本和需求损失,并找到了一个好的启发式车辆分配策略。实验表明,启发式策略在小规模网络中接近最优,在大规模现实场景中优于基准策略。一个有趣的发现是,即使在长途客户正在等待的情况下,保留闲置车辆以等待未来的短途客户到来也是有益的。
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