考虑CACC汽车队列动态特性的混合交通流建模与仿真

doi:10.16182/j.issn1004731x.joss.24-0175

摘要/Abstract

摘要：

为研究混入协同自适应巡航控制(cooperative adaptive cruise control，CACC)汽车队列的单车道混合交通流特性，提出一种基于元胞自动机的建模方法，区分人工驾驶车辆与CACC车辆跟驰策略，引入队列动态车间距与实际控制行为，构建具有固有动态特性的混合交通流模型。该模型可以深入研究队形几何、跟驰控制策略、队列规模等队列特征对混合交通流特性的影响，以及队列的调整控制与交通流间的耦合作用。结果表明：在满足队列内稳定性与弦稳定性的条件下，增加汽车队列渗透率、减小车头时距可显著提升混合交通流的峰值流量；随队列规模增大，峰值流量呈现非线性变化，交通流波动增强，均匀性降低；相较于自适应巡航控制队列，CACC队列对交通流干扰的抑制能力更强，能更有效改善混合交通流特性。

关键词: 智能交通, 智能汽车, 汽车队列, 元胞自动机, 混合交通流

Abstract:

To investigate the characteristics of single-lane mixed traffic flow with the presence of cooperative adaptive cruise control (CACC) vehicle platoons, a modeling approach based on cellular automata is proposed. This method distinguishes between the car-following strategies of human-driven vehicles and CACC vehicles, incorporating dynamic inter-vehicle spacing within the platoon and actual control behaviors to construct a mixed traffic flow model with inherent dynamic properties. The model enables an in-depth analysis of the influence of platoon features, such as geometric formation, car-following control strategies, and platoon size, on the characteristics of mixed traffic flow. It also allows us to study the coupling effects between platoon control adjustments and overall traffic flow. The results show that under conditions satisfying both the internal stability and string stability of platoon, increasing the penetration rate of CACC vehicles and reducing time headway can significantly enhance the peak flow of mixed traffic. As the platoon size increases, peak flow exhibits nonlinear variation, traffic flow fluctuations intensify, and uniformity decreases. Compared with ACC platoons, CACC platoons demonstrate stronger capabilities in suppressing traffic disturbances and improving the performance of mixed traffic flow more effectively.

Key words: intelligent transportation, intelligent vehicle, vehicular platoon, cellular automata, hybrid traffic flow

中图分类号:

TP391.9

杨秀建,黄菁菁,王曦 . 考虑CACC汽车队列动态特性的混合交通流建模与仿真[J]. 系统仿真学报, 2025, 37(6): 1388-1399.

Yang Xiujian,Huang Jingjing,Wang Xi . Modeling and Simulation of Hybrid Traffic Flow Considering the Inherent Dynamics of CACC Vehicular Platoons[J]. Journal of System Simulation, 2025, 37(6): 1388-1399.

图/表 13

图1

图2

表1

仿真参数值

参数	取值
道路长度L/m	1 500
仿真时长/s	1 000
车辆长度l/m	5
人工驾驶车辆随机慢化概率P_slow	0.3
人工驾驶车辆最大加、减速度a_max/(m·s^-2)	6
人工驾驶车辆、队列车辆最大速度v_max/(m·s^-1)	33
人工驾驶车辆反应时间 $t i a$ /s	2
队列车辆反应时间 $t i b$ /s	1

表1

图3

图4

图5

图6

图7

图8

图9

图10

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图12

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