TY - JOUR
T1 - Ubiquitous Control Over Heterogeneous Vehicles
T2 - A Digital Twin Empowered Edge AI Approach
AU - Fan, Bo
AU - Su, Zixun
AU - Chen, Yanyan
AU - Wu, Yuan
AU - Xu, Chengzhong
AU - Quek, Tony Q.S.
N1 - Funding Information:
This work was supported in part by National Natural Science Foundation of China under Grant 61901013 and 62072490, in part by Science and Technology Development Fund of Macau SAR under Grants 0015/2019/AKP, 0060/2019/A1, and 0162/2019/A3, in part by FDCT-MOST Joint Project under Grant 0066/2019/AMJ, in part by the National Research Foundation, Singapore, and Infocomm Media Development Authority under its Future Communications Research and Development Programme.
Publisher Copyright:
© 2002-2012 IEEE.
PY - 2023/2/1
Y1 - 2023/2/1
N2 - The forthcoming of automated driving has led to vehicular heterogeneity, where vehicles with different automation levels, including connected and automated vehicles (CAVs), connected vehicles (CVs), and human-driven vehicles (HVs), coexist in the road traffic. However, the design of current traffic control systems fail to account for the vehicular traffic heterogeneity. In addition, the emerging artificial intelligence (AI) based traffic control strategies require large quantities of computation resources and generate high delay, which cannot meet the fault-intolerance requirement of the traffic control system. Therefore, there is an urgent need for constructing a new traffic control framework to jointly satisfy the fault-intolerance requirement and realize ubiquitous control over the heterogeneous vehicles. Inspired by this, a digital twin (DT) empowered edge AI framework is proposed in this article. The DT's virtualization capability is utilized to enable virtual risk assessment and performance analysis under the fault-intolerant traffic control system. In addition, the DT's offline learning capability helps the edge AI understand the road traffic data more intelligently to perform enforced optimizations and decisions. Then, a three-layer vehicle control paradigm is discussed under the proposed framework. In the first layer, deep reinforcement learning (DRL) is utilized to intelligently control the CAV acceleration and lane-changing. In the second layer, indirect CV/HV control can be performed by adjusting the target speed and penetration rate of the DRL-controlled CAVs which are mixed in the traffic flow. In the third layer, vehicle-to-everything (V2X) communications and variable message signs are utilized to realize the direct control of CVs and HVs. Experimental results validate the effectiveness of our proposed control paradigm.
AB - The forthcoming of automated driving has led to vehicular heterogeneity, where vehicles with different automation levels, including connected and automated vehicles (CAVs), connected vehicles (CVs), and human-driven vehicles (HVs), coexist in the road traffic. However, the design of current traffic control systems fail to account for the vehicular traffic heterogeneity. In addition, the emerging artificial intelligence (AI) based traffic control strategies require large quantities of computation resources and generate high delay, which cannot meet the fault-intolerance requirement of the traffic control system. Therefore, there is an urgent need for constructing a new traffic control framework to jointly satisfy the fault-intolerance requirement and realize ubiquitous control over the heterogeneous vehicles. Inspired by this, a digital twin (DT) empowered edge AI framework is proposed in this article. The DT's virtualization capability is utilized to enable virtual risk assessment and performance analysis under the fault-intolerant traffic control system. In addition, the DT's offline learning capability helps the edge AI understand the road traffic data more intelligently to perform enforced optimizations and decisions. Then, a three-layer vehicle control paradigm is discussed under the proposed framework. In the first layer, deep reinforcement learning (DRL) is utilized to intelligently control the CAV acceleration and lane-changing. In the second layer, indirect CV/HV control can be performed by adjusting the target speed and penetration rate of the DRL-controlled CAVs which are mixed in the traffic flow. In the third layer, vehicle-to-everything (V2X) communications and variable message signs are utilized to realize the direct control of CVs and HVs. Experimental results validate the effectiveness of our proposed control paradigm.
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U2 - 10.1109/MWC.012.2100587
DO - 10.1109/MWC.012.2100587
M3 - Article
AN - SCOPUS:85135751620
SN - 1536-1284
VL - 30
SP - 166
EP - 173
JO - IEEE Wireless Communications
JF - IEEE Wireless Communications
IS - 1
ER -