Connect ＆ Drive： design and evaluation of cooperative adaptive cruise control for congestion reduction

Road throughput can be increased by driving at small inter-vehicle time gaps. The amplification of velocity disturbances in upstream direction, however, poses limitations to the minimum feasible time gap. This effect is covered by the notion of string stability. String-stable behavior is thus consid...

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Veröffentlicht in:	Journal of modern transportation 2011-09, Vol.19 (3), p.207-213
Hauptverfasser:	Ploeg, Jeroen, Serrarens, Alex F. A., Heijenk, Geert J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptive control Automotive Engineering Control systems Cruise control Design analysis Design engineering Engineering Feasibility Foundations Geoengineering Highway and Urban Transportation Hydraulics Regional/Spatial Science Roads Trucks Wireless communication 商业化应用安全驾驶实时信息客运车辆控制系统无线通信系统自适应巡航控制连接
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container_title	Journal of modern transportation
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creator	Ploeg, Jeroen Serrarens, Alex F. A. Heijenk, Geert J.
description	Road throughput can be increased by driving at small inter-vehicle time gaps. The amplification of velocity disturbances in upstream direction, however, poses limitations to the minimum feasible time gap. This effect is covered by the notion of string stability. String-stable behavior is thus considered an essential requirement for the design of automatic distance control systems, which are needed to allow for safe driving at time gaps well below 1 s. Using wireless inter-vehicle communications to provide real-time information of the preceding vehicle, in addition to the information obtained by common Adaptive Cruise Control （ACC） sensors, appears to significantly decrease the feasible time gap, which is shown by practical experiments with a test fleet consisting of six passenger vehicles. The large-scale deployment of this system, known as Cooperative ACC （CACC）, however, poses challenges with respect to the reliability of the wireless communication system. A solution for this scalability problem can be found in decreasing the transmission power and/or beaconing rate, or adapting the communications protocol. Although the main CACC objective is to increase road throughput, the first commercial application of CACC is foreseen to be in truck platooning, since short distance following is expected to yield significant fuel savings in this case.
doi_str_mv	10.1007/bf03325760
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subjects	Adaptive control Automotive Engineering Control systems Cruise control Design analysis Design engineering Engineering Feasibility Foundations Geoengineering Highway and Urban Transportation Hydraulics Regional/Spatial Science Roads Trucks Wireless communication 商业化应用安全驾驶实时信息客运车辆控制系统无线通信系统自适应巡航控制连接
title	Connect ＆ Drive： design and evaluation of cooperative adaptive cruise control for congestion reduction
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