Design and experimental evaluation of cooperative adaptive cruise control

2011 14th International IEEE Conference on Intelligent Transportation Systems (ITSC) Pub Date : 2011-11-18 DOI:10.1109/ITSC.2011.6082981

J. Ploeg, Bart Scheepers, E. V. Nunen, N. Wouw, H. Nijmeijer

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引用次数: 500

Abstract

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. 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. Theoretical analysis reveals that this requirement can be met using wireless inter-vehicle communication to provide real-time information of the preceding vehicle, in addition to the information obtained by common Adaptive Cruise Control (ACC) sensors. In order to validate these theoretical results and to demonstrate the technical feasibility, the resulting control system, known as Cooperative ACC (CACC), is implemented on a test fleet consisting of six passenger vehicles. Experiments clearly show that the practical results match the theoretical analysis, thereby indicating the possibilities for short-distance vehicle following.

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协同自适应巡航控制系统设计与实验评价

在较小的车辆间时间间隔行驶可以增加道路吞吐量。然而，上游速度扰动的放大对最小可行时间间隔造成了限制。因此，管柱的稳定性能被认为是自动距离控制系统设计的基本要求，该系统需要在远低于15秒的时间间隔内实现安全驾驶。理论分析表明，在常规自适应巡航控制(ACC)传感器获取信息的基础上，利用无线车际通信提供前车实时信息可以满足这一要求。为了验证这些理论结果并证明技术可行性，由此产生的控制系统被称为合作ACC (CACC)，在由六辆乘用车组成的测试车队上实施。实验结果清楚地表明，实际结果与理论分析相吻合，从而表明了短距离车辆跟随的可能性。

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2011 14th International IEEE Conference on Intelligent Transportation Systems (ITSC)

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