Safe and Stable Connected Cruise Control for Connected Automated Vehicles with Response Lag

arXiv - EE - Systems and Control Pub Date : 2024-09-10 DOI:arxiv-2409.06884

Yuchen Chen, Gabor Orosz, Tamas G. Molnar

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Abstract

Controlling connected automated vehicles (CAVs) via vehicle-to-everything (V2X) connectivity holds significant promise for improving fuel economy and traffic efficiency. However, to deploy CAVs and reap their benefits, their controllers must guarantee their safety. In this paper, we apply control barrier function (CBF) theory to investigate the safety of CAVs implementing connected cruise control (CCC). Specifically, we study how stability, connection architecture, and the CAV's response time impact the safety of CCC. Through safety and stability analyses, we derive stable and safe choices of control gains, and show that safe CAV operation requires plant and head-to-tail string stability in most cases. Furthermore, the reaction time of vehicles, which is represented as a first-order lag, has a detrimental effect on safety. We determine the critical value of this lag, above which safe CCC gains do not exist. To guarantee safety even with lag while preserving the benefits of CCC, we synthesize safety-critical CCC using CBFs. With the proposed safety-critical CCC, the CAV can leverage information from connected vehicles farther ahead to improve its safety. We evaluate this controller by numerical simulation using real traffic data.

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为有响应滞后的互联自动驾驶汽车提供安全稳定的互联巡航控制

通过车对物（V2X）连接来控制联网自动驾驶汽车（CAV），为提高燃油经济性和交通效率带来了巨大希望。然而，要部署 CAV 并从中获益，其控制器必须保证其安全性。在本文中，我们应用控制屏障函数（CBF）理论来研究实施互联巡航控制（CCC）的 CAV 的安全性。通过安全和稳定性分析，我们得出了稳定和安全的控制增益选择，并表明在大多数情况下，CAV 的安全运行需要厂房和头尾稳定。此外，车辆的反应时间（表现为一阶滞后）会对安全性产生不利影响。我们确定了该滞后的临界值，超过该值就不存在安全的 CCC 增益。为了在有滞后的情况下也能保证安全，同时保留 CCC 的优点，我们使用 CBF 合成了安全临界 CCC。有了所提出的安全临界 CCC，CAV 可以利用前方更远处联网车辆的信息来提高其安全性。我们通过使用真实交通数据进行数值模拟来评估这种控制器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - EE - Systems and Control

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