Mean-square exponential stabilization of mixed-autonomy traffic PDE system

IF 4.8 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS Automatica Pub Date : 2024-08-21 DOI:10.1016/j.automatica.2024.111859

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Abstract

Control of mixed-autonomy traffic where Human-driven Vehicles (HVs) and Autonomous Vehicles (AVs) coexist on the road has gained increasing attention over the recent decades. This paper addresses the boundary stabilization problem for mixed traffic on freeways. The traffic dynamics are described by uncertain coupled hyperbolic partial differential equations (PDEs) with Markov jumping parameters, which aim to address the distinctive driving strategies between AVs and HVs. Considering that the spacing policies of AVs vary in mixed traffic, the stochastic impact area of AVs is governed by a continuous Markov chain. The interactions between HVs and AVs such as overtaking or lane changing are mainly induced by impact areas. Using backstepping design, we develop a full-state feedback boundary control law to stabilize the deterministic system (nominal system). Applying Lyapunov analysis, we demonstrate that the nominal backstepping control law is able to stabilize the traffic system with Markov jumping parameters, provided the nominal parameters are sufficiently close to the stochastic ones on average. The mean-square exponential stability conditions are derived, and the results are validated by numerical simulations.

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混合自主交通 PDE 系统的均方指数稳定

近几十年来，人类驾驶车辆（HVs）和自动驾驶车辆（AVs）共存于道路上的混合自动驾驶交通控制问题日益受到关注。本文探讨了高速公路混合交通的边界稳定问题。交通动态由带有马尔科夫跳跃参数的不确定耦合双曲偏微分方程（PDE）描述，旨在解决 AV 和 HV 之间不同的驾驶策略。考虑到混合交通中 AVs 的间距策略各不相同，AVs 的随机影响区域由连续马尔可夫链控制。HV 与 AV 之间的相互作用（如超车或变道）主要是由撞击区域引起的。利用反步进设计，我们开发了一种全状态反馈边界控制法，以稳定确定性系统（标称系统）。应用 Lyapunov 分析，我们证明了只要标称参数足够接近随机参数的平均值，标称反步态控制法则就能稳定具有马尔可夫跳跃参数的交通系统。我们推导出了均方指数稳定性条件，并通过数值模拟对结果进行了验证。

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来源期刊

Automatica 工程技术-工程：电子与电气

CiteScore

10.70

自引率

7.80%

发文量

617

审稿时长

5 months

期刊介绍： Automatica is a leading archival publication in the field of systems and control. The field encompasses today a broad set of areas and topics, and is thriving not only within itself but also in terms of its impact on other fields, such as communications, computers, biology, energy and economics. Since its inception in 1963, Automatica has kept abreast with the evolution of the field over the years, and has emerged as a leading publication driving the trends in the field. After being founded in 1963, Automatica became a journal of the International Federation of Automatic Control (IFAC) in 1969. It features a characteristic blend of theoretical and applied papers of archival, lasting value, reporting cutting edge research results by authors across the globe. It features articles in distinct categories, including regular, brief and survey papers, technical communiqués, correspondence items, as well as reviews on published books of interest to the readership. It occasionally publishes special issues on emerging new topics or established mature topics of interest to a broad audience. Automatica solicits original high-quality contributions in all the categories listed above, and in all areas of systems and control interpreted in a broad sense and evolving constantly. They may be submitted directly to a subject editor or to the Editor-in-Chief if not sure about the subject area. Editorial procedures in place assure careful, fair, and prompt handling of all submitted articles. Accepted papers appear in the journal in the shortest time feasible given production time constraints.

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