Analysis of a Novel Command Governor-Based Adaptive Cruise Controller for Non-Cooperative Vehicle Following

IF 1 Q4 AUTOMATION & CONTROL SYSTEMS

Mechatronic Systems and Control Pub Date : 2019-11-26 DOI:10.1115/dscc2019-9196

Ben Groelke, Christian Earnhardt, John Borek, C. Vermillion

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引用次数: 1

Abstract

This paper presents a novel adaptive cruise control (ACC) strategy that utilizes a command governor (CG) to enforce vehicle following constraints. The CG formulation relies on knowledge of the maximum possible braking deceleration of the lead vehicle and a tunable assumption regarding the lead vehicle velocity profile (offering different levels of conservatism) to modify wheel torque commands to ensure safe following. In particular, a safe following distance is defined as one in which the ego vehicle can avoid collision with the lead vehicle and maintain a sufficient following distance in the event that the lead vehicle exerts maximum braking deceleration. The CG seeks to adjust the wheel torque command such that the aforementioned constraint is satisfied at every step in a prediction horizon (i.e., at every step, if the lead vehicle exerts maximum braking deceleration, the ego vehicle can brake and remain outside of the aforementioned buffer zone), which requires an estimate of future lead vehicle behavior. In this work, we explore different levels of conservatism with regard to this assumption. Simulations are presented for a heavy-duty truck, using a stochastic lead vehicle model that has been calibrated with actual traffic data. Even for the most conservative lead vehicle prediction models, results show that this CG-based ACC strategy can reduce braking energy expended (used as a surrogate for fuel wasted) by up to 78%, while improving drivability and reducing total trip time.

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基于命令调速器的非合作车辆跟随自适应巡航控制器分析

本文提出了一种新的自适应巡航控制(ACC)策略，该策略利用指令调控器(CG)来强制车辆跟随约束。CG公式依赖于对领先车辆的最大可能制动减速的了解，以及关于领先车辆速度剖面的可调假设(提供不同程度的保守性)，以修改车轮扭矩命令，以确保安全跟随。其中，安全跟随距离的定义是:在前车施加最大制动减速度的情况下，自我车辆能够避免与前车发生碰撞，并保持足够的跟随距离。CG试图调整车轮扭矩指令，以便在预测范围内的每一步都满足上述约束(即，在每一步，如果领先车辆施加最大制动减速，自我车辆可以制动并保持在上述缓冲区之外)，这需要对未来领先车辆的行为进行估计。在这项工作中，我们探讨了关于这一假设的不同程度的保守主义。本文以某重型卡车为例，采用随机先导车辆模型进行了仿真，并与实际交通数据进行了标定。即使在最保守的领先车辆预测模型中，结果也表明，这种基于gc的ACC策略可以将制动能量消耗(用作燃料浪费的替代指标)减少高达78%，同时提高驾驶性能并缩短总行程时间。

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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来源期刊

Mechatronic Systems and Control AUTOMATION & CONTROL SYSTEMS-

CiteScore

1.40

自引率

66.70%

发文量

期刊介绍： This international journal publishes both theoretical and application-oriented papers on various aspects of mechatronic systems, modelling, design, conventional and intelligent control, and intelligent systems. Application areas of mechatronics may include robotics, transportation, energy systems, manufacturing, sensors, actuators, and automation. Techniques of artificial intelligence may include soft computing (fuzzy logic, neural networks, genetic algorithms/evolutionary computing, probabilistic methods, etc.). Techniques may cover frequency and time domains, linear and nonlinear systems, and deterministic and stochastic processes. Hybrid techniques of mechatronics that combine conventional and intelligent methods are also included. First published in 1972, this journal originated with an emphasis on conventional control systems and computer-based applications. Subsequently, with rapid advances in the field and in view of the widespread interest and application of soft computing in control systems, this latter aspect was integrated into the journal. Now the area of mechatronics is included as the main focus. A unique feature of the journal is its pioneering role in bridging the gap between conventional systems and intelligent systems, with an equal emphasis on theory and practical applications, including system modelling, design and instrumentation. It appears four times per year.