An MPC-based Task Priority Management Approach for Connected and Automated Vehicles Reference Tracking with Obstacle Avoidance*

2021 European Control Conference (ECC) Pub Date : 2021-06-29 DOI:10.23919/ecc54610.2021.9654856

Francesco Vitale, C. Roncoli

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引用次数: 2

Abstract

We present a reference tracking control problem with obstacle avoidance for connected and automated vehicles. The proposed approach allows to deal with obstacles in the control loop in the first instance, coping with real-time operations while safely waiting for an eventually new planned trajectory from the guidance loop. An obstacle avoidance algorithm is designed to produce suitable constraints for an optimization control problem to be solved via Nonlinear Model Predictive Control. Such an algorithm is based on task priority management, so that the reference tracking task is handled as a lower priority task with respect to the obstacle avoidance task. Automated vehicles are managed in a decentralized fashion, so that they can process independently any sensed potential obstacles, including conventional vehicles. In the presence of vehicle connectivity, vehicles may exchange information about their states to make decisions based on more accurate predictions. The proposed method is evaluated via simulation experiments, for a set of scenarios in the context of urban traffic.

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基于mpc的网联自动车辆避障参考跟踪任务优先级管理方法*

提出了一种网联自动驾驶车辆的避障参考跟踪控制问题。所提出的方法允许在第一时间处理控制回路中的障碍，在安全等待最终来自制导回路的新计划轨迹的同时应对实时操作。设计了一种避障算法，为非线性模型预测控制的优化控制问题产生合适的约束条件。该算法基于任务优先级管理，将参考跟踪任务作为相对于避障任务的低优先级任务来处理。自动驾驶车辆以分散的方式进行管理，因此它们可以独立处理任何感知到的潜在障碍，包括传统车辆。在车辆连接的情况下，车辆可以交换有关其状态的信息，以便根据更准确的预测做出决策。通过模拟实验，对该方法在城市交通环境下的一系列场景进行了评估。

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

2021 European Control Conference (ECC)

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