Barrier Lyapunov Function-based Backstepping Controller Design for Path Tracking of Autonomous Vehicles

IF 3.1 4区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Journal of Intelligent & Robotic Systems Pub Date : 2024-08-07 DOI:10.1007/s10846-024-02152-w

Alireza Hosseinnajad, Navid Mohajer, Saeid Nahavandi

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引用次数: 0

Abstract

This research proposes a novel BLF-based backstepping controller for path tracking of Autonomous Vehicles (AVs) with unknown dynamics and unmeasurable states. The proposed framework includes: (1) forming geometric-dynamic model of the vehicle by combining the dynamics of the vehicle with the kinematics of the visual measurement system, (2) designing a fixed-time Extended-State Observer (ESO) to estimate the unknown dynamics and unmeasurable states, and (3) introducing a BLF-based controller for faster response and more accurate path tracking compared to previous BLF-based controllers. Besides the novelty of the BLF-based controller, by transforming the closed-loop error dynamics into a unified proportional-derivative (PD)-type structure, an intuitive criterion is proposed to provide a systematic procedure for comparing BLF-based controllers. A combined BLF is further proposed based on this performance criterion to eliminate the sensitivity of BLF-based controllers to the magnitude of the constraint. The stability analysis is performed for the fixed-time ESO and the closed-loop control system. MATLAB/CarSim co-simulation is conducted to evaluate the performance of the proposed control system. The outcomes of the work show that the closed-loop control system is exponentially stable. In addition, it can provide a faster response and result in more accurate path tracking compared to previous BLF-based control systems.

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基于路障 Lyapunov 函数的自动驾驶汽车路径跟踪反步进控制器设计

本研究提出了一种基于 BLF 的新型反步进控制器，用于具有未知动态和不可测量状态的自动驾驶汽车（AV）的路径跟踪。提出的框架包括(1) 结合车辆的动力学和视觉测量系统的运动学，形成车辆的几何动态模型；(2) 设计固定时间扩展状态观测器（ESO）来估计未知动力学和不可测状态；(3) 引入基于 BLF 的控制器，与之前的基于 BLF 的控制器相比，响应速度更快，路径跟踪更准确。除了基于 BLF 的控制器的新颖性外，还通过将闭环误差动态转换为统一的比例-派生（PD）型结构，提出了一个直观的标准，为比较基于 BLF 的控制器提供了一个系统的程序。在此性能标准的基础上，进一步提出了一种组合 BLF，以消除基于 BLF 的控制器对约束大小的敏感性。对固定时间 ESO 和闭环控制系统进行了稳定性分析。通过 MATLAB/CarSim 协同仿真，评估了拟议控制系统的性能。研究结果表明，闭环控制系统具有指数稳定性。此外，与之前基于 BLF 的控制系统相比，它能提供更快的响应速度，并实现更精确的路径跟踪。

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

Journal of Intelligent & Robotic Systems 工程技术-机器人学

CiteScore

7.00

自引率

9.10%

发文量

219

审稿时长

6 months

期刊介绍： The Journal of Intelligent and Robotic Systems bridges the gap between theory and practice in all areas of intelligent systems and robotics. It publishes original, peer reviewed contributions from initial concept and theory to prototyping to final product development and commercialization. On the theoretical side, the journal features papers focusing on intelligent systems engineering, distributed intelligence systems, multi-level systems, intelligent control, multi-robot systems, cooperation and coordination of unmanned vehicle systems, etc. On the application side, the journal emphasizes autonomous systems, industrial robotic systems, multi-robot systems, aerial vehicles, mobile robot platforms, underwater robots, sensors, sensor-fusion, and sensor-based control. Readers will also find papers on real applications of intelligent and robotic systems (e.g., mechatronics, manufacturing, biomedical, underwater, humanoid, mobile/legged robot and space applications, etc.).