具有控制饱和度的自主地面飞行器的基于 PID 路径跟踪控制的鲁棒 $H_\infty$ 容错观测器

IF 5.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Bor-Sen Chen;Hao-Ting Liu;Ruei-Syuan Wu
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引用次数: 0

摘要

本研究为自主地面车辆(AGV)提出了一种基于观测器的鲁棒 PID 路径跟踪控制策略,以有效减弱外部干扰、致动器/传感器故障信号和控制饱和的影响,从而实现鲁棒路径跟踪设计。为简化设计程序,提出了一种新颖的基于路径参考的前馈线性化方案,将非线性动态 AGV 系统转换为具有非线性致动器信号的等效线性跟踪误差系统。为了保护 AGV 系统免受致动器/传感器故障信号的破坏,引入了两个平滑信号模型来精确估计这些故障信号,以补偿它们的破坏。此外,所提出的基于观测器的 $H_\infty$ AGV 系统容错 PID 路径跟踪控制策略可以转化为等效的双线性矩阵不等式(BMI)。因此,通过所提出的两步法,可以将复杂的 BMI 转化为两个线性矩阵不等式(LMI),这些不等式可以通过 MATLAB 中的 LMI TOOLBOX 轻松求解。因此,还考虑了控制限制,以满足物理执行器饱和对 PID 控制器的约束,使提出的控制方案更加适用。最后,以 AGV 的三车道转换任务为例进行了仿真,以说明设计过程并验证所提设计方法的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Robust $H_\infty$ Fault-Tolerant Observer-Based PID Path Tracking Control of Autonomous Ground Vehicle With Control Saturation
In this study, a robust $H_\infty$ observer-based PID path tracking control strategy is proposed for Autonomous Ground Vehicle (AGV) to efficiently attenuate the effect of external disturbance, actuator/sensor fault signals, and control saturation to achieve the robust path tracking design. To simplify the design procedure, a novel path reference-based feedforward linearization scheme is proposed to transform nonlinear dynamic AGV system to an equivalent linear tracking error system with nonlinear actuator signal. To protect the AGV system from the corruption of actuator/sensor fault signals, two smoothed signal models are introduced to precisely estimate these fault signals to compensate their corruption. Further, the proposed $H_\infty$ fault-tolerant observer-based PID path tracking control strategy of AGV system can be transformed to an equivalent bilinear matrix inequality (BMI). Consequently, by the proposed two-step method, the complex BMI can be transformed into two linear matrix inequalities (LMIs), which can be easily solved via LMI TOOLBOX in MATLAB. Therefore, control restriction is also considered to meet the constraints of physical actuator saturation on PID controller, making the proposed control scheme more applicable. Finally, the triple-lane change task of AGV is simulated as a numerical example to illustrate the design procedure and to validate the performance of proposed design method.
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来源期刊
CiteScore
9.60
自引率
0.00%
发文量
25
审稿时长
10 weeks
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