Observer-based finite-time time-varying elliptical formation control of a group mobile mecanum-wheeled omnidirectional vehicles for collaborative wildfire monitoring

IF 2.2 4区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS

IET Control Theory and Applications Pub Date : 2024-07-08 DOI:10.1049/cth2.12713

Joewell Mawanza

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Abstract

This article addresses the issue of collaborative wildfire monitoring using a group mobile mecanum-wheeled omnidirectional vehicles (MWOVs) affected by nonlinear uncertainties and external disturbances. By integrating finite-time extended state observers (FTESO) and backstepping nonsingular fast terminal sliding mode (BNFTSM) control method, an observer-based finite-time time-varying elliptical formation control scheme is proposed for a group of MWOVs tasked with monitoring the propagation of wildfires in an elliptical pattern. First, the FTESO is employed to estimate the unavailable velocity system states and the lumped disturbances. Then, a novel nonsingular fast terminal sliding surface, enhanced with an exponential term, is introduced to improve the convergence rate. Through the Lyapunov theorem, the convergence of position and velocity cooperative tracking errors to zero in fast finite-time is demonstrated. To showcase the effectiveness of the proposed control scheme, comparative simulation results are presented.

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基于观测器的有限时时变椭圆编队控制，用于协同野火监测的移动式机械轮全向车辆群

本文探讨了使用受非线性不确定性和外部干扰影响的移动式机械轮式全向车辆（MWOVs）进行野火协同监测的问题。通过集成有限时间扩展状态观测器（FTESO）和反步非奇异快速终端滑动模态（BNFTSM）控制方法，提出了一种基于观测器的有限时间时变椭圆编队控制方案，用于监测野火以椭圆模式传播的一组 MWOV。首先，采用 FTESO 估算不可用的速度系统状态和叠加干扰。然后，引入一个新颖的非奇异快速终端滑动面，并用指数项进行增强，以提高收敛速度。通过 Lyapunov 定理，证明了位置和速度协同跟踪误差在快速有限时间内收敛为零。为了展示所提控制方案的有效性，还给出了比较仿真结果。

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

IET Control Theory and Applications 工程技术-工程：电子与电气

CiteScore

5.70

自引率

7.70%

发文量

167

审稿时长

5.1 months

期刊介绍： IET Control Theory & Applications is devoted to control systems in the broadest sense, covering new theoretical results and the applications of new and established control methods. Among the topics of interest are system modelling, identification and simulation, the analysis and design of control systems (including computer-aided design), and practical implementation. The scope encompasses technological, economic, physiological (biomedical) and other systems, including man-machine interfaces. Most of the papers published deal with original work from industrial and government laboratories and universities, but subject reviews and tutorial expositions of current methods are welcomed. Correspondence discussing published papers is also welcomed. Applications papers need not necessarily involve new theory. Papers which describe new realisations of established methods, or control techniques applied in a novel situation, or practical studies which compare various designs, would be of interest. Of particular value are theoretical papers which discuss the applicability of new work or applications which engender new theoretical applications.