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Fast Fixed-Time Output Multi-Formation Tracking of Networked Autonomous Surface Vehicles: A Mathematical Induction Method

Teng‐Fei Ding, Kun-Ting Xu, Ming‐Feng Ge, Ju H. Park, Chang‐Duo Liang

2023IEEE Transactions on Vehicular Technology31 citationsDOIOpen Access PDF

Abstract

In this paper, we aim to exploit an effective way to solve the output multi-formation tracking problem of the networked autonomous surface vehicles (ASVs) in a fast fixed time manner. Specifically, addressing the output multi-formation tracking problem implies that 1) the networked ASVs are divided into multiple interconnected subnetworks with respect to multiple targets; 2) for each subnetwork, the outputs of the networked ASVs form a desired geometric formation with exchanging the local interactions. Besides, solving the fast fixed-time tracking problem in this paper implies that 1) the convergence time is independent of the initial conditions; 2) the system states are forced to reach the employed nonsingular fixed-time sliding surface in a prescribed time, which thus called fast fixed-time control. Then, based on a time-related function and a nonsingular fixed-time sliding surface, a hierarchical fast fixed-time control algorithm is proposed to solve the aforementioned problem within a fast fixed time being independent of the initial conditions. Furthermore, by employing the Lyapunov argument and mathematical induction, we present the sufficient conditions for fast fixed-time convergence of the tracking errors with respect to multiple targets. Finally, numerous simulation examples are presented to demonstrate the effectiveness of the proposed control algorithm.

Topics & Concepts

Control theory (sociology)SubnetworkConvergence (economics)Fixed pointLyapunov functionComputer scienceTracking (education)Invertible matrixNetwork packetSurface (topology)MathematicsMathematical optimizationControl (management)Nonlinear systemArtificial intelligenceComputer securityPure mathematicsEconomicsMathematical analysisPhysicsComputer networkPedagogyGeometryPsychologyEconomic growthQuantum mechanicsDistributed Control Multi-Agent SystemsAdaptive Control of Nonlinear SystemsUnderwater Vehicles and Communication Systems