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Distributed Path Following of Multiple Under-Actuated Autonomous Surface Vehicles Based on Data-Driven Neural Predictors via Integral Concurrent Learning

Lu Liu, Dan Wang, Zhouhua Peng, Qing‐Long Han

2021IEEE Transactions on Neural Networks and Learning Systems141 citationsDOI

Abstract

This article addresses the problem of distributed path following of multiple under-actuated autonomous surface vehicles (ASVs) with completely unknown kinetic models. An integrated distributed guidance and learning control architecture is proposed for achieving a time-varying formation. Specifically, a robust distributed guidance law at the kinematic level is developed based on a consensus approach, a path-following mechanism, and an extended state observer. At the kinetic level, a model-free kinetic control law based on data-driven neural predictors via integral concurrent learning is designed such that the kinetic model can be learned by using recorded data. The advantage of the proposed method is two-folds. First, the proposed formation controllers are able to achieve various time-varying formations without using the velocities of neighboring vehicles. Second, the proposed control law is model-free without any parameter information on kinetic models. Simulation results substantiate the effectiveness of the proposed robust distributed guidance and model-free control laws for multiple under-actuated ASVs with fully unknown kinetic models.

Topics & Concepts

KinematicsObserver (physics)Control theory (sociology)Computer sciencePath (computing)Surface (topology)Kinetic energyControl (management)Control engineeringArtificial intelligenceEngineeringMathematicsPhysicsGeometryProgramming languageClassical mechanicsQuantum mechanicsDistributed Control Multi-Agent SystemsAdaptive Control of Nonlinear SystemsGuidance and Control Systems
Distributed Path Following of Multiple Under-Actuated Autonomous Surface Vehicles Based on Data-Driven Neural Predictors via Integral Concurrent Learning | Litcius