Add to ORKGIn this paper, fast and accurate trajectory tracking control of an autonomous surface vehicle (ASV) with complex unknowns including unmodeled dynamics, uncertainties and/or unknown disturbances is addressed within a proposed homogeneity-based finite-time control (HFC) framework. Major contributions are as follows: (1) In the absence of external disturbances, a nominal HFC framework is established to achieve exact trajectory tracking control of an ASV, whereby global finitetime stability is ensured by combining homogeneous analysis and Lyapunov approach; (2) Within the HFC scheme, a finite-time disturbance observer (FDO) is further nested to rapidly and accurately reject complex disturbances, and thereby contributing to an FDO-based HFC (FDO...
ObjectivesUnder complex environmental conditions, unmanned surface vehicles (USVs) may deviate from ...
This brief considers the problem of trajectory tracking control for marine surface vessels with unkn...
This chapter proposes a nonlinear robust H-infinity control approach to enhance the trajectory-follo...
2510-2518In this paper, disturbance/uncertainty estimation based approaches are developed to achieve...
The issue of fixed-time trajectory tracking control for the autonomous surface vehicles (ASVs) syste...
In this paper, accurate trajectory tracking problem of a surface vehicle disturbed by complex marine...
2493-2501In this paper, subject to input saturations and unknown disturbances, finite-time trajector...
To achieve a fully autonomous navigation for unmanned surface vessels (USVs), a robust control capab...
The aim of this study is to achieve the trajectory-tracking control of an autonomous underwater vehi...
In this paper, under parametric uncertainties and complex disturbances, a leader–follower formation ...
This paper focuses on an issue involving robust adaptive path following for the uncertain underactua...
53rd IEEE Annual Conference on Decision and Control, CDC 2014; JW Marriott Hotel Los Angeles L.A.; U...
1028-1036A robust model-free path following controller is developed for autonomous surface vehicle (...
In this paper, we present a control strategy for trajectory tracking and path following of generic p...
1048-1055Subject to harsh ocean environment, a novel path following control scheme with accurate gui...
ObjectivesUnder complex environmental conditions, unmanned surface vehicles (USVs) may deviate from ...
This brief considers the problem of trajectory tracking control for marine surface vessels with unkn...
This chapter proposes a nonlinear robust H-infinity control approach to enhance the trajectory-follo...
2510-2518In this paper, disturbance/uncertainty estimation based approaches are developed to achieve...
The issue of fixed-time trajectory tracking control for the autonomous surface vehicles (ASVs) syste...
In this paper, accurate trajectory tracking problem of a surface vehicle disturbed by complex marine...
2493-2501In this paper, subject to input saturations and unknown disturbances, finite-time trajector...
To achieve a fully autonomous navigation for unmanned surface vessels (USVs), a robust control capab...
The aim of this study is to achieve the trajectory-tracking control of an autonomous underwater vehi...
In this paper, under parametric uncertainties and complex disturbances, a leader–follower formation ...
This paper focuses on an issue involving robust adaptive path following for the uncertain underactua...
53rd IEEE Annual Conference on Decision and Control, CDC 2014; JW Marriott Hotel Los Angeles L.A.; U...
1028-1036A robust model-free path following controller is developed for autonomous surface vehicle (...
In this paper, we present a control strategy for trajectory tracking and path following of generic p...
1048-1055Subject to harsh ocean environment, a novel path following control scheme with accurate gui...
ObjectivesUnder complex environmental conditions, unmanned surface vehicles (USVs) may deviate from ...
This brief considers the problem of trajectory tracking control for marine surface vessels with unkn...
This chapter proposes a nonlinear robust H-infinity control approach to enhance the trajectory-follo...