Los puntos clave no están disponibles para este artículo en este momento.
In this article, a finite-time line-of-sight-based control (FTLC) scheme is presented for path following of unmanned surface vessels (USV) subject to unknown time-varying sideslip angles and input saturation as well as uncertainties induced by unknown internal dynamics and external disturbances. Specifically, finite-time observers (FTOBs) are introduced to acquire the sideslip angle and kinetic uncertainties. Finite-time line-of-sight guidance is developed by incorporating the FTOB and fractional power techniques. The profile of desired surge velocity is designed based on the hyperbolic tangent function of cross-track error. Nonlinear feedback is then introduced to attenuate the overshoot of surge velocity. Finite-time stability auxiliary systems are designed using fractional power to compensate for actuator constraints with finite-time convergence. The proposed FTLC scheme enables a USV to reach and follow a predefined path while satisfying spatial and dynamical specifications and obtaining finite-time stability and small overshoot in the presence of actuator limitations and uncertainties. All errors in the closed-loop system of USV converge to an arbitrarily small neighborhood of the origin within a finite settling time, which still holds in the presence of unpredictable errors. Three USV cases and ten simulation groups are included to demonstrate the effective performance of the FTLC.
Yu et al. (Wed,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: