Nonlinear robust heading control for sailing yachts

L. Xiao; T.I. Fossen; J. Jouffroy

doi:10.3182/20120919-3-IT-2046.00069

Nonlinear robust heading control for sailing yachts

L. Xiao
, T.I. Fossen
, J. Jouffroy

Syddansk Universitet
Norwegian University of Science and Technology

Publikation: Bidrag til bog/antologi/rapport › Konferenceartikel i proceeding › peer review

Abstract

In this paper, we present ℒ1 adaptive control theory to provide stabilization of the sailing yachts around any desired heading angle. The nonlinear heading model of the sailing yachts, which is presented in a recent paper, is expressed as a linear time-invariant system, i.e. the first-order Nomoto model, for which an ℒ1 adaptive heading controller is designed. A conventional PID heading controller is also constructed by pole-placement for the yacht system, and the previously presented backstepping controller is redesigned by adding an integral action. Afterwards, the performance achieved with the ℒ1 controller is compared with that obtained via the backstepping controller and the PID benchmark controller. Simulation results show that the ℒ1 heading controller ensures stable tracking and guarantees robustness. Furthermore, the performance of the ℒ1 surpasses that of the rest two controllers in terms of robustness.

Originalsprog	Udefineret/Ukendt
Titel	IFAC Proceedings Volumes (IFAC-PapersOnline)
Publikationsdato	2012
DOI	https://doi.org/10.3182/20120919-3-IT-2046.00069
Status	Udgivet - 2012
Udgivet eksternt	Ja

Emneord

Teknik, ingeniørvidenskab og IT
Control systems
L1 adaptive control
Sailing robotics

Adgang til dokumentet

10.3182/20120919-3-IT-2046.00069

Andre filer og links

https://www.scopus.com/pages/publications/84900479688

Citationsformater

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title = "Nonlinear robust heading control for sailing yachts",

abstract = "In this paper, we present ℒ1 adaptive control theory to provide stabilization of the sailing yachts around any desired heading angle. The nonlinear heading model of the sailing yachts, which is presented in a recent paper, is expressed as a linear time-invariant system, i.e. the first-order Nomoto model, for which an ℒ1 adaptive heading controller is designed. A conventional PID heading controller is also constructed by pole-placement for the yacht system, and the previously presented backstepping controller is redesigned by adding an integral action. Afterwards, the performance achieved with the ℒ1 controller is compared with that obtained via the backstepping controller and the PID benchmark controller. Simulation results show that the ℒ1 heading controller ensures stable tracking and guarantees robustness. Furthermore, the performance of the ℒ1 surpasses that of the rest two controllers in terms of robustness.",

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doi = "10.3182/20120919-3-IT-2046.00069",

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AU - Xiao, L.

AU - Fossen, T.I.

AU - Jouffroy, J.

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AB - In this paper, we present ℒ1 adaptive control theory to provide stabilization of the sailing yachts around any desired heading angle. The nonlinear heading model of the sailing yachts, which is presented in a recent paper, is expressed as a linear time-invariant system, i.e. the first-order Nomoto model, for which an ℒ1 adaptive heading controller is designed. A conventional PID heading controller is also constructed by pole-placement for the yacht system, and the previously presented backstepping controller is redesigned by adding an integral action. Afterwards, the performance achieved with the ℒ1 controller is compared with that obtained via the backstepping controller and the PID benchmark controller. Simulation results show that the ℒ1 heading controller ensures stable tracking and guarantees robustness. Furthermore, the performance of the ℒ1 surpasses that of the rest two controllers in terms of robustness.

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