Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine

Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine

This work is focused on the improvement of variable-speed variable-pitch wind turbine performance by means of its control structure. This kind of systems can be considered as multivariable nonlinear processes subjected to undesired interactions between variables and presenting different dynamics at...

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Main Authors: Sergio Fragoso, Juan Garrido, Francisco Vázquez, Fernando Morilla
Format: Article
Language:English
Published: MDPI AG 2017-04-01
Series:Sustainability
Subjects:
decoupling networks
multivariable control
robust control
lab-scale VS-VP wind turbine
Online Access:http://www.mdpi.com/2071-1050/9/5/713
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spelling doaj-d47ed7b790654a5d9d1ab74c8381963d2020-11-24T20:59:00ZengMDPI AGSustainability2071-10502017-04-019571310.3390/su9050713su9050713Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind TurbineSergio Fragoso0Juan Garrido1Francisco Vázquez2Fernando Morilla3Department of Computer Science and Numerical Analysis, Universidad de Córdoba, Campus de Rabanales, 14071 Cordoba, SpainDepartment of Computer Science and Numerical Analysis, Universidad de Córdoba, Campus de Rabanales, 14071 Cordoba, SpainDepartment of Computer Science and Numerical Analysis, Universidad de Córdoba, Campus de Rabanales, 14071 Cordoba, SpainDepartment of Computer Science and Automatic Control, Universidad Nacional de Educación a Distancia, Juan del Rosal 16, 28040 Madrid, SpainThis work is focused on the improvement of variable-speed variable-pitch wind turbine performance by means of its control structure. This kind of systems can be considered as multivariable nonlinear processes subjected to undesired interactions between variables and presenting different dynamics at different operational zones. This interaction level and the dynamics uncertainties complicate the control system design. The aim of this work is developing multivariable controllers that cope with such problems. The study shows the applicability of different decoupling methodologies and provides a comparison with a H∞ controller, which is an appropriate strategy to cope with uncertainties. The methodologies have been tested in simulation and verified experimentally in a lab-scale wind turbine. It is demonstrated that the wind turbine presents more interaction at the transition zone. Then, this operational point is used as the nominal one for the controller designs. At this point, decoupling controllers obtain perfect decoupling while the H∞ control presents important interaction in the generated power loop. On the other hand, they are slightly surpassed by the robust design at other points, where perfect decoupling is not achieved. However, decoupling controllers are easier to design and implement, and specifically dynamic simplified decoupling achieve the best global response. Then, it is concluded that the proposed methodologies can be considered for implantation in industrial wind turbines to improve their performance.http://www.mdpi.com/2071-1050/9/5/713decoupling networksmultivariable controlrobust controllab-scale VS-VP wind turbine
collection DOAJ
language English
format Article
sources DOAJ
author Sergio Fragoso
Juan Garrido
Francisco Vázquez
Fernando Morilla
spellingShingle Sergio Fragoso
Juan Garrido
Francisco Vázquez
Fernando Morilla
Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
Sustainability
decoupling networks
multivariable control
robust control
lab-scale VS-VP wind turbine
author_facet Sergio Fragoso
Juan Garrido
Francisco Vázquez
Fernando Morilla
author_sort Sergio Fragoso
title Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
title_short Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
title_full Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
title_fullStr Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
title_full_unstemmed Comparative Analysis of Decoupling Control Methodologies and H∞ Multivariable Robust Control for Variable-Speed, Variable-Pitch Wind Turbines: Application to a Lab-Scale Wind Turbine
title_sort comparative analysis of decoupling control methodologies and h∞ multivariable robust control for variable-speed, variable-pitch wind turbines: application to a lab-scale wind turbine
publisher MDPI AG
series Sustainability
issn 2071-1050
publishDate 2017-04-01
description This work is focused on the improvement of variable-speed variable-pitch wind turbine performance by means of its control structure. This kind of systems can be considered as multivariable nonlinear processes subjected to undesired interactions between variables and presenting different dynamics at different operational zones. This interaction level and the dynamics uncertainties complicate the control system design. The aim of this work is developing multivariable controllers that cope with such problems. The study shows the applicability of different decoupling methodologies and provides a comparison with a H∞ controller, which is an appropriate strategy to cope with uncertainties. The methodologies have been tested in simulation and verified experimentally in a lab-scale wind turbine. It is demonstrated that the wind turbine presents more interaction at the transition zone. Then, this operational point is used as the nominal one for the controller designs. At this point, decoupling controllers obtain perfect decoupling while the H∞ control presents important interaction in the generated power loop. On the other hand, they are slightly surpassed by the robust design at other points, where perfect decoupling is not achieved. However, decoupling controllers are easier to design and implement, and specifically dynamic simplified decoupling achieve the best global response. Then, it is concluded that the proposed methodologies can be considered for implantation in industrial wind turbines to improve their performance.
topic decoupling networks
multivariable control
robust control
lab-scale VS-VP wind turbine
url http://www.mdpi.com/2071-1050/9/5/713
work_keys_str_mv AT sergiofragoso comparativeanalysisofdecouplingcontrolmethodologiesandhmultivariablerobustcontrolforvariablespeedvariablepitchwindturbinesapplicationtoalabscalewindturbine
AT juangarrido comparativeanalysisofdecouplingcontrolmethodologiesandhmultivariablerobustcontrolforvariablespeedvariablepitchwindturbinesapplicationtoalabscalewindturbine
AT franciscovazquez comparativeanalysisofdecouplingcontrolmethodologiesandhmultivariablerobustcontrolforvariablespeedvariablepitchwindturbinesapplicationtoalabscalewindturbine
AT fernandomorilla comparativeanalysisofdecouplingcontrolmethodologiesandhmultivariablerobustcontrolforvariablespeedvariablepitchwindturbinesapplicationtoalabscalewindturbine
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