Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator

Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator

Pneumatic artificial muscle-based robotic systems usually necessitate the use of various nonlinear control techniques in order to improve their performance. Their robustness to parameter variation, which is generally difficult to predict, should also be tested. Here a fast hybrid adaptive control is...

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Main Authors: Alexander Hošovský, Jozef Novák-Marcinčin, Ján Pitel', Jana Boržíková, Kamil Židek
Format: Article
Language:English
Published: SAGE Publishing 2012-07-01
Series:International Journal of Advanced Robotic Systems
Online Access:https://doi.org/10.5772/50347
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spelling doaj-f3d2c47e6c1943d787d37b25194f3d812020-11-25T03:17:10ZengSAGE PublishingInternational Journal of Advanced Robotic Systems1729-88142012-07-01910.5772/5034710.5772_50347Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle ActuatorAlexander HošovskýJozef Novák-MarcinčinJán Pitel'Jana BoržíkováKamil ŽidekPneumatic artificial muscle-based robotic systems usually necessitate the use of various nonlinear control techniques in order to improve their performance. Their robustness to parameter variation, which is generally difficult to predict, should also be tested. Here a fast hybrid adaptive control is proposed, where a conventional PD controller is placed into the feedforward branch and a fuzzy controller is placed into the adaptation branch. The fuzzy controller compensates for the actions of the PD controller under conditions of inertia moment variation. The fuzzy controller of Takagi-Sugeno type is evolved through a genetic algorithm using the dynamic model of a pneumatic muscle actuator. The results confirm the capability of the designed system to provide robust performance under the conditions of varying inertia.https://doi.org/10.5772/50347
collection DOAJ
language English
format Article
sources DOAJ
author Alexander Hošovský
Jozef Novák-Marcinčin
Ján Pitel'
Jana Boržíková
Kamil Židek
spellingShingle Alexander Hošovský
Jozef Novák-Marcinčin
Ján Pitel'
Jana Boržíková
Kamil Židek
Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
International Journal of Advanced Robotic Systems
author_facet Alexander Hošovský
Jozef Novák-Marcinčin
Ján Pitel'
Jana Boržíková
Kamil Židek
author_sort Alexander Hošovský
title Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
title_short Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
title_full Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
title_fullStr Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
title_full_unstemmed Model-Based Evolution of a Fast Hybrid Fuzzy Adaptive Controller for a Pneumatic Muscle Actuator
title_sort model-based evolution of a fast hybrid fuzzy adaptive controller for a pneumatic muscle actuator
publisher SAGE Publishing
series International Journal of Advanced Robotic Systems
issn 1729-8814
publishDate 2012-07-01
description Pneumatic artificial muscle-based robotic systems usually necessitate the use of various nonlinear control techniques in order to improve their performance. Their robustness to parameter variation, which is generally difficult to predict, should also be tested. Here a fast hybrid adaptive control is proposed, where a conventional PD controller is placed into the feedforward branch and a fuzzy controller is placed into the adaptation branch. The fuzzy controller compensates for the actions of the PD controller under conditions of inertia moment variation. The fuzzy controller of Takagi-Sugeno type is evolved through a genetic algorithm using the dynamic model of a pneumatic muscle actuator. The results confirm the capability of the designed system to provide robust performance under the conditions of varying inertia.
url https://doi.org/10.5772/50347
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AT janpitel modelbasedevolutionofafasthybridfuzzyadaptivecontrollerforapneumaticmuscleactuator
AT janaborzikova modelbasedevolutionofafasthybridfuzzyadaptivecontrollerforapneumaticmuscleactuator
AT kamilzidek modelbasedevolutionofafasthybridfuzzyadaptivecontrollerforapneumaticmuscleactuator
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