Cover Image

On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.

Classical sliding mode controller is robust to model uncertainties and external disturbances. A sliding mode control method with a switching control low guarantees asymptotic stability of the system, but the addition of the switching control law introduces chattering in to the system. One way of att...

Full description

Saved in:
Bibliographic Details
Main Authors: Sulaiman, Nasri, Piltan, Farzin, Gavahian, Atefeh, Roosta, Samaneh, Soltani, Samira
Format: Article
Language:English
Published: 2011
Online Access:http://psasir.upm.edu.my/id/eprint/23363/
http://www.academia.edu/5550457/On_line_Tuning_Premise_and_Consequence_FIS_Design_Fuzzy_Adaptive_Fuzzy_Sliding_Mode_Controller_Based_on_Lyaponuv_Theory
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.upm.eprints.23363
record_format eprints
spelling my.upm.eprints.233632014-09-10T04:34:15Z http://psasir.upm.edu.my/id/eprint/23363/ On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory. Sulaiman, Nasri Piltan, Farzin Gavahian, Atefeh Roosta, Samaneh Soltani, Samira Classical sliding mode controller is robust to model uncertainties and external disturbances. A sliding mode control method with a switching control low guarantees asymptotic stability of the system, but the addition of the switching control law introduces chattering in to the system. One way of attenuating chattering is to insert a saturation function inside of a boundary layer around the sliding surface. Unfortunately, this addition disrupts Lyapunov stability of the closed-loop system. Classical sliding mode control method has difficulty in handling unstructured model uncertainties. One can overcome this problem by combining a sliding mode controller and fuzzy system together. Fuzzy rules allow fuzzy systems to approximate arbitrary continuous functions. To approximate a time-varying nonlinear system, a fuzzy system requires a large amount of fuzzy rules. This large number of fuzzy rules will cause a high computation load. The addition of an adaptive law to a fuzzy sliding mode controller to online tune the parameters of the fuzzy rules in use will ensure a moderate computational load. Refer to this research; tuning methodology can online adjust both the premise and the consequence parts of the fuzzy rules. Since this algorithm for is specifically applied to a robot manipulator. 2011 Article PeerReviewed Sulaiman, Nasri and Piltan, Farzin and Gavahian, Atefeh and Roosta, Samaneh and Soltani, Samira (2011) On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory. International Journal of Robotics and Automation, 2 (5). pp. 386-404. ISSN 2180-1312 http://www.academia.edu/5550457/On_line_Tuning_Premise_and_Consequence_FIS_Design_Fuzzy_Adaptive_Fuzzy_Sliding_Mode_Controller_Based_on_Lyaponuv_Theory English
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
description Classical sliding mode controller is robust to model uncertainties and external disturbances. A sliding mode control method with a switching control low guarantees asymptotic stability of the system, but the addition of the switching control law introduces chattering in to the system. One way of attenuating chattering is to insert a saturation function inside of a boundary layer around the sliding surface. Unfortunately, this addition disrupts Lyapunov stability of the closed-loop system. Classical sliding mode control method has difficulty in handling unstructured model uncertainties. One can overcome this problem by combining a sliding mode controller and fuzzy system together. Fuzzy rules allow fuzzy systems to approximate arbitrary continuous functions. To approximate a time-varying nonlinear system, a fuzzy system requires a large amount of fuzzy rules. This large number of fuzzy rules will cause a high computation load. The addition of an adaptive law to a fuzzy sliding mode controller to online tune the parameters of the fuzzy rules in use will ensure a moderate computational load. Refer to this research; tuning methodology can online adjust both the premise and the consequence parts of the fuzzy rules. Since this algorithm for is specifically applied to a robot manipulator.
format Article
author Sulaiman, Nasri
Piltan, Farzin
Gavahian, Atefeh
Roosta, Samaneh
Soltani, Samira
spellingShingle Sulaiman, Nasri
Piltan, Farzin
Gavahian, Atefeh
Roosta, Samaneh
Soltani, Samira
On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
author_facet Sulaiman, Nasri
Piltan, Farzin
Gavahian, Atefeh
Roosta, Samaneh
Soltani, Samira
author_sort Sulaiman, Nasri
title On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
title_short On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
title_full On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
title_fullStr On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
title_full_unstemmed On line Tuning Premise and Consequence FIS: Design Fuzzy Adaptive Fuzzy Sliding Mode Controller based on Lyaponuv Theory.
title_sort on line tuning premise and consequence fis: design fuzzy adaptive fuzzy sliding mode controller based on lyaponuv theory.
publishDate 2011
url http://psasir.upm.edu.my/id/eprint/23363/
http://www.academia.edu/5550457/On_line_Tuning_Premise_and_Consequence_FIS_Design_Fuzzy_Adaptive_Fuzzy_Sliding_Mode_Controller_Based_on_Lyaponuv_Theory
_version_ 1643828035885989888
score 13.160551

Similar Items