A polynomial LPV approach for flexible robot end-effector position controller analysis

Author

Halalchi, Houssem ; Laroche, Edouard ; Bara, G. Iuliana

Author_Institution

LSIIT Lab., Univ. of Strasbourg, Illkirch, France

fYear

2011

fDate

12-15 Dec. 2011

Firstpage

3764

Lastpage

3769

Abstract

This paper presents an application of polynomial linear parameter varying (LPV) methods based on matrix sum-of-squares (SOS) relaxations for the end-effector position controller analysis of flexible-link manipulators. The proposed approach exploits an effective way for solving polynomial parameter-dependent linear matrix inequalities (PD-LMIs) and allows to consider more general admissible sets than hyper-rectangles or convex polytopes. This leads to less conservative results when considering an H_∞ output feedback controlled system. In particular, some performance analysis results are presented. A practical case study shows the effectiveness of the proposed methodology.

Keywords

H^∞ control; end effectors; feedback; flexible manipulators; linear matrix inequalities; linear systems; polynomials; position control; H∞ output feedback controlled system; PD-LMI; SOS relaxation; convex polytope; flexible robot end-effector; flexible-link manipulator; hyper-rectangle; linear parameter varying method; matrix sum-of-squares relaxation; polynomial LPV approach; polynomial parameter-dependent linear matrix inequalities; position controller analysis; Matrix decomposition; Performance analysis; Polynomials; Robots; Strontium; Symmetric matrices; Vectors;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control and European Control Conference (CDC-ECC), 2011 50th IEEE Conference on

Conference_Location

Orlando, FL

ISSN

0743-1546

Print_ISBN

978-1-61284-800-6

Electronic_ISBN

0743-1546

Type

conf

DOI

10.1109/CDC.2011.6161057

Filename

6161057