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Computational effectiveness of LMI design strategies for vibration control of large structures

Author
Palacios-Quiñonero, F.; Rubió-Massegú, J.; Rossell, Josep M.; Karimi, H.R.
Type of activity
Presentation of work at congresses
Name of edition
VII European Congress on Computational Methods in Applied Sciences and Engineering
Date of publication
2016
Presentation's date
2016-06-06
Book of congress proceedings
VII European Congress on Computational Methods in Applied Sciences and Engineering (ECCOMAS 2016): Crete, Greece: June 5-10, 2016: proceedings
First page
1
Last page
13
Project funding
Design of advanced control strategies and fault detection for complex mechatronic systems
Repository
http://hdl.handle.net/2117/98633 Open in new window
URL
https://www.eccomas2016.org/proceedings/ Open in new window
Abstract
Distributed control systems for vibration control of large structures involve a large number of actuation devices and sensors that work coordinately to produce the desired control actions. Design strategies based on linear matrix inequality (LMI) formulations allow obtaining controllers for these complex control problems, which are characterized by large dimensionality, high computational cost and severe information constraints. In this paper, we conduct a comparative study of the computational ...
Citation
Palacios-Quiñonero, F., Rubió-Massegú, J., Rossell, Josep M., Karimi, H.R. Computational effectiveness of LMI design strategies for vibration control of large structures. A: European Congress on Computational Methods in Applied Sciences and Engineering. "ECCOMAS 2016: proceedings, June 5-10 2016, Crete, Greece". Crete: 2016, p. 1-13.
Keywords
Computational effectiveness, Linear matrix inequalities, Seismic protection, Structural vibration control
Group of research
CoDAlab - Control, Dynamics and Applications

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