Feedback linearization approach to distributed feedback manipulation

Author

Hurak, Zdenek ; Zemanek, Jiri

Author_Institution

Dept. of Control Eng., Czech Tech. Univ. in Prague, Prague, Czech Republic

fYear

2012

fDate

27-29 June 2012

Firstpage

991

Lastpage

996

Abstract

This report formulates the problem of a distributed planar manipulation realized by shaping a spatially continuous force field. It also suggests a control strategy based on feedback linearization. Force fields derived from potential fields are considered. The potentials are “shaped” by a set of spatially discrete “actuators“ such as electrodes in the case of dielectrophoresis, electromagnets in the case of planar magnetic manipulators, or linear piezoelectric actuators in the case of deformable flat surfaces. The actuators form arrays. Distinguished feature of such force fields is that the contribution from an individual actuator usually affects the situation in the neighboring zones too, but usually not in too remote zones. As an idealization, the spatial domain is considered unbounded, which enables examination of asymptotic behavior of the manipulation scheme.

Keywords

distributed control; feedback; linearisation techniques; microactuators; micromanipulators; asymptotic behavior; control strategy; dielectrophoresis; distributed feedback manipulation; distributed planar manipulation; electrodes; electromagnets; feedback linearization approach; linear piezoelectric actuators; planar magnetic manipulators; potential fields; spatially continuous force field shaping; spatially discrete actuators; unbounded spatial domain; Actuators; Electric potential; Electrodes; Force; Magnetic domains; Mathematical model; Shape;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference (ACC), 2012

Conference_Location

Montreal, QC

ISSN

0743-1619

Print_ISBN

978-1-4577-1095-7

Electronic_ISBN

0743-1619

Type

conf

DOI

10.1109/ACC.2012.6315262

Filename

6315262