Nonlinear control of a membrane mirror strip actuated axially and in bending
Nonlinear control of a membrane mirror strip actuated axially and in bending
The sliding mode technique is used to control the deformation of a membrane mirror strip augmented with two
macrofiber composite bimorphs located near the ends of the strip. The first bimorph is actuated in bending and the
second is actuated axially. The structure is modeled as an Euler–Bernoulli beam under tensile load and the
macrofiber composite patches are modeled as monolithic piezoceramic wafers. To cast the system into a finitedimensional
state-space form, the finite element method is used, and the model presented accounts for the dynamics
of the augmented bimorphs. The membrane strip is placed under uniform tension. Because one of the bimorphs acts
axially, the resulting tension in the membrane strip is discontinuous at the location of this bimorph and, consequently,
the obtained model is nonlinear. First, we validate the model experimentally by considering the system in its quasilinear
state, then we consider the control problem. We formulate the regulation problem by using the sliding mode
technique. Additionally, to allow coupling this system with an adaptive optics scheme, the shape-control problem is
considered as well. The control law uses both actuators: the bending and axial bimorphs. However, a system
singularity dictates using a switching command to avoid this singularity. Various examples are presented for the
regulation and shape-control problems. The simulation results demonstrate the efficacy of the proposed control law.
484-493
Renno, Jamil M.
132f3c49-a612-4ccc-8772-293c8e015d1c
Inman, Daniel J.
e7a193c3-1285-415c-9f40-404ce6823a7d
Chevva, Konda Reddy
555680bc-4afd-4ce0-8430-6b3f72a4c9d7
March 2009
Renno, Jamil M.
132f3c49-a612-4ccc-8772-293c8e015d1c
Inman, Daniel J.
e7a193c3-1285-415c-9f40-404ce6823a7d
Chevva, Konda Reddy
555680bc-4afd-4ce0-8430-6b3f72a4c9d7
Renno, Jamil M., Inman, Daniel J. and Chevva, Konda Reddy
(2009)
Nonlinear control of a membrane mirror strip actuated axially and in bending.
AIAA Journal, 47 (3), .
(doi:10.2514/1.31166).
Abstract
The sliding mode technique is used to control the deformation of a membrane mirror strip augmented with two
macrofiber composite bimorphs located near the ends of the strip. The first bimorph is actuated in bending and the
second is actuated axially. The structure is modeled as an Euler–Bernoulli beam under tensile load and the
macrofiber composite patches are modeled as monolithic piezoceramic wafers. To cast the system into a finitedimensional
state-space form, the finite element method is used, and the model presented accounts for the dynamics
of the augmented bimorphs. The membrane strip is placed under uniform tension. Because one of the bimorphs acts
axially, the resulting tension in the membrane strip is discontinuous at the location of this bimorph and, consequently,
the obtained model is nonlinear. First, we validate the model experimentally by considering the system in its quasilinear
state, then we consider the control problem. We formulate the regulation problem by using the sliding mode
technique. Additionally, to allow coupling this system with an adaptive optics scheme, the shape-control problem is
considered as well. The control law uses both actuators: the bending and axial bimorphs. However, a system
singularity dictates using a switching command to avoid this singularity. Various examples are presented for the
regulation and shape-control problems. The simulation results demonstrate the efficacy of the proposed control law.
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Published date: March 2009
Organisations:
Dynamics Group
Identifiers
Local EPrints ID: 71465
URI: http://eprints.soton.ac.uk/id/eprint/71465
ISSN: 0001-1452
PURE UUID: 322960b3-8bca-4b88-acfc-884c6b1be651
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Date deposited: 11 Feb 2010
Last modified: 13 Mar 2024 20:27
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Contributors
Author:
Jamil M. Renno
Author:
Daniel J. Inman
Author:
Konda Reddy Chevva
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