ACTIVE STRUCTURAL ENHANCEMENT RESEARCH
MEMS BASED ACTIVE STABILIZATION OF STRUCTURES
This research is part of a wider investigation of how we can use
smart materials to "couple computation to the real world". Hence this
work involves the integration of sensing, computation, and actuation
to the physical world. The results are artifacts that can loosely be
defined as "smart matter", which are essentially things that can
adaptively modify their physical behavior to achieve desired
performance.
Active structural enhancement consists of the use of active
control to modify structural behavior. This enhancement can be used
to actively stiffen, or strengthen (against Euler buckling) a given
structure. Therefore, actively controlled structures can adaptively
modify their stiffness properties to be either stiff or flexible as
demanded. This research investigates optimal closed-loop control
strategies to maximize the critical buckling load of a pinned-end
column using MEMS based sensors and actuators. In this instance,
active control is employed to actively stabilize a structural member
to prevent it from collapsing. From a controls standpoint this
problem consists of developing control strategies for a time-varying,
inherently unstable system.
The project is a joint effort between
PARC and the
Sarcos Research Corp. The PARC team
includes Andy Berlin (PI),
Geoff Chase,
Mark Yim, and
Prof. Feng Zhao.
This page is organized as follows:
Experimental Setup
Control Architectures and Experiments
Notable Results
Future Work
Acknowledgments
Experimental Setup
This project integrates PZT (piezo-ceramic) actuators and MEMS based UAST
strain sensors with a structural beam element to control linear buckling
phenomena. Using optimal feedback control strategies we have been able to
increase the buckling load of this column by 2.9 times. The picture shows the
beam and fixture apparatus. The filament based PZT actuators and the UAST
sensors are both technologies developed by
Sarcos. The combination of smart material
actuators and MEMS based UAST sensors with external computation emulates
smart matter.
The beam is clamped vertically within the test fixture which allows
us to apply a compressive axial load to the pinned-end beam. The load
is applied mechanically using a load arm (shown in the foreground) and
a moving weight. The weight is driven by a motor under computer
control so that load may be applied dynamically.
The picture on the right shows UAST strain sensors (the little
black boxes) and filament PZT patches between them. The beam material
is G10 fiberglass composite. For reference, the beam is 18 inches
long, 2 inches wide and 0.093 inches thick.
The UAST's sense strain with an accuracy of 3 micro-strain. Nine
pairs are attached to this beam to determine bending strains.
Structural deformation and can be determined from these measurements.
The PZT patches are used as actuators for the control
system. Voltages applied to the PZT enable it to expand or contract,
creating surface strains on the beam. Eight pairs of PZT patches
create bending strains which are applied as the control input. The
control is implemented with a servo rate of 1000Hz using a PC and a TI
DSP card.
The following animation shows the beam under control in both its straight position
and the buckled position.
Control Architectures and Experiments
Several control strategies were developed and implemented for this beam. The
general goal is to minimize deviation from the straight position at all times.
The specific controllers developed include:
- Optimal buckling control (MIMO)
- Sliding mode control (SISO on first mode)
- Modal PID
- Local PD
Optimal buckling control uses semi-definite programming (SDP) to optimally
specify the first critical buckling load and the structural damping. As such,
multiple modes can be controlled.
A finite element model was used to define the eigenvalue problems used in the
optimization. This optimization problem is convex, and easily solved using
SDPSOL.
The Modal PID controller is a SISO controller based on controlling
only the first buckling mode. This controller could be modified to
control additional modes under the assumption that they are decoupled.
The Local PD controller used only local sensor measurements to
determine the associated local actuation. This controller's objective
was to minimize local response in maintaining beam stability. This collection of controllers
represents a wide range in the number of inputs and outputs, and in global/local
control design.
All of these controllers were tested on the experimental apparatus. The
maximum axial load achieved was 2.9 times the critical buckling load
(PCR). These controllers supported all loads up to and including this
value, where the load was steadily increased using the load arm
mechanism. At loads lower than this value, the beam was able to
support the load indefinitely (>30 minutes). The optimal buckling
control was robust to sensor noise, adequately supporting the beam
even when a sensor failed.
We were unable to determine which controller was best, because no
controller outperformed the others. This result is due to problems
with fixturing, beam imperfections, and external disturbances which
caused the beam to buckle before the full actuator authority was used. As part of
future work we will be examining new fixturing methods to eliminate this effect.
Notable Results
This project has made several notable achievements :
- Beam stabilized from tension to 2.9PCR
- Axial load applied dynamically over the whole range.
- Continuously stable at lower axial loads.
- Optimal controller design
- Optimal MIMO buckling controller - first such controller as far as we can
determine from the literature
- can specify desired buckling load
- buckling load obtained in implementation dependent on actuator authority.
- Design method generalizable to any structural eigenvalue problem
- Stability verified using Lyapunov methods
- Application using MEMS
- Precision of 3 micro-strain MEMS based UAST sensors enabling higher buckling
load than might be obtained with standard 20 micro-strain strain guage.
- First experimental use of MEMS filament based PZT actuators.
- Fast sensor processing in hardware and software enables 1000Hz servo-rate.
- Coordinated 9 sensor pairs 8 actuator pairs with optimal feedback (340 gains)
Future Work
The future directions of this project will focus on two main areas. The
first is controlling buckling for a greater number of physical
dimensions and the second is greater control decentralization. The
current project stabilized buckling for a single dimension. The next
step is to generalize this work to multiple dimensions such as plate,
shell, and compound structures. This generalization will require much
larger numbers of sensors and actuators. Control
decentralization is required for systems with greater numbers of
sensors and actuators to avoid the communications and processing
bottlenecks, and design intractability of a global controller.
Other topics include:
- Integrated electronics to create "true" smart matter.
- Develop design trade-off curves for particular structural applications to examine
the application domain.
- New or modified fixturing for the single column experiment.
Acknowledgments
This research is the result of a collaboration between
Sarcos Research Corporation
and
Xerox Palo Alto Research Center.
The project or effort depicted is sponsored
in part under contracts DABT63-95-C-0025 and DABT63-95-C-0033 by the Defense Advanced
Reserach Projects Agency
(DARPA).
The content of the information does not
necessarily reflect the position or the policy of the Government and no official
endorsement should be inferred.
last modified January 13, 1997