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On the Tightness of the Balanced Truncation Error Bound with an Application to Arrowhead SystemsReiter, Sean Joseph 28 January 2022 (has links)
Balanced truncation model reduction for linear systems yields reduced-order models that satisfy a well-known error bound in terms of a system's Hankel singular values. This bound is known to hold with equality under certain conditions, such as when the full-order system is state-space symmetric.
In this work, we derive more general conditions in which the balanced truncation error bound holds with equality. We show that this holds for single-input, single-output systems that exhibit a generalized type of state-space symmetry based on the sign parameters corresponding to a system's Hankel singular values. We prove an additional result that shows how to determine this state-space symmetry from the arrowhead realization of a system, if available. In particular, we provide a formula for the sign parameters of an arrowhead system in terms of the off-diagonal entries of its arrowhead realization.
We then illustrate these results with an example of an arrowhead system arising naturally in power systems modeling that motivated our study. / Master of Science / Mathematical modeling of dynamical systems provides a powerful means for studying physical phenomena. Due the complexities of real-world problems, many mathematical models face computational difficulties due to the costs of accurate modeling. Model-order reduction of large-scale dynamical systems circumvents this by approximating the large-scale model with a ``smaller'' one that still accurately describes the problem of interest. Balanced truncation model reduction for linear systems is one such example, yielding reduced-order models that satisfy a tractable upper bound on the approximation error. This work investigates conditions in which this bound is known to hold with equality, becoming an exact formula for the error in reduction. We additionally show how to determine these conditions for a special class of linear dynamical systems known as arrowhead systems, which arise in special applications of network modeling. We provide an example of one such system from power systems modeling that motivated our study.
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Balanced Truncation Model Reduction of Large and Sparse Generalized Linear SystemsBadía, José M., Benner, Peter, Mayo, Rafael, Quintana-Ortí, Enrique S., Quintana-Ortí, Gregorio, Remón, Alfredo 26 November 2007 (has links) (PDF)
We investigate model reduction of large-scale linear time-invariant systems in
generalized state-space form. We consider sparse state matrix pencils, including
pencils with banded structure. The balancing-based methods employed here are
composed of well-known linear algebra operations and have been recently shown to be
applicable to large models by exploiting the structure of the matrices defining
the dynamics of the system.
In this paper we propose a modification of the LR-ADI iteration to solve
large-scale generalized Lyapunov equations together with a practical
convergence criterion, and several other implementation refinements.
Using kernels from several serial and parallel linear algebra libraries,
we have developed a parallel package for model reduction, SpaRed, extending
the applicability of balanced truncation to sparse systems with up to
$O(10^5)$ states.
Experiments on an SMP parallel architecture consisting of Intel Itanium 2 processors
illustrate the numerical performance of this approach and the potential of the
parallel algorithms for model reduction of large-scale sparse systems.
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Novel Model Reduction Techniques for Control of Machine ToolsBenner, Peter, Bonin, Thomas, Faßbender, Heike, Saak, Jens, Soppa, Andreas, Zaeh, Michael 13 November 2009 (has links) (PDF)
Computational methods for reducing the complexity of Finite Element (FE)
models in structural dynamics are usually based on modal analysis.
Classical approaches such as modal truncation, static condensation
(Craig-Bampton, Guyan), and component mode synthesis (CMS) are
available in many CAE tools such as ANSYS. In other disciplines, different
techniques for Model Order Reduction (MOR) have been developed in the
previous 2 decades. Krylov subspace methods are one possible
choice and often lead to much smaller models than modal truncation
methods given the same prescribed tolerance threshold. They have become
available to ANSYS users through the tool mor4ansys. A disadvantage
is that neither modal truncation nor CMS nor Krylov subspace methods
preserve properties important to control design. System-theoretic
methods like balanced truncation approximation (BTA), on the other
hand, are directed towards reduced-order models for use in closed-loop
control. So far, these methods are considered to be too expensive for
large-scale structural models. We show that recent algorithmic
advantages lead to MOR methods that are applicable to FE models in
structural dynamics and that can easily be integrated into CAE
software. We will demonstrate the efficiency of the proposed MOR
method based on BTA using a control system including as plant the FE
model of a machine tool.
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Gramian-Based Model Reduction for Data-Sparse SystemsBaur, Ulrike, Benner, Peter 27 November 2007 (has links) (PDF)
Model reduction is a common theme within the simulation, control and
optimization of complex dynamical systems. For instance, in control
problems for partial differential equations, the associated large-scale
systems have to be solved very often. To attack these problems in
reasonable time it is absolutely necessary to reduce the dimension of the
underlying system. We focus on model reduction by balanced truncation
where a system theoretical background provides some desirable properties
of the reduced-order system. The major computational task in
balanced truncation is the solution of large-scale Lyapunov equations,
thus the method is of limited use for really large-scale applications.
We develop an effective implementation of balancing-related model reduction
methods in exploiting the structure of the underlying problem.
This is done by a data-sparse approximation of the large-scale state
matrix A using the hierarchical matrix format. Furthermore, we integrate
the corresponding formatted arithmetic in the sign function method
for computing approximate solution factors of the Lyapunov equations.
This approach is well-suited for a class of practical relevant problems
and allows the application of balanced truncation and related methods
to systems coming from 2D and 3D FEM and BEM discretizations.
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Reduced-Order Reference Models for Adaptive Control of Space StructuresScherling, Alexander I. 01 June 2014 (has links)
In addition to serving as a brief overview of aspects relevant to reduced-order modeling (in particular balanced-state and modal techniques) as applied to structural finite element models, this work produced tools for visualizing the relationship between the modes of a model and the states of its balanced representation.
Specifically, error contour and mean error plots were developed that provide a designer with frequency response information absent from a typical analysis of a balanced model via its Hankel singular values. The plots were then used to analyze the controllability and observability aspects of finite element models of an illustrative system from a modal perspective -- this aided in the identification of computational artifacts in the models and helped predict points at which to halt the truncation of balanced states.
Balanced reduced-order reference models of the illustrative system were implemented as part of a direct adaptive control algorithm to observe the effectiveness of the models. It was learned that the truncation point selected by observing the mean error plot produced the most satisfactory results overall -- the model closely approximated the dominant modes of the system and eliminated the computational artifacts.
The problem of improving the performance of the system was also considered. The truncated balanced model was recast in modal form so that its damping could be increased, and the settling time decreased by about eighty percent.
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Reduced Order Controllers for Distributed Parameter SystemsEvans, Katie Allison 02 December 2003 (has links)
Distributed parameter systems (DPS) are systems defined on infinite dimensional spaces. This includes problems governed by partial differential equations (PDEs) and delay differential equations. In order to numerically implement a controller for a physical system we often first approximate the PDE and the PDE controller using some finite dimensional scheme. However, control design at this level will typically give rise to controllers that are inherently large-scale. This presents a challenge since we are interested in the design of robust, real-time controllers for physical systems. Therefore, a reduction in the size of the model and/or controller must take place at some point. Traditional methods to obtain lower order controllers involve reducing the model from that for the PDE, and then applying a standard control design technique. One such model reduction technique is balanced truncation. However, it has been argued that this type of method may have an inherent weakness since there is a loss of physical information from the high order, PDE approximating model prior to control design. In an attempt to capture characteristics of the PDE controller before the reduction step, alternative techniques have been introduced that can be thought of as controller reduction methods as opposed to model reduction methods. One such technique is LQG balanced truncation. Only recently has theory for LQG balanced truncation been developed in the infinite dimensional setting. In this work, we numerically investigate the viability of LQG balanced truncation as a suitable means for designing low order, robust controllers for distributed parameter systems. We accomplish this by applying both balanced reduction techniques, coupled with LQG, MinMax and central control designs for the low order controllers, to the cable mass, Klein-Gordon, and Euler-Bernoulli beam PDE systems. All numerical results include a comparison of controller performance and robustness properties of the closed loop systems. / Ph. D.
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The Search for a Reduced Order Controller: Comparison of Balanced Reduction TechniquesCamp, Katie A. E. 09 May 2001 (has links)
When designing a control for a physical system described by a PDE, it is often necessary to reduce the size of the controller for the PDE system. This is done so that real time control can be achieved. One approach often taken by engineers is to reduce the approximating finite-dimensional system using a balanced reduction method known as balanced truncation and then design a control for the lower order system. The unsettling idea about this method is that it involves discarding information and then designing a control. What if valuable physical information were lost that would have allowed a more effective control to be designed? This paper will explore an alternate balanced reduction method called LQG balancing. This approach allows for the designing of a control on the full order approximating system and then reducing the control. Along the way, the basic ideas of feedback control design will be discussed, including system balancing and model reduction. Following, there will be mention of the linear Klein-Gordon equation and the development of the one-dimensional finite element approximation of the PDE. Finally, simulations and numerical experiments are used to discuss the differences between the two balanced reduction methods. / Master of Science
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Parallel Order Reduction via Balanced Truncation for Optimal Cooling of Steel ProfilesBadía, José M., Benner, Peter, Mayo, Rafael, Quintana-Ortí, Enrique S., Quintana-Ortí, Gregorio, Saak, Jens 06 September 2006 (has links) (PDF)
We employ two efficient parallel approaches to reduce a model arising from a semi-discretization of a controlled heat transfer process for optimal cooling of a steel profile. Both algorithms are based on balanced truncation but differ in the numerical method that is used to solve two dual generalized Lyapunov equations, which is the major computational task. Experimental results on a cluster of Intel Xeon processors compare the efficacy of the parallel model reduction algorithms.
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Balanced Truncation Model Reduction of Large and Sparse Generalized Linear SystemsBadía, José M., Benner, Peter, Mayo, Rafael, Quintana-Ortí, Enrique S., Quintana-Ortí, Gregorio, Remón, Alfredo 26 November 2007 (has links)
We investigate model reduction of large-scale linear time-invariant systems in
generalized state-space form. We consider sparse state matrix pencils, including
pencils with banded structure. The balancing-based methods employed here are
composed of well-known linear algebra operations and have been recently shown to be
applicable to large models by exploiting the structure of the matrices defining
the dynamics of the system.
In this paper we propose a modification of the LR-ADI iteration to solve
large-scale generalized Lyapunov equations together with a practical
convergence criterion, and several other implementation refinements.
Using kernels from several serial and parallel linear algebra libraries,
we have developed a parallel package for model reduction, SpaRed, extending
the applicability of balanced truncation to sparse systems with up to
$O(10^5)$ states.
Experiments on an SMP parallel architecture consisting of Intel Itanium 2 processors
illustrate the numerical performance of this approach and the potential of the
parallel algorithms for model reduction of large-scale sparse systems.
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Gramian-Based Model Reduction for Data-Sparse SystemsBaur, Ulrike, Benner, Peter 27 November 2007 (has links)
Model reduction is a common theme within the simulation, control and
optimization of complex dynamical systems. For instance, in control
problems for partial differential equations, the associated large-scale
systems have to be solved very often. To attack these problems in
reasonable time it is absolutely necessary to reduce the dimension of the
underlying system. We focus on model reduction by balanced truncation
where a system theoretical background provides some desirable properties
of the reduced-order system. The major computational task in
balanced truncation is the solution of large-scale Lyapunov equations,
thus the method is of limited use for really large-scale applications.
We develop an effective implementation of balancing-related model reduction
methods in exploiting the structure of the underlying problem.
This is done by a data-sparse approximation of the large-scale state
matrix A using the hierarchical matrix format. Furthermore, we integrate
the corresponding formatted arithmetic in the sign function method
for computing approximate solution factors of the Lyapunov equations.
This approach is well-suited for a class of practical relevant problems
and allows the application of balanced truncation and related methods
to systems coming from 2D and 3D FEM and BEM discretizations.
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