Model Reduction for Active Control Design Using Multiple-Point Arnoldi Methods

Lassaux, Guillaume; Willcox, Karen

doi:10.2514/6.2003-616

Cited by 11 publications

(15 citation statements)

References 17 publications

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“…see [26,27]. One obvious disadvantage of this approach is that the dimension of the resulting reduced-order model is doubled to 2n.…”

Section: Complex Expansion Pointsmentioning

confidence: 99%

Recent Advances in Structure-Preserving Model Order Reduction

Freund

2011

Simulation and Verification of Electronic and Biological Systems

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In recent years, model order reduction techniques based on Krylov subspaces have become the methods of choice for generating small-scale macromodels of the large-scale multi-port RCL networks that arise in VLSI interconnect analysis. A difficult and not yet completely resolved issue is how to ensure that the resulting macromodels preserve all the relevant structures of the original large-scale RCL networks. In this paper, we present a brief review of how Krylov subspace techniques emerged as the algorithms of choice in VLSI circuit simulation, describe the current state-of-art of structure preservation, discuss some recent advances, and mention open problems.

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“…see [26,27]. One obvious disadvantage of this approach is that the dimension of the resulting reduced-order model is doubled to 2n.…”

Section: Complex Expansion Pointsmentioning

confidence: 99%

Recent Advances in Structure-Preserving Model Order Reduction

Freund

2011

Simulation and Verification of Electronic and Biological Systems

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“…Primarily, inlet modeling for controls applications has originated from the discipline Computational Fluid Dynamics (CFD) based on discretization of the 3D and 2D Euler and Navier-Stokes equations. 1,2,3 These models have been reduced by developing an orthogonal basis to match selected frequency points or by singular value decomposition 4 to develop reduced order linear models. However, these laborious tasks are not necessary when the same objective can be accomplished starting with 1D CFD models.…”

Section: Introductionmentioning

confidence: 99%

Quasi 1D Modeling of Mixed Compression Supersonic Inlets

Kopasakis

Connolly

Paxson

et al. 2012

50th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition

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The AeroServoElasticity task under the NASA Supersonics Project is developing dynamic models of the propulsion system and the vehicle in order to conduct research for integrated vehicle dynamic performance. As part of this effort, a nonlinear quasi 1-dimensional model of the 2-dimensional bifurcated mixed compression supersonic inlet is being developed. The model utilizes computational fluid dynamics for both the supersonic and subsonic diffusers. The oblique shocks are modeled utilizing compressible flow equations. This model also implements variable geometry required to control the normal shock position. The model is flexible and can also be utilized to simulate other mixed compression supersonic inlet designs. The model was validated both in time and in the frequency domain against the legacy LArge Perturbation INlet code, which has been previously verified using test data. This legacy code written in FORTRAN is quite extensive and complex in terms of the amount of software and number of subroutines. Further, the legacy code is not suitable for closed loop feedback controls design, and the simulation environment is not amenable to systems integration. Therefore, a solution is to develop an innovative, more simplified, mixed compression inlet model with the same steady state and dynamic performance as the legacy code that also can be used for controls design. The new nonlinear dynamic model is implemented in MATLAB Simulink. This environment allows easier development of linear models for controls design for shock positioning. The new model is also well suited for integration with a propulsion system model to study inlet/propulsion system performance, and integration with an aero-servo-elastic system model to study integrated vehicle ride quality, vehicle stability, and efficiency.

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“…Our second example is the INLET problem from the Oberwolfach Model Reduction Benchmark Collection [1], an active control model of a supersonic engine inlet; see also [22]. There are two nonsymmetric matrices {A, E} ⊂ R N ×N , a block of vectors B ∈ R N ×2 , and a row vector c T ∈ R 1×N in this problem, where N = 11730.…”

Section: Model Order Reductionmentioning

confidence: 99%

“…8.5]), these methods have seen an increasing number of other applications over the last two decades or so. Examples of rational Krylov applications can be found in model order reduction [11,16,17,22], matrix function approximation [10,13,19], matrix equations [3,9,24], nonlinear eigenvalue problems [20,21,31], and nonlinear rational least squares fitting [5,6].At the core of most rational Krylov applications is the rational Arnoldi algorithm, which is a Gram-Schmidt procedure for generating an orthonormal basis of a rational Krylov space. Given a matrix A ∈ C N,N , a vector b ∈ C N , and a polynomial q m of degree at most m and such that q m (A) is nonsingular, the rational Krylov space of order m is defined as…”

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confidence: 99%

Parallelization of the Rational Arnoldi Algorithm

Berljafa¹,

Güttel²

2017

SIAM J. Sci. Comput.

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Abstract. Rational Krylov methods are applicable to a wide range of scientific computing problems, and the rational Arnoldi algorithm is a commonly used procedure for computing an orthonormal basis of a rational Krylov space. Typically, the computationally most expensive component of this algorithm is the solution of a large linear system of equations at each iteration. We explore the option of solving several linear systems simultaneously, thus constructing the rational Krylov basis in parallel. If this is not done carefully, the basis being orthogonalized may become badly conditioned, leading to numerical instabilities in the orthogonalization process. We introduce the new concept of continuation pairs, which gives rise to a near-optimal parallelization strategy that allows us to control the growth of the condition number of this nonorthogonal basis. As a consequence we obtain a significantly more accurate and reliable parallel rational Arnoldi algorithm. The computational benefits are illustrated using several numerical examples from different application areas.Key words. rational Krylov, orthogonalization, parallelization AMS subject classifications. 68W10, 65F25, 65G50, 65F15 DOI. 10.1137/16M10791781. Introduction. Rational Krylov methods have become an indispensable tool of scientific computing. Invented by Ruhe for the solution of large sparse eigenvalue problems (see, e.g., [26,27]) and frequently advocated for this purpose (see, e.g., [23,32] and [2, sect. 8.5]), these methods have seen an increasing number of other applications over the last two decades or so. Examples of rational Krylov applications can be found in model order reduction [11,16,17,22], matrix function approximation [10,13,19], matrix equations [3,9,24], nonlinear eigenvalue problems [20,21,31], and nonlinear rational least squares fitting [5,6].At the core of most rational Krylov applications is the rational Arnoldi algorithm, which is a Gram-Schmidt procedure for generating an orthonormal basis of a rational Krylov space. Given a matrix A ∈ C N,N , a vector b ∈ C N , and a polynomial q m of degree at most m and such that q m (A) is nonsingular, the rational Krylov space of order m is defined as

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Model Reduction for Active Control Design Using Multiple-Point Arnoldi Methods

Cited by 11 publications

References 17 publications

Recent Advances in Structure-Preserving Model Order Reduction

Recent Advances in Structure-Preserving Model Order Reduction

Quasi 1D Modeling of Mixed Compression Supersonic Inlets

Parallelization of the Rational Arnoldi Algorithm

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