Abstract
Mathematical modeling often yields linear dynamical systems in science and engineering. We change physical parameters of the system into random variables to perform an uncertainty quantification. The stochastic Galerkin method yields a larger linear dynamical system, whose solution represents an approximation of random processes. A model order reduction (MOR) of the Galerkin system is advantageous due to the high dimensionality. However, asymptotic stability may be lost in some MOR techniques. In Galerkin-type MOR methods, the stability can be guaranteed by a transformation to a dissipative form. Either the original dynamical system or the stochastic Galerkin system can be transformed. We investigate the two variants of this stability-preserving approach. Both techniques are feasible, while featuring different properties in numerical methods. Results of numerical computations are demonstrated for two test examples modeling a mechanical application and an electric circuit, respectively.
Highlights
Numerical simulation of mathematical models represents the main issue in scientific computing
We examine the stability-preserving approach in the case of linear stochastic Galerkin systems consisting of ordinary differential equations
2 Stability preservation in reduction We review a concept for stability preservation in Galerkin-type projection-based model order reduction (MOR) for general linear dynamical systems
Summary
Numerical simulation of mathematical models represents the main issue in scientific computing. Several MOR methods are available for general linear dynamical systems, see [1, 3, 4, 32]. MOR of linear stochastic Galerkin systems was examined in several previous works [9, 18, 25, 26, 31, 40]. Even though the linear stochastic Galerkin system is asymptotically stable, the reduced Galerkin system often looses this stability in some MOR techniques. We investigate stability-preserving strategies in the case of Galerkin-type projection-based MOR like the Arnoldi method or proper orthogonal decomposition, for example. Galerkin-type MOR can be applied to any linear dynamical system ( stochastic Galerkin systems). We examine the stability-preserving approach in the case of linear stochastic Galerkin systems consisting of ordinary differential equations. We apply the analyzed techniques to mathematical models of two test examples: a massspring-damper system and an electric circuit of a band-pass filter
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