Polynomial chaos based rational approximation in linear structural dynamics with parameter uncertainties

Felix Schneider, Iason Papaioannou, Max Ehre, Daniel Straub

Research output: Contribution to journalArticlepeer-review

14 Scopus citations

Abstract

Surrogate models enable efficient propagation of uncertainties in computationally demanding models of physical systems. We employ surrogate models that draw upon polynomial bases to model the stochastic response of structural dynamics systems. In linear structural dynamics problems, the system response can be described by the frequency response function. It is well known that standard polynomial chaos expansions of the frequency response present slow convergence around system eigenfrequencies, due to the highly nonlinear nature of the frequency response for low damping. To overcome this issue, we develop a rational approximation that expresses the system response as a rational of two polynomials with complex coefficients. To estimate the latter, we propose a regression approach that is non-intrusive and can be easily coupled with existing deterministic solvers. We demonstrate the effectiveness of the proposed method with two examples, a two-degree-of-freedom system and a finite element model of a cross laminated timber plate.

Original languageEnglish
Article number106223
JournalComputers and Structures
Volume233
DOIs
StatePublished - Jun 2020

Keywords

  • Frequency response function
  • Polynomial chaos
  • Rational function approximation
  • Regression
  • Structural dynamics
  • Uncertainty quantification

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