Randomized low-rank approximation methods for projection-based model order reduction of large nonlinear dynamical problems

C. Bach, D. Ceglia, L. Song, F. Duddeck

Research output: Contribution to journalArticlepeer-review

20 Scopus citations

Abstract

Projection-based nonlinear model order reduction (MOR) methods typically make use of a reduced basis V ∈ R m×k to approximate high-dimensional quantities. However, the most popular methods for computing V, eg, through a singular value decomposition of an m × n snapshot matrix, have asymptotic time complexities of (Formula presented.) and do not scale well as m and n increase. This is problematic for large dynamical problems with many snapshots, eg, in case of explicit integration. In this work, we propose the use of randomized methods for reduced basis computation and nonlinear MOR, which have an asymptotic complexity of only O(mnk) or O(mnlog(k)). We evaluate the suitability of randomized algorithms for nonlinear MOR and compare them to other strategies that have been proposed to mitigate the demanding computing times incurred by large nonlinear models. We analyze the computational complexities of traditional, iterative, incremental, and randomized algorithms and compare the computing times and accuracies for numerical examples. The results indicate that randomized methods exhibit an extremely high level of accuracy in practice, while generally being faster than any other analyzed approach. We conclude that randomized methods are highly suitable for the reduction of large nonlinear problems.

Original languageEnglish
Pages (from-to)209-241
Number of pages33
JournalInternational Journal for Numerical Methods in Engineering
Volume118
Issue number4
DOIs
StatePublished - 27 Apr 2019

Keywords

  • explicit FEM
  • low-rank approximation
  • nonlinear dynamics
  • nonlinear model order reduction
  • randomized SVD
  • randomized numerical linear algebra

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