Rank-adaptive structure-preserving model order reduction of Hamiltonian systems

Jan S. Hesthaven, Cecilia Pagliantini (Corresponding author), Nicolò Ripamonti

Research output: Contribution to journalArticleAcademicpeer-review

23 Citations (Scopus)
218 Downloads (Pure)

Abstract

This work proposes an adaptive structure-preserving model order reduction method for finite-dimensional parametrized Hamiltonian systems modeling non-dissipative phenomena. To overcome the slowly decaying Kolmogorov width typical of transport problems, the full model is approximated on local reduced spaces that are adapted in time using dynamical low-rank approximation techniques. The reduced dynamics is prescribed by approximating the symplectic projection of the Hamiltonian vector field in the tangent space to the local reduced space. This ensures that the canonical symplectic structure of the Hamiltonian dynamics is preserved during the reduction. In addition, accurate approximations with low-rank reduced solutions are obtained by allowing the dimension of the reduced space to change during the time evolution. Whenever the quality of the reduced solution, assessed via an error indicator, is not satisfactory, the reduced basis is augmented in the parameter direction that is worst approximated by the current basis. Extensive numerical tests involving wave interactions, nonlinear transport problems, and the Vlasov equation demonstrate the superior stability properties and considerable runtime speedups of the proposed method as compared to global and traditional reduced basis approaches.
Original languageEnglish
Pages (from-to)617-650
Number of pages34
JournalMathematical Modelling and Numerical Analysis
Volume56
Issue number2
DOIs
Publication statusPublished - 8 Mar 2022

Keywords

  • Adaptive algorithms
  • Dynamical low-rank approximation
  • Hamiltonian dynamics
  • Reduced basis methods (RBM)
  • Symplectic manifolds

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