Randomized Dynamic Mode Decomposition for Non-Intrusive Reduced Order Modelling
Abstract
This paper focuses on a new framework for reduced order modelling of non-intrusive data with application to 2D flows. To overcome the shortcomings of intrusive model order reduction usually derived by combining the POD and the Galerkin projection methods, we developed a novel technique based on Randomized Dynamic Mode Decomposition as a fast and accurate option in model order reduction of non-intrusive data originating from Saint-Venant systems. Combining efficiently the Randomized Dynamic Mode Decomposition algorithm with Radial Basis Function interpolation, we produced an efficient tool in developing the linear model of a complex flow field described by non-intrusive (or experimental) data. The rank of the reduced DMD model is given as the unique solution of a constrained optimization problem. We emphasize the excellent behavior of the non-intrusive reduced order models by performing a qualitative analysis. In addition, we gain a significantly reduction of CPU time in computation of the reduced order models (ROMs) for non-intrusive numerical data.
Cite
@article{arxiv.1611.04884,
title = {Randomized Dynamic Mode Decomposition for Non-Intrusive Reduced Order Modelling},
author = {D. A. Bistrian and I. M. Navon},
journal= {arXiv preprint arXiv:1611.04884},
year = {2016}
}
Comments
22 pages, 14 figures