Wavelet Adaptive Proper Orthogonal Decomposition for Large Scale Flow Data
Abstract
The proper orthogonal decomposition (POD) is a powerful classical tool in fluid mechanics used, for instance, for model reduction and extraction of coherent flow features. However, its applicability to high-resolution data, as produced by three-dimensional direct numerical simulations, is limited owing to its computational complexity. Here, we propose a wavelet-based adaptive version of the POD (the wPOD), in order to overcome this limitation. The amount of data to be analyzed is reduced by compressing them using biorthogonal wavelets, yielding a sparse representation while conveniently providing control of the compression error. Numerical analysis shows how the distinct error contributions of wavelet compression and POD truncation can be balanced under certain assumptions, allowing us to efficiently process high-resolution data from three-dimensional simulations of flow problems. Using a synthetic academic test case, we compare our algorithm with the randomized singular value decomposition. Furthermore, we demonstrate the ability of our method analyzing data of a 2D wake flow and a 3D flow generated by a flapping insect computed with direct numerical simulation.
Cite
@article{arxiv.2011.05016,
title = {Wavelet Adaptive Proper Orthogonal Decomposition for Large Scale Flow Data},
author = {Philipp Krah and Thomas Engels and Kai Schneider and Julius Reiss},
journal= {arXiv preprint arXiv:2011.05016},
year = {2020}
}
Comments
The algorithm can be found as a post processing tool in the open source software package wabbit (https://github.com/adaptive-cfd/WABBIT). Please note, that this paper is a working paper and is not reviewed yet. It was submitted to ACOM Journal at the 10th of November 2020