Grassmannian Shape Representations for Aerodynamic Applications
Abstract
Airfoil shape design is a classical problem in engineering and manufacturing. Our motivation is to combine principled physics-based considerations for the shape design problem with modern computational techniques informed by a data-driven approach. Traditional analyses of airfoil shapes emphasize a flow-based sensitivity to deformations which can be represented generally by affine transformations (rotation, scaling, shearing, translation). We present a novel representation of shapes which decouples affine-style deformations from a rich set of data-driven deformations over a submanifold of the Grassmannian. The Grassmannian representation, informed by a database of physically relevant airfoils, offers (i) a rich set of novel 2D airfoil deformations not previously captured in the data, (ii) improved low-dimensional parameter domain for inferential statistics informing design/manufacturing, and (iii) consistent 3D blade representation and perturbation over a sequence of nominal shapes.
Keywords
Cite
@article{arxiv.2201.04649,
title = {Grassmannian Shape Representations for Aerodynamic Applications},
author = {Olga A. Doronina and Zachary J. Grey and Andrew Glaws},
journal= {arXiv preprint arXiv:2201.04649},
year = {2022}
}
Comments
5 pages, 4 figures, submitted to AI for Design and Manufacturing(ADAM) workshop of AAAI-2022 conference