Schrödinger Operator for Sparse Approximation of 3D Meshes
Abstract
We introduce a Schrödinger operator for spectral approximation of meshes representing surfaces in 3D. The operator is obtained by modifying the Laplacian with a potential function which defines the rate of oscillation of the harmonics on different regions of the surface. We design the potential using a vertex ordering scheme which modulates the Fourier basis of a 3D mesh to focus on crucial regions of the shape having high-frequency structures and employ a sparse approximation framework to maximize compression performance. The combination of the spectral geometry of the Hamiltonian in conjunction with a sparse approximation approach outperforms existing spectral compression schemes.
BibTeX
@inproceedings {10.2312:sgp.20171205,
booktitle = {Symposium on Geometry Processing 2017- Posters},
editor = {Jakob Andreas Bærentzen and Klaus Hildebrandt},
title = {{Schrödinger Operator for Sparse Approximation of 3D Meshes}},
author = {Choukroun, Yoni and Pai, Gautam and Kimmel, Ron},
year = {2017},
publisher = {The Eurographics Association},
ISSN = {1727-8384},
ISBN = {978-3-03868-047-5},
DOI = {10.2312/sgp.20171205}
}
booktitle = {Symposium on Geometry Processing 2017- Posters},
editor = {Jakob Andreas Bærentzen and Klaus Hildebrandt},
title = {{Schrödinger Operator for Sparse Approximation of 3D Meshes}},
author = {Choukroun, Yoni and Pai, Gautam and Kimmel, Ron},
year = {2017},
publisher = {The Eurographics Association},
ISSN = {1727-8384},
ISBN = {978-3-03868-047-5},
DOI = {10.2312/sgp.20171205}
}