Accurate and Efficient Computation of Laplacian Spectral Distances and Kernels

This paper introduces the Laplacian spectral distances, as a function that resembles the usual distance map, but exhibits properties (e.g. smoothness, locality, invariance to shape transformations) that make them useful to processing and analysing geometric data. Spectral distances are easily define...

Full description

Saved in:
Bibliographic Details
Published in:Computer graphics forum 2017-01, Vol.36 (1), p.184-196
Main Author: Patane, Giuseppe
Format: Article
Language:English
Subjects:
Accuracy
Approximation
Coding
Computational efficiency
Computer Graphics [Computing methodologies]: Shape modelling
Convergence
digital geometry processing
Eigenvalues
Electromagnetic wave filters
Filtering
geometric modelling
Invariance
Kernels
Linear systems
Mathematical analysis
Mathematical models
modelling
Operators
Prolongation
Smoothness
Spectra
Systems analysis
Transformations (mathematics)
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper introduces the Laplacian spectral distances, as a function that resembles the usual distance map, but exhibits properties (e.g. smoothness, locality, invariance to shape transformations) that make them useful to processing and analysing geometric data. Spectral distances are easily defined through a filtering of the Laplacian eigenpairs and reduce to the heat diffusion, wave, biharmonic and commute‐time distances for specific filters. In particular, the smoothness of the spectral distances and the encoding of local and global shape properties depend on the convergence of the filtered eigenvalues to zero. Instead of applying a truncated spectral approximation or prolongation operators, we propose a computation of Laplacian distances and kernels through the solution of sparse linear systems. Our approach is free of user‐defined parameters, overcomes the evaluation of the Laplacian spectrum and guarantees a higher approximation accuracy than previous work. This paper introduces the Laplacian spectral distances, as a function that resembles the usual distancemap, but exhibits properties (e.g. smoothness, locality, invariance to shape transformations) that make them useful to processing and analysing geometric data. Spectral distances are easily defined through a filtering of the Laplacian eigenpairs and reduce to the heat diffusion, wave, biharmonic and commutetime distances for specific filters. In particular, the smoothness of the spectral distances and the encoding of local and global shape properties depend on the convergence of the filtered eigenvalues to zero.
ISSN:0167-7055
1467-8659
DOI:10.1111/cgf.12794