Orthogonalized Fourier Polynomials for Signal Approximation and Transfer

F. Maggioli; S. Melzi; M. Ovsjanikov; M. M. Bronstein; E. Rodolà

doi:10.1111/cgf.142645

Orthogonalized Fourier Polynomials for Signal Approximation and Transfer

F. Maggioli
, S. Melzi
, M. Ovsjanikov
, M. M. Bronstein
, E. Rodolà

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a novel approach for the approximation and transfer of signals across 3D shapes. The proposed solution is based on taking pointwise polynomials of the Fourier-like Laplacian eigenbasis, which provides a compact and expressive representation for general signals defined on the surface. Key to our approach is the construction of a new orthonormal basis upon the set of these linearly dependent polynomials. We analyze the properties of this representation, and further provide a complete analysis of the involved parameters. Our technique results in accurate approximation and transfer of various families of signals between near-isometric and non-isometric shapes, even under poor initialization. Our experiments, showcased on a selection of downstream tasks such as filtering and detail transfer, show that our method is more robust to discretization artifacts, deformation and noise as compared to alternative approaches.

Original language	English
Pages (from-to)	435-447
Number of pages	13
Journal	Computer Graphics Forum
Volume	40
Issue number	2
DOIs	https://doi.org/10.1111/cgf.142645
Publication status	Published - 1 May 2021

Keywords

CCS Concepts
Computing methodologies → Shape analysis
Mathematics of computing → Functional analysis
Theory of computation → Computational geometry

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10.1111/cgf.142645

Cite this

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title = "Orthogonalized Fourier Polynomials for Signal Approximation and Transfer",

abstract = "We propose a novel approach for the approximation and transfer of signals across 3D shapes. The proposed solution is based on taking pointwise polynomials of the Fourier-like Laplacian eigenbasis, which provides a compact and expressive representation for general signals defined on the surface. Key to our approach is the construction of a new orthonormal basis upon the set of these linearly dependent polynomials. We analyze the properties of this representation, and further provide a complete analysis of the involved parameters. Our technique results in accurate approximation and transfer of various families of signals between near-isometric and non-isometric shapes, even under poor initialization. Our experiments, showcased on a selection of downstream tasks such as filtering and detail transfer, show that our method is more robust to discretization artifacts, deformation and noise as compared to alternative approaches.",

keywords = "CCS Concepts, Computing methodologies → Shape analysis, Mathematics of computing → Functional analysis, Theory of computation → Computational geometry",

author = "F. Maggioli and S. Melzi and M. Ovsjanikov and Bronstein, \{M. M.\} and E. Rodol{\`a}",

note = "Publisher Copyright: {\textcopyright} 2021 The Author(s) Computer Graphics Forum {\textcopyright} 2021 The Eurographics Association and John Wiley \& Sons Ltd. Published by John Wiley \& Sons Ltd.",

year = "2021",

month = may,

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doi = "10.1111/cgf.142645",

language = "English",

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journal = "Computer Graphics Forum",

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TY - JOUR

T1 - Orthogonalized Fourier Polynomials for Signal Approximation and Transfer

AU - Maggioli, F.

AU - Melzi, S.

AU - Ovsjanikov, M.

AU - Bronstein, M. M.

AU - Rodolà, E.

PY - 2021/5/1

Y1 - 2021/5/1

N2 - We propose a novel approach for the approximation and transfer of signals across 3D shapes. The proposed solution is based on taking pointwise polynomials of the Fourier-like Laplacian eigenbasis, which provides a compact and expressive representation for general signals defined on the surface. Key to our approach is the construction of a new orthonormal basis upon the set of these linearly dependent polynomials. We analyze the properties of this representation, and further provide a complete analysis of the involved parameters. Our technique results in accurate approximation and transfer of various families of signals between near-isometric and non-isometric shapes, even under poor initialization. Our experiments, showcased on a selection of downstream tasks such as filtering and detail transfer, show that our method is more robust to discretization artifacts, deformation and noise as compared to alternative approaches.

AB - We propose a novel approach for the approximation and transfer of signals across 3D shapes. The proposed solution is based on taking pointwise polynomials of the Fourier-like Laplacian eigenbasis, which provides a compact and expressive representation for general signals defined on the surface. Key to our approach is the construction of a new orthonormal basis upon the set of these linearly dependent polynomials. We analyze the properties of this representation, and further provide a complete analysis of the involved parameters. Our technique results in accurate approximation and transfer of various families of signals between near-isometric and non-isometric shapes, even under poor initialization. Our experiments, showcased on a selection of downstream tasks such as filtering and detail transfer, show that our method is more robust to discretization artifacts, deformation and noise as compared to alternative approaches.

KW - CCS Concepts

KW - Computing methodologies → Shape analysis

KW - Mathematics of computing → Functional analysis

KW - Theory of computation → Computational geometry

U2 - 10.1111/cgf.142645

DO - 10.1111/cgf.142645

M3 - Article

AN - SCOPUS:85109662825

SN - 0167-7055

VL - 40

SP - 435

EP - 447

JO - Computer Graphics Forum

JF - Computer Graphics Forum

IS - 2

ER -

Orthogonalized Fourier Polynomials for Signal Approximation and Transfer

Abstract

Keywords

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