Sphere intersection 3D shape descriptor (SID)

Kirill Pevzner; Andrei Sharf; Jihad El-Sana

doi:10.1016/j.cagd.2015.09.002

Sphere intersection 3D shape descriptor (SID)

Kirill Pevzner, Andrei Sharf, Jihad El-Sana

Department of Computer Science

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

Abstract

This paper presents a novel 3D shape descriptor which explicitly captures the local geometry and encodes it using an efficient representation. Our method consists of multiple evolving fronts which are realized by a set of growing spheres on the surface. At the core of this method is a simple intersection operator between the spheres and the shape's surface. Intersection curves yield a discrete sampling of the surface at different positions and scales. Our key idea is to define a shape descriptor that captures the continuous local geometry of the surface in an efficient and consistent representation by intersecting the surface with multiple spheres and transforming the intersection curve to frequency domain. To evaluate our descriptor, we define shape similarity metric and perform shape matching on the SHREC11 non-rigid benchmark and other classes.

Original language	English
Pages (from-to)	51-63
Number of pages	13
Journal	Computer Aided Geometric Design
Volume	38
DOIs	https://doi.org/10.1016/j.cagd.2015.09.002
State	Published - 1 Oct 2015

Keywords

Descriptor
Mesh processing
Retrieval
Signature
Similarity

ASJC Scopus subject areas

Modeling and Simulation
Automotive Engineering
Aerospace Engineering
Computer Graphics and Computer-Aided Design

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10.1016/j.cagd.2015.09.002

Cite this

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title = "Sphere intersection 3D shape descriptor (SID)",

abstract = "This paper presents a novel 3D shape descriptor which explicitly captures the local geometry and encodes it using an efficient representation. Our method consists of multiple evolving fronts which are realized by a set of growing spheres on the surface. At the core of this method is a simple intersection operator between the spheres and the shape's surface. Intersection curves yield a discrete sampling of the surface at different positions and scales. Our key idea is to define a shape descriptor that captures the continuous local geometry of the surface in an efficient and consistent representation by intersecting the surface with multiple spheres and transforming the intersection curve to frequency domain. To evaluate our descriptor, we define shape similarity metric and perform shape matching on the SHREC11 non-rigid benchmark and other classes.",

keywords = "Descriptor, Mesh processing, Retrieval, Signature, Similarity",

author = "Kirill Pevzner and Andrei Sharf and Jihad El-Sana",

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T1 - Sphere intersection 3D shape descriptor (SID)

AU - Pevzner, Kirill

AU - Sharf, Andrei

AU - El-Sana, Jihad

PY - 2015/10/1

Y1 - 2015/10/1

N2 - This paper presents a novel 3D shape descriptor which explicitly captures the local geometry and encodes it using an efficient representation. Our method consists of multiple evolving fronts which are realized by a set of growing spheres on the surface. At the core of this method is a simple intersection operator between the spheres and the shape's surface. Intersection curves yield a discrete sampling of the surface at different positions and scales. Our key idea is to define a shape descriptor that captures the continuous local geometry of the surface in an efficient and consistent representation by intersecting the surface with multiple spheres and transforming the intersection curve to frequency domain. To evaluate our descriptor, we define shape similarity metric and perform shape matching on the SHREC11 non-rigid benchmark and other classes.

AB - This paper presents a novel 3D shape descriptor which explicitly captures the local geometry and encodes it using an efficient representation. Our method consists of multiple evolving fronts which are realized by a set of growing spheres on the surface. At the core of this method is a simple intersection operator between the spheres and the shape's surface. Intersection curves yield a discrete sampling of the surface at different positions and scales. Our key idea is to define a shape descriptor that captures the continuous local geometry of the surface in an efficient and consistent representation by intersecting the surface with multiple spheres and transforming the intersection curve to frequency domain. To evaluate our descriptor, we define shape similarity metric and perform shape matching on the SHREC11 non-rigid benchmark and other classes.

KW - Descriptor

KW - Mesh processing

KW - Retrieval

KW - Signature

KW - Similarity

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SP - 51

EP - 63

JO - Computer Aided Geometric Design

JF - Computer Aided Geometric Design

ER -

Sphere intersection 3D shape descriptor (SID)

Abstract

Keywords

ASJC Scopus subject areas

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