Finding ridges and valleys in a discrete surface using a modified MLS approximation

Soo Kyun Kim; Chang Hun Kim

doi:10.1016/j.cad.2005.10.004

Finding ridges and valleys in a discrete surface using a modified MLS approximation

Soo Kyun Kim, Chang Hun Kim

Department of Computer Science and Engineering

Research output: Contribution to journal › Comment/debate › peer-review

24 Citations (Scopus)

Abstract

Implicit surface fitting is a promising approach to finding ridges and valleys in discrete surfaces, but existing techniques are time-consuming and rely on user-supplied tuning parameters. We use a modified MLS (moving-least-squares) approximation technique to estimate the local differential information near a vertex by means of an approximating surface. Ridge and valley vertices are easily detected as zero-crossings, and can then be connected along the direction of principal curvature. Our method, demonstrated on several large meshed models, produces a good fit which leads to improved visualization. It does not oscillate and is quick to compute.

Original language	English
Pages (from-to)	173-180
Number of pages	8
Journal	CAD Computer Aided Design
Volume	38
Issue number	2
DOIs	https://doi.org/10.1016/j.cad.2005.10.004
Publication status	Published - 2006 Feb

Keywords

Curvature extrema
Moving-least-squares
Ridge lines

ASJC Scopus subject areas

Computer Science Applications
Computer Graphics and Computer-Aided Design
Industrial and Manufacturing Engineering

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10.1016/j.cad.2005.10.004

Cite this

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title = "Finding ridges and valleys in a discrete surface using a modified MLS approximation",

abstract = "Implicit surface fitting is a promising approach to finding ridges and valleys in discrete surfaces, but existing techniques are time-consuming and rely on user-supplied tuning parameters. We use a modified MLS (moving-least-squares) approximation technique to estimate the local differential information near a vertex by means of an approximating surface. Ridge and valley vertices are easily detected as zero-crossings, and can then be connected along the direction of principal curvature. Our method, demonstrated on several large meshed models, produces a good fit which leads to improved visualization. It does not oscillate and is quick to compute.",

keywords = "Curvature extrema, Moving-least-squares, Ridge lines",

author = "Kim, {Soo Kyun} and Kim, {Chang Hun}",

note = "Funding Information: Thanks to Yutaka Ohtake, Sun-Jeong Kim and Hyun-Chel Cho for useful comments. This work was supported by grant No.(R01-2005-000-10120-0) from Korea Science and Engineering Foundation in Ministry of Science & Technology, and Three-Dimensional Digital Real Object Duplication System (RODS) Development Project from the ministry of commerce, industry and energy. ",

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AU - Kim, Chang Hun

N1 - Funding Information: Thanks to Yutaka Ohtake, Sun-Jeong Kim and Hyun-Chel Cho for useful comments. This work was supported by grant No.(R01-2005-000-10120-0) from Korea Science and Engineering Foundation in Ministry of Science & Technology, and Three-Dimensional Digital Real Object Duplication System (RODS) Development Project from the ministry of commerce, industry and energy.

PY - 2006/2

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N2 - Implicit surface fitting is a promising approach to finding ridges and valleys in discrete surfaces, but existing techniques are time-consuming and rely on user-supplied tuning parameters. We use a modified MLS (moving-least-squares) approximation technique to estimate the local differential information near a vertex by means of an approximating surface. Ridge and valley vertices are easily detected as zero-crossings, and can then be connected along the direction of principal curvature. Our method, demonstrated on several large meshed models, produces a good fit which leads to improved visualization. It does not oscillate and is quick to compute.

AB - Implicit surface fitting is a promising approach to finding ridges and valleys in discrete surfaces, but existing techniques are time-consuming and rely on user-supplied tuning parameters. We use a modified MLS (moving-least-squares) approximation technique to estimate the local differential information near a vertex by means of an approximating surface. Ridge and valley vertices are easily detected as zero-crossings, and can then be connected along the direction of principal curvature. Our method, demonstrated on several large meshed models, produces a good fit which leads to improved visualization. It does not oscillate and is quick to compute.

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KW - Moving-least-squares

KW - Ridge lines

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DO - 10.1016/j.cad.2005.10.004

M3 - Comment/debate

AN - SCOPUS:29844442997

SN - 0010-4485

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JO - CAD Computer Aided Design

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Finding ridges and valleys in a discrete surface using a modified MLS approximation

Abstract

Keywords

ASJC Scopus subject areas

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