Discrete multiscale vector field decomposition

Yiying Tong; Santiago Lombeyda; Anil N. Hirani; Mathieu Desbrun

doi:10.1145/882262.882290

Discrete multiscale vector field decomposition

Yiying Tong
, Santiago Lombeyda
, Anil N. Hirani
, Mathieu Desbrun

University of Southern California
California Institute of Technology

Research output: Contribution to journal › Conference article › peer-review

Abstract

While 2D and 3D vector fields are ubiquitous in computational sciences, their use in graphics is often limited to regular grids, where computations are easily handled through finite-difference methods. In this paper, we propose a set of simple and accurate tools for the analysis of 3D discrete vector fields on arbitrary tetrahedral grids. We introduce a variational, multiscale decomposition of vector fields into three intuitive components: a divergence-free part, a curl-free part, and a harmonic part. We show how our discrete approach matches its well-known smooth analog, called the HelmotzHodge decomposition, and that the resulting computational tools have very intuitive geometric interpretation. We demonstrate the versatility of these tools in a series of applications, ranging from data visualization to fluid and deformable object simulation.

Original language	English
Pages (from-to)	445-452
Number of pages	8
Journal	ACM Transactions on Graphics
Volume	22
Issue number	3
DOIs	https://doi.org/10.1145/882262.882290
Publication status	Published - 1 Jul 2003
Externally published	Yes
Event	ACM SIGGRAPH 2003 - San Diego, CA, United States Duration: 27 Jul 2003 → 31 Jul 2003

Keywords

Animation
Hodge decomposition
Scale-space description
Variational approaches
Vector fields
Visualization

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10.1145/882262.882290

Cite this

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title = "Discrete multiscale vector field decomposition",

abstract = "While 2D and 3D vector fields are ubiquitous in computational sciences, their use in graphics is often limited to regular grids, where computations are easily handled through finite-difference methods. In this paper, we propose a set of simple and accurate tools for the analysis of 3D discrete vector fields on arbitrary tetrahedral grids. We introduce a variational, multiscale decomposition of vector fields into three intuitive components: a divergence-free part, a curl-free part, and a harmonic part. We show how our discrete approach matches its well-known smooth analog, called the HelmotzHodge decomposition, and that the resulting computational tools have very intuitive geometric interpretation. We demonstrate the versatility of these tools in a series of applications, ranging from data visualization to fluid and deformable object simulation.",

keywords = "Animation, Hodge decomposition, Scale-space description, Variational approaches, Vector fields, Visualization",

author = "Yiying Tong and Santiago Lombeyda and Hirani, \{Anil N.\} and Mathieu Desbrun",

year = "2003",

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language = "English",

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T1 - Discrete multiscale vector field decomposition

AU - Tong, Yiying

AU - Lombeyda, Santiago

AU - Hirani, Anil N.

AU - Desbrun, Mathieu

PY - 2003/7/1

Y1 - 2003/7/1

N2 - While 2D and 3D vector fields are ubiquitous in computational sciences, their use in graphics is often limited to regular grids, where computations are easily handled through finite-difference methods. In this paper, we propose a set of simple and accurate tools for the analysis of 3D discrete vector fields on arbitrary tetrahedral grids. We introduce a variational, multiscale decomposition of vector fields into three intuitive components: a divergence-free part, a curl-free part, and a harmonic part. We show how our discrete approach matches its well-known smooth analog, called the HelmotzHodge decomposition, and that the resulting computational tools have very intuitive geometric interpretation. We demonstrate the versatility of these tools in a series of applications, ranging from data visualization to fluid and deformable object simulation.

AB - While 2D and 3D vector fields are ubiquitous in computational sciences, their use in graphics is often limited to regular grids, where computations are easily handled through finite-difference methods. In this paper, we propose a set of simple and accurate tools for the analysis of 3D discrete vector fields on arbitrary tetrahedral grids. We introduce a variational, multiscale decomposition of vector fields into three intuitive components: a divergence-free part, a curl-free part, and a harmonic part. We show how our discrete approach matches its well-known smooth analog, called the HelmotzHodge decomposition, and that the resulting computational tools have very intuitive geometric interpretation. We demonstrate the versatility of these tools in a series of applications, ranging from data visualization to fluid and deformable object simulation.

KW - Animation

KW - Hodge decomposition

KW - Scale-space description

KW - Variational approaches

KW - Vector fields

KW - Visualization

U2 - 10.1145/882262.882290

DO - 10.1145/882262.882290

M3 - Conference article

AN - SCOPUS:1542325749

SN - 0730-0301

VL - 22

SP - 445

EP - 452

JO - ACM Transactions on Graphics

JF - ACM Transactions on Graphics

IS - 3

T2 - ACM SIGGRAPH 2003

Y2 - 27 July 2003 through 31 July 2003

ER -

Discrete multiscale vector field decomposition

Abstract

Keywords

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