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

Résultats de recherche: Contribution à un journal › Article de conférence › Revue par des pairs

Résumé

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.

langue originale	Anglais
Pages (de - à)	445-452
Nombre de pages	8
journal	ACM Transactions on Graphics
Volume	22
Numéro de publication	3
Les DOIs	https://doi.org/10.1145/882262.882290
état	Publié - 1 juil. 2003
Modification externe	Oui
Evénement	ACM SIGGRAPH 2003 - San Diego, CA, États-Unis Durée: 27 juil. 2003 → 31 juil. 2003

Accès au document

10.1145/882262.882290

Contient cette citation

@article{897457d1bc4d40f284ad440d290b4f45,

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",

month = jul,

day = "1",

doi = "10.1145/882262.882290",

language = "English",

volume = "22",

pages = "445--452",

journal = "ACM Transactions on Graphics",

issn = "0730-0301",

number = "3",

note = "ACM SIGGRAPH 2003 ; Conference date: 27-07-2003 Through 31-07-2003",

}

TY - JOUR

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

Résumé

Accès au document

Empreinte digitale

Contient cette citation