A detail preserving fluid surface rendering method

Fengquan Zhang; Xukun Shen; Liuqing Xu

A detail preserving fluid surface rendering method

Fengquan Zhang
, Xukun Shen
, Liuqing Xu

School of New Media Art and Design

North China University of Technology
Chinese Academy of Sciences

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

1 Scopus citations

Abstract

An efficient algorithm for vivid fluid surface rendering is presented. Firstly, a new computing model is defined, which replaces the spherical kernel with ellipsoidal kernel. Furthermore, the scalar field function of particle uses a restraint and adjustment way to adaptively compute the particle sizes. Comparison with the traditional methods, it has better accuracy due to full consideration for the distribution of neighboring particles. In addition, it automatically computes grid resolution according to the particle sizes and reconstructs surface from the near fluid surface particle data. Finally in the rendering stage, the geometric and lighting calculations are decoupled for rendering the objects in scene, and a screen-space method is used to render caustics and refraction. The results demonstrate a significant improvement in the quality of rendered surfaces as compared to existing methods.

Original language	English
Pages (from-to)	1217-1222
Number of pages	6
Journal	Jisuanji Fuzhu Sheji Yu Tuxingxue Xuebao/Journal of Computer-Aided Design and Computer Graphics
Volume	27
Issue number	7
State	Published - 1 Jul 2015

Keywords

Detail preserving
Fluid simulation
Surface reconstruction
Visualization

Cite this

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title = "A detail preserving fluid surface rendering method",

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AU - Zhang, Fengquan

AU - Shen, Xukun

AU - Xu, Liuqing

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N2 - An efficient algorithm for vivid fluid surface rendering is presented. Firstly, a new computing model is defined, which replaces the spherical kernel with ellipsoidal kernel. Furthermore, the scalar field function of particle uses a restraint and adjustment way to adaptively compute the particle sizes. Comparison with the traditional methods, it has better accuracy due to full consideration for the distribution of neighboring particles. In addition, it automatically computes grid resolution according to the particle sizes and reconstructs surface from the near fluid surface particle data. Finally in the rendering stage, the geometric and lighting calculations are decoupled for rendering the objects in scene, and a screen-space method is used to render caustics and refraction. The results demonstrate a significant improvement in the quality of rendered surfaces as compared to existing methods.

AB - An efficient algorithm for vivid fluid surface rendering is presented. Firstly, a new computing model is defined, which replaces the spherical kernel with ellipsoidal kernel. Furthermore, the scalar field function of particle uses a restraint and adjustment way to adaptively compute the particle sizes. Comparison with the traditional methods, it has better accuracy due to full consideration for the distribution of neighboring particles. In addition, it automatically computes grid resolution according to the particle sizes and reconstructs surface from the near fluid surface particle data. Finally in the rendering stage, the geometric and lighting calculations are decoupled for rendering the objects in scene, and a screen-space method is used to render caustics and refraction. The results demonstrate a significant improvement in the quality of rendered surfaces as compared to existing methods.

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KW - Fluid simulation

KW - Surface reconstruction

KW - Visualization

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JO - Jisuanji Fuzhu Sheji Yu Tuxingxue Xuebao/Journal of Computer-Aided Design and Computer Graphics

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A detail preserving fluid surface rendering method

Abstract

Keywords

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