Modelling Complex Volume Shape Using Ellipsoid: Application to Pore Space Representation

2017 13th International Conference on Signal-Image Technology & Internet-Based Systems (SITIS) Pub Date : 2017-12-01 DOI:10.1109/SITIS.2017.52

Alain Trésor Kemgue, O. Monga, S. M. Mpong, S. Foufou

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引用次数: 1

Abstract

Natural shapes have complex volume forms that are usually difficult to model using simple analytical equations. The complexity of the representation is due to the heterogeneity of the physical environment and the variety of phenomena involved. In this study we consider the representation of the porous media. Thanks to the technological advances in Computed Topography scanners, the acquisition of images of complex shapes becomes possible. However, and unfortunately, the image data is not directly usable for simulation purposes. In this paper, we investigate the modeling of such shapes using a piece wise approximation of image data by ellipsoids. We propose to use a split-merge strategy and a region growing algorithm to optimize a functional including an error term and a scale term. The input of our algorithm is voxel-based shape description and the result is a set of tangent or disjoint ellipsoids representing the shape in an intrinsic way. We apply our method to represent 3D soil pore space from CT volume images. Within this specific context, we validate our geometrical modelling by using it for water draining simulation in porous media.

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利用椭球体建模复杂体积形状:在孔隙空间表示中的应用

自然形状具有复杂的体积形式，通常难以用简单的解析方程来建模。表征的复杂性是由于物理环境的异质性和所涉及现象的多样性。在这项研究中，我们考虑了多孔介质的表征。由于计算机地形扫描仪的技术进步，获取复杂形状的图像成为可能。然而，不幸的是，图像数据不能直接用于模拟目的。在本文中，我们研究了这种形状的建模使用椭球图像数据的分段逼近。我们提出使用分裂合并策略和区域增长算法来优化包含误差项和尺度项的函数。该算法的输入是基于体素的形状描述，结果是一组切线或不相交的椭球以一种内在的方式表示形状。我们将该方法应用于CT体图像的三维土壤孔隙空间表示。在这种特定的背景下，我们通过将其用于多孔介质中的排水模拟来验证我们的几何模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 13th International Conference on Signal-Image Technology & Internet-Based Systems (SITIS)

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