一种新的轮廓线三维地质表面重建方法

doi:10.3724/SP.J.1047.2015.00253

地球信息科学学报 ›› 2015, Vol. 17 ›› Issue (3): 253-259.doi: 10.3724/SP.J.1047.2015.00253

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一种新的轮廓线三维地质表面重建方法

杨洋¹(), 潘懋^1,^*(), 吴耕宇¹, 孙颖², 李魁星³

1. 北京大学造山带与地壳演化教育部重点实验室,北京 100871
2. 北京市水文地质工程地质大队,北京 100871
3. 北京市超维创想信息技术有限公司,北京 100871

收稿日期:2014-05-09 修回日期:2014-07-27 出版日期:2015-03-10 发布日期:2015-03-10
通讯作者: 潘懋 E-mail:5320179@163.com;panmao@pku.edu.cn
作者简介:
作者简介：杨洋(1988-),男,博士,研究方向为三维构造建模及计算机图形学。E-mail:5320179@163.com
基金资助:
北京岩溶水资源勘查评价工程项目(BJYRS-ZT-02)

High Quality Geological Surface Reconstruction from Planar Contours

YANG Yang¹(), PAN Mao^1,^*(), WU Gengyu¹, SUN Ying², LI Kuixing³

1. Key Laboratory of Orogenic Belts and Crustal Evolution,Ministry of Education, Peking University, Beijing 100871, China
2. Beijing Institute of Hydrogeology and Engineering Geology, Beijing 100195, China
3. Creatar Co., Ltd., Beijing 100085, China

Received:2014-05-09 Revised:2014-07-27 Online:2015-03-10 Published:2015-03-10
Contact: PAN Mao E-mail:5320179@163.com;panmao@pku.edu.cn
About author:
*The author: SHEN Jingwei, E-mail:jingweigis@163.com

摘要/Abstract

摘要：

在三维地质建模中,由于地质剖面与医学CT有本质上的相似性,因此,轮廓线的三维表面重建技术有广泛的应用。目前,较为成熟的算法并没有考虑地质数据的特殊性,由于地质体形态复杂多变,地质剖面稀疏、数据来源多样等特点,将普适的算法应用到地质建模中,只是解决了重建曲面的合理性,并没有关注曲面的几何质量,导致曲面无法达到地质建模对于模型质量的要求。本文针对地质数据的特点,提出了一种新的轮廓线表面重构方法。在不改变轮廓线连接的合理性与正确性的情况下,通过生成过渡剖面轮廓线,克服传统方法生成曲面过于粗糙的缺点,以提高建模质量。在Creatar三维地质基础平台上,对多种情况的剖面数据实验结果表明,在数据稀疏的情况下达到了良好的建模效果。该方法的扩展模型满足了地质剖面轮廓线建模中复杂地质情况,以及交叉剖面数据的曲面重建,且算法复杂度低,实现简单,有较强的实用性。

关键词: 三维地质建模, 表面重建, 轮廓线, 质量控制

Abstract:

In three-dimensional geological modeling, because the geological section and the medical section are essentially similar, the three-dimensional surface reconstruction methods based on contour lines that have been widely used in biomedical modeling are now introduced to geological modeling. But most algorithms from medical modeling that have been applied to geological modeling do not fit specifically for geological data. They only consider the rationality of reconstructed surface, however they concern little about the quality of surface geometry. In geological modeling, there are challenges including the complex and changeable shapes of geological objects, sparse geological section data and various origins of data sources; therefore, the methods that simply connect data could not meet the quality requirements of three-dimensional geological modeling. To overcome it, we consider solving the problem of how to reconstruct high quality triangular surfaces from sparse contour lines in this paper. According to the characteristics of geological data, a new algorithm that improves the quality of geological modeling by interpolating transitional sections is presented. The algorithm deals with geological sections that are stored as vectors and integrate them through a series of manipulations, including: matching features between contour lines that have the same geological property; building a mapping function between each matched pair; generating transitional contour lines; constructing surfaces from transitional contours and original contours. The main process can be summarized as follows: (1) matching geological feature; (2) building mapping function; (3) generating transition model; (4) constructing surface. A standard mathematical model which can resolve contour lines from parallel sections and a extended model that can resolve contour lines from cross sections are both defined in this paper. Some illustrative examples and analytical data are given at the end of this paper to prove that the surface reconstructed by this algorithm has much better quality than traditional ones.

Key words: geological modeling, surface reconstruction, contours, quality control

杨洋, 潘懋, 吴耕宇, 孙颖, 李魁星. 一种新的轮廓线三维地质表面重建方法[J]. 地球信息科学学报, 2015, 17(3): 253-259.DOI:10.3724/SP.J.1047.2015.00253

YANG Yang,PAN Mao,WU Gengyu,SUN Ying,LI Kuixing. High Quality Geological Surface Reconstruction from Planar Contours[J]. Journal of Geo-information Science, 2015, 17(3): 253-259.DOI:10.3724/SP.J.1047.2015.00253

图/表 13

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表1

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图11

表2

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测试模型	模型说明
简单矿体（图3）	共6条剖面轮廓线数据,且均为“1对1”的情况,无尖灭情况
水平地层（图8）	共3条剖面轮廓线数据,趋势较为平滑不存在复杂构造
复杂矿体（图9）	共13条剖面轮廓线数据,存在“n对n”,以及“1对n”的情况,并且沿矿体展布方向存在尖灭（“1对0”）的情况
断层面（图10）	由2条剖面轮廓线（图10中实线）,以及地表地质图上该断层的走势线（图10中虚线）组成
复杂褶皱（图11）	由4条交叉剖面上的轮廓线组成

测试模型	传统算法美化度B	传统算法光滑度H	本算法美化度B	本算法光滑度H
图3	0.161608	5.847635	0.299777	1.258108
图8	0.075692	27.52082	0.422103	5.292667
图9	0.144637	20.63944	0.369782	3.956764
图10	0.110934	2.144750	0.408326	1.545399
图11	0.097412	6.380472	0.399181	0.075950

一种新的轮廓线三维地质表面重建方法

High Quality Geological Surface Reconstruction from Planar Contours

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