Title :
Feature preserving distance fields
Author :
Qu, Huamin ; Zhang, Nan ; Shao, Ran ; Kaufman, Arie ; Mueller, Klaus
Author_Institution :
Dept. of Comput. Sci., State Univ. of New York, Stony Brook, NY, USA
Abstract :
We present two distance field representations which can preserve sharp features in original geometric models: the offset distance field (ODF) and the unified distance field (UDF). The ODF is sampled on a special curvilinear grid named an offset grid. The sample points of the ODF are not on a regular grid and they can float in the cells of a regular base grid. The ODF can naturally adapt to curvature variations in the original mesh and can preserve sharp features. We describe an energy minimization approach to convert geometric models to ODFs. The UDF integrates multiple distance field representations into one data structure. By adaptively using different representations for different parts of a shape, the UDF can provide high fidelity surface representation with compact storage and fast rendering speed.
Keywords :
computational geometry; image representation; rendering (computer graphics); curvilinear grid; distance field representations; energy minimization; feature preserving distance fields; geometric models; irregular grids; offset distance field; offset grid; surface representation; unified distance field; volume sculpting; Chromium; Computational geometry; Computer graphics; Computer science; Data structures; Radio access networks; Rendering (computer graphics); Sampling methods; Solid modeling; Surface reconstruction; Distance fields; Feature Preserving; Irregular grids; Sampling; Volume Sculpting;
Conference_Titel :
Volume Visualization and Graphics, 2004 IEEE Symposium on
Print_ISBN :
0-7803-8781-3
DOI :
10.1109/SVVG.2004.3
