Title :
RBF Dipole Surface Evolution
Author :
Jia, Yuntao ; Ni, Xinlai ; Lorimer, Eric ; Mullan, Michael ; Whitaker, Ross ; Hart, John C.
Author_Institution :
Univ. of Illinois at Urbana-Champaign, Urbana, IL, USA
Abstract :
The level set method can implement a wide variety of shape modeling operations (e.g. offsetting, skeletonization, morphing, blending, smoothing, sharpening, embossing, denoising, sculpting, growing, texturing and fitting) simply by specifying a corresponding speed function that controls the growth of an evolving voxel isosurface. The problem is that the basic level set method is implemented on a fixed resolution grid, which limits the utility of these shape modeling operations. We instead represent surfaces with a collection of radial basis function dipole pairs, and derive the motion of these dipoles to implement a surface propagation similar to the level set method but on a smooth, arbitrary resolution model. We demonstrate the utility of this approach with new level set methods for surface fitting, blending and center redistribution for RBF dipole models.
Keywords :
image resolution; radial basis function networks; solid modelling; surface fitting; RBF dipole surface evolution; arbitrary resolution model; fixed resolution grid; level set method; radial basis function dipole pairs; shape modeling operations; surface fitting; surface propagation; voxel isosurface; Embossing; Isosurfaces; Level set; Noise reduction; Shape control; Smoothing methods; Solid modeling; Surface fitting; Surface morphology; Surface texture; implicit surface; level set; particle system; radial basis function; surface fitting;
Conference_Titel :
Shape Modeling International Conference (SMI), 2010
Conference_Location :
Aix-en-Provence
Print_ISBN :
978-1-4244-7259-8
Electronic_ISBN :
978-1-4244-7260-4
DOI :
10.1109/SMI.2010.41
