Title :
Ambient Occlusion Effects for Combined Volumes and Tubular Geometry
Author :
Schott, M. ; Martin, T. ; Grosset, A. V. Pascal ; Smith, Stuart T. ; Hansen, Charles D.
Author_Institution :
NVIDIA Corp., Santa Clara, CA, USA
Abstract :
This paper details a method for interactive direct volume rendering that computes ambient occlusion effects for visualizations that combine both volumetric and geometric primitives, specifically tube-shaped geometric objects representing streamlines, magnetic field lines or DTI fiber tracts. The algorithm extends the recently presented the directional occlusion shading model to allow the rendering of those geometric shapes in combination with a context providing 3D volume, considering mutual occlusion between structures represented by a volume or geometry. Stream tube geometries are computed using an effective spline-based interpolation and approximation scheme that avoids self-intersection and maintains coherent orientation of the stream tube segments to avoid surface deforming twists. Furthermore, strategies to reduce the geometric and specular aliasing of the stream tubes are discussed.
Keywords :
approximation theory; data visualisation; hidden feature removal; interpolation; rendering (computer graphics); splines (mathematics); ambient occlusion effect; directional occlusion shading model; geometric aliasing; geometric primitive; interactive direct volume rendering; specular aliasing; spline-based approximation scheme; spline-based interpolation scheme; surface deforming twist; tube-shaped geometric object; visualization; volumetric primitive; Aerospace electronics; Diffusion tensor imaging; Electron tubes; Geometry; Image color analysis; Lighting; Rendering (computer graphics); Volume rendering; ambient occlusion; stream tubes;
Journal_Title :
Visualization and Computer Graphics, IEEE Transactions on
DOI :
10.1109/TVCG.2012.306
