Paper Info
Title
Multimodal volume illumination
Abstract
Despite the increasing importance of multimodal volumetric data acquisition and the recent progress in advanced volume illumination, interactive multimodal volume illumination remains an open challenge. As a consequence, the perceptual benefits of advanced volume illumination algorithms cannot be exploited when visualizing multimodal data - a scenario where increased data complexity urges for improved spatial comprehension. The two main factors hindering the application of advanced volumetric illumination models to multimodal data sets are rendering complexity and memory consumption. Solving the volume rendering integral by considering multimodal illumination increases the sampling complexity. At the same time, the increased storage requirements of multimodal data sets forbid to exploit precomputation results, which are often facilitated by advanced volume illumination algorithms to reduce the amount of per-frame computations. In this paper, we propose an interactive volume rendering approach that supports advanced illumination when visualizing multimodal volumetric data sets. The presented approach has been developed with the goal to simplify and minimize per-sample operations, while at the same time reducing the memory requirements. We will show how to exploit illumination-importance metrics, to compress and transform multimodal data sets into an illumination-aware representation, which is accessed during rendering through a novel light-space-based volume rendering algorithm. Both, data transformation and rendering algorithm, are closely intervened by taking compression errors into account during rendering. We describe and analyze the presented approach in detail, and apply it to real-world multimodal data sets from biology, medicine, meteorology and engineering. Graphical abstractDisplay Omitted HighlightsVolume rendering with multimodal volume illumination and multiple light sources.Limit illumination computations to samples visible to the camera and light source.Reduces the memory footprint by exploiting illumination-importance metrics.We take clustering metrics into account during the visualization process.
Year
DOI
Venue
2015
10.1016/j.cag.2015.05.004
Computers & Graphics
Keywords
Field
DocType
Volume rendering,Volumetric illumination,Multimodal visualization
Computer vision,Volume rendering,Data set,Precomputation,Computer graphics (images),Computer science,Visualization,Artificial intelligence,Rendering (computer graphics),Memory footprint,Cluster analysis,Computation
Journal
Volume
Issue
ISSN
50
C
0097-8493
Citations 
PageRank 
References 
0
0.34
48
Authors
3
Name
Order
Citations
PageRank
Erik Sundén1716.04
Sathish Kottravel2122.92
Timo Ropinski364053.79