2017: Clouds and Atmospheric Processes
Description
The output generated by climate simulations is increasing in size, as well as complexity. Both aspects pose equal challenges for the visualization and interactive analysis of the data. The increase in complexity is due to maturing models that are able to better describe the intricacies of the climate system, while the gain in data size is a direct result of an increased spatial and temporal resolution used by modern climate models. The benefit of these high resolution models is not only that they are able to simulate the Earth's past, current and future climate with a higher accuracy, these models also allow us to gain more insight in the complexity of the weather and climate system itself. Until very recently, clouds and precipitation processes were only approximated within climate models and not fully resolved. Now, with maturing models and increasing computational capacities, we are not only able to really simulate clouds and precipitation processes in global models, but also small scale features from the formation of clouds, ice and rain. The data generated, however, is huge and requires special methods for the analysis and visualization of very large data sets. The visualization and analysis assignments for the 2017 IEEE SciVis Contest cover a large variety of different tasks with varying level of difficulty. Especially those associated with cloud detection and tracking, or the analysis and comparison of different resolutions, are very important to us, and maybe your solutions and answers will help us to gain more and faster insight into our data, and finally enable us to improve our research through better visualization.
Date
2017
Items
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2017 Contest Website Archive
This contains an archive of the contest website in both PDF and HTML formats.