Visibility-oriented Visualization Design for Flow Illustration
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Flow phenomena are ubiquitous in our world and they affect many aspects of our daily life. For this reason, they are the subject of extensive studies in several research fields. In medicine, the blood flow through our vessels can reveal important information about cardiovascular diseases. The air flow around a vehicle and the motion of fluids in a combustion engine are examples of relevant flow phenomena in engineering disciplines. Meteorologists, climatologists and oceanographers are instead concerned with winds and water currents. Thanks to the recent advancements in computational fluid dynamics and to the increasing power of modern hardware, accurate simulations of flow phenomena are feasible nowadays. The evolution of multiple flow attributes, such as velocity, temperature and pressure, can be simulated over large spatial and temporal domains (4D). The amount of data generated by this process is massive, therefore visualization techniques are often adopted in order to ease the analysis phase. The overall goal is to convey information about the phenomena of interest through a suitable representation of the data at hand. Due to the multivariate and multidimensional nature of the data, visibility issues (such as cluttering and occlusion), represent a significant challenge. Flow visualization can greatly benefit from studying and addressing visibility issues already in the design phase. In this thesis we investigate and demonstrate the effectiveness of taking visibility management into account early in the design process. We apply this principle to three characteristic flow visualization scenarios: (1) The simultaneous visualization of multiple flow attributes. (2) The visual inspection of single and multiple integral surfaces. (3) The selection of seeding curves for constructing families of integral surfaces. Our techniques result in clutter- and occlusion-free visualizations, which effectively illustrate the key aspects of the flow behavior. For demonstration purposes, we have applied our approaches to a number of application cases. Additionally, we have discussed our visualization designs with domain experts. They showed a genuine interest in our work and provided insightful suggestions for future research directions.
Består avPaper I: Andrea Brambilla, R. Carnecky, R. Peikert, I. Viola, H. Hauser. Illustrative flow visualization: State of the art, trends and challenges. Proc. of Eurographics 2012-State of the Art Reports, 75–94, 2012. The article is available at: http://hdl.handle.net/1956/8962.
Paper II: Andrea Brambilla, Ø. Andreassen, H. Hauser. Integrated Multi-aspect visualization of 3D Fluid Flows. Proc. of VMV 2013: Vision, Modeling & Visualization, 1–9, 2013. The article is available at: http://hdl.handle.net/1956/8963.
Paper III: Andrea Brambilla, I. Viola, H. Hauser. A Hierarchical Splitting Scheme to Reveal Insight into Highly Self-Occluded Integral Surfaces. Journal of WSCG, 20, 1, 57–64, 2012. The article is available at: http://hdl.handle.net/1956/8965.
Paper IV: Andrea Brambilla, P. Angelelli, Ø. Andreassen, H. Hauser. Comparative Visualization of Multiple Time Surfaces by Planar Surface Reformation. Full text not available in BORA.
Paper V: Andrea Brambilla, H. Hauser. Expressive Seeding of Multiple Stream Surfaces for Interactive Flow Exploration. Full text not available in BORA.