Title :
Virtual Rheoscopic Fluids
Author :
Hecht, Florian ; Mucha, Peter J. ; Turk, Greg
Author_Institution :
Coll. of Comput., Georgia Inst. of Technol., Atlanta, GA, USA
Abstract :
We present a visualization technique for simulated fluid dynamics data that visualizes the gradient of the velocity field in an intuitive way. Our work is inspired by rheoscopic particles, which are small, flat particles that, when suspended in fluid, align themselves with the shear of the flow. We adopt the physical principles of real rheoscopic particles and apply them, in model form, to 3D velocity fields. By simulating the behavior and reflectance of these particles, we are able to render 3D simulations in a way that gives insight into the dynamics of the system. The results can be rendered in real time, allowing the user to inspect the simulation from all perspectives. We achieve this by a combination of precomputations and fast ray tracing on the GPU. We demonstrate our method on several different simulations, showing their complex dynamics in the process.
Keywords :
computational fluid dynamics; flow simulation; flow visualisation; ray tracing; reflectivity; shear flow; 3D velocity fields; particle reflectance; ray tracing; rheoscopic particles; shear flow; simulated fluid dynamics data; velocity field gradient visualization; virtual rheoscopic fluid; Animation; Application software; Computational fluid dynamics; Computational modeling; Computer science; Data visualization; Fluid dynamics; Ray tracing; Reflectivity; Tensile stress; Rheoscopic fluid; ellipsoidal particle dynamics.; flow visualization; tensor field visualization; Computer Graphics; Computer Simulation; Imaging, Three-Dimensional; Models, Theoretical; Rheology; User-Computer Interface;
Journal_Title :
Visualization and Computer Graphics, IEEE Transactions on
DOI :
10.1109/TVCG.2009.46
