Title :
Baroclinic Turbulence with Varying Density and Temperature
Author :
Kim, Doyub ; Lee, Seung Woo ; Song, Oh-young ; Ko, Hyeong-Seok
Author_Institution :
Graphics Lab., Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
The explosive or volcanic scenes in motion pictures involve complex turbulent flow as its temperature and density vary in space. To simulate this turbulent flow of an inhomogeneous fluid, we propose a simple and efficient framework. Instead of explicitly computing the complex motion of this fluid dynamical instability, we first approximate the average motion of the fluid. Then, the high-resolution dynamics is computed using our new extended version of the vortex particle method with baroclinity. This baroclinity term makes turbulent effects by generating new vortex particles according to temperature/density distributions. Using our method, we efficiently simulated a complex scene with varying density and temperature.
Keywords :
computational fluid dynamics; computer animation; flow instability; turbulence; vortices; baroclinic turbulence; baroclinity term; complex motion; complex turbulent flow; fluid dynamical instability; high-resolution dynamics; inhomogeneous fluid; motion pictures; turbulent effects; varying density; varying temperature; volcanic scenes; vortex particle; vortex particles; Computational modeling; Computer graphics; Equations; Force; Heating; Mathematical model; Nonhomogeneous media; Fluid animation; turbulent flow; variable density; vortex particle method.;
Journal_Title :
Visualization and Computer Graphics, IEEE Transactions on
DOI :
10.1109/TVCG.2011.264
