Extended galilean invariance for adaptive fluid simulation
M Shah, JM Cohen, S Patel, P Lee… - Proceedings of the 2004 …, 2004 - dl.acm.org
Proceedings of the 2004 ACM SIGGRAPH/Eurographics symposium on Computer …, 2004•dl.acm.org
In an unbounded physical domain, simulating a turbulent fluid on an Eulerian grid is rather
tricky. Since it is difficult to predict the motion of the fluid, it is also difficult to guess which
computational domain would allow the simulation of the fluid without crossing the
computational boundaries. To address this dilemma, we have developed a novel adaptive
framework where the simulation grid follows the motion of the flow. Our technique is based
on the principle of Galilean Invariance and the culling of simulation cells using a metric …
tricky. Since it is difficult to predict the motion of the fluid, it is also difficult to guess which
computational domain would allow the simulation of the fluid without crossing the
computational boundaries. To address this dilemma, we have developed a novel adaptive
framework where the simulation grid follows the motion of the flow. Our technique is based
on the principle of Galilean Invariance and the culling of simulation cells using a metric …
In an unbounded physical domain, simulating a turbulent fluid on an Eulerian grid is rather tricky. Since it is difficult to predict the motion of the fluid, it is also difficult to guess which computational domain would allow the simulation of the fluid without crossing the computational boundaries. To address this dilemma, we have developed a novel adaptive framework where the simulation grid follows the motion of the flow. Our technique is based on the principle of Galilean Invariance and the culling of simulation cells using a metric derived from continuative boundary conditions. We describe our framework and showcase its advantages over traditional techniques. Timing results and visual comparisons are presented.