TY - GEN
T1 - A multiscale approach to mesh-based surface tension flows
AU - Thürey, Nils
AU - Wojtan, Chris
AU - Gross, Markus
AU - Turk, Greg
N1 - Publisher Copyright:
© 2010 ACM.
PY - 2010/7/26
Y1 - 2010/7/26
N2 - We present an approach to simulate flows driven by surface tension based on triangle meshes. Our method consists of two simulation layers: the first layer is an Eulerian method for simulating surface tension forces that is free from typical strict time step constraints. The second simulation layer is a Lagrangian finite element method that simulates sub-grid scale wave details on the fluid surface. The surface wave simulation employs an unconditionally stable, symplectic time integration method that allows for a high propagation speed due to strong surface tension. Our approach can naturally separate the grid- and sub-grid scales based on a volume-preserving mean curvature flow. As our model for the sub-grid dynamics enforces a local conservation of mass, it leads to realistic pinch off and merging effects. In addition to this method for simulating dynamic surface tension effects, we also present an efficient non-oscillatory approximation for capturing damped surface tension behavior. These approaches allow us to efficiently simulate complex phenomena associated with strong surface tension, such as Rayleigh-Plateau instabilities and crown splashes, in a short amount of time.
AB - We present an approach to simulate flows driven by surface tension based on triangle meshes. Our method consists of two simulation layers: the first layer is an Eulerian method for simulating surface tension forces that is free from typical strict time step constraints. The second simulation layer is a Lagrangian finite element method that simulates sub-grid scale wave details on the fluid surface. The surface wave simulation employs an unconditionally stable, symplectic time integration method that allows for a high propagation speed due to strong surface tension. Our approach can naturally separate the grid- and sub-grid scales based on a volume-preserving mean curvature flow. As our model for the sub-grid dynamics enforces a local conservation of mass, it leads to realistic pinch off and merging effects. In addition to this method for simulating dynamic surface tension effects, we also present an efficient non-oscillatory approximation for capturing damped surface tension behavior. These approaches allow us to efficiently simulate complex phenomena associated with strong surface tension, such as Rayleigh-Plateau instabilities and crown splashes, in a short amount of time.
KW - Fluid simulation
KW - Physically based animation
KW - Surface tension
UR - http://www.scopus.com/inward/record.url?scp=85029592432&partnerID=8YFLogxK
U2 - 10.1145/1778765.1778785
DO - 10.1145/1778765.1778785
M3 - Conference contribution
AN - SCOPUS:85029592432
T3 - ACM SIGGRAPH 2010 Papers, SIGGRAPH 2010
BT - ACM SIGGRAPH 2010 Papers, SIGGRAPH 2010
A2 - Hoppe, Hugues
PB - Association for Computing Machinery, Inc
T2 - 37th International Conference and Exhibition on Computer Graphics and Interactive Techniques, SIGGRAPH 2010
Y2 - 26 July 2010 through 30 July 2010
ER -