Computer Methods in Applied Mechanics and Engineering
Viscous flow with large free surface motion
Computer Methods in Applied Mechanics and Engineering
Computer Methods in Applied Mechanics and Engineering
Computer Methods in Applied Mechanics and Engineering
HPCA '95 Proceedings of the 1st IEEE Symposium on High-Performance Computer Architecture
Parallel finite element computation of incompressible flows
Parallel Computing
Space---time SUPG finite element computation of shallow-water flows with moving shorelines
Computational Mechanics
A parallel sparse algorithm targeting arterial fluid mechanics computations
Computational Mechanics
Stabilized space---time computation of wind-turbine rotor aerodynamics
Computational Mechanics
Multiscale space---time fluid---structure interaction techniques
Computational Mechanics
Space---time FSI modeling and dynamical analysis of spacecraft parachutes and parachute clusters
Computational Mechanics
Fluid---structure interaction modeling of wind turbines: simulating the full machine
Computational Mechanics
Toward free-surface modeling of planing vessels: simulation of the Fridsma hull using ALE-VMS
Computational Mechanics
Patient-specific computer modeling of blood flow in cerebral arteries with aneurysm and stent
Computational Mechanics
The generation of arbitrary order curved meshes for 3D finite element analysis
Computational Mechanics
Space---time computation techniques with continuous representation in time (ST-C)
Computational Mechanics
Space---time VMS computation of wind-turbine rotor and tower aerodynamics
Computational Mechanics
Fluid---structure interaction simulation of pulsatile ventricular assist devices
Computational Mechanics
On numerical modeling of animal swimming and flight
Computational Mechanics
Finite element computation and experimental validation of sloshing in rectangular tanks
Computational Mechanics
Hi-index | 4.10 |
The authors describe their work on the massively parallel finite-element computation of compressible and incompressible flows with the CM-200 and CM-5 Connection Machines. Their computations are based on implicit methods, and their parallel implementations are based on the assumption that the mesh is unstructured. Computations for flow problems involving moving boundaries and interfaces are achieved by using the deformable-spatial-domain/stabilized-space-time method. Using special mesh update schemes, the frequency of remeshing is minimized to reduce the projection errors involved and also to make parallelizing the computations easier. This method and its implementation on massively parallel supercomputers provide a capability for solving a large class of practical problems involving free surfaces, two-liquid interfaces, and fluid-structure interactions.