AbstractWe present a numerical scheme geared for high performance computation of wall-bounded turbulent flows. The number of all-to-all communications is decreased to only six instances by using a two-dimensional (pencil) domain decomposition and utilizing the favourable scaling of the CFL time-step constraint as compared to the diffusive time-step constraint. As the CFL condition is more restrictive at high driving, implicit time integration of the viscous terms in the wall-parallel directions is no longer required. This avoids the communication of non-local information to a process for the computation of implicit derivatives in these directions. We explain in detail the numerical scheme used for the integration of the equations, and the u...
In this article we discuss a strategy for speeding up the solution of the Navier—Stokes equations on...
Physics-based simulation, Computational Fluid Dynamics (CFD) in particular, has substantially reshap...
An algorithm for the Direct Numerical Simulation (DNS) of the incompressible Navier–Stokes equations...
We present a numerical scheme geared for high performance computation of wall-bounded turbulentflows...
AbstractWe present a numerical scheme geared for high performance computation of wall-bounded turbul...
AbstractFuture architectures designed to deliver exascale performance motivate the need for novel al...
Implicit finite difference schemes are often the preferred numerical schemes in computational fluid ...
In recent years, the increased use of off-the-shelf components and the large-scale adoption of paral...
In the present work, a highly efficient incompressible flow solver with a semi-implicit time advance...
Turbulence is inherent in fluid dynamics, in that laminar flows are rather the exception than the ru...
We present a reformulation of unsteady turbulent flow simulations. The initial condition is relaxed ...
A new parallel numerical scheme for solving incompressible steady-state flows is presented. The algo...
Nearly all moving objects on Earth pass through fluids and many of them move at high speed. This mak...
A new method to perform direct numerical simulations of wall-bounded flows has been developed and im...
A set of direct simulations of zero-pressure gradient, turbulent boundary layer flows are conducted ...
In this article we discuss a strategy for speeding up the solution of the Navier—Stokes equations on...
Physics-based simulation, Computational Fluid Dynamics (CFD) in particular, has substantially reshap...
An algorithm for the Direct Numerical Simulation (DNS) of the incompressible Navier–Stokes equations...
We present a numerical scheme geared for high performance computation of wall-bounded turbulentflows...
AbstractWe present a numerical scheme geared for high performance computation of wall-bounded turbul...
AbstractFuture architectures designed to deliver exascale performance motivate the need for novel al...
Implicit finite difference schemes are often the preferred numerical schemes in computational fluid ...
In recent years, the increased use of off-the-shelf components and the large-scale adoption of paral...
In the present work, a highly efficient incompressible flow solver with a semi-implicit time advance...
Turbulence is inherent in fluid dynamics, in that laminar flows are rather the exception than the ru...
We present a reformulation of unsteady turbulent flow simulations. The initial condition is relaxed ...
A new parallel numerical scheme for solving incompressible steady-state flows is presented. The algo...
Nearly all moving objects on Earth pass through fluids and many of them move at high speed. This mak...
A new method to perform direct numerical simulations of wall-bounded flows has been developed and im...
A set of direct simulations of zero-pressure gradient, turbulent boundary layer flows are conducted ...
In this article we discuss a strategy for speeding up the solution of the Navier—Stokes equations on...
Physics-based simulation, Computational Fluid Dynamics (CFD) in particular, has substantially reshap...
An algorithm for the Direct Numerical Simulation (DNS) of the incompressible Navier–Stokes equations...