We present a numerical solver for the incompressible Navier–Stokes equations that combines fourth-order-accurate discrete approximations and an adaptive tree grid (i.e. h-refinement). The scheme employs a novel compact-upwind advection scheme and a 4th-order accurate projection algorithm whereby the numerical solution exactly satisfies the incompressibility constraint. Further, we introduce a new refinement indicator that is tailored to this solver. We show tests and examples to illustrate the consistency, convergence rate and the application for the adaptive solver. The combination of the solver scheme and the proposed grid adaptation algorithm result in fourth-order convergence rates whilst only tuning a single grid-refinement parameter. ...
Abstract: We describe two finite difference schemes for simulating incompressible flows on nonunifor...
A further investigation has been conducted for a previously proposed multiple one-dimensional adapti...
In this paper we present a method for solving the equations governing time-dependent, variable densi...
Summarization: A multigrid pressure correction scheme suitable for high order discretizations of the...
We present an algorithm for the solution of the incompressible Navier- Stokes equations combined wit...
The present paper describes a newly developed Navier-Stokes solver of fourth-order global spatial ac...
We outline a new class of robust and efficient methods for solving the Navier- Stokes equations. We ...
A quadtree grid method used in conjunction with a pressure-based flow solution algorithm for the inc...
We outline a new class of robust and efficient methods for solving the Navier–Stokes equations. We d...
We outline a new class of robust and efficient methods for solving the Navier-Stokes equations. We ...
none8siThis paper studies if adaptive grid refinement combined with finite-volume simulation of the ...
A non-linear multigrid solver for incompressible Navier-Stokes equations, exploiting finite volume d...
In this paper, we present a fourth-order in space and time block-structured adaptive mesh refinement...
A new node based upwind scheme for the solution of the 3D Navier- Stokes equations on adaptively ref...
Fluids (gases and liquids) exist everywhere around us. Water covers 70% of the Earth’s crust and gas...
Abstract: We describe two finite difference schemes for simulating incompressible flows on nonunifor...
A further investigation has been conducted for a previously proposed multiple one-dimensional adapti...
In this paper we present a method for solving the equations governing time-dependent, variable densi...
Summarization: A multigrid pressure correction scheme suitable for high order discretizations of the...
We present an algorithm for the solution of the incompressible Navier- Stokes equations combined wit...
The present paper describes a newly developed Navier-Stokes solver of fourth-order global spatial ac...
We outline a new class of robust and efficient methods for solving the Navier- Stokes equations. We ...
A quadtree grid method used in conjunction with a pressure-based flow solution algorithm for the inc...
We outline a new class of robust and efficient methods for solving the Navier–Stokes equations. We d...
We outline a new class of robust and efficient methods for solving the Navier-Stokes equations. We ...
none8siThis paper studies if adaptive grid refinement combined with finite-volume simulation of the ...
A non-linear multigrid solver for incompressible Navier-Stokes equations, exploiting finite volume d...
In this paper, we present a fourth-order in space and time block-structured adaptive mesh refinement...
A new node based upwind scheme for the solution of the 3D Navier- Stokes equations on adaptively ref...
Fluids (gases and liquids) exist everywhere around us. Water covers 70% of the Earth’s crust and gas...
Abstract: We describe two finite difference schemes for simulating incompressible flows on nonunifor...
A further investigation has been conducted for a previously proposed multiple one-dimensional adapti...
In this paper we present a method for solving the equations governing time-dependent, variable densi...