AbstractThe paper presents a finite volume numerical method universally applicable for solving both linear and nonlinear aeroacoustics problems on arbitrary unstructured meshes. It is based on the vertex centered multi-parameter scheme offering up to the 6th accuracy order achieved on the Cartesian meshes. An adaptive dissipation is added for the numerical treatment of possible discontinuities. The scheme properties are studied on a series of test cases, its efficiency is demonstrated at simulating the noise suppression in resonance-type liners
A novel optimized framework for unstructured finite-volume methods is presented, with an emphasis on...
The numerical simulation of aeroacoustic phenomena requires high-order accurate numerical schemes wi...
In developing suitable numerical techniques for computational aero-acoustics, the dispersion-relatio...
AbstractComputational fluid dynamics (CFD) has become increasingly used in the industry for the simu...
A finite volume-based high-order scheme with optimized dispersion and dissipation characteristics in...
Computational aeroacoustics requires numerical techniques capable of yielding low artificial dispers...
A new numerical method toward accurate and efficient aeroacoustic computations of multi-dimensional ...
High-order cell-vertex finite difference schemes applied to multi-block structured grids are used wi...
An adaptive nonlinear artificial dissipation model is presented for performing aeroacoustic computat...
International audienceIn this paper, a numerical method for solving the linearized Navier-Stokes equ...
In this work a patched grid technique is proposed with the aim of increasing the flexi-bility and ef...
This paper reports on the development of an accurate and easy-to-use prediction tool for the propaga...
A Discontinuous Galerkin Method is applied to unstructured grids to simulate aeroacoustic propagatio...
Using an unstructured grid, for which the mesh size is adapted to the local flow and acoustic soluti...
A Discontinuous Galerkin Method is applied to unstructured grids to simulate aeroacoustic propagatio...
A novel optimized framework for unstructured finite-volume methods is presented, with an emphasis on...
The numerical simulation of aeroacoustic phenomena requires high-order accurate numerical schemes wi...
In developing suitable numerical techniques for computational aero-acoustics, the dispersion-relatio...
AbstractComputational fluid dynamics (CFD) has become increasingly used in the industry for the simu...
A finite volume-based high-order scheme with optimized dispersion and dissipation characteristics in...
Computational aeroacoustics requires numerical techniques capable of yielding low artificial dispers...
A new numerical method toward accurate and efficient aeroacoustic computations of multi-dimensional ...
High-order cell-vertex finite difference schemes applied to multi-block structured grids are used wi...
An adaptive nonlinear artificial dissipation model is presented for performing aeroacoustic computat...
International audienceIn this paper, a numerical method for solving the linearized Navier-Stokes equ...
In this work a patched grid technique is proposed with the aim of increasing the flexi-bility and ef...
This paper reports on the development of an accurate and easy-to-use prediction tool for the propaga...
A Discontinuous Galerkin Method is applied to unstructured grids to simulate aeroacoustic propagatio...
Using an unstructured grid, for which the mesh size is adapted to the local flow and acoustic soluti...
A Discontinuous Galerkin Method is applied to unstructured grids to simulate aeroacoustic propagatio...
A novel optimized framework for unstructured finite-volume methods is presented, with an emphasis on...
The numerical simulation of aeroacoustic phenomena requires high-order accurate numerical schemes wi...
In developing suitable numerical techniques for computational aero-acoustics, the dispersion-relatio...