Nonreflecting boundary conditions are essential elements in the computation of many compressible flows. Such simulations are very sensitive to the treatment of acoustic waves at boundaries. Nonreflecting conditions allow acoustic waves to propagate through boundaries with zero or small levels of reflection into the domain. However, perfectly nonreflecting conditions must be avoided because they can lead to ill-posed problems for the mean flow. Various methods have been proposed to construct boundary conditions that can be sufficiently nonreflecting for the acoustic field while still making the mean flow problem well-posed. A widely used technique for nonreflectin
About a half of applied problems in mathematical physics are formulated for infinite spatial domains...
Many compressible flow and aeroacoustic computations rely on accurate nonre-flecting or radiation bo...
The performance of several non-reflective acoustic boundary conditions is quantitatively compared us...
The accuracy of existing impedance boundary conditions is investigated, and new impedance boundary c...
The actual impedance of non-reflecting boundary conditions: implications for the computation of reso...
Accurate nonreflecting or radiation boundary conditions are important for effective computation of a...
Non-reflective boundary conditions for prediction of acoustic tones in non-uniform mean flow for duc...
Direct aeroacoustic computations require nonreflective boundary conditions that allow disturbances t...
A simple method is used to quantify the performance of non-reflecting boundary conditions for duct a...
A novel nonreflecting boundary condition, which converges to the specified time-dependent boundary c...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
About a half of applied problems in mathematical physics are formulated for infinite spatial domains...
Many compressible flow and aeroacoustic computations rely on accurate nonre-flecting or radiation bo...
The performance of several non-reflective acoustic boundary conditions is quantitatively compared us...
The accuracy of existing impedance boundary conditions is investigated, and new impedance boundary c...
The actual impedance of non-reflecting boundary conditions: implications for the computation of reso...
Accurate nonreflecting or radiation boundary conditions are important for effective computation of a...
Non-reflective boundary conditions for prediction of acoustic tones in non-uniform mean flow for duc...
Direct aeroacoustic computations require nonreflective boundary conditions that allow disturbances t...
A simple method is used to quantify the performance of non-reflecting boundary conditions for duct a...
A novel nonreflecting boundary condition, which converges to the specified time-dependent boundary c...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
The quality of any time-domain nonlinear CFD simulation of silencers is determined by the modeling p...
About a half of applied problems in mathematical physics are formulated for infinite spatial domains...
Many compressible flow and aeroacoustic computations rely on accurate nonre-flecting or radiation bo...
The performance of several non-reflective acoustic boundary conditions is quantitatively compared us...