International audienceThis work concerns the variational formulation and the numerical computation of internal acoustic problems with absorbing walls. The originality of the proposed approach, compared to other existing methods, is the introduction of the normal fluid displacement field on the damped walls. This additional variable allows to transpose formulations in frequency domain to time domain when the fluid is described by a scalar field (pressure or fluid displacement potential). With this new scalar unknown, various absorbing wall models can be introduced in the variational formulation. Moreover, the associated finite element matrix system in symmetric form can be solved in frequency and time domain
Within the framework of the state-of-the-art, this paper presents a summary of some common research ...
International audienceThe well-posedness of the acoustic radiation in a 2D duct in presence of both ...
The numerical treatment of noise insulation of solid walls has been an object of scientific research...
International audienceThis work concerns finite elements modeling of vibroacoustic internal problems...
International audienceThis work concerns the variational formulation and the numerical computation o...
This paper presents an advanced computational method for the prediction of the responses in the freq...
Numerical models for the calculation of sound transmission in double walls are presented. The finite...
This thesis investigates structure-acoustic systems by use of finite element analysis. The systems s...
An alternative approach based on the use of reverberation time measurements to characterize the boun...
International audienceThe problem under consideration relates to a model of porous wall devoted to a...
The Fourier method is applied to the description of the room acoustics field with the combination of...
This paper presents a new model for modelling locally reacting walls, that can be used in finite dif...
A finite element method is applied to compute the vibrations of an elastoacoustic system subject to ...
© 2018 Elsevier Ltd A method is developed for computing the mean and variance of the diffuse field s...
International audienceThis paper presents an advanced computational method for the prediction of the...
Within the framework of the state-of-the-art, this paper presents a summary of some common research ...
International audienceThe well-posedness of the acoustic radiation in a 2D duct in presence of both ...
The numerical treatment of noise insulation of solid walls has been an object of scientific research...
International audienceThis work concerns finite elements modeling of vibroacoustic internal problems...
International audienceThis work concerns the variational formulation and the numerical computation o...
This paper presents an advanced computational method for the prediction of the responses in the freq...
Numerical models for the calculation of sound transmission in double walls are presented. The finite...
This thesis investigates structure-acoustic systems by use of finite element analysis. The systems s...
An alternative approach based on the use of reverberation time measurements to characterize the boun...
International audienceThe problem under consideration relates to a model of porous wall devoted to a...
The Fourier method is applied to the description of the room acoustics field with the combination of...
This paper presents a new model for modelling locally reacting walls, that can be used in finite dif...
A finite element method is applied to compute the vibrations of an elastoacoustic system subject to ...
© 2018 Elsevier Ltd A method is developed for computing the mean and variance of the diffuse field s...
International audienceThis paper presents an advanced computational method for the prediction of the...
Within the framework of the state-of-the-art, this paper presents a summary of some common research ...
International audienceThe well-posedness of the acoustic radiation in a 2D duct in presence of both ...
The numerical treatment of noise insulation of solid walls has been an object of scientific research...