Purpose-In this work, an SFEM is proposed for solving acoustic problems by redistributing the entries in the mass matrix to "tune" the balance between "stiffness" and "mass" of discrete equation systems, aiming to minimize the dispersion error. The paper aims to discuss this issue. Design/methodology/approach-This is done by simply shifting the four integration points' locations when computing the entries of the mass matrix in the scheme of SFEM, while ensuring the mass conservation. The proposed method is devised for bilinear quadratic elements. Findings-The balance between "stiffness" and "mass" of discrete equation systems is critically important in simulating wave propagation problems such as acoustics. A formula is also derived for pos...
This paper considers the extension of the frequency application range of the finite element method (...
This paper discusses the use of wave based prediction methods for the analysis of steady-state inter...
This work describes two perspectives for understanding the numerical difficulties that arise in the ...
A 2D mass-redistributed finite element method (MR-FEM) for pure acoustic problems was recently propo...
Wave-based methods for acoustic simulations within enclosures suffer the numerical dispersion and th...
Modeling and simulation of the acoustic response in enclosed cavities of a diesel engine are of grea...
Finite-element discretizations of the acoustic wave equation in the time domain often employ mass lu...
This thesis studies the construction of improved mass matrices for dynamic structural analysis using...
This paper deals with the numerical simulation of the acoustic wave propagation. It is well known to...
We present new and efficient quadrature rules for computing the stiffness matrices of mass-lumped te...
10.1002/nme.3100International Journal for Numerical Methods in Engineering86111322-1338IJNM
International audienceGalerkin/least-squares and Galerkin gradient/least-squares stand out among sev...
Conforming Galerkin discretization of the constant-density acoustic wave equation provides optimal o...
The finite element method (FEM) is widely accepted for the steady-state dynamic response analysis of...
Efficient finite element techniques for time harmonic structural acoustics are developed and examine...
This paper considers the extension of the frequency application range of the finite element method (...
This paper discusses the use of wave based prediction methods for the analysis of steady-state inter...
This work describes two perspectives for understanding the numerical difficulties that arise in the ...
A 2D mass-redistributed finite element method (MR-FEM) for pure acoustic problems was recently propo...
Wave-based methods for acoustic simulations within enclosures suffer the numerical dispersion and th...
Modeling and simulation of the acoustic response in enclosed cavities of a diesel engine are of grea...
Finite-element discretizations of the acoustic wave equation in the time domain often employ mass lu...
This thesis studies the construction of improved mass matrices for dynamic structural analysis using...
This paper deals with the numerical simulation of the acoustic wave propagation. It is well known to...
We present new and efficient quadrature rules for computing the stiffness matrices of mass-lumped te...
10.1002/nme.3100International Journal for Numerical Methods in Engineering86111322-1338IJNM
International audienceGalerkin/least-squares and Galerkin gradient/least-squares stand out among sev...
Conforming Galerkin discretization of the constant-density acoustic wave equation provides optimal o...
The finite element method (FEM) is widely accepted for the steady-state dynamic response analysis of...
Efficient finite element techniques for time harmonic structural acoustics are developed and examine...
This paper considers the extension of the frequency application range of the finite element method (...
This paper discusses the use of wave based prediction methods for the analysis of steady-state inter...
This work describes two perspectives for understanding the numerical difficulties that arise in the ...