In this paper we present an analytical model of Perfectly Matched Layers for flexural waves within elongated beam structures. The model is based on transformation optics techniques and it is shown to work both in time harmonic and transient regimes. A comparison between flexural and longitudinal waves is detailed and it is shown that the bending problem requires special interface conditions. A connection with transformation of eigenfrequencies and eigenmodes is given and the effect of the additional boundary conditions introduced at the border of the Perfectly Matched Layer domain is discussed in detailed. Such a model is particularly useful for Finite Element analyses pertaining propagating flexural waves in infinite domain
International audienceThis review article revisits and outlines the perfectly matched layer (PML) me...
This brief article outlines a new and rather simple method for obtaining the finite element matrices...
International audienceIn this article we discuss different techniques to solve numerically wave prop...
In this paper we present an analytical model of Perfectly Matched Layers for flexural waves within e...
The work is divided into two main topics. In the first part a formulation for Perfectly Matched Laye...
We propose Perfectly Matched Layers (PMLs) for flexural waves in plate structures. The analytical mo...
One approach to the numerical solution of a wave equation on an unbounded domain uses a bounded doma...
A general convolutional version of perfectly matched layer (PML) formulation for second-order wave e...
The paper presents new results on the localization and transmission of flexural waves in a structure...
In this paper, the linear transformation method (LTM) to control flexural waves propagating in thin ...
This paper explores the coupling of the perfectly matched layer technique (PML) with the thin layer ...
International audienceAn efficient method to compute the scattering of a guided wave by a localized ...
The paper addresses an important issue of cloaking transformations for fourth-order partial differen...
It is known that design of elastic cloaks is much more challenging than that of acoustic cloaks, clo...
The presence of wave motion is the defining feature in many fields of application,such as electro-ma...
International audienceThis review article revisits and outlines the perfectly matched layer (PML) me...
This brief article outlines a new and rather simple method for obtaining the finite element matrices...
International audienceIn this article we discuss different techniques to solve numerically wave prop...
In this paper we present an analytical model of Perfectly Matched Layers for flexural waves within e...
The work is divided into two main topics. In the first part a formulation for Perfectly Matched Laye...
We propose Perfectly Matched Layers (PMLs) for flexural waves in plate structures. The analytical mo...
One approach to the numerical solution of a wave equation on an unbounded domain uses a bounded doma...
A general convolutional version of perfectly matched layer (PML) formulation for second-order wave e...
The paper presents new results on the localization and transmission of flexural waves in a structure...
In this paper, the linear transformation method (LTM) to control flexural waves propagating in thin ...
This paper explores the coupling of the perfectly matched layer technique (PML) with the thin layer ...
International audienceAn efficient method to compute the scattering of a guided wave by a localized ...
The paper addresses an important issue of cloaking transformations for fourth-order partial differen...
It is known that design of elastic cloaks is much more challenging than that of acoustic cloaks, clo...
The presence of wave motion is the defining feature in many fields of application,such as electro-ma...
International audienceThis review article revisits and outlines the perfectly matched layer (PML) me...
This brief article outlines a new and rather simple method for obtaining the finite element matrices...
International audienceIn this article we discuss different techniques to solve numerically wave prop...