Perfectly Matched Layers (PMLs) are widely used for the numerical simulation of wave-like problems defined on large or infinite spatial domains. However, for both the time-dependent and the time-harmonic cases, their performance critically depends on the so-called absorption function. This paper deals with the choice of this function when classical numerical methods are used (based on finite differences, finite volumes, continuous finite elements and discontinuous finite elements). After reviewing the properties of the PMLs at the continuous level, we analyse how they are altered by the different spatial discretizations. In the light of these results, different shapes of absorption function are optimized and compared by means of both one- a...
The perfectly matched layer (PML) boundary condition is generally employed to prevent spurious refle...
Absorbing boundary conditions are a requisite element of many computational wave prop-agation proble...
In electromagnetic compatibility, scattering problems are defined in an infinite spatial domain, whi...
International audiencePerfectly matched layers (PMLs) are widely used for the numerical simulation o...
Perfectly Matched Layers (PML) are widely used for the simulation of unbounded wave-like problems. ...
High-order absorbing boundary conditions (ABC) and perfectly matched layers (PML) are two powerful m...
The perfectly matched layer (PML) is a novel technique to simulate the absorption of waves in unboun...
The Perfectly Matched Layer (PML) is widely used for unbounded problems. However its performances d...
As an absorbing boundary in infinite domain problems, the perfectly matched layer (PML) is introduce...
It has been previously demonstrated that no reflection is generated when elastic (or electromagnetic...
The perfectly matched layer (PML) is a perfectly non-reflecting layer that simulates the absorption ...
One approach to the numerical solution of a wave equation on an unbounded domain uses a bounded doma...
The perfectly matched layer (PML) has recently been introduced by Berenger as a material absorbing b...
The main goal of this work is to give a review of the Perfectly Matched Layer (PML) technique for ti...
The main goal of this work is to give a review of the Perfectly Matched Layer (PML) technique for ti...
The perfectly matched layer (PML) boundary condition is generally employed to prevent spurious refle...
Absorbing boundary conditions are a requisite element of many computational wave prop-agation proble...
In electromagnetic compatibility, scattering problems are defined in an infinite spatial domain, whi...
International audiencePerfectly matched layers (PMLs) are widely used for the numerical simulation o...
Perfectly Matched Layers (PML) are widely used for the simulation of unbounded wave-like problems. ...
High-order absorbing boundary conditions (ABC) and perfectly matched layers (PML) are two powerful m...
The perfectly matched layer (PML) is a novel technique to simulate the absorption of waves in unboun...
The Perfectly Matched Layer (PML) is widely used for unbounded problems. However its performances d...
As an absorbing boundary in infinite domain problems, the perfectly matched layer (PML) is introduce...
It has been previously demonstrated that no reflection is generated when elastic (or electromagnetic...
The perfectly matched layer (PML) is a perfectly non-reflecting layer that simulates the absorption ...
One approach to the numerical solution of a wave equation on an unbounded domain uses a bounded doma...
The perfectly matched layer (PML) has recently been introduced by Berenger as a material absorbing b...
The main goal of this work is to give a review of the Perfectly Matched Layer (PML) technique for ti...
The main goal of this work is to give a review of the Perfectly Matched Layer (PML) technique for ti...
The perfectly matched layer (PML) boundary condition is generally employed to prevent spurious refle...
Absorbing boundary conditions are a requisite element of many computational wave prop-agation proble...
In electromagnetic compatibility, scattering problems are defined in an infinite spatial domain, whi...