Software
Main.Software History
Show minor edits - Show changes to markup
GERShWIN - discontinuous GalERkin Solver for microWave INteraction with biological tissues
(:linebreaks:) (:linebreaks:)
GERShWIN is a simulation software dedicated to the simulation of microwave interaction with biological tissues. GERShWIN is based on a high order DG method formulated on unstructured tetrahedral meshes for solving the 3D system of time-domain Maxwell equations coupled to a Debye dispersion model.
More details
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3D system of frequency-domain Maxwell equations.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3D system of frequency-domain Maxwell equations.\\
HORSE - High Order solver for Radar cross Section Evaluation
HORSE - High Order solver for Radar cross Section Evaluation
(:linebreaks:)
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3D system of frequency-domain Maxwell equations.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3D system of frequency-domain Maxwell equations.
DIOGENeS - DIscOntinuous GalErkin Nanoscale Solvers
(:linebreaks:)
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will officially start in January 2015 in the context of a Software Development Action supported by Inria (Direction of Technological Development).
DIOGENeS essentially relies on a two layer architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.
DIOGENeS is programmed in Fortran 2003 and the underlying algorithms are adapted to distributed memory (MPI) and shared memory (OpenMP) parallel computing.
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3D time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
Features of version V1.0 (currently planned for the end of 2016)
- Time-domain Maxwell equations in mixed form
- Drude, Drude-Lorentz and generalized dispersion models
- Linear isotropic and anisotropic media
- Affine and curvilinear tetrahedral elements
- Nodal DG schemes based on centered or upwind numerical fluxes
- Arbitrary high order nodal (Lagrange) interpolation of the field components within a mesh cell
- Explicit time-stepping schemes: 2nd and 4th order leap-frog, and optimized low storage Runge-Kutta schemes
- Silver-Muller absorbing boundary condition and PML
(:title:) Software
DIOGENeS essentially relies on a two layer architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.
DIOGENeS essentially relies on a two layer architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.
More details
DIOGENeS - DIscOntinuous GalErkin Nanoscale Solvers
(:linebreaks:)
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will officially start in January 2015 in the context of a Software Development Action supported by Inria (Direction of Technological Development).
DIOGENeS essentially relies on a two layer architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.
(:linebreaks:)
Software
(:linebreaks:) (:linebreaks:)
Features of version V1.0 (currently planned for the end of 2015)
Features of version V1.0 (currently planned for the end of 2016)
DIOGENeS - DIscOntinuous GalErkin Nanoscale Solver
DIOGENeS - DIscOntinuous GalErkin Nanoscale Solvers
DIOGENeS - DIscOntinuous GalErkin Nano Solver
DIOGENeS - DIscOntinuous GalErkin Nanoscale Solver
HORSE - High Order solver for Radar cross Section Evaluation
HORSE - High Order solver for Radar cross Section Evaluation
DIOGENeS - DIscOntinuous GalErkin Nano Solver
DIOGENeS - DIscOntinuous GalErkin Nano Solver
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3D time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3d system of frequency-domain Maxwell equations.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3D system of frequency-domain Maxwell equations.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project.
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project. HORSE is based on a high order HDG method formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes for solving the 3d system of frequency-domain Maxwell equations.
- linebreaks
- )
HORSE - High Order solver for Radar cross Section Evaluation
HORSE - High Order solver for Radar cross Section Evaluation
(:linebreaks:)
HORSE is a simulation software whose development has started in October 2014 in the context of the ANR TECSER project.
- linebreaks
- )
HORSE - High Order solver for Radar cross Section Evaluation
(:linebreaks:)
DIOGENeS is programmed in Fortran 2003 and the underlying algorithms are adapted to distributed memory (MPI) and shared memory (OpenMP) parallel computing.\\
DIOGENeS essentially relies on a two layers architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.\\
DIOGENeS essentially relies on a two layer architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.\\
DIOGENeS - DIscOntinuous GalErkin Nano Solver
(:linebreaks:)
DIOGENeS - DIscOntinuous GalErkin Nano Solver
DIOGENeS DIscOntinuous GalErkin Nano Solver
DIOGENeS - DIscOntinuous GalErkin Nano Solver
DIOGENeS essentially relies on a two layers architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various physical (material) models.\\
DIOGENeS essentially relies on a two layers architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various material models.\\
DIOGENeS essentially relies on a two layers architecture. The core of the suite is a library of generic software components (data structures and algorithms) for the implementation of high order DG and HDG schemes formulated on unstructured tetrahedral and hybrid structured/unstructured (cubic/tetrahedral) meshes. This library will be used to develop dedicated simulation software for time-domain and frequency-domain problems relevant to nanophotonics and nanoplasmonics, considering various physical (material) models.\\
Features of version V1.0 (currently planned for end of 2015)
Features of version V1.0 (currently planned for the end of 2015)
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.\\
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.\\
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will officially start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).\\
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will officially start in January 2015 in the context of a Software Development Action supported by Inria (Direction of Technological Development).\\
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will effectively start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).\\
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will officially start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).\\
DIOGENeS DIscOntinuous GalErkin Nano Solver
DIOGENeS DIscOntinuous GalErkin Nano Solver
DIscOntinuous GalErkin Nano Solver
DIscOntinuous GalErkin Nano Solver
DIOGENeS
DIscOntinuous GalErkin Nano Solver
DIOGENeS DIscOntinuous GalErkin Nano Solver
Features of version V1.0
Features of version V1.0 (currently planned for end of 2015)
!!! DIOGENeS
!!! DIscOntinuous GalErkin Nano Solver
DIOGENeS
DIscOntinuous GalErkin Nano Solver
DIOGENeS
DIscOntinuous GalErkin Nano Solver
!!! DIOGENeS
!!! DIscOntinuous GalErkin Nano Solver
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models.
This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
Features of version V1.0:
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models. This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
Features of version V1.0
DIOGENeS
DIscOntinuous GalErkin Nano Solver
DIOGENeS
DIscOntinuous GalErkin Nano Solver
(:linebreaks:)
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics.
Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will effectively start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics. Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will effectively start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).
This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
- Silver-Muller absorbing boundary condition and PML\\\
- Silver-Muller absorbing boundary condition and PML
(:linebreaks:)
DIOGENeS
DIscOntinuous GalErkin Nano Solver
(:linebreaks:) (:linebreaks:)
DIOGENeS is a software suite dedicated to the numerical modeling of light interaction with nanometer scale structures with applications to nanophotonics and nanoplasmonics.
Although the team is already working on several software components that will ultimately be part of this software suite, the development of DIOGENeS will effectively start in January 2015 in the context of Software Development Action supported by Inria (Direction of Technological Development).
With version V1.0 of this suite, the first dedicated simulation software relying on the core library of generic components will be a 3d time-domain Maxwell solver able to deal with local dispersion models.
This solver will be based on a nodal discontinuous Galerkin (DG) method formulated on a fully unstructured tetrahedral mesh.
Features of version V1.0:
- Time-domain Maxwell equations in mixed form
- Drude, Drude-Lorentz and generalized dispersion models
- Linear isotropic and anisotropic media
- Affine and curvilinear tetrahedral elements
- Nodal DG schemes based on centered or upwind numerical fluxes
- Arbitrary high order nodal (Lagrange) interpolation of the field components within a mesh cell
- Explicit time-stepping schemes: 2nd and 4th order leap-frog, and optimized low storage Runge-Kutta schemes
- Silver-Muller absorbing boundary condition and PML
>><<