AbstractNumerical tests are used to evaluate the accuracy of two finite element formulations associated with the discrete ordinates method for solving the radiative transfer equation: the Least Square and the Discontinuous Galerkin finite element formulations. The results show that the use of a penalization method to set the Dirichlet boundary conditions leads to a more accurate solution than the weakly type setting where the Least Square method is seen to be more sensitive. Convergence in mesh size shows that, while both methods give accurate results, the Discontinuous Galerkin formulation uses five times more degrees of freedom than the Least Square formulation, which may lead to large systems to handle when the number of mesh elements is...
This two part study introduces new developments in frequency domain optical tomography to take into ...
The discrete ordinates method has evolved as a powerful tool in the analysis of radiative heat trans...
This paper presents a robust and accurate way to solve steady-state linear transport (radiative tran...
Optical tomography is an inverse method of probing semi-transparent media with the help of light sou...
In optical tomography, the optical properties are recovered through an iterative scheme, which consi...
We present a method for the treatment of the time dependent radiative transfer equation under the di...
Abstract: Weighted mesh approximations of the radiation transport equation corresponding t...
The stationary monochromatic radiative transfer equation (RTE) is a partial differential transport e...
The time-dependent equation of radiative transfer is solved for an axisymmetric cylindrical medium u...
Abstract. Optical tomography consists in reconstructing the spatial distribution of absorption and s...
This research article discusses a numerical solution of the radiative transfer equation based on the...
A finite element method for solving the monochromatic radiation transfer equation including scatteri...
The stationary monochromatic radiative transfer equation (RTE) is a partial differential transport e...
International audienceWe examine the accuracy of a modified finite volume method compared to analyti...
Predictive accuracy of the method-of-lines (MOL) solution of discrete ordinates method (DOM) for tra...
This two part study introduces new developments in frequency domain optical tomography to take into ...
The discrete ordinates method has evolved as a powerful tool in the analysis of radiative heat trans...
This paper presents a robust and accurate way to solve steady-state linear transport (radiative tran...
Optical tomography is an inverse method of probing semi-transparent media with the help of light sou...
In optical tomography, the optical properties are recovered through an iterative scheme, which consi...
We present a method for the treatment of the time dependent radiative transfer equation under the di...
Abstract: Weighted mesh approximations of the radiation transport equation corresponding t...
The stationary monochromatic radiative transfer equation (RTE) is a partial differential transport e...
The time-dependent equation of radiative transfer is solved for an axisymmetric cylindrical medium u...
Abstract. Optical tomography consists in reconstructing the spatial distribution of absorption and s...
This research article discusses a numerical solution of the radiative transfer equation based on the...
A finite element method for solving the monochromatic radiation transfer equation including scatteri...
The stationary monochromatic radiative transfer equation (RTE) is a partial differential transport e...
International audienceWe examine the accuracy of a modified finite volume method compared to analyti...
Predictive accuracy of the method-of-lines (MOL) solution of discrete ordinates method (DOM) for tra...
This two part study introduces new developments in frequency domain optical tomography to take into ...
The discrete ordinates method has evolved as a powerful tool in the analysis of radiative heat trans...
This paper presents a robust and accurate way to solve steady-state linear transport (radiative tran...