A Finite Element Method for Angular Discretization of the Radiation Transport Equation on Spherical Geodesic Grids

12/02/2022

∙

Discrete ordinate (S_N) and filtered spherical harmonics (FP_N) based schemes have been proven to be robust and accurate in solving the Boltzmann transport equation but they have their own strengths and weaknesses in different physical scenarios. We present a new method based on a finite element approach in angle that combines the strengths of both methods and mitigates their disadvantages. The angular variables are specified on a spherical geodesic grid with functions on the sphere being represented using a finite element basis. A positivity-preserving limiting strategy is employed to prevent non-physical values from appearing in the solutions. The resulting method is then compared with both S_N and FP_N schemes using four test problems and is found to perform well when one of the other methods fail.

READ FULL TEXT

A Finite Element Method for Angular Discretization of the Radiation Transport Equation on Spherical Geodesic Grids

Finite element solution of a radiation/propagation problem for a Helmholtz equation with a compactly supported nonlinearity

An Angular Multigrid Preconditioner for the Radiation Transport Equation with Forward-Peaked Scatter

Advanced Modeling of Rectangular Waveguide Devices with Smooth Profiles by Hierarchical Model Reduction

Solving the Discretised Boltzmann Transport Equations using Neural Networks: Applications in Neutron Transport

Hermite-Chebyshev pseudospectral method for inhomogeneous superconducting strip problems and magnetic flux pump modeling

Goal-based angular adaptivity for Boltzmann transport in the presence of ray-effects

Angle Sensitive Pixels for Lensless Imaging on Spherical Sensors

A Finite Element Method for Angular Discretization of the Radiation Transport Equation on Spherical Geodesic Grids

Related Research

Finite element solution of a radiation/propagation problem for a Helmholtz equation with a compactly supported nonlinearity

An Angular Multigrid Preconditioner for the Radiation Transport Equation with Forward-Peaked Scatter

Advanced Modeling of Rectangular Waveguide Devices with Smooth Profiles by Hierarchical Model Reduction

Solving the Discretised Boltzmann Transport Equations using Neural Networks: Applications in Neutron Transport

Hermite-Chebyshev pseudospectral method for inhomogeneous superconducting strip problems and magnetic flux pump modeling

Goal-based angular adaptivity for Boltzmann transport in the presence of ray-effects

Angle Sensitive Pixels for Lensless Imaging on Spherical Sensors