Grunnleggende konsepter
The authors present a provably energy stable high-order discontinuous Galerkin (DG) method for solving the acoustic wave equation on cut meshes. They pair the DG scheme with state redistribution, a technique to address the small cell problem on cut meshes, and prove that the resulting scheme remains energy stable.
Sammendrag
The authors present a high-order energy stable discontinuous Galerkin (DG) method for solving the acoustic wave equation on cut meshes. The key points are:
- The DG formulation is derived in skew-symmetric form to ensure energy stability under arbitrary quadrature rules, which are necessary for cut elements.
- State redistribution is used to address the small cell problem on cut meshes by merging and redistributing the solution on small cut elements.
- The authors prove that state redistribution can be added to the energy stable DG scheme without damaging its energy stability.
- Numerical experiments are performed to verify the high-order accuracy, energy stability, and CFL condition relaxation of the scheme on 2D wave propagation problems, including a comparison to the "Pacman" benchmark.
Statistikk
1
c2
∂p
∂t + ∇· u = 0
∂u
∂t + ∇p = 0
The acoustic wave equation governing the pressure p and velocity u.
Sitater
"Cut meshes are a type of mesh that is formed by allowing embedded boundaries to "cut" a simple underlying mesh resulting in a hybrid mesh of cut and standard elements."
"State redistribution can be used to address the small cell problem."
"We prove that state redistribution can be added to a provably L2 energy stable discontinuous Galerkin method on a cut mesh without damaging the scheme's L2 stability."