A Flux-Correction Form of the Third-Order Edge-Based Scheme for a General Numerical Flux Function
This is an incremental improvement for computational fluid dynamics researchers, allowing more flexible flux choices in high-order simulations.
The authors tackled the problem of enabling a third-order edge-based scheme for the Euler equations to use general numerical flux functions, achieving third-order accuracy as verified with HLLC and LDFSS fluxes on irregular tetrahedral grids.
In this short note, we present a flux-correction form of the third-order edge-based scheme for the Euler equations that enables the direct use of a general flux function. The core idea is to replace, without loss of accuracy, the arithmetic average of the flux extrapolations by a general numerical flux evaluated at the edge midpoint, together with a correction term. We show that the proposed flux-correction form preserves third-order accuracy, provided that the general numerical flux is evaluated with the left and right states that are computed exactly for a quadratic function, which can be achieved effectively by the U-MUSCL scheme with κ = 1/2. Numerical results are presented to verify third-order accuracy with the HLLC and LDFSS flux functions on irregular tetrahedral grids.