| Abstract: | A concept of "static reconstruction" and "dynamic reconstruction" was introduced for higher-order (third-order or more) numerical methods in our previous
work. Based on this concept, a class of hybrid DG/FV methods had been developed
for one-dimensional conservation law using a "hybrid reconstruction" approach, and
extended to two-dimensional scalar equations on triangular and Cartesian/triangular
hybrid grids. In the hybrid DG/FV schemes, the lower-order derivatives of the piecewise polynomial are computed locally in a cell by the traditional DG method (called
as "dynamic reconstruction"), while the higher-order derivatives are reconstructed by
the "static reconstruction" of the FV method, using the known lower-order derivatives
in the cell itself and in its adjacent neighboring cells. In this paper, the hybrid DG/FV
schemes are extended to two-dimensional Euler equations on triangular and Cartesian/triangular hybrid grids. Some typical test cases are presented to demonstrate
the performance of the hybrid DG/FV methods, including the standard vortex evolution problem with exact solution, isentropic vortex/weak shock wave interaction,
subsonic flows past a circular cylinder and a three-element airfoil (30P30N), transonic
flow past a NACA0012 airfoil. The accuracy study shows that the hybrid DG/FV
method achieves the desired third-order accuracy, and the applications demonstrate
that they can capture the flow structure accurately, and can reduce the CPU time and
memory requirement greatly than the traditional DG method with the same order of
accuracy. |
