IMPLICIT UPWIND SOLUTION ALGORITHMS FOR 3-DIMENSIONAL UNSTRUCTURED MESHES

The development of implicit upwind algorithms for the solution of the three-dimensional, time-dependent Euler equations on unstructured tetrahedral meshes is described. The implicit temporal discretization involves either a two-sweep Gauss-Seidel relaxation procedure, a two-sweep point-Jacobi relaxation procedure, or a single-sweep point-implicit procedure; the upwind spatial discretization is based on the flux-difference splitting of Roe. Detailed descriptions of the three implicit solution algorithms are given, and calculations for the Boeing 747 transport configuration are presented to demonstrate the algorithms. Advantages and disadvantages of the implicit algorithms are discussed. A steady-state solution for the 747 configuration, obtained at transonic flow conditions using a mesh of over 100,000 cells, required less than 1 h of CPU time on a Cray-2 computer, thus demonstrating the speed and robustness of the general capability.