This paper is devoted to a new high-accuracy finite difference scheme for solving reaction-convection-diffusion problems with a small diffusivityε.With a novel treatment for the reaction term,we first derive a differ...This paper is devoted to a new high-accuracy finite difference scheme for solving reaction-convection-diffusion problems with a small diffusivityε.With a novel treatment for the reaction term,we first derive a difference scheme of accuracy O(ε^(2)h+εh^(2)+h^(3))for the 1-D case.Using the alternating direction technique,we then extend the scheme to the 2-D case on a nine-point stencil.We apply the high-accuracy finite difference scheme to solve the 2-D steady incompressible Navier-Stokes equations in the stream function-vorticity formulation.Numerical examples are given to illustrate the effectiveness of the proposed difference scheme.Comparisons made with some high-order compact difference schemes show that the newly proposed scheme can achieve good accuracy with a better stability。展开更多
基金the National Science Council of Taiwan under the grants NSC 101-2811-M-008-032 and NSC 102-2115-M-033-007-MY2the National Science Council of Taiwan under the grants NSC 99-2115-M-008-012-MY2 and NSC 101-2115-M-008-008-MY2.
文摘This paper is devoted to a new high-accuracy finite difference scheme for solving reaction-convection-diffusion problems with a small diffusivityε.With a novel treatment for the reaction term,we first derive a difference scheme of accuracy O(ε^(2)h+εh^(2)+h^(3))for the 1-D case.Using the alternating direction technique,we then extend the scheme to the 2-D case on a nine-point stencil.We apply the high-accuracy finite difference scheme to solve the 2-D steady incompressible Navier-Stokes equations in the stream function-vorticity formulation.Numerical examples are given to illustrate the effectiveness of the proposed difference scheme.Comparisons made with some high-order compact difference schemes show that the newly proposed scheme can achieve good accuracy with a better stability。
