Finite-difference methods for calculating steady incompressible flows in three dimensions

With the advent of state-of-the-art computers and their rapid availability, the time is ripe for the development of efficient uncertainty quantification (UQ) methods to reduce the complexity of numerical models used to simulate complicated systems with incomplete knowledge and data. The spectral sto

We give a brief overview of frequently used stabilised finite element schemes for steady incompressible flow. We derive Taylor-Galerkin schemes for the flow equations and show how SUPG-type and Taylor-Galerkin methods can be interpreted within the same framework.

A finite-difference scheme for the direct simulation of the incompressible time-dependent three-dimensional Navier-Stokes equa- [6] proposed an accurate method for three-dimensional tions in cylindrical coordinates is presented. The equations in primipipe flows with Jacobi polynomials for the radial

boundary. Recently, this result was improved in [15] to show second-order convergence of solutions including Thom's vorticity condition for solving the incompressible Navier-Stokes equations is generally known as a first-order method since boundary vorticity for the steady Stokes equations using the