A compact finite difference scheme on a non-equidistant mesh

In this paper, the development of a fourth-(respectively third-) order compact scheme for the approximation of first (respectively second) derivatives on non-uniform meshes is studied. A full inclusion of metrics in the coefficients of the compact scheme is proposed, instead of methods using Jacobia

Numerical simulation of turbulent flows (DNS or LES) requires numerical methods that are both stable and free of numerical dissipation. One way to achieve this is to enforce additional constraints, such as discrete conservation of mass, momentum, and kinetic energy. The objective of this work is to

Many important dynamical systems can be modeled one-dimensional non-linear oscillators [1,2]. For information on the properties of such systems, a variety of analytical methods exist which can be used to construct approximations to the periodic solutions [3,4]. However, when very accurate solutions

A simple high resolution finite difference technique is presented to approximate weak solutions to hyperbolic systems of conservation laws. The method does not rely on Riemann problem solvers and is therefore easy to extend to a wide variety of problems. The overall performance (resolution and CPU r