Time dependent boundary conditions for hyperbolic systems
Journal of Computational Physics
Summation by parts for finite difference approximations for d/dx
Journal of Computational Physics
New Guide to Artificial Intelligence
New Guide to Artificial Intelligence
The T Experiments: Errors In Scientific Software
IEEE Computational Science & Engineering
Journal of Computational Physics
Higher entropy conservation and numerical stability of compressible turbulence simulations
Journal of Computational Physics
Review of code and solution verification procedures for computational simulation
Journal of Computational Physics
Journal of Computational Physics
| Hi-index | 31.45 |
A novel method is described for verification of fluid-dynamics solvers based on correlations with solutions from linear stability analysis. A difficulty with the linear stability analysis solutions for spatially developing flows is that flow fields typically exhibit exponentially growing features compromising the performance of classical error metrics. This motivates the construction of a projection-based metric that only assumes the shape of the solution and not the growth rate of the perturbations, thus also allowing the latter to be determined. The proposed correlation metric complements classical error metrics, such as p-norms, and can also be used for time-dependent problems with realistic boundary conditions. We demonstrate how the present method can be applied in the verification of an Euler solver for the instability behavior of laminar compressible free and confined shear layers.