![Hybrid Navier–Stokes–Direct Simulation Monte Carlo Automatic Mesh Optimization for Hypersonics | Journal of Thermophysics and Heat Transfer Hybrid Navier–Stokes–Direct Simulation Monte Carlo Automatic Mesh Optimization for Hypersonics | Journal of Thermophysics and Heat Transfer](https://arc.aiaa.org/cms/10.2514/1.T6770/asset/images/medium/figure18.gif)
Hybrid Navier–Stokes–Direct Simulation Monte Carlo Automatic Mesh Optimization for Hypersonics | Journal of Thermophysics and Heat Transfer
![Automatic Delaunay mesh generation method and physically-based mesh optimization method on two-dimensional regions | SpringerLink Automatic Delaunay mesh generation method and physically-based mesh optimization method on two-dimensional regions | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs00366-020-01262-x/MediaObjects/366_2020_1262_Fig3_HTML.png)
Automatic Delaunay mesh generation method and physically-based mesh optimization method on two-dimensional regions | SpringerLink
![Keenan Crane on X: "[37/n] Another nice example is preconditioning for mesh optimization. For instance, Holst & Chen 2011 suggests H1 preconditioning to accelerate computation of optimal Delaunay triangulations: https://t.co/BpXkXgUtqR (We use Keenan Crane on X: "[37/n] Another nice example is preconditioning for mesh optimization. For instance, Holst & Chen 2011 suggests H1 preconditioning to accelerate computation of optimal Delaunay triangulations: https://t.co/BpXkXgUtqR (We use](https://pbs.twimg.com/media/E70YDwlWEAMzwJD.jpg:large)