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<pdf>Media:Draft_Garcia_330241719A_IDC6_65.pdf</pdf> | <pdf>Media:Draft_Garcia_330241719A_IDC6_65.pdf</pdf> |
Shock tracking, as an alternative method to shock capturing, aims to generate a mesh such that element faces align with shock surfaces and other non-smooth features to perfectly represent them with the inter-element jumps in the solution basis. These methods have been shown to enable high- order approximation of high-speed flows and do not require extensive refinement in non-smooth regions because, once the non-smooth features are tracked by the mesh, the solution basis approximates the remaining smooth features. In previous work, we introduced an implicit shock tracking framework that re-casts the geometrically complex problem of generating a mesh that conforms to all discontinuity surfaces as a PDE-constrained optimization problem. In this talk, we present a number of extensions to the implicit shock tracking method aimed at improving robustness for complex problems.
Published on 17/05/21
Submitted on 17/05/21
Licence: CC BY-NC-SA license
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