Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations
Insight into the accuracy of steady shock-capturing CFD methods is obtained through analysis of a simple problem involving steady transonic flow in a quasi-1D diverging duct. It is proved that the discrete solution error on either side of the shock is $O(h^{n})$ where $n$ is the order of accuracy of...
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| Format: | Report |
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Unspecified
1995
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| _version_ | 1826307057463066624 |
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| author | Giles, M |
| author_facet | Giles, M |
| author_sort | Giles, M |
| collection | OXFORD |
| description | Insight into the accuracy of steady shock-capturing CFD methods is obtained through analysis of a simple problem involving steady transonic flow in a quasi-1D diverging duct. It is proved that the discrete solution error on either side of the shock is $O(h^{n})$ where $n$ is the order of accuracy of the conservative finite volume discretisation. Furthermore, it is shown that provided that $n \ge 2$ then the error in approximating $\int p dx$ is $O(h^{2})$. This result is in contrast to the general belief that shocks in 2D and 3D Euler calculations lead to first order errors, which motivates much of the research into grid adaptation methods. |
| first_indexed | 2024-03-07T06:57:17Z |
| format | Report |
| id | oxford-uuid:fe8daa03-348f-40e7-9f22-4091c2595c9b |
| institution | University of Oxford |
| last_indexed | 2024-03-07T06:57:17Z |
| publishDate | 1995 |
| publisher | Unspecified |
| record_format | dspace |
| spelling | oxford-uuid:fe8daa03-348f-40e7-9f22-4091c2595c9b2022-03-27T13:37:30ZAnalysis of the accuracy of shock-capturing in the steady quasi-1D Euler equationsReporthttp://purl.org/coar/resource_type/c_93fcuuid:fe8daa03-348f-40e7-9f22-4091c2595c9bMathematical Institute - ePrintsUnspecified1995Giles, MInsight into the accuracy of steady shock-capturing CFD methods is obtained through analysis of a simple problem involving steady transonic flow in a quasi-1D diverging duct. It is proved that the discrete solution error on either side of the shock is $O(h^{n})$ where $n$ is the order of accuracy of the conservative finite volume discretisation. Furthermore, it is shown that provided that $n \ge 2$ then the error in approximating $\int p dx$ is $O(h^{2})$. This result is in contrast to the general belief that shocks in 2D and 3D Euler calculations lead to first order errors, which motivates much of the research into grid adaptation methods. |
| spellingShingle | Giles, M Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title | Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title_full | Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title_fullStr | Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title_full_unstemmed | Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title_short | Analysis of the accuracy of shock-capturing in the steady quasi-1D Euler equations |
| title_sort | analysis of the accuracy of shock capturing in the steady quasi 1d euler equations |
| work_keys_str_mv | AT gilesm analysisoftheaccuracyofshockcapturinginthesteadyquasi1deulerequations |