2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives
A method for computing target element size for tidal, shallow water flow is developed and demonstrated. The method, Localized truncation error analysis with complex derivatives (LTEA-CD) utilizes localized truncation error estimates of the linearized shallow water momentum equations consisting of co...
| Format: | Text |
|---|---|
| Language: | English |
| Published: |
STARS
2007
|
| Subjects: | |
| Online Access: | https://stars.library.ucf.edu/facultybib2000/7508 |
| id |
ftunicentralflor:oai:stars.library.ucf.edu:facultybib2000-8507 |
|---|---|
| record_format |
openpolar |
| spelling |
ftunicentralflor:oai:stars.library.ucf.edu:facultybib2000-8507 2023-05-15T17:30:23+02:00 2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives 2007-01-01T08:00:00Z https://stars.library.ucf.edu/facultybib2000/7508 English eng STARS https://stars.library.ucf.edu/facultybib2000/7508 Faculty Bibliography 2000s localized truncation error analysis unstructured mesh generation shallow water equations tidal computations complex derivatives Western North Atlantic tidal model domain SHALLOW-WATER EQUATIONS VELOCITY CURRENTS DOMAIN GRIDS TIDES Mechanics Physics Fluids & Plasmas text 2007 ftunicentralflor 2021-12-21T09:05:45Z A method for computing target element size for tidal, shallow water flow is developed and demonstrated. The method, Localized truncation error analysis with complex derivatives (LTEA-CD) utilizes localized truncation error estimates of the linearized shallow water momentum equations consisting of complex derivative terms. This application of complex derivatives is the chief way in which the method differs from a similar existing method, LTEA. It is shown that LTEA-CD produces results that are essentially equivalent to those of LTEA (which in turn has been demonstrated to be capable of producing practicable target element sizes) with reduced computational cost. Moreover, LTEA-CD is capable of computing truncation error and corresponding target element sizes at locations up to and including the boundary, whereas LTEA can be applied only on the interior of the model domain. We demonstrate the convergence of solutions over meshes generated with LTEA-CD using an idealized representation of the western North Atlantic Ocean, Caribbean Sea and Gulf of Mexico. Text North Atlantic University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship) |
| institution |
Open Polar |
| collection |
University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship) |
| op_collection_id |
ftunicentralflor |
| language |
English |
| topic |
localized truncation error analysis unstructured mesh generation shallow water equations tidal computations complex derivatives Western North Atlantic tidal model domain SHALLOW-WATER EQUATIONS VELOCITY CURRENTS DOMAIN GRIDS TIDES Mechanics Physics Fluids & Plasmas |
| spellingShingle |
localized truncation error analysis unstructured mesh generation shallow water equations tidal computations complex derivatives Western North Atlantic tidal model domain SHALLOW-WATER EQUATIONS VELOCITY CURRENTS DOMAIN GRIDS TIDES Mechanics Physics Fluids & Plasmas 2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| topic_facet |
localized truncation error analysis unstructured mesh generation shallow water equations tidal computations complex derivatives Western North Atlantic tidal model domain SHALLOW-WATER EQUATIONS VELOCITY CURRENTS DOMAIN GRIDS TIDES Mechanics Physics Fluids & Plasmas |
| description |
A method for computing target element size for tidal, shallow water flow is developed and demonstrated. The method, Localized truncation error analysis with complex derivatives (LTEA-CD) utilizes localized truncation error estimates of the linearized shallow water momentum equations consisting of complex derivative terms. This application of complex derivatives is the chief way in which the method differs from a similar existing method, LTEA. It is shown that LTEA-CD produces results that are essentially equivalent to those of LTEA (which in turn has been demonstrated to be capable of producing practicable target element sizes) with reduced computational cost. Moreover, LTEA-CD is capable of computing truncation error and corresponding target element sizes at locations up to and including the boundary, whereas LTEA can be applied only on the interior of the model domain. We demonstrate the convergence of solutions over meshes generated with LTEA-CD using an idealized representation of the western North Atlantic Ocean, Caribbean Sea and Gulf of Mexico. |
| format |
Text |
| title |
2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| title_short |
2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| title_full |
2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| title_fullStr |
2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| title_full_unstemmed |
2D unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| title_sort |
2d unstructured mesh generation for oceanic and coastal tidal models from a localized truncation error analysis with complex derivatives |
| publisher |
STARS |
| publishDate |
2007 |
| url |
https://stars.library.ucf.edu/facultybib2000/7508 |
| genre |
North Atlantic |
| genre_facet |
North Atlantic |
| op_source |
Faculty Bibliography 2000s |
| op_relation |
https://stars.library.ucf.edu/facultybib2000/7508 |
| _version_ |
1766126762795728896 |