Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models

An enhanced version of our localized truncation error analysis with complex derivatives (LTEA-CD) a posteriori approach to computing target element sizes for tidal, shallow water flow, LTEA+CD, is applied to the Western North Atlantic Tidal model domain. The LTEA+CD method utilizes localized truncat...

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Main Authors: Parrish, D. Michael, Hagen, Scott C.
Format: Text
Language:unknown
Published: STARS 2009
Subjects:
Complex derivatives
Localized truncation error analysis
Shallow water equations
Tidal computations
Unstructured mesh generation
Western North Atlantic Tidal model domain
North Atlantic
Online Access:https://stars.library.ucf.edu/scopus2000/11859
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spelling ftunicentralflor:oai:stars.library.ucf.edu:scopus2000-12858 2023-05-15T17:31:41+02:00 Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models Parrish, D. Michael Hagen, Scott C. 2009-05-30T07:00:00Z https://stars.library.ucf.edu/scopus2000/11859 unknown STARS https://stars.library.ucf.edu/scopus2000/11859 Scopus Export 2000s Complex derivatives Localized truncation error analysis Shallow water equations Tidal computations Unstructured mesh generation Western North Atlantic Tidal model domain text 2009 ftunicentralflor 2022-08-01T17:33:41Z An enhanced version of our localized truncation error analysis with complex derivatives (LTEA-CD) a posteriori approach to computing target element sizes for tidal, shallow water flow, LTEA+CD, is applied to the Western North Atlantic Tidal model domain. The LTEA+CD method utilizes localized truncation error estimates of the shallow water momentum equations and builds upon LTEA and LTEA-CD-based techniques by including: (1) velocity fields from a nonlinear simulation with complete constituent forcing; (2) spatially variable bottom stress; and (3) Coriolis force. Use of complex derivatives in this case results in a simple truncation error expression, and the ability to compute localized truncation errors using difference equations that employ only seven to eight computational points. The compact difference molecules allow the computation of truncation error estimates and target element sizes throughout the domain, including along the boundary; this fact, along with inclusion of locally variable bottom stress and Coriolis force, constitute significant advancements beyond the capabilities of LTEA. The goal of LTEA+CD is to drive the truncation error to a more uniform, domain-wide value by adjusting element sizes (we apply LTEA+CD by re-meshing the entire domain, not by moving nodes). We find that LTEA+CD can produce a mesh that is comprised of fewer nodes and elements than an initial high-resolution mesh while performing as well as the initial mesh when considering the resynthesized tidal signals (elevations). Copyright © 2008 John Wiley & Sons, Ltd. 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 unknown
topic Complex derivatives
Localized truncation error analysis
Shallow water equations
Tidal computations
Unstructured mesh generation
Western North Atlantic Tidal model domain
spellingShingle Complex derivatives
Localized truncation error analysis
Shallow water equations
Tidal computations
Unstructured mesh generation
Western North Atlantic Tidal model domain
Parrish, D. Michael
Hagen, Scott C.
Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
topic_facet Complex derivatives
Localized truncation error analysis
Shallow water equations
Tidal computations
Unstructured mesh generation
Western North Atlantic Tidal model domain
description An enhanced version of our localized truncation error analysis with complex derivatives (LTEA-CD) a posteriori approach to computing target element sizes for tidal, shallow water flow, LTEA+CD, is applied to the Western North Atlantic Tidal model domain. The LTEA+CD method utilizes localized truncation error estimates of the shallow water momentum equations and builds upon LTEA and LTEA-CD-based techniques by including: (1) velocity fields from a nonlinear simulation with complete constituent forcing; (2) spatially variable bottom stress; and (3) Coriolis force. Use of complex derivatives in this case results in a simple truncation error expression, and the ability to compute localized truncation errors using difference equations that employ only seven to eight computational points. The compact difference molecules allow the computation of truncation error estimates and target element sizes throughout the domain, including along the boundary; this fact, along with inclusion of locally variable bottom stress and Coriolis force, constitute significant advancements beyond the capabilities of LTEA. The goal of LTEA+CD is to drive the truncation error to a more uniform, domain-wide value by adjusting element sizes (we apply LTEA+CD by re-meshing the entire domain, not by moving nodes). We find that LTEA+CD can produce a mesh that is comprised of fewer nodes and elements than an initial high-resolution mesh while performing as well as the initial mesh when considering the resynthesized tidal signals (elevations). Copyright © 2008 John Wiley & Sons, Ltd.
format Text
author Parrish, D. Michael
Hagen, Scott C.
author_facet Parrish, D. Michael
Hagen, Scott C.
author_sort Parrish, D. Michael
title Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
title_short Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
title_full Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
title_fullStr Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
title_full_unstemmed Incorporating Spatially Variable Bottom Stress And Coriolis Force Into 2D, A Posteriori, Unstructured Mesh Generation For Shallow Water Models
title_sort incorporating spatially variable bottom stress and coriolis force into 2d, a posteriori, unstructured mesh generation for shallow water models
publisher STARS
publishDate 2009
url https://stars.library.ucf.edu/scopus2000/11859
genre North Atlantic
genre_facet North Atlantic
op_source Scopus Export 2000s
op_relation https://stars.library.ucf.edu/scopus2000/11859
_version_ 1766129383702003712

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