A Measure-Theoretic Algorithm for Estimating Bottom Friction in a Coastal Inlet: Case Study of Bay St. Louis during Hurricane Gustav (2008)

The majority of structural damage and loss of life during a hurricane is due to storm surge, thus it is important for communities in hurricane-prone regions to understand their risk due to surge. Storm surge in particular is largely influenced by coastal features such as topography/bathymetry and bo...

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Veröffentlicht in:	Monthly weather review 2017-03, Vol.145 (3), p.929-954
Hauptverfasser:	Graham, Lindley, Butler, Troy, Walsh, Scott, Dawson, Clint, Westerink, Joannes J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Banks (topography) Bathymetry Bed roughness Bottom friction Bottom roughness Bottom stress Boundary conditions Case studies Circulation Coastal inlets Computational efficiency Computer applications Computer simulation Cost engineering ENVIRONMENTAL SCIENCES Exploitation Frameworks Friction Hurricanes Inlets (waterways) Inverse methods Inverse problems Mathematical models Numerical weather prediction/forecasting Physics Roughness Sensitivity analysis Slope Statistical forecasting Statistical techniques Storm damage Storm surges Storms Structural damage Tidal waves Topography Topography (geology) Vegetation
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creator	Graham, Lindley Butler, Troy Walsh, Scott Dawson, Clint Westerink, Joannes J.
description	The majority of structural damage and loss of life during a hurricane is due to storm surge, thus it is important for communities in hurricane-prone regions to understand their risk due to surge. Storm surge in particular is largely influenced by coastal features such as topography/bathymetry and bottom roughness. Bottom roughness determines how much resistance there is to the flow. Manning’s formula can be used to model the bottom stress with the Manning’s n coefficient, a spatially dependent field. Given a storm surge model and a set of model outputs, an inverse problem may be solved to determine probable Manning’s n fields to use for predictive simulations. The inverse problem is formulated and solved in a measure-theoretic framework using the state-of-the-art Advanced Circulation (ADCIRC) storm surge model. The use of measure theory requires minimal assumptions and involves the direct inversion of the physics-based map from model inputs to output data determined by the ADCIRC model. Thus, key geometric relationships in this map are preserved and exploited. By using a recently available subdomain implementation of ADCIRC that significantly reduces the computational cost of forward model solves, the authors demonstrate the method on a case study using data obtained from an ADCIRC hindcast study of Hurricane Gustav (2008) to quantify uncertainties in Manning’s n within Bay St. Louis. However, the methodology is general and could be applied to any inverse problem that involves a map from model input to output quantities of interest.
doi_str_mv	10.1175/MWR-D-16-0149.1
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By using a recently available subdomain implementation of ADCIRC that significantly reduces the computational cost of forward model solves, the authors demonstrate the method on a case study using data obtained from an ADCIRC hindcast study of Hurricane Gustav (2008) to quantify uncertainties in Manning’s n within Bay St. Louis. 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Measure-Theoretic Algorithm for Estimating Bottom Friction in a Coastal Inlet: Case Study of Bay St. Louis during Hurricane Gustav (2008)</title><author>Graham, Lindley ; Butler, Troy ; Walsh, Scott ; Dawson, Clint ; Westerink, Joannes J.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c296t-b71d89e173103ea4550a5670a15c2bf79150f08705b5fdee390294735eb90d453</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Banks (topography)</topic><topic>Bathymetry</topic><topic>Bed roughness</topic><topic>Bottom friction</topic><topic>Bottom roughness</topic><topic>Bottom stress</topic><topic>Boundary conditions</topic><topic>Case studies</topic><topic>Circulation</topic><topic>Coastal inlets</topic><topic>Computational efficiency</topic><topic>Computer applications</topic><topic>Computer simulation</topic><topic>Cost engineering</topic><topic>ENVIRONMENTAL 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Storm surge in particular is largely influenced by coastal features such as topography/bathymetry and bottom roughness. Bottom roughness determines how much resistance there is to the flow. Manning’s formula can be used to model the bottom stress with the Manning’s n coefficient, a spatially dependent field. Given a storm surge model and a set of model outputs, an inverse problem may be solved to determine probable Manning’s n fields to use for predictive simulations. The inverse problem is formulated and solved in a measure-theoretic framework using the state-of-the-art Advanced Circulation (ADCIRC) storm surge model. The use of measure theory requires minimal assumptions and involves the direct inversion of the physics-based map from model inputs to output data determined by the ADCIRC model. Thus, key geometric relationships in this map are preserved and exploited. By using a recently available subdomain implementation of ADCIRC that significantly reduces the computational cost of forward model solves, the authors demonstrate the method on a case study using data obtained from an ADCIRC hindcast study of Hurricane Gustav (2008) to quantify uncertainties in Manning’s n within Bay St. Louis. However, the methodology is general and could be applied to any inverse problem that involves a map from model input to output quantities of interest.</abstract><cop>Washington</cop><pub>American Meteorological Society</pub><doi>10.1175/MWR-D-16-0149.1</doi><tpages>26</tpages></addata></record>
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subjects	Banks (topography) Bathymetry Bed roughness Bottom friction Bottom roughness Bottom stress Boundary conditions Case studies Circulation Coastal inlets Computational efficiency Computer applications Computer simulation Cost engineering ENVIRONMENTAL SCIENCES Exploitation Frameworks Friction Hurricanes Inlets (waterways) Inverse methods Inverse problems Mathematical models Numerical weather prediction/forecasting Physics Roughness Sensitivity analysis Slope Statistical forecasting Statistical techniques Storm damage Storm surges Storms Structural damage Tidal waves Topography Topography (geology) Vegetation
title	A Measure-Theoretic Algorithm for Estimating Bottom Friction in a Coastal Inlet: Case Study of Bay St. Louis during Hurricane Gustav (2008)
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