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Downscaling storm surge models for engineering applications

Downscaling storm surge models for engineering applications. John Baugh A. Altuntas , J. Rutledge, T. Dyer Department of Civil, Construction, and Environmental Engineering North Carolina State University. Starting Point. How do we assess the effects of storm surge on civil infrastructure?

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Downscaling storm surge models for engineering applications

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  1. Downscaling storm surge models for engineering applications John Baugh A. Altuntas, J. Rutledge, T. Dyer Department of Civil, Construction, and Environmental Engineering North Carolina State University

  2. Starting Point • How do we assess the effects of storm surge on civil infrastructure? • Engineering design scenarios imply topographic changes, as do failures. • Hundreds of cases may be worth considering.

  3. Relevance to DHS • Gap being addressed: No computationally tractable approach exists for assessing storm surge effects on proposed infrastructure changes and improvements. • The DHS mission includes managing risks to critical infrastructure, ensuring resilience to disasters, and mitigating hazards.

  4. Interface Conditions • May be formulated in a variety of ways: • One-way nesting (Spall and Robinson 1989) • Two-way nesting (Debreu and Blayo 2008) • Full coupling (Cailleau et al. 2008) • Used to resolve smaller spatial and temporal scale processes

  5. Levee Failure Scenarios • Nesting for infrastructure assessment: • (3 different failures, flooding outlined in white)

  6. Year 5 Activities • Subdomain modeling of storm surge and wave effects using ADCIRC and SWAN • Time-varying topobathy in ADCIRC using a predetermined set of parameters • Additional means of reducing computational cost in simulation approaches

  7. 1. Storm Surge and Waves • SWAN is a phase-averaged spectral wave model with two possible types of boundary conditions: • TPAR files contain significant wave height, wave period, peak direction, and directional spread. • 2D Spectra files contain N discrete frequencies and M directions.

  8. Hurricane Fran and Cape Fear

  9. Hurricane Fran and Cape Fear Conclusion: Using 2D spectra files to enforce the boundaries of a subdomain results in accurate and efficient computational modeling for engineering purposes.

  10. 2. Time-Varying Topobathy • The result of a net transport of sand along the ocean bottom or the overtopping and collapse of a dune, or the failure of engineered structures such as levees and geotubes. • To accommodate, allow time-varying changes in bathymetric depth DP using a predetermined set of parameters.

  11. When bathymetric depth DP changes • adjust water surface elevation ETA to maintain constant water column height • mark node wet for reevaluation • remember prior DP values for consistency in calculating heights H0, H1, and H2

  12. Test Case: Hatteras Subdomain • Extracted from the western North Atlantic grid with refinements for simulating Isabel Inlet

  13. 3. Subduration Modeling • Subduration modeling is introduced as a means of downscaling hurricane storm surge models in time. • The hot-start feature of ADCIRC allows users to begin a run from a specified timestep using initial conditions obtained from a previously performed run. • This feature is used to reduce the total runtime of series of simulations where users have made topographic or other changes to a model.

  14. Subduration Modeling in ADCIRC Step 0 : Begin with an ADCIRC model ETA: Surface Elevation, DP: Bathymetric Depth

  15. Subduration Modeling in ADCIRC Step 1 : Identify nodes that are part of the changed terrain.

  16. Subduration Modeling in ADCIRC Step 2 : Record a hot-start file before one of the changed nodes becomes wet.

  17. Subduration Modeling in ADCIRC Step 3 : Make changes to parts of the terrain (DP) in the fort.14 file.

  18. Subduration Modeling in ADCIRC Subdomain ADCIRC has been modified so that the original ETA of a changed node is initially set to be equal to changed DP, during a hot-started run.

  19. Subduration Modeling in ADCIRC Step 4 : Perform the hot-started run. Modified subdomain ADCIRC runs the hot-started simulation as it normally would.

  20. Test Case: Cape Fear Subdomain • Extracted from the western North Atlantic grid with a protective structure to prevent flooding

  21. Test Case: Cape Fear Subdomain

  22. Products • Software tools for subdomain modeling, modifications to ADCIRC, user scripts, visualization tools, user guide already being distributed. • Theses, technical reports, conference talks, articles under review and in preparation.

  23. Prospective Collaborators and End Users Researchers • Yoonhee Park / Professor Art Rice, Landscape Architecture, NCSU, Raleigh, NC • Fernando Magarinos Lamas, Mathematician, Physical Oceanography, Universidad NacionalAutonoma de Mexico, Mexico City, Mexico • Celso Ferreira, Assistant Professor, George Mason University, Fairfax, VA Consulting • Mark Prater, Research Analyst, WeatherPredict Consulting, Kingston, RI Emergency Management • Sandy Sanderson, Director, Dare County Emergency Management, Manteo, NC Federal Agencies • Tucker Mahoney, Coastal Engineer, FEMA Region IV, Atlanta, GA • Max Agnew, Hydraulic Engineer, USACE New Orleans district, New Orleans, LA

  24. Prospective Collaborators and End Users International Agencies • Professor Weihua Fang, Academy of Disaster Reduction and Emergency Management, Ministry of Civil Affairs and Ministry of Education, Beijing, China

  25. Looking Forward • Case studies that draw on approaches developed in preceding years, demonstrating their benefit in enhancing the resilience of coastal communities • Interactive software tools that support modeling activities for the actual case studies being performed • Decision-making approaches that constitute best practices from the operations research community for coastal infrastructure design

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