Extra-Tropical Storm Surge (ETSS 2.0) Pre-Implementation Briefing College Park, MD May 14, 2015 Arthur Taylor, Huiqing Liu and Ryan Schuster MDL/NWS/NOAA.

Slides:



Advertisements
Similar presentations
5 th NOAA Testbeds and Proving Grounds Workshop, April 16-18, 2014 André van der Westhuysen, Joannes Westerink, Juan Gonzalez, Jane Smith, Jamie Rhome,
Advertisements

Modeling to Revise Coastal Inundation and Flooding Estimates in Georgia and Northeast Florida Association of State Flood Plain Managers Conference May.
Hurricane Storm Surge Simulation on Petascale Computers Clint Dawson and Ethan Kubatko, UT Austin; Joannes Westerink, Notre Dame; Anna Spagnuolo, Oakland.
1.Real-time rainfall observations: Addition of USGS and NC State Climate Office precipitation stations so EMs can get real- time observations of how much.
National Weather Service SLOSH S ea, L ake, and L ake, and O verland O verland S urges from S urges from H urricanes H urricanes Part 1: W. Shaffer / MDL.
The Storm Surge Toolkit Jamie Rhome Storm Surge Specialist/Team Lead National Hurricane Center Jamie Rhome Storm Surge Specialist/Team Lead National Hurricane.
CHAPTER 5: PREDICTING STORM SURGE LESSONS FROM HURRICANE IKE.
NOAA’s National Weather Service: Probabilistic Storm Surge (P-Surge) Arthur Taylor, Nicole P. Kurkowski MDL / OST July 26, 2006.
MDL Accomplishments and Plans: MOS, LAMP, EKDMOS, Storm Surge, AutoNowCaster, VLab NCEP Production Suite Review December 4, 2013.
Bryan Norcross Sr. Executive Director of Weather Content Sr. Hurricane Specialist The Weather Channel Interdepartmental Hurricane Conference College Park,
Kodi Monroe Sea Grant Weather & Climate Extension Agent National Severe Storms Laboratory Norman, OK CI-FLOW Project Coastal & Inland Flooding Observation.
Office of Coast Survey NOS Coastal and Surge Modeling 2011 NCEP Production Suite Review Jesse C. Feyen Coast Survey Development Laboratory.
Session 10: Hurricane Storm Surge Modeling and Analysis 1 Hurricane Storm Surge Modeling.
Storm Surge Products John Cole Warning Coordination Meteorologist NWS Morehead City/Newport NC Acknowledgements: Jamie Rhome and Rick Knabb (NHC), Mark.
Bering Sea Storm, November 2011 Aimee Fish, NOAA National Weather Service Alaska Region Alaska HSRP: May 2012.
Company Confidential/Proprietary A Regional Prototype System for a National Problem Chesapeake Inundation Prediction System Bridging the Gap from Forecast.
United States Coast Guard 1985 Evaluation of a Multi-Model Storm Surge Ensemble for the New York Metropolitan Region Brian A. Colle Tom Di Liberto Stony.
N A T I O N A L O C E A N I C A N D A T M O S P H E R I C A D M I N I S T R A T I O N Mark Tew Chief, Marine and Coastal Weather Services Branch Office.
Meteorological Development Lab (MDL) FY14 Accomplishments and Plans for FY15 Dr. Mike Farrar, MDL Director NCEP Production Suite Review December 03, 2014.
Review of the NCEP production Suite: Recent Changes and Plans
Model Simulation Studies of Hurricane Isabel in Chesapeake Bay Jian Shen Virginia Institute of Marine Sciences College of William and Mary.
Surge Height (NAWIPS) 5.4 feet Impact (Inundation) 4 feet TWL – (MHHW – MSL) 8 – (4-0)=4.
NOAA’s CENTER for OPERATIONAL OCEANOGRAPHIC PRODUCTS and SERVICES Center for Operational Products and Services (CO-OPS) Storm QuickLook Product Paul Fanelli.
Extratropical Storm-Induced Coastal Inundation: Scituate, MA Robert C. Beardsley 1, Changsheng Chen 2, Qichun Xu 2, Jianhua Qi 2, Huichan Lin 2 2 School.
NOAA Navigation Services CO-OPS Update Richard Edwing National Ocean Service Center for Operational Oceanographic Products and Services Hydrographic Services.
Office of Coast Survey Improving NOAA’s Capacity to Address Coastal Inundation Events The Storm Surge Roadmap and the Way Forward Jesse C. Feyen Storm.
Office of Coast Survey NOAA’s Storm Surge Roadmap: a Pathway to Improved Products and Services Jesse C. Feyen Storm Surge Roadmap Portfolio Manager.
NOAA’s Advances in Storm Surge Modeling & Prediction “Weather-Ready Nation: Saving Lives and Livelihoods” Jason P. Tuell, Ph.D National Weather Service.
Using Partnerships to Meet NOAA’s Needs for its Next Generation Storm Surge System NOS/OCS/CSDL J. Feyen F. Aikman M. Erickson NWS/NCEP/EMC H. Tolman NWS/OST/MDL.
Office of Coast Survey 2013 NOS Coastal Modeling Development and Performance Office of Coast Survey/Development Laboratory, Center for Operational Oceanographic.
Update on Storm Surge at NCEP Dr. Rick Knabb, Director, National Hurricane Center and representing numerous partners 21 January 2014.
Office of Coast Survey Establishing a Community-Based Extratropical Storm Surge and Tide Model for NOAA’s Operational Forecasts for the Atlantic and Gulf.
1 Extra-Tropical Storm Surge (ETSS) Model and Post Processing V 2.0 Pre-Implementation Briefing December, 2014 Huiqing Liu, Ryan Schuster, and Arthur Taylor.
Office of Coast Survey Overview of the Extratropical Surge and Tide Operational Forecast System for the Pacific Jesse Feyen and Jiangtao Xu National Ocean.
1 Requirements for hurricane track and intensity guidance Presented By: Vijay Tallapragada and Sam Trahan (NWS/NCEP) Contributors: HWRF Team at EMC, NHC.
Office of Coast Survey NOAA’s Storm Surge Modeling Capabilities Jesse C. Feyen Storm Surge Roadmap Portfolio Manager.
Use of sea level observations in DMIs storm surge model Jacob L. Høyer, Weiwei Fu, Kristine S. Madsen & Lars Jonasson Center for Ocean and Ice, Danish.
An Improved Wind Probability Program: A Year 2 Joint Hurricane Testbed Project Update Mark DeMaria and John Knaff, NOAA/NESDIS, Fort Collins, CO Stan Kidder,
Probabilistic Hurricane Storm Surge (P-Surge) Arthur Taylor MDL / OST December 4, 2006.
WFO MHX Coastal Flood Program
Chawla et al., Dec NCEP production suite review, 1/18 Review of the NCEP production Suite: Recent Changes and Plans Marine Modeling and Analysis.
Storm Surge Modeling and Forecasting LTJG Jeffrey Pereira, NOAA Storm Surge Unit National Hurricane Center NOAA Storm Surge Workshop May 2011 LTJG Jeffrey.
Office of Coast Survey Using Partnerships to Improve NOAA’s Storm Surge Products and Forecasts Jesse C. Feyen Storm Surge Roadmap Portfolio Manager National.
Rebecca Cosgrove NCEP/NCO/Production Management Branch March 26, 2015
UMAC data callpage 1 of 16Nearshore Wave Prediction System (NWPS) EMC Operational Models Nearshore Wave Prediction System (NWPS) André van der Westhuysen.
 Hurricanes are areas of low air pressure that form over oceans in tropical climate regions.  Hurricanes hit land with tremendous force, bringing.
Office of Coast Survey Improving NOAA’s Capacity to Address Coastal Inundation Events Jesse C. Feyen, Ph.D. Storm Surge Roadmap Portfolio Manager Acting.
1 “Where America’s Climate, Weather and Ocean Services Begin” FY16 Production Suite Plans Rebecca Cosgrove Chief, Production Management Branch, NCO August.
Hurricane Irene August 2011 Hurricane Irene August 2011 NOAA Service Assessment Frank Marks and Wes Browning (Co-team leads) November 27, 2012.
Probabilistic Hurricane Storm Surge (P-Surge) Arthur Taylor Meteorological Development Laboratory, National Weather Service January 20, 2008.
1 Objective Drought Monitoring and Prediction Recent efforts at Climate Prediction Ct. Kingtse Mo & Jinho Yoon Climate Prediction Center.
Forecasting Hurricane Storm Surge on the Mississippi River David Reed Bob Stucky National Weather Service Lower Mississippi River Forecast Center.
1 Extratropical Storm Surge Modeling Presented By: Jesse Feyen (NOS/OCS, Storm Surge Roadmap) Contributors:
MDL’s Extratropical Storm Surge An Introduction Anne Kramer Scientific Programmer NOAA/NWS/OST/MDL & TCA.
The Lake Pontchartrain Forecast System Rick Luettich Jason G. Fleming Institute of Marine Sciences University of North Carolina.
NOAA Data & Catastrophe Modeling Prepared by Steve Bowen of Impact Forecasting September 16, 2015.
Tropical Report: Modeling Hurricane Ike with SLOSH Don Slinn, Jeff Ren, Go Fujita Univ of Florida Coastal Engineering.
Modeling Storm-Induced Inundation on the Yukon Kuskokwim Delta for Present and Future Climates Tom Ravens and Jon Allen, Univ. of Alaska Anchorage 10 km.
NAME SWG th Annual NOAA Climate Diagnostics and Prediction Workshop State College, Pennsylvania Oct. 28, 2005.
Extra-Tropical Storm Surge (ETSS 1.5) Pre-Implementation Briefing College Park, MD October 8, 2014 Arthur Taylor, Huiqing Liu and Ryan Schuster MDL/NWS/NOAA.
NOAA’s Storm Surge Roadmap: Transition Research to NWS Operations RITT Forum 21 July 2010 Jesse Feyen, Roadmap Portfolio Manager.
Latin American and Caribbean Flood and Drought Monitor – What it does and does not do Figure showing current system Coarse resolution 25km, daily Satellite.
Coastal Emergency Risks Assessment (CERA)
Tom Ravens and Jon Allen, Univ. of Alaska Anchorage
Storm Surge Forecasting Practices, Tools for Emergency Managers, A Probabilistic Storm Surge Model Based on Ensembles and Past Error Distributions.
Virginia Institute of Marine Sciences College of William and Mary
Discussion topics (examples):
Storm Surge Modeling and Forecasting
Storm Surge Definitions:
Extra-Tropical Storm Surge (ETSS 2.1)
Presentation transcript:

Extra-Tropical Storm Surge (ETSS 2.0) Pre-Implementation Briefing College Park, MD May 14, 2015 Arthur Taylor, Huiqing Liu and Ryan Schuster MDL/NWS/NOAA

2 Extra Tropical Storm Surge (ETSS)  Predicts storm surge to the coastline but not overland  Uses 0.5 degree Global Forecast System (GFS) winds and pressure as input 4 times a day  Does so in the following areas Arctic AK (updated Jan 1996), Bering Sea (updated Oct 1998), Gulf of AK (updated Apr 2008), East Coast (updated Feb 2009), Gulf of MX (updated Jan 2011), West Coast (updated Feb 2011)  Based on the SLOSH model  Intended for extra-tropical storms (versus hurricanes)  Does not model Tides, Waves, River Flow

3 Motivation  Future coastal flood and storm surge warnings will likely require overland guidance  ETSS and ESTOFS predict storm surge to the coastline but not overland May 2015 (ETSS 2.0)  Overland storm surge guidance  for East Coast and Gulf of MX  Operationalize total water level guidance Aug 2015 (ETSS 2.1)  Overland “surge and tide” guidance  for East Coast and Gulf of MX  Merge Bering Sea and Arctic basins creating coarse overland “surge and tide” guidance ETSS (1995 – 2014) ESTOFS (2012 – ) ETSS 1.5 (2014 – 2015) Extra-TropicalTropical Overland Storm Surge Storm Surge to Coastline SPLASH (1972 – 1984) ETSS 2.0 (May 2015) No Real-Time Ensemble No Climate Ensemble SLOSH (1984 – ) P-Surge 1.0 (2008 – 2013) MEOW/MOM (1986 – ) Overland Storm Surge + Gridded Tide ETSS 2.1 (Aug 2015) P-ETSS ( ) No Climate Ensemble SLOSH + Tide (2012 – ) P-Surge 2.0 (2014 – 2015) P-Surge 2.5 (May 2015) No Climate Ensemble

4 ETSS 2.0 Objectives 1.For East Coast and Gulf of Mexico …  Nest coarse extra-tropical with fine scale tropical basins  Overland calculations based on surge only 2.Operationalize ETSS post processing at stations  Provide AWIPS/AHPS with SHEF encode total water level guidance Benefits  For East Coast and Gulf of Mexico …  Provide overland extra-tropical storm surge guidance to WFOs  Combine the extended areal coverage of the extra-tropical grids with the finer overland details of the tropical grids  Provide bias corrected surge + tide (a.k.a. total water level) guidance at coastal stations to WFOs and RFCs via AWIPS/AHIPs  Make the ETSS post-processing more resilient

5 Objective 1: Nesting Grids East Coast and Gulf of Mexico A sample of finer overland tropical grids nested within the coarser extra-tropical grids Extra-tropical grids provide a boundary condition for tropical grids

6 ETSS 2.0 Accuracy RMSE2011 Irene2012 Sandy2013 Extra Tropical 2014 Extra Tropical ETSS feet1.23 feet0.82 feet0.78 feet ETSS feet0.99 feet0.78 feet0.73 feet Mean Peak Error 2011 Irene2012 Sandy2013 Extra Tropical 2014 Extra Tropical ETSS feet1.52 feet0.96 feet1.04 feet ETSS feet1.13 feet0.76 feet0.99 feet Mean Error2011 Irene2012 Sandy2013 Extra Tropical 2014 Extra Tropical ETSS feet-0.89 feet-0.42 feet-0.67 feet ETSS feet-0.63 feet-0.26 feet-0.62 feet

7 Irene-2011 Forecasting (Aug 26 00Z to Aug 30 00Z)

8 Sandy-2012 Forecasting (Oct 28 00Z to Nov 1 00Z)

9 ET-March 2013 Forecasting (Mar 5 00Z to Mar 9 00Z)

10 ETSS 2.0 Timeliness? StepJobVersion 1.5Version – CONUS – ModelJETSS1 CPU, 4m 20s5 CPU, 3m 1 – AK – ModelJETSS1 CPU, 4m 20s1 CPU, 3m 2 – CONUS – ModelJETSS6 CPU, 30m Historic Product Timeline4m 20s33m and 3m 2 – AK Post ProcessJETSS_GEMPAK_AK1 CPU, 18s1 CPU, 45s 3 – CONUS Post ProcessJETSS_GEMPAK_CONUS(done in step 2)1 CPU, 50s 3 – Begin SHEF encodeJETSURGE_PARSEDATNA6 CPU, 1m 10s 4 – SHEF Encode JETSURGE_GRIDDAT, JETSURGE_COMBDAT NA 1 CPU, 1m 10s 1 CPU, 1m 50s Finish4m 38s37m 10s ProductVersion 1.5Version 2.0 Station Text – EC, GM ; Grid – CONUS4m 20s after model start33m after model start Station Text – WC, AK ; Grid – AK4m 20s after model start3m after model start (*) Times can vary some from test to test due to weather

11 Reasons for Slower Run Time  Model is serial (per basin)  Tropical basins take longer to compute –23-m (*) for Chesapeake (slowest Tropical basin on East coast) –20-m (*) for Pensacola (slowest Tropical basin in Gulf of Mexico)  Tropical basins have to wait for Extra-Tropical basins –23-m 30-s (*) combined for Chesapeake (East Coast takes 30-s) –25-m (*) combined for Pensacola (Gulf of Mexico takes 5-m)  Investigating ways to increase run-times (*) These times are on Phase 2

12 Objective 2: ETSS Post Processing – Total Water Level at Stations  Use observations to account for model bias, sea level rise, rainfall, wave action, etc. t = hourly 5-day hindcast t = hourly 96-hour forecast Anomaly(t) = Obs(t) – (Tide(t) + Surge(t))Total Water Level(t) = F(t) + (Tide(t) + Surge(t)) F(t), for the first 12 hours, is a linear interpolation between Anomaly(t=0) and the 5-day Avg. Anomaly. After that, F(t) is the 5-day Avg. Anomaly. Goal: Provide WFOs, and RFCs with total water level guidance at stations via SHEF messages to AWIPS

13 ETSS Post Processing (ET-Surge)

14 ETSS Post Processing (ET-Surge)

15 ETSS Post Processing (ET-Surge) Goal 1: Use Google maps to allow for addition of more stations Goal 2: Provide information as to when the maximum surge will occur Goal 3: Provide more interactive hydrographs Goal 1: Use Google maps to allow for addition of more stations Goal 2: Provide information as to when the maximum surge will occur Goal 3: Provide more interactive hydrographs  Goal 4: Incorporate gridded information  Goal 5: Incorporate other model’s guidance (e.g. ESTOFS)  Goal 6: Incorporate user requests  Goal 4: Incorporate gridded information  Goal 5: Incorporate other model’s guidance (e.g. ESTOFS)  Goal 6: Incorporate user requests

16 ETSS 2.0 Should we Implement? Objectives 1.For East Coast and Gulf of Mexico … Nest coarse extra-tropical with fine scale tropical basins Overland calculations based on surge only 2.Operationalize ETSS post processing at stations Provide AWIPS/AHPS with SHEF encode total water level guidance Recommend Implementation MDL NHC/TAFB Eastern Region NCO  Others?

17 Backup

18 Aug 2015 – ETSS 2.1  Goal 1: Create a replacement basin (ENO3) for the Arctic (Jan 1996) and Bering Sea (Oct 1998) basins, which is capable of overland calculations  Goal 2: Enable the model to compute overland (versus to the coast) storm surge  Goal 1: Create a replacement basin (ENO3) for the Arctic (Jan 1996) and Bering Sea (Oct 1998) basins, which is capable of overland calculations  Goal 2: Enable the model to compute overland (versus to the coast) storm surge  Goal 3: Compute gridded surge + gridded tide

19 Aug 2015 – ETSS 2.1 Goals 1 & 2: Created a replacement basin with six km resolution overland, which can compute overland (versus to the coast) storm surge Goal 3: Computing gridded tide based on 13 constituents from OSU – TPXO global tidal model  Develop and nest higher resolution overland basin(s)  Switch to 37 constituents  Use tidal constituents from local ADCIRC model  Switch to 37 constituents  Use tidal constituents from local ADCIRC model

20 Aug 2015 – ETSS 2.1 Norton Sound, YK Delta

21 Future Efforts  Create a West Pacific basin to replace Gulf of Alaska (Apr 2008) and West Coast (Feb 2011)  Provides overland information  Models surge flowing along the Canadian coast  Create Probabilistic Extra-Tropical Storm Surge (PETSS) using 21 GFS ensemble members as input  Provides probabilistic overland inundation guidance to assist with future storm surge warnings  Scalable to include other ensemble models  Ensemble member results can be provided to RFCs

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.