1 / 21

An Improved Wind Probability Program: A Year 2 Joint Hurricane Testbed Project Update

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, CIRA/CSU, Fort Collins, CO Buck Sampson, NRL, Monterey, CA Chris Lauer and Chris Sisko, NCEP/TPC, Miami, FL. Presented at the

ehren
Download Presentation

An Improved Wind Probability Program: A Year 2 Joint Hurricane Testbed Project Update

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 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, CIRA/CSU, Fort Collins, CO Buck Sampson, NRL, Monterey, CA Chris Lauer and Chris Sisko, NCEP/TPC, Miami, FL Presented at the Interdepartmental Hurricane Conference March 5, 2009

  2. Monte Carlo Wind Probability Model • Estimates probability of 34, 50 and 64 kt wind to 5 days • Implemented at NHC for 2006 hurricane season • Replaced Hurricane Strike Probabilities • 1000 track realizations from random sampling NHC track error distributions • Intensity of realizations from random sampling NHC intensity error distributions • Special treatment near land • Wind radii of realizations from radii CLIPER model and its radii error distributions • Serial correlation of errors included • Probability at a point from counting number of realizations passing within the wind radii of interest

  3. MC Probability Example Hurricane Ike 7 Sept 2008 12 UTC 1000 Track Realizations 64 kt 0-120 h Cumulative Probabilities

  4. Project Tasks • Improved Monte Carlo wind probability program by using situation-depending track error distributions • Track error depends on Goerss Predicted Consensus Error (GPCE) • Improve timeliness by optimization of MC code • Update NHC wind speed probability product • Extend from 3 to 5 days • Update probability distributions (was based on 1988-1997)

  5. Tasks 2 and 3 Completed • Optimized code implemented for 2007 season • Factor of 6 speed up • Wind Speed Probability Table • Calculated directly from MC model intensity realizations • Implemented for 2008 season

  6. Task 1: Forecast Dependent Track Errors • Use GPCE input as a measure of track uncertainty • Divide NHC track errors into three groups based on GPCE values • Low, Medium and High • For real time runs, use probability distribution for real time GPCE value tercile • Different forecast times can use different distributions • Relies on relationship between NHC track errors and GPCE value

  7. Goerss Predicted Consensus Error (GPCE) • Predicts error of CONU track forecast • Consensus of GFDI, AVNI, NGPI, UKMI, GFNI • GPCE Input • Spread of CONU member track forecasts • Initial latitude • Initial and forecasted intensity • Explains 15-50% of CONU track error variance • GPCE estimates radius that contains ~70% of CONU verifying positions at each time • In 2008, GPCE predicts TVCN error • GFS, UKMET, NOGAPS, GFDL, HWRF, GFDN, ECMWF

  8. 72 hr Atlantic NHC Along Track Error Distributions Stratified by GPCE

  9. 2008 Evaluation Procedure • GPCE version not ready for 2008 real time parallel runs • Re-run operational and GPCE versions for 169 Atlantic cases within 1000 km of land at t=0 • Qualitative Evaluation: Post 34, 50, 64 kt probabilities on web page for NHC • Operational, GPCE and difference plots • Quantitative Evaluation: Calculate probabilistic forecast metrics from output on NHC breakpoints

  10. GPCE MC Model Evaluation Web Page http://rammb.cira.colostate.edu/research/tropical_cyclones/tc_wind_prob/gpce.asp

  11. Individual Forecast Case Page

  12. Tropical Storm Hanna 5 Sept 2008 12 UTC 34 kt 0-120 h cumulative probability difference field (GPCE-Operational) All GPCE values in “High” tercile

  13. Hurricane Gustav 30 Aug 2008 18 UTC 64 kt 0-120 h cumulative probability difference field (GPCE-Operational) All GPCE values in “Low” tercile

  14. Quantitative Evaluation • Calculate probabilities at NHC breakpoints • Operational and GPCE versions • 34, 50 and 64 kt • 12 hr cumulative and incremental to 120 h • 169 forecasts X 257 breakpoints = 43,433 data points at each forecast time • Two evaluation metrics • Brier Score • Optimal Threat Score

  15. Operational and GPCE Probabilities Calculated at 257 NHC Breakpoints West Coast of Mexico and Hawaii breakpoints excluded to eliminate zero or very low probability points

  16. Brier Score (BS) • Common metric for probabilistic forecasts • Pi= MC model probability at a grid point (0 to 1) • Oi= “Observed probability” (=1 if yes, =0 if no) • Perfect BS =0, Worst =1 • Calculate BS for GPCE and operational versions • Skill of GPCE is percent improvement of BS

  17. Brier Score Improvements2008 GPCE MC Model Test Cumulative Incremental

  18. Threat Score (TS) • Choose a probability threshold to divide between yes or no forecast • Calculate Threat Score (TS) • Repeat for wide range of thresholds • Every 0.5% from 0 to 100% • Find maximum TS possible • Compare best TS for GPCE and operational model runs a c b Observed Area Forecast Area

  19. Threat Score Improvements2008 GPCE MC Model Test Cumulative Incremental

  20. Potential Impact of GPCE on Hurricane Warnings • Automated hurricane warning guidance from MC probabilities under development • Schumacher et al. (2009 IHC) • Warning algorithm run for Hurricane Gustav (2008) • Operational and GPCE versions

  21. Summary • Code optimization and wind speed table product are complete • Implemented before 2007 and 2008 seasons • GPCE-dependent MC model • Tested on 169 Atlantic cases from 2008 • Results are qualitatively reasonable • Improves Brier Score at all time periods relative to operational MC model • Improves Threat Score at most time periods • Not tested in the eastern and western Pacific

More Related