1 / 14

Wind Gust Analysis in RTMA

Wind Gust Analysis in RTMA. Yanqiu Zhu, Geoff DiMego, John Derber, Manuel Pondeca, Geoff Manikin, Russ Treadon, Dave Parrish, Jim Purser. Environmental Modeling Center. National Centers for Environmental Prediction. Real-Time Mesoscale Analysis (RTMA).

wenda
Download Presentation

Wind Gust Analysis in RTMA

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. Wind Gust Analysis in RTMA Yanqiu Zhu, Geoff DiMego, John Derber, Manuel Pondeca, Geoff Manikin, Russ Treadon, Dave Parrish, Jim Purser Environmental Modeling Center National Centers for Environmental Prediction

  2. Real-Time Mesoscale Analysis (RTMA) • RTMA is a NOAA-NWS gridded surface analysis system developed at EMC of NCEP in collaboration with the Global Systems Division (GSD) • One of its important applications is to provide a comprehensive set of high spatial and temporal resolution analyses that can be used to monitor potential severe weather events • 2DVAR-version of Gridded Statistical Interpolation • Terrain-following anisotropic background error covariances • Background fields for CONUS is generated by downscaling RUC 1h forecasts

  3. Generalizing GSI Control Variables • RTMA analyses for surface pressure, 10 m wind, 2m temperature and moisture over CONUS on the 5-km NDFD grid • Enhanced GSI flexibility to add/remove 2D and 3D control variables • Wind gust was added as a new control variable • A univariate analysis for wind gust

  4. Main issues • Compatibility among different data sources - Type 180 SFCSHP -- Surface marine - Type 181 ADPSFC -- Surface land (Synoptic, METAR) - Type 187 ADPSFC -- Surface land (METAR) - Type 188 MSONET – Surface mesonet • Applicability of Mesonet use list and reject list Time period: Sept. 13 ~ 22, 2008

  5. 2D-pattern: Bias of O-F

  6. Break-down of mesonet gust data after applying mesonet use & reject lists (Only a total of 43.4% of 1951945 remained)

  7. Gust data handling • For the observations which were at the same location, the one that was closest to the analysis time was chosen • Observation error was inflated based on the relative time to the analysis time. Less weight was given to the observations that were far away from the analysis time • mesonet use list and reject list were applied • Less weight was given to mesonet data that were less than 7.2m/s • The discrepancy of observation station elevation and model surface was taken into account • Gust background correlation length was chosen to be comparable to that of 10m wind

  8. Bias and RMS of QC-ed O-F|O-A

  9. Case study • A high wind event on Dec. 31, 2008 • Very strong wind across mid-Atlantic as low deepened off east coast • 19m/s + gusts at DCA, IAD, BWI • Tree and power line damage

  10. 1500Z gust observations

  11. 1500Z Guess and Analysis Guess over-forecasted in most of the area Analysis improved gust field, small scale features were evident

  12. 1800Z guess and analysis

  13. Conclusions • Wind gust speed was added as a new control variable • Gust data from various data sources were examined and assimilated for an arbitrary time period • Surface marine gust data showed reasonable good O-F bias • METAR and strong mesonet gust data exhibited a pattern with negative bias over eastern regions except Florida and positive bias over western regions, while weak mesonet gust data had a significant negative bias over the CONUS • The results implied the incompatibility between METAR gust data and weak mesonet gust data. • The application of mesonet use and reject lists to mesonet gust data removed stations with very large O-F departures • The use of gust data led to significant improvement of the gust field with detailed small scale features.

  14. Future work • Conduct routine gust analysis • Further refine parameters used to construct gust background error covariance • Gust data quality control - utilize wind data information - variational quality control • Bias correction of gust background

More Related