1 / 26

The Climate Prediction Center Rainfall Estimation Algorithm Version 2 Tim Love -- RSIS/CPC

The Climate Prediction Center Rainfall Estimation Algorithm Version 2 Tim Love -- RSIS/CPC. Presentation Outline. Overview Input data / methodology Satellite estimate combination process Merging steps Output data System requirements. CPC RFE 2.0. RFE 2.0 Overview.

kasi
Download Presentation

The Climate Prediction Center Rainfall Estimation Algorithm Version 2 Tim Love -- RSIS/CPC

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. The Climate Prediction CenterRainfall Estimation Algorithm Version 2Tim Love -- RSIS/CPC

  2. Presentation Outline • Overview • Input data / methodology • Satellite estimate combination process • Merging steps • Output data • System requirements CPC RFE 2.0

  3. RFE 2.0 Overview • Run daily at CPC for Africa, southern Asia, Afghanistan area domains • Final output is minimally biased and greatly improves spatial resolution of information • Inputs include satellite IR temperature data, microwave precip estimates, gauge fields • Computing resources required are relatively minimal • Code highly portable CPC RFE 2.0

  4. Input Data • Meteosat files • Half hourly 0.05° infrared temperature data thru a McIDAS server • Files are ftp’d to host machine once daily and gridded based on current satellite position constants • Code conducts QC via lag and cross-correlation methods • Fractional coverage for 235K and 275K determined CPC RFE 2.0

  5. Meteosat Data, cont. • Resultant field = cold count duration (CCD) @ 0.1° resolution • CCD used for GOES Precipitation Index (GPI) calculation • GPI tends to overestimate spatial distribution but underestimates convective precipitation CPC RFE 2.0

  6. GPI Quality Control • Each pixel must have > 4 half hour values, or pixel is undefined • > 70% of all pixels must be defined after incorporating all half hour data sets CPC RFE 2.0

  7. GPI Estimate CPC RFE 2.0

  8. GTS Data • 2534 stations available daily • Only 400-800 report daily • Few reports from Nigeria, none from Liberia, Sierra Leone • Data ingested from GTS line, QC’d, fed to operational machine, then gridded to 0.1° resolution file • Other station data may be readily used as input to algorithm via changing 2 tables in base code • Requirements for RFE processing: • GPI and GTS inputs CPC RFE 2.0

  9. GTS Quality Control • Must have > 200 stations available daily • Station undefined if GTS daily rainfall: > 200 mm > 1 mm and fc275 = 0 in all surrounding pixels < 0.1 mm and all satellite estimates > 2 mm > 50 mm and all satellites < 20 mm < 5 mm, all satellites > 20 mm, and if sat-GTS > 20 > 20 mm and all satellites < 1 mm CPC RFE 2.0

  10. GTS Interpolation Technique • Shepard technique • Using an initial search radius (rs0), a new radius is determined depending on number of stations within rs0 • If an adequate # of gauges is within new radius, interpolate rainfall to 0.1° grid using station-station vector • Otherwise, interpolate using least squares regression • If rainfall is undef or 0 within a 1.0 degree box, rainfall at center grid is zero CPC RFE 2.0

  11. Initial Search Radius CPC RFE 2.0

  12. GTS Inputs CPC RFE 2.0

  13. GTS vs GPI CPC RFE 2.0

  14. SSM/I Inputs • 2 instruments estimate precip twice daily ~6 hourly data frequency • Fails to catch other rainfall in temporal gaps • Data needs only small conversion in preparation for input to algorithm CPC RFE 2.0

  15. SSM/I Quality Control • > 70% of pixels must be defined after combining each input data set • SSM/I daily rainfall is zero if: • fc275 = 0 (no clouds) • SSM/I rain < 0.1 mm • fc275 < 0.1 and SSM/I rain > 5 mm • target grid is over the coast and 1 or less neighboring grids have SSM/I rain = 0 CPC RFE 2.0

  16. SSM/I Estimate CPC RFE 2.0

  17. SSM/I vs GTS vs GPI CPC RFE 2.0

  18. AMSU-B Data • As with SSM/I, data is available 4 times daily, staggered temporally • Tends to overestimate most precip, but does well with highly convective systems • Data sent in HDF format, thus needs to be deciphered before input to RFE algorithm • Preprocessing straightforward CPC RFE 2.0

  19. AMSU-B Quality Control • > 60% of pixels must be defined after incorporating all input data • AMSU-B daily rainfall is zero if: • fc275 = 0 (no clouds) • AMSU rain < 0.1 mm • fc275 < 0.1 and AMSU rain > 5 mm • target grid is over the coast and 1 or less neighboring grids have AMSU rain = 0 CPC RFE 2.0

  20. AMSU-B Estimate CPC RFE 2.0

  21. CPC RFE 2.0

  22. Combining Satellite Estimates • Combines 3 satellite data sets linearly where Wi = weighting coefficients Si = precip estimates σi = random error CPC RFE 2.0

  23. Bias Removal • Satellite estimates are merged with station data to remove bias where S = first step output G = gauge observations P = final output CPC RFE 2.0

  24. Output Data • Operational: GTS+GPI+SSM/I+AMSUB • Other: • GTS+GPI • GTS+GPI+SSM/I+AMSUB+GDAS • With and without bias removal • Archival: • All inputs needed for reprocessing • Some mid-processing outputs CPC RFE 2.0

  25. System Requirements • Linux or Unix operating system • System has also been ported to Windows • Minimum 2Gb hard drive space • Minimum 500MHz processor • Fortran 77/90 compiler • C, Korn, or Bourne Shell • GrADS software to display/create graphics CPC RFE 2.0

  26. System Outreach • Seek collaboration with external users to: • Develop local capability • Develop independent validation • Improve algorithm CPC RFE 2.0

More Related