1 / 41

Operational Drought Information System Kingtse Mo

Operational Drought Information System Kingtse Mo Climate Prediction Center NCEP/ NWS/NOAA Operation--- real time, on time and all the time. Mission. CPC issues operational monthly and seasonal drought outlook and participates in the Drought Monitor

marcel
Download Presentation

Operational Drought Information System Kingtse Mo

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. Operational Drought Information System Kingtse Mo Climate Prediction CenterNCEP/ NWS/NOAA Operation--- real time, on time and all the time

  2. Mission • CPC issues operational monthly and seasonal drought outlook and participates in the Drought Monitor • These products are used by government, NIDIS, local state government , regional centers and private sectors • To support the CPC mission, we give drought briefing each month to review the current conditions and forecasts

  3. Definition of drought– persistent dry conditions Colorado basin SE

  4. 75-85W,31-35N A wet region 6 mo running mean black line drought 3 mo running mean (black line) No smoothing Red line: monthly mean, no smoothing SM 1-2 months delay

  5. A dry region SM has much lower freq. over the western region

  6. Good indices • 1. They do not depend on season • 2. They do not depend on location • 3. They are accessible in real time • 4. It measures the spatial and temporal scales of drought • 5. All indices should be able to pick up strong drought evens Kelly Redmond

  7. Different faces of droughtdefine drought by impact • Meteorological drought– P deficit • Agricultural drought--- soil moisture deficit • Hydrological drought_ runoff or streamflow deficit Using index to define drought

  8. SPI fcsts 20130831 • Recent rain diminishes drought over the Southwest and California • Continuous rainfall events causes floods over the Southeast and the East cast • The SPI24 still shows the strong drought events of 2012 SPI gives the historical development of drought/floods

  9. SPI SPI Advantages: • Easy to use and only need station data • Cover all time scales • Do not need a hydrologic model. • (Other indices are model derived products) SPI Disadvantages: • It does not contain snow information • Areas where soil moisture feedback is important or large E, SPI may not be representative (e. g. Amazon)

  10. North American Land Data Assimilation system They are not TRUTH • Surface land model- Noah, SAC, VIC, Mosaic and Catchment model • They are driven by forcing which consists of precipitation (P), Max and min Tsurf and wind speed for a water balance model • Some models like Noah and Mosaic have the energetics –radiation terms. VIC has both versions • Outputs: Evaporation, Soil moisture, soil temperature, runoff , Snow water equivalent. And many others

  11. Don’t worry, be happy!! Even though the total soil moistures differ from one model to another, their anomalies (or percentiles) are very similar!! (Robock et al 2004; Dirmeyer et al. (2004) Koster et al. (2008) All models were driven by the same forcing 15

  12. U Washington Multi model SM information NCEP/EMC Both captures the wetness over the Eastern and East central United States and dryness over the Southwest and the Plains, But intensity differs

  13. Differences between two systems are larger than the spread among members of the same system • The differences are not caused by one model. They are caused by forcing. • In general, extreme values from the UW (Green) are larger than from the NCEP (red) standardized SM anomalies for area 38-42N,110-115W NCEP(red),UW(green)

  14. The EMC NCEP system • Four models: Noah, VIC, Mosaic and SAC • Climatology: 1979-2007 • On 0.125 degrees grid • P forcing : From the CPC P analysis based on rain gauges with the PRISM correction. (all stations reports within cutoff time • Other atmospheric forcing: From the NARR

  15. University of Washington system • Four models: Noah, VIC, SAC ,CLM Catchment • (models may have the same name, but versions may not be the same) • Climatology: 1915-2007 • P, Tsurf and low level winds from NOAA/NCDC co-op stations • P from index stations

  16. Forcing • Since the differences among the members of the same system are small, the differences do not come from models. • Differences come from forcing. • There are two major forcing terms: precipitation and temperature. • Their differences are larger after 2002

  17. Experiments • The VIC model of 0.5 degrees resolution from the UW system was chosen for experiments. • All experiments started from Jan 1 1979 using the same initial conditions from the UW VIC model in the UW system. • Experiments end on 31Dec 2008 • Forcing terms have two components • P forcing :Precipitation • F forcing : Tmax, Tmin and wind speed

  18. Four experiments • Comparison between • Exp (P uw F uw) vsExp(Pncep,Fuw) and • Exp (Puw, Fncep) vsExp(Pnecp,Fncep) indicates the differences caused by Precip • Comparison between • Exp (P uw F uw) vsExp(Puw,Fncep) and • Exp (Pncep, Fuw) vsExp(Pnecp,Fncep) indicates the differences caused by F forcing (Tsurf and winds)

  19. Experiments :RMS differences of SM % Same F forcing Same P forcing Large differences between experiments with the same F forcing but the same P forcing are large

  20. Number of station reports averaged over a year

  21. Number of reports /month averaged over the box Large drop in real time

  22. Challenges: improving drought monitoring • Improve historical and real time Precipitation data and analyses • Improve NLDAS model forcing: P, downward short wave radiation etc • Improve hydrologic model • Improve and integrate satellite observations with station data. • Link to attribution

  23. NMME/IMME seasonal fcsts JAS 2013 ASO 2013 ASO 2013 We have 6 models: CFSv2 24 members; GFDL, CMC1 and CMC2 : 10 members NASA: 11 members NCAR : 6 members Hindcasts from 1982-2010 P, Tsurf monthly means

  24. Hydroclimate FCSTs • SPI forecasts based on the National Multi Model ensemble (NMME) • ESP forecasts from the UW • Cfsv2_VIC forecasts from the Princeton, EMC and MSU • NASA SM from their Coupled model forecasts

  25. SPI forecast If you have precip monthly mean fcsts, you can have the SPI forecasts CGCM Yoon et al. JHM 2012

  26. SPI fcsts (201308) verification

  27. ESP (Ensemble streamflow prediction) vs NMME_VIC Fcsts Starting date ESP- P T inputs taken from randomly selected observations Run VIC with observed P and Tsurf Jan 1,1915 from UW Jan 1, 1979 IC s Fcst forward Feb 5 Feb 6--- NMME_VIC :forcing s were taken from error corrected T P from CGCM Both ESP and NMME_VIC have the same initial conditions, but ESP has no climate forecast information of P and Tsurf

  28. ESP FCST UW ICs=20130802 Oct lead=3mo August lead=1mo \ Acc ro lead=1mo Sep lead=2mo

  29. SM fcsts EMC_MSU_Princeton AUGUST lead=1mo Same as the ESP, but climate forcing is given by the CFSv2 forecasts September lead=2mo Oct lead=3mo

  30. NMME_VIC forecasts • Initial conditions from the VIC simulation taken from the UW NLDAS_VIC (perfect) • Climate forcing derived from the members of the NMME for each model • Drive VIC to get SM and Runoff • For a given model and given lead time, we took the ensemble mean of all members. The climatology of the forecasts is corrected in the cross validated way. • SM /Runoff or SRI3 ensemble mean is the equally weighted mean of all 6 models

  31. Fcst skill for SM • Lead-1 : correlation >0.8 (WOW!!!) • Lead-3: Over the western interior dry region, the fcsts are still skillful for all seasons and the North Central for January (high skill regions) • Low skill regions are circled

  32. Lead-3 Differences btw NMME-ESP No significant differences for Lead-1 and Lead-2 Only October and January forecasts pass the Livezey Chen field pass 3. Differences are in the areas that the skill is low and dynamically active areas 4. Oct fcsts are helped by skillful P forecasts

  33. Two regimes Dry: western interior & eastern Texas • Forecast skill of SM and Runoff are high at lead-3, • Contributions are from the initial conditions • ESP_VIC also has high skill • Areas with low P mean and Low P variability WET: Eastern region and monsoon region • Wet areas with large mean P and P variability • Skill is low even at Lead-1 • Dynamically active and P depends on the moisture transport • NMME has higher skill than the ESP

  34. Problem with hydroclimate prediction- low P fcst skill No skill after Lead-1 Except the Southeast In Oct When the CF starts to contribute at Lead-2 or higher, the skill of P forecasts are so low, it does not make a difference

  35. Issues of hydroclimatefcsts • At Lead-1, the initial conditions dominant the forecast skill. The NMMS precipitation forecasts have some skill, but it competes with the initial conditions • At Lead-2 and Lead-3, the impact of forcing starts to contribute to skill, but the skill of P fcsts decreases . In the western region, the Ics still contribute but over the dynamically active region such as the Southeast or the monsoon region, the P forecasts need to be good enough to contribute to SM or RO forecasts at higher lead

  36. Conclusions • GIVE Me : Better P forecasts at Lead-2 and Lead-3 You will have Better SM and Runoff forecasts over the dynamically active region • Give me better station data reporting in real time You will get : better NLDAS with less uncertainties and better forecasts over the dry areas

  37. Measure the differences among models Rm for a group of models Wm :the mean intermodel variance (or spread) Wint (m): interannual variance of the ensemble mean 17 Similar formula was used by Dirmeyer et al (2004). to assess Global wetness products except we use variance instead of standard dev.

  38. R values for SM % • The spread among the members from the same system (UW or NCEP) is small. It is less than 0.4. (Fig. a and b) • 2. R values with all UW and NCEP members together is much larger (Fig.c). • This implies that the mean differences between two systems are large

  39. The RMS difference (Fig.d) between the ncep and the UW ensemble SM means are large over the western U. S. (> 20%). • Largest differences occur after 2001 as indicated by the mean differences for two periods (Fig. f and g)

  40. Prediction • Oceanic conditions • ENSO normal • the positive SSTAs over the North Pacific will continue through summer. • Precipitation • above normal rainfall over the East • above normal rainfall over the Southwest • Drought • All forecasts indicate that drought over the Central U. S. and Texas will improve • A normal to slightly above normal monsoon will improve drought conditions over the Southwest

  41. RMSE (NMME) R(NMME/ESP) Comparison with ESP Lead=1mo • Over the central and western U.S., the ESP has advantages up to lead=2mo • Over the eastern U.S., the NMME has advantage than the esp • For lead=3, skill overall is very low and the NMME and ESP have comparable skill • The spreads are small and located in the area with low skill • . Lead=2mo Lead=3mo Spread lead=2 and 3 mo

More Related