1. Verification of a downscaling approach for large area flood prediction over the Ohio River Basin
N. Voisin, J.C. Schaake and D.P. Lettenmaier
University of Washington, Seattle, WA
AMS Annual Meeting, Phoenix AZ Jan 2009

2. Objective
Predict streamflow and associated hydrologic variables, soil moisture, runoff, evaporation and snow water equivalent :
Applicable to large river basins, eventually globally: spatial consistency, ungauged basins
Using a fully distributed hydrology model
Using ensemble weather forecasts
Lead time up to 2 weeks

3. Objective Forecast schematic
BCSD = Bias correction and statistical downscaling
Forecast schematic
Several years back
Medium range forecasts (2 weeks)
ECMWF EPS
50 ensemble members
Daily ERA-40
surrogate for near real time analysis fields
Daily
ECMWF Analysis
BCSD to 0.25 degree
BCSD with forecast calibration, 0.25 degree
Atmospheric inputs
VIC Hydrology
Model
Hydrologic model spinup 0.25 degree
Hydrologic fcst
(stream flow, soil moist., SWE,
runoff )
Initial State
Flow fcst calibration

4. Objective Compare different downscaling techniques
Applicable at a global scale
For precipitation forecast
Improve or conserve the skill

5. Outline Existing downscaling methods
Analog technique and various variations of it
Forecast Verification at different spatial and temporal scales:
Mean errors
Predictability, reliability
Spatial rank structure

6. 1. Downscaling techniques
MOS (Glahn and Lowry 1972, Clark and Hay 2004)
Bias correction followed by spatial and temporal resampling for seasonal forecast (Wood et al and 2004)
National Weather Service (NWS) Ensemble Precipitation Processor (EPP) ( Schaake et al. 2007)
Analog techniques ( Hamill and Whitaker 2006)

7. 2. Analog technique 3 methods for choosing the analog:
( adapted from Hamill and Whitaker 2006)
Retrosp. FCST dataset, +/- 45 days around day n
1 degree resolution
Corresp.
Observation (TRMM)
0.25 degree resolution
FCST D DAY
OBS D DAY
Downscaled
FCST
day n
0.25 degree
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST D DAY
OBS D DAY
FCST n
+/- 45 days
Year-1
OBS n
+/- 45 days
Year-1
FCST day n
1 degree
5 degree
3 methods for choosing the analog:
Closest in terms of RMSD, for each ensemble
15 closest in terms of RMSD, to the ensemble mean fcst
Closest in terms of rank, for each ensemble
5 degree

8. 2. Analog technique Spatial domain for the analog
Choose an analog for the entire domain (Maurer et al. 2008): entire US, or the globe
Ensure spatial rank structure
Need a long dataset of retrofcst-observation.
Moving spatial window (Hamill and Whitaker 2006):
5x5 degree window (25 grid points)
Choose analog based on ΣRMSD, or Σ(Δrank)
Date of analog is assigned to the center grid point

9. 2. Analog technique Ens. Mean Fcst, 20050713 Fcst 20050713
4 closest analogs in the retrospective forecast dataset
Corresponding 0.25 degree TRMM for the analogs,
Downscaled ensemble forecast members
Downscaled ens. mean forecast
TRMM (obs)
( adapted from Hamill and Whitaker 2006)

10. 3. Forecast Verification
Evaluate the different analog techniques, simple interpolation, and basic resampling downscaling
Verification conditioned on the forecast:
Mean errors
Reliability
Predictability
Verification conditioned on the observation
Discrimination (ROC)
For lead times 1,5 and 10 days
at 0.25 and 1 degree spatial resolution,
Daily and 5 day accumulation

11. Mean Errors 0.25 degree Ohio Basin 2002-2006 TRMM as obs
Upper tercile: improved bias

12. Reliability of ens. spread
0.25 degree
Ohio Basin
TRMM as obs
Improved reliability

13. Predictability 0.25 degree Ohio Basin 2002-2006 TRMM as obs
Status quo or no improvement

14. Discrimination ROC diagram 0.25 degree Ohio Basin 2002-2006
TRMM as obs
Prob. of detection
Or hit rate
False alarm rate

15. Spatial structure 2005, Jul 13th 75th Percentile
basin daily acc., TRMM

16. Conclusions The analog technique with a moving spatial window
improves:
reliability (considerably), mean errors (slightly)
Status quo on:
discrimination,predictability
Results consistent at different spatial and temporal scales ( not shown, 1 degree and 5 day acc.)
More realistic precipitation patterns.
Spatial rank structure?
An analog technique with no moving spatial window would ensure it. Issue with short observed dataset.
Try the NWS EPP.

17. Climatologies of forecasts
Ohio Basin

18. Mean Errors 0.25 degree Ohio Basin 2002-2006 TRMM as obs
Upper tercile: improved bias

19. Mean Errors 1 degree Ohio Basin 2002-2006 TRMM as obs
Upper tercile: improved bias

20. Mean Errors 0.25 degree 5 day acc. Ohio Basin 2002-2006 TRMM as obs
Upper tercile: improved bias

21. Reliability 0.25 degree Ohio Basin 2002-2006 TRMM as obs
- Improved reliability
- poor reliability for medium tercile
- poor reliability lead time 10

22. Reliability 1 degree Ohio Basin 2002-2006 TRMM as obs
- Improved reliability
- No reliability for medium tercile
- No reliability lead time 10

23. Reliability 0.25 degree 5 day acc Ohio Basin 2002-2006 TRMM as obs
- Improved reliability
No reliability for medium tercile
- Some reliability day 6-10

24. Sharpness 0.25 degree Ohio Basin 2002-2006 TRMM as obs
Improved sharpness
for lower tercile

25. Sharpness 1 degree Ohio Basin 2002-2006 TRMM as obs Improved sharpness
for lower tercile

26. Sharpness 0.25 degree 5 day acc Ohio Basin 2002-2006 TRMM as obs
No improvement

27. Predictability 0.25 degree Ohio Basin 2002-2006 TRMM as obs
Status quo or no improvement

28. Predictability 1 degree Ohio Basin 2002-2006 TRMM as obs
Status quo or no improvement

29. Predictability 0.25 degree 5 day acc Ohio Basin 2002-2006 TRMM as obs
Status quo or no improvement

30. Reliability of ens. spread
0.25 degree
Ohio Basin
TRMM as obs

31. Reliability of ens. spread
1 degree
Ohio Basin
TRMM as obs

32. Reliability of ens. spread
0.25 degree
5 day acc.
Ohio Basin
TRMM as obs