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Forecast Sensitivity Tests with New Observations

Forecast Sensitivity Tests with New Observations. Mario Majcen and Jan Paegle University of Utah Salt Lake City Utah. Outline. Background Motivation Goals Tools Results Summary and conclusions Questions. Background. Mesoscale convective system observed on January 17 th 2003.

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Forecast Sensitivity Tests with New Observations

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  1. Forecast Sensitivity Tests with New Observations Mario Majcen and Jan Paegle University of Utah Salt Lake City Utah

  2. Outline • Background • Motivation • Goals • Tools • Results • Summary and conclusions • Questions

  3. Background • Mesoscale convective system observed on January 17th 2003 January 17 at 17:45 UTC January 17 at 23:45 UTC January 18 at 05:45 UTC January 18 at 17:45 UTC

  4. Motivation • Model forecasts intercomparison by Dr. Saulo (University of Buenos Aires) • Models: • Global and regional model at CPTEC/INPE (Brazil) • ETA model at CPTEC/INPE (Brazil) • ETA model at the University of Maryland (USA) • RAMS model at University of Sao Paolo (Brazil) • RAMS model at University of Buenos Aires (Argentina) • MM5 model at University of Chile (Chile) • MM5 model at CIMA (Argentina) • All models were initialized with the GDAS analysis at 00 UTC January 17.

  5. Motivation • Mean forecasted precipitation accumulation:

  6. Motivation • Dispersion between forecasts:

  7. Motivation • Forecasted and observed wind profiles (at Mariscal Estigarribia):

  8. Outline • Background • Motivation • Goals • Tools • Results • Summary and conclusions • Questions

  9. Goals • Goals of this study: • Examine if a new approach with a global variable resolution Euler model could predict this event better • Examine forecast sensitivity to analysis • Examine forecast sensitivity to inclusion of special observations • Compare forecasts and analyses to the radiosonde observations taken at Resistencia, Santiago del Estero and Santa Cruz

  10. Tools • Characteristics of models and analyses used in previous studies: • Most of the models used in previous studies have primitive equations dynamical core • All but one are limited area models (lateral boundary conditions may not represent well overturning divergent circulation associated with strong convection and precipitation, J. Paegle 1978,Wang et al 1999) • A global (CPTEC) model had coarse resolution • All models were initialized with the GDAS analysis

  11. Tools • Characteristics of the model and analyses used in this study: • Euler equations dynamical core (retains rapidly propagating sound and gravity waves) • A global model (no lateral boundary conditions imposed) • Better resolution in the area of interest • Model was initialized with the GDAS analysis, the CPTEC analysis (with and without special observations)

  12. Tools • Uniform resolution grid in Euler model:

  13. Tools • Mathematical pole rotation and variable resolution in Euler model:

  14. Tools • Increased resolution over the area of interest in Euler model:

  15. Outline • Background • Motivation • Goals • Tools • Results • Summary and conclusions • Questions

  16. Results 00 UTC 01/17 18 UTC 01/17. • Case description: GDAS analysis 500 mb wind and geopotential height

  17. Results 00 UTC 01/17 18 UTC 01/17 • Case description: GDAS analysis 850 mb wind and temperature

  18. Results 00 UTC 01/17 18 UTC 01/17 • Case description: 850 mb wind and mixing ratio

  19. Results 00 UTC 01/17 18 UTC 01/17 • Case description: Convective Available Potential Energy (CAPE)

  20. Results • Experiments performed in this study:

  21. Results • Upper air observation sites:

  22. Results • Experiment 1: 500mb height anomaly correlation coefficients: black: global, blue: 90S-20S, red: 20N-90N 20 N – 90 N global 90 S – 20 S

  23. Results Experiment 1 Observed One-day precipitation accumulation valid at 00 UTC, January 18

  24. Results Experiment 1 Observed • One-day precipitation accumulation valid at 00 UTC, January 19

  25. Results • Noise/signal ratio of RMS difference between Experiment 1 and the GDAS analysis wind. 850 mb 500 mb

  26. Results • Vertical profiles of wind at Santa Cruz 06 UTC January 18. Zonal wind (squares) and meridional wind (circles), solid lines denote observations. GDAS analysis Experiment 1 Obs. u Obs. u Obs. v Obs. v GDAS FCST

  27. Results 500mb wind and geopotential height 850mb wind and temperature • Difference between Experiment 2 and Experiment 1 initialization at 00 UTC January 17.

  28. Results Experiment 1 Experiment 2 • Comparison of Exp. 1 and Exp. 2 500mb height anomaly correlation coefficients: black- global, blue- 90S-20S, red- 20N-90N

  29. Results Experiment 2 Observed • One-day precipitation accumulation valid at 00 UTC, January 18

  30. Results Experiment 2 Observed • One-day precipitation accumulation valid at 00 UTC, January 19

  31. Results Experiment 1 Experiment 2 • One-day precipitation accumulation valid at 00 UTC, January 18

  32. Results Experiment 1 Experiment 2 • One-day precipitation accumulation valid at 00 UTC, January 19

  33. Results • Noise/signal ratio of RMS difference between Experiment 2 and Experiment 1 wind at 500mb (circles) and 850 mb (squares). 850 mb 500 mb

  34. Results 500mb wind and geopotential height 850mb wind and temperature • Difference between Experiment 2 and Experiment 3 initialization at 00 UTC January 17

  35. Results Experiment 2 Experiment 3 • One-day precipitation accumulation valid at 00 UTC, January 18

  36. Results Experiment 2 Experiment 3 • One-day precipitation accumulation valid at 00 UTC, January 19

  37. Results • Noise/signal ratio of RMS difference between Experiment 2 and Experiment 3 wind at 500mb (circles) and 850 mb (squares). 850 mb 500 mb

  38. Results • Vertical profile of temperature at Resistencia at 06 UTC January 17: observed (solid, circles), GDAS analysis (dashed, asterisk), CPTEC analysis (dashed, squares), CPTEC analysis with SALLJEX (dashed, circles).

  39. Results • Vertical profile of dew point temperature at Resistencia at 06 UTC January 17: observed (solid, circles), GDAS analysis (dashed, asterisk), CPTEC analysis (dashed, squares), CPTEC analysis with SALLJEX (dashed, circles).

  40. Results • Vertical profile of wind at Resistencia at 06 UTC January 17: observed (solid, circles), GDAS analysis (dashed, asterisk), CPTEC analysis (dashed, squares), CPTEC analysis with SALLJEX (dashed, circles).

  41. Outline • Background • Motivation • Goals • Tools • Results • Summary and conclusions • Questions

  42. Summary and conclusions • The model retains a good predictability in the first 48 hours (500mb height anomaly correlation coefficients greater than 0.8) • The 500mb height anomaly correlation coefficients are greater than 0.6 until about forecast hour 100. • Precipitation is not forecasted well. • Sensitivity to analysis is evident in precipitation prediction. • Sensitivity to additional observations is small. This could reflect limited impact of local observations, or the possibility that the observations were poorly assimilated. • Additional observations have a small impact on these analyses at this time. • None of the three studied analyses represent the atmosphere well at the three locations (Resistencia, Santiago del Estero, Santa Cruz) where special observations were taken during this event. • More research is needed regarding the inclusion of special observations into objective analyses to make certain that good observations are not discarded.

  43. Future Work • Repeat the experiments using forthcoming GDAS analyses that are being performed at NCEP for the SALLJEX period. • Study other cases. • Check impact of model treatments of precipitation and turbulent diffusion. • Check impact of global-scale uncertainty.

  44. Questions?

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