Realtime Analysis of Model ICs

1. Realtime Analysis of Model ICs Wallace Hogsett, NHC

2. Introduction • Part I: NHC diagnostics module • This diagnostics system inputs data from GFS/GFDL/HWRF and outputs figures of vortex structure. • Goal is to facilitate inter-model comparisons of initial vortex structure and gain insight into systematic characteristics of the various model initializations. • Part II: A look toward 2011 • EMC/NHC collaboration. • More sophisticated and quantitative diagnostics.

3. Example 1 – Tomas Approaches Jamaica R34kt R34kt RMW RMW GFS HWRF GFDL Approximate observed locations of RMW and 34kt radius (via P3 radar & SFMR). Above: near-surface winds (shaded, kts), streamlines, and surface pressure (green dashed, hPa) from the GFS (left) and HWRF inner nest (center), and GFDL inner nest (right) ICs. * GFDL is superior to HWRF in this case in terms of constraining initial storm size, which is key factor in the initial balance/imbalance issue. * Suggestion: Leverage GFDL size constraint methodology.

4. Example 2: Tomas’ Unexpected Weakening • On Halloween, Tomas weakened rapidly. • HWRF predicted well the rapid weakening. • GFDL predicted intensification prior to weakening. • Was this HWRF success a lucky coincidence? Above: Time-series of minimum pressure (top) and maximum 10m winds (bottom) from HWRF (red) and GFDL (green) forecasts. Figure courtesy of Vijay and the HWRF team at EMC.

5. Example 2: Vertical Structure of Weakening Tomas Dry layer eastward tilt GFS HWRF GFDL Above: South-north (top) and west-east (bottom) vertical cross sections of wind speed (shaded, kts), horizontal wind barbs (kts), and vertical vorticity (contoured, x 10-4 s-1) taken through the center of the GFS (left), HWRF nest (middle), and GFDL nest (bottom) initial conditions. • Vertical cross sections suggest that the HWRF handled well a northeasterly vortex tilt and the associated very dry layer directly above the vortex center. • Why does HWRF capture this structure, but GFDL does not? Was a satellite dataset assimilated into HWRF?

6. Part I Summary • NHC diagnostics module allows model-model comparisons in near realtime (Stream1). • It has brought to light some strengths and weaknesses of the model initializations. • As the Tomas example shows, initial vortex structure may be critical for short-term intensity forecast improvements.

7. Part II: Looking forward to 2011 … example of next-level diagnostic product: Sfc convergence field, hodographs, Shear. • Continue to produce realtime diagnostic products. • Possible expansion beyond initialization. • Include other HFIP models (stream 1.5)? • Begin newly-formalized NHC-EMC collaboration, including assessment of upcoming 2011 size correction upgrades, and begin work on next-level diagnostics.

8. Part II: Looking forward to 2011 • Goal: develop capability to calculate budget terms on native grids to diagnose source of systematic model biases. • feedback results to EMC Upper level drying

9. Summary • A diagnostics module developed at NHC has enabled realtime analysis of operational model ICs. • Some 2010 results, including the HWRF vertical vortex structure and storm size, will hopefully aid EMC’s continuing development efforts. • In 2011, we hope to take on some of the more difficult issues quantitatively (e.g., moisture budget).