Improvement of track and intensity forecasting through ensemble-based targeting techniques.

HRD's "Synoptic Flow" experiments use dropwindsondes to gather vertical profiles of wind, temperature, and humidity within 1,000 km of hurricanes. The experiment is typically conducted over the data-sparse oceanic regions of the western Atlantic or Gulf of Mexico roughly 48-72 hours before the projected landfall of a mature hurricane on the coast of the United States. The dropwindsondes define the hurricane's surrounding large-scale flow, particularly in the 300-700 mb middle tropospheric layer - the layer most directly related to tropical cyclone motion. From 1982-1996, HRD has completed a series of synoptic flow experiments in which dropwindsondes gather vertical profiles of wind, temperature, and humidity within about 1000 km of the center of potentially landfalling tropical cyclones in the North Atlantic Ocean. These observations have been shown to reduce errors by up to 30% on averge, an improvement equivalent to that obtained operationally during the last two decades. Since such observations have been shown to significantly impact track forecasts, a means to target such observations to optimally affect the forecasts is being developed.

The method of breeding the fastest growing modes in the operational global models used at the National Centers for Environmental Prediction (NCEP) and VICBAR provide information concerning locations of likely uncertainty in both initial conditions and forecasts. The ensemble ttransform technique will be used to find target locations from the models. By taking observations in these locations and outside of these locations, studies of the effectiveness of such a method are to be pursued. The NCEP global model is to be perturbed using different configurations of observations based upon information from the bred growing modes, and other operational models will be run based upon these global model runs. The overall impact of these observations will be assessed.

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Last modified: 8/29/2002