GPS Dropwindsonde Wind Profiles in Hurricanes and Their
Operational Implications
Michael L. Black
Hurricane Research Division
NOAA/Atlantic Oceanographic and
Meteorological Laboratory
Miami, Florida
Krystal Valde
Hurricane Research Division
NOAA/Atlantic Oceanographic and
Meteorological Laboratory
Miami, Florida
Jimmy Franklin
National Weather Service
Miami, Florida
(Manuscript received 9 June 2002, in final form 2 October 2002)
ABSTRACT
The recent development of the global positioning system (GPS)
dropwindsonde has allowed the wind and thermodynamic structure of
the hurricane eyewall to be documented with unprecedented
accuracy and resolution. In an attempt to assist operational
hurricane forecasters in their duties, dropwindsonde data have
been used in this study to document, for the first time, the mean
vertical profile of wind speed in the hurricane inner core from
the surface to the 700-hPa level, the level typically flown by
reconnaissance aircraft. The dropwindsonde-derived mean eyewall
wind profile is characterized by a broad maximum centered 500 m
above the surface. In the frictional boundary layer below this
broad maximum, the wind decreases nearly linearly with the
logarithm of the altitude. Above the maximum, the winds decrease
because of the hurricane's warm core. These two effects combine
to give a surface wind that is, on average, about 90% of the
700-hPa value. The dropwindsonde observations largely confirm
recent operational practices at the NWS for
the interpretation of flight-level data. Hurricane wind profiles
outside of the eyewall region are characterized by a higher level
of maximum wind, near 1 km, and a more constant wind speed
between 700 hPa and the top of the boundary layer. Two factors
that likely affect the eyewall profile structure are wind speed
and vertical motion. A minimum in surface wind adjustment factor
(i.e., relatively low surface wind speeds) was found when the
wind near the top of the boundary layer was between 40 and 60
m/s. At higher wind speeds, the fraction of the boundary layer
wind speed found at the surface increased, contrary to
expectation. Low-level downdrafts, and enhanced vertical motion
generally, were also associated with higher relative surface
winds. These results may be of interest to engineers concerned
with building codes, to emergency managers who may be tempted to
use high-rise buildings as a 'refuge of last resort' in coastal
areas, and to those people on locally elevated terrain. The top
of a 25-story coastal high-rise in the hurricane eyewall will
experience a mean wind that is about 17% higher (or one
Saffir-Simpson hurricane-scale category) than the surface or
advisory value. For this reason, residents who must take refuge
in coastal high-rises should generally do so at the lowest levels
necessary to avoid storm surge.
© Copyright by American Meteorological Society 2003