Measuring the Might of Haiyan
Aaron Byrd
The Future of Storms:
Scientists disagree over whether climate change is altering hurricanes.
It is impossible, when looking at one storm, to know whether global
warming had an impact, but researchers see a trend.
By HENRY FOUNTAIN
Published: November 18, 2013
Typhoon Haiyan, which ravaged the Philippines earlier this month, might
have been one of the strongest tropical cyclones ever to hit land, but
its exact strength was a matter of dispute. Forecasting agencies said it
would pack winds of up to 195 miles (about 315 kilometers) an hour, but
meteorologists in the Philippines said that top measured speeds were
closer to 150 m.p.h., or 240 k.p.h.
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Times Topic: Typhoon Haiyan (2013)
Charism Sayat/Agence France-Presse — Getty Images
The top measured wind speed for Typhoon Haiyan in the Philippines was about 150 m.p.h.
The difference means little to the millions of people who were affected,
but precise data on the intensity of hurricanes and typhoons — monsters
like Haiyan, as well as far more frequent weaker storms — is important
to scientists, especially those who are trying to determine the possible
effects of climate change on weather.
But the tools for determining the strength of tropical cyclones have
limitations, and not all of them are available everywhere or for every
storm. Other than the United States, for example, few countries make
direct measurements by flying planes into these kinds of storms.
Worldwide, hurricanes and typhoons are analyzed primarily with imagery
from satellites that measure the temperature of the sea surface and
clouds by sensing the infrared radiation emitted from them. Called the Dvorak technique,
after Vernon Dvorak, the scientist who developed it four decades ago,
the method is used by trained analysts and, increasingly, computers.
“It’s basically an inkblot test for hurricanes,” said James Franklin, chief of the hurricane specialist unit at the National Hurricane Center.
Analysts or automated programs pore over heat maps of clouds in search
of patterns that reveal the degree to which they are organized into a
storm. “You can relate the appearance of the storm to intensity,” Mr.
Franklin said.
Among other things, the analysis includes how cold the cloud tops are,
which is an indication of their depth, and the width and temperature of
the eye, he said. A storm system is then given a rating that corresponds
to certain wind speeds and air pressures as determined through direct
measurements of past storms.
John A. Knaff, a researcher with the National Oceanic and Atmospheric Administration’s Center for Satellite Applications and Research,
who has evaluated the Dvorak technique, said that it has been tweaked
over the years and worked well, especially for stronger storms with a
high degree of organization.
Haiyan, for example, was rated a T-8, the highest number, through Dvorak
analysis. It was clear from the satellite imagery that this was a
superstorm. “From the technique’s standpoint, this was about as good as
you can get,” Dr. Knaff said.
But the technique is not without its problems. Two analysts looking at
the same image can come up with different ratings, especially for weaker
storms. And some meteorological agencies relate the same ratings to
different wind speeds, which can lead to confusion.
Ultimately the wind speeds are only estimates, and can be off by 25
m.p.h. or more. That may account for some of the differences between the
forecast and the actual measurements during Haiyan. It is also not
clear that the instruments in the Philippines captured peak wind speeds,
which occur in the wall of clouds surrounding the eye.
“You’d have to be pretty lucky, or unlucky, to encounter them,” Mr. Franklin said.
For direct measurements before a storm hits land, the only real tools
are airplanes. The United States flies aircraft through storms in the
Atlantic and the eastern Pacific, but has not conducted flights in the
western Pacific since 1987. Hong Kong and Taiwan fly into typhoons, but
less extensively than the United States.
“Nobody out there does routine inner-core reconnaissance in the way we
do it here,” Mr. Franklin said. But even the United States flies into
only about one-third of Atlantic storms — those that threaten land, he
said.
A flight passes through the eyewall at 10,000 feet, and instruments
gather wind speed and other data. If there is no other way to get data
near the surface, “we will take 90 percent of whatever we measure at
10,000 feet and use that,” Mr. Franklin said.
But usually the flights also eject parachute-equipped instruments, called dropsondes,
that are caught in the winds and transmit data as they descend. Even
with them, there is no guarantee of measuring maximum winds, as they
have to be precisely ejected to fall into the eyewall. “It’s kind of
like a bombing exercise,” Mr. Franklin said.
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