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NOAA'S EYES IN THE SKY KEEP TABS ON THE EARTH’S ENVIRONMENT
May
20, 2005— April 1, 2005, marked 45 years since the launch of the
world's first weather satellite. Named TIROS
(for Television Infrared Observation Satellite), it successfully demonstrated
the advantage of mapping the Earth's cloud cover from space. Soon after,
meteorologists saw the first pictures of a hurricane threatening the northeastern
United States — and a new chapter in weather history had begun.
With today's advanced technology, it may be difficult to remember the days when there were no weather satellites, but it was less than a half century ago that many areas had little or no advance severe weather warning. Fortunately, modern NOAA satellites can spot and accurately track severe storms while they are still more than half a continent away.
NOAA’s
Modern Satellite Capabilities
Since
then, many NOAA weather satellites have been launched into orbit and their
capabilities have improved significantly with new technologies. Not only
do modern NOAA satellites observe clouds to track potentially devastating
storms, but they also carry many instruments used to measure various environmental
variables — providing vital information to not only meteorologists,
but farmers, geologists, fishermen, foresters, the military, transportation
sector and others. Perhaps most importantly, satellites are a vital component
in the creation of a global earth observing system.
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| Click NOAA image for a larger view of poster depicting the climatological capabilities of NOAA's polar-orbiting satellites. Click here for high resolution version. Please credit “NOAA.” |
- Atmospheric information about vertical moisture and temperature profiles, cloud properties, the Earth’s radiation budget, precipitation and brightness temperature (a measure of the intensity of radiation thermally emitted by an object)
- Land-based surface temperatures, as well as snow and ice cover
- Sea surface temperatures
- Opportunistic imagery from dust storms, fire/smoke, flooding, severe weather, tropical and volcanic events
- Other information from surface-based platforms (i.e., instrumented buoys, river gauges, automatic weather stations, seismic and tsunami stations and ships), space environmental monitoring and search and rescue satellite-aided tracking systems (also known as COSPAS-SARSAT) in support of humanitarian rescue operations.
Some environmental variables, however, are measured by only one particular type of NOAA satellite system. GOES, for example, can measure winds and the overall stability of the atmosphere. POES, on the other hand, can provide information about aerosols and ozone levels in the atmosphere, land surface emissivity and vegetation on land, sea ice and even oil spill events.
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| Click NOAA image a larger view of poster depicting the atmospheric capabilities of NOAA's polar-orbiting satellites. Click here for high resolution version. Please credit “NOAA.” |
NOAA
SATELLITES
Today, the nation's environmental satellites are operated by the NOAA
Satellite and Information Service in Suitland, Md. The NOAA satellite
system is composed of two types of satellites: GOES for national, regional,
short-range warning and "now-casting" and POES for global, climate
forecasting and environmental monitoring. Both types of satellites are
necessary for providing a complete global weather monitoring system.
In addition, NOAA operates satellites in the Defense
Meteorological Satellite Program, which are polar-orbiting satellites
once owned by the U.S. Department of Defense’s Air Force Space and
Missile Systems Center. In
1998, President Clinton combined the functions of the DMSP satellites
with that of NOAA's POES satellites, in order to create a
more cost effective and higher performance integrated system. Later
this decade, these satellites will be replaced by NOAA's next generation
of polar satellites (i.e., the National
Polar-Orbiting Operational Environmental Satellite System).
The NOAA Satelllite and Information Service also manages the processing
and distribution of the millions of bits of data and images the satellites
produce each day. Specifically, NOAA satellites send more than 16,000
global measurements daily to the NOAA Environmental Satellite Processing
Center computers, adding valuable information to weather forecasting and
climate models, especially for remote ocean areas where conventional data
are lacking. The prime customer is the NOAA
National Weather Service, which uses satellite data to create forecasts
for television, radio and weather advisory and warning services. Satellite
information is also shared with various Federal agencies, such as the
U.S. Departments of Agriculture, Interior, Defense and Transportation;
with other countries, such as Japan, India and Russia; members of the
European Space Agency and the United Kingdom Meteorological Office; and
the private sector.
NOAA’s
Geostationary Operational Environmental Satellites
GOES provide the kind of continuous monitoring necessary for intensive
data analysis. They circle the Earth in a geosynchronous orbit, traveling
at an altitude of 22,300 miles (35,800 km) above the Earth's equatorial
plane at a speed matching the Earth's rotation.
Because they
both stay at a fixed spot on and provide a complete view of the Earth's
surface, GOES are ideal for monitoring large-scale environmental phenomena
(i.e., meteorology, hydrology and oceanography). For example, GOES can
constantly monitor for atmospheric "triggers" for severe weather
conditions, such as tornadoes,
flash floods, hail storms
and hurricanes. When these conditions
develop, the GOES satellites can monitor storms and track their movements
in near real time.
Most satellite images seen on the nation’s broadcast media and The
Weather Channel are produced by GOES satellites. Usually, the infrared
images are "animated" to show the progression and movement of
storms.
The
data gathered by the GOES satellites, combined with that from new Doppler
radars and sophisticated communications systems have made for improved
forecasts and weather warnings that save lives, protect property and benefit
agricultural and a variety of commercial interests.
The United States normally operates two meteorological satellites in geostationary
orbit over the equator. Each satellite views almost a third of the Earth's
surface: one monitors North and South America and most of the Atlantic
Ocean, the other most of the Pacific Ocean basin, including Alaska and
Hawaii.
NOAA's geostationary weather satellites trace their roots to NASA's Applications
Technology Satellite (ATS), launched in December 1966, while the first
GOES was launched on Oct. 16, 1975. It formed part of a two-satellite
constellation that viewed nearly 60 percent of the Earth's surface (Unfortunately,
GOES can only provide a very distorted view of the poles).
Currently
Operating GOES
Currently, the United States is operating GOES-10
and GOES-12. (GOES-9, which is partially operational, is being used
by the Japanese Meteorological Agency over the West Pacific Ocean. JMA
launched MTSAT-1R in February 2005, which is expected to replace the aging
GOES-9 in mid-summer 2005. GOES-11 is being stored in orbit as a replacement
for GOES-12 or GOES-10 in the event of failure. GOES-12 (or GOES-East)
is positioned at 75 W longitude and the equator, while GOES-10 (or GOES-West)
is positioned at 135 W longitude and the equator. The two operate together
to produce a full-face picture of the Earth — both day and night.
The Future of the GOES Satellite Program
The recent procurement of the GOES-N
through -Q spacecraft marks the extension of the multi-satellite program
designed to provide continuous monitoring of the Earth’s weather
systems and the related space environment. The new spacecraft will be
used to continue and enhance the functions of the current GOES series
of spacecraft. The next GOES satellite, GOES-N, will be launched later
this year.
NOAA’s
Polar-Orbiting Satellites
Complementing the geostationary satellites are two polar orbiting satellites.
Constantly circling the Earth in sun-synchronous orbit, these satellites
support large-scale, long-range forecasts and numerous secondary missions.
The global data from these satellites are used extensively in NOAA's weather
and climate prediction
numerical models.
The satellites circle the Earth in an almost north-south orbit, passing
close to both poles. As the Earth rotates to the east beneath the satellite,
each pass monitors an area to the west of the previous pass. These "strips"
can be pieced together to produce a picture of a larger area. POES also
circle at a much lower altitude (about 530 miles or 850 km) compared to
GOES, providing more detailed information about the atmosphere. Operating
as a pair, these satellites ensure that data for any region of the Earth
are no more than six hours old. One crosses the equator at 7:30 a.m. local
time, the other at 1:40 p.m. local time.
Currently Operating POES
Today's polar-orbiting weather satellites trace their roots to the Television
Infrared Observation Satellite (also known as TIROS), launched in 1960.
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| Click NOAA image for a larger view of poster depicting the capabilities of NOAA's polar-orbiting satellites to detect various hazards. Click here for high resolution version. Please credit “NOAA.” |
The
Future of the POES Satellite Program
A new NOAA polar-orbiting environmental satellite, NOAA-N
was launched on May 20, 2005, will be critical in the continued development
of a global Earth observation program,
while improving the agency's weather and climate forecasts and U.S. search
and rescue operations.
"NOAA-N is key to achieving the goals of a strong Global Earth Observation System of Systems," said retired Navy Vice Admiral Conrad C. Lautenbacher, Jr., Ph.D., undersecretary of commerce for oceans and atmosphere and NOAA administrator. "Because it will strengthen our understanding about what the environment around the world is doing, not just here in the U.S., NOAA-N will bring us one step closer to truly global coverage of Earth's complex processes."
When launched, NOAA-N will replace NOAA-16, in operation since 2000, and join NOAA-17, launched in 2002. When it reached orbit, NOAA-N was renamed NOAA-18.Initial
Joint Polar-Orbiting Operational Satellite System
The launch of NOAA-N will also start a new era of international cooperation.
Under an agreement between NOAA and the European Organization for the
Exploitation of Meteorological Satellites, NOAA will provide NOAA-N and
a later satellite, NOAA-N Prime, for an afternoon orbit of the globe,
carrying an EUMETSAT instrument. In return, EUMETSAT will provide and
launch three European-built satellites, called Metop, into morning orbits
during the next 10 years, carrying key NOAA instruments. The first Metop
launch is scheduled for April 2006. The cooperative agreement created
what is now known as the Initial
Joint Polar-Orbiting Operational Satellite System.
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| Click NOAA image for a larger view of poster depicting the oceanic capabilities of NOAA's polar-orbiting satellites. Click here for high resolution version. Please credit “NOAA.” |
This group of satellites will remain operational until NOAA's next generation of polar spacecraft — National Polar-Orbiting Operational Environmental Satellite System, a joint program with NASA and the Department of Defense — launches in early 2010. NPOESS and its managing Integrated Program Office were established in 1994 to converge existing Air Force, NASA and NOAA polar-orbiting satellites into an integrated national program.
Both IJPS and NPOES reflect recent trends toward cooperative (national and international) efforts to consolidate environmental satellite data, in order to minimize duplicate data collection efforts, lower costs and improve forecasting and monitoring capabilities through the introduction of new satellite technologies.
Relevant
Web Sites
NOAA Satellite and Information
Service
NOAA's Geostationary and Polar-Orbiting Weather Satellites
Media
Contact:
John
Leslie, NOAA Satellites and Information,
(301) 457-5005