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Title	The Seven Sisters Pose for Spitzer
Description	The Seven Sisters, also known as the Pleiades star cluster, seem to float on a bed of feathers in a new infrared image from NASA's Spitzer Space Telescope. Clouds of dust sweep around the stars, swaddling them in a cushiony veil. The Pleiades, located more than 400 light-years away in the Taurus constellation, are the subject of many legends and writings. Greek mythology holds that the flock of stars was transformed into celestial doves by Zeus to save them from a pursuant Orion. The 19th-century poet Alfred Lord Tennyson described them as "glittering like a swarm of fireflies tangled in a silver braid." The star cluster was born when dinosaurs still roamed the Earth, about 100 million years ago. It is significantly younger than our 5-billion-year-old sun. The brightest members of the cluster, also the highest-mass stars, are known in Greek mythology as two parents, Atlas and Pleione, and their seven daughters, Alcyone, Electra, Maia, Merope, Taygeta, Celaeno and Asterope. There are thousands of additional lower-mass members, including many stars like our sun. Some scientists believe that our sun grew up in a crowded region like the Pleiades, before migrating to its present, more isolated home. The new infrared image from Spitzer highlights the "tangled silver braid" mentioned in the poem by Tennyson. This spider-web-like network of filaments, colored yellow, green and red in this view, is made up of dust associated with the cloud through which the cluster is traveling. The densest portion of the cloud appears in yellow and red, and the more diffuse outskirts are shown in green hues. One of the parent stars, Atlas, can be seen at the bottom, while six of the sisters are visible at top. Additional stars in the cluster are sprinkled throughout the picture in blue. The Spitzer data also reveal never-before-seen brown dwarfs, or "failed stars," and disks of planetary debris (not pictured). John Stauffer of NASA's Spitzer Space Telescope mission says Spitzer's infrared vision allows astronomers to better study the cooler, lower-mass stars in the region, which are much fainter when viewed in optical light. Stauffer, who admits to being biased because the Pleiades is his favorite astronomical object, says the cluster is the perfect laboratory for understanding the evolution of stars. This image is made up of data taken by Spitzer's multiband imaging photometer and its infrared array camera. Light with a wavelength of 4.5 microns is blue, light of 8 microns is green, and light of 24 microns is red.

Title	The Seven Sisters Pose for Spitzer
Description	The Seven Sisters, also known as the Pleiades star cluster, seem to float on a bed of feathers in a new infrared image from NASA's Spitzer Space Telescope. Clouds of dust sweep around the stars, swaddling them in a cushiony veil. The Pleiades, located more than 400 light-years away in the Taurus constellation, are the subject of many legends and writings. Greek mythology holds that the flock of stars was transformed into celestial doves by Zeus to save them from a pursuant Orion. The 19th-century poet Alfred Lord Tennyson described them as "glittering like a swarm of fireflies tangled in a silver braid." The star cluster was born when dinosaurs still roamed the Earth, about 100 million years ago. It is significantly younger than our 5-billion-year-old sun. The brightest members of the cluster, also the highest-mass stars, are known in Greek mythology as two parents, Atlas and Pleione, and their seven daughters, Alcyone, Electra, Maia, Merope, Taygeta, Celaeno and Asterope. There are thousands of additional lower-mass members, including many stars like our sun. Some scientists believe that our sun grew up in a crowded region like the Pleiades, before migrating to its present, more isolated home. The new infrared image from Spitzer highlights the "tangled silver braid" mentioned in the poem by Tennyson. This spider-web-like network of filaments, colored yellow, green and red in this view, is made up of dust associated with the cloud through which the cluster is traveling. The densest portion of the cloud appears in yellow and red, and the more diffuse outskirts are shown in green hues. One of the parent stars, Atlas, can be seen at the bottom, while six of the sisters are visible at top. Additional stars in the cluster are sprinkled throughout the picture in blue. The Spitzer data also reveal never-before-seen brown dwarfs, or "failed stars," and disks of planetary debris (not pictured). John Stauffer of NASA's Spitzer Space Telescope mission says Spitzer's infrared vision allows astronomers to better study the cooler, lower-mass stars in the region, which are much fainter when viewed in optical light. Stauffer, who admits to being biased because the Pleiades is his favorite astronomical object, says the cluster is the perfect laboratory for understanding the evolution of stars. This image is made up of data taken by Spitzer's multiband imaging photometer and its infrared array camera. Light with a wavelength of 4.5 microns is blue, light of 8 microns is green, and light of 24 microns is red.

Title	Pink Pleiades
Description	The Seven Sisters, also known as the Pleiades star cluster, seem to float on a bed of feathers in a new infrared image from NASA's Spitzer Space Telescope. Clouds of dust sweep around the stars, swaddling them in a cushiony veil. The Pleiades, located more than 400 light-years away in the Taurus constellation, are the subject of many legends and writings. Greek mythology holds that the flock of stars was transformed into celestial doves by Zeus to save them from a pursuant Orion. The 19th-century poet Alfred Lord Tennyson described them as "glittering like a swarm of fireflies tangled in a silver braid." The star cluster was born when dinosaurs still roamed the Earth, about 100 million years ago. It is significantly younger than our 5-billion-year-old sun. The brightest members of the cluster, also the highest-mass stars, are known in Greek mythology as two parents, Atlas and Pleione, and their seven daughters, Alcyone, Electra, Maia, Merope, Taygeta, Celaeno and Asterope. There are thousands of additional lower-mass members, including many stars like our sun. Some scientists believe that our sun grew up in a crowded region like the Pleiades, before migrating to its present, more isolated home. The new infrared image from Spitzer highlights the "tangled silver braid" mentioned in the poem by Tennyson. This spider-web-like network of filaments, colored red in this view, is made up of dust associated with the cloud through which the cluster is traveling. One of the parent stars, Atlas, can be seen at the bottom, while six of the sisters are visible at top. Additional stars in the cluster are sprinkled throughout the picture in blue. The Spitzer data also reveal never-before-seen brown dwarfs, or "failed stars," and disks of planetary debris (not pictured). John Stauffer of NASA's Spitzer Space Telescope mission says Spitzer's infrared vision allows astronomers to better study the cooler, lower-mass stars in the region, which are much fainter when viewed in optical light. Stauffer, who admits to being biased because the Pleiades is his favorite astronomical object, says the cluster is the perfect laboratory for understanding the evolution of stars. This image shows infrared light captured by Spitzer's infrared array camera. Light with wavelengths of 8 and 5.8 microns is red and orange, light of 4.5 microns is green, and light of 3.6 microns is blue.

Title	Pink Pleiades
Description	The Seven Sisters, also known as the Pleiades star cluster, seem to float on a bed of feathers in a new infrared image from NASA's Spitzer Space Telescope. Clouds of dust sweep around the stars, swaddling them in a cushiony veil. The Pleiades, located more than 400 light-years away in the Taurus constellation, are the subject of many legends and writings. Greek mythology holds that the flock of stars was transformed into celestial doves by Zeus to save them from a pursuant Orion. The 19th-century poet Alfred Lord Tennyson described them as "glittering like a swarm of fireflies tangled in a silver braid." The star cluster was born when dinosaurs still roamed the Earth, about 100 million years ago. It is significantly younger than our 5-billion-year-old sun. The brightest members of the cluster, also the highest-mass stars, are known in Greek mythology as two parents, Atlas and Pleione, and their seven daughters, Alcyone, Electra, Maia, Merope, Taygeta, Celaeno and Asterope. There are thousands of additional lower-mass members, including many stars like our sun. Some scientists believe that our sun grew up in a crowded region like the Pleiades, before migrating to its present, more isolated home. The new infrared image from Spitzer highlights the "tangled silver braid" mentioned in the poem by Tennyson. This spider-web-like network of filaments, colored red in this view, is made up of dust associated with the cloud through which the cluster is traveling. One of the parent stars, Atlas, can be seen at the bottom, while six of the sisters are visible at top. Additional stars in the cluster are sprinkled throughout the picture in blue. The Spitzer data also reveal never-before-seen brown dwarfs, or "failed stars," and disks of planetary debris (not pictured). John Stauffer of NASA's Spitzer Space Telescope mission says Spitzer's infrared vision allows astronomers to better study the cooler, lower-mass stars in the region, which are much fainter when viewed in optical light. Stauffer, who admits to being biased because the Pleiades is his favorite astronomical object, says the cluster is the perfect laboratory for understanding the evolution of stars. This image shows infrared light captured by Spitzer's infrared array camera. Light with wavelengths of 8 and 5.8 microns is red and orange, light of 4.5 microns is green, and light of 3.6 microns is blue.

Description	An image of Saturn through the rings.
Full Description	This magnificent view looks down upon, and partially through, Saturn's rings from their unlit side. The densest part of the rings occults the bright globe of Saturn. Scientists can use observations like this to determine precisely the concentration of ring particles. When the bright source is the signals coming from the spacecraft, the technique is called a 'radio occultation.' In a radio occultation measurement, a signal is beamed toward Earth from Cassini's 4-meter-wide (13-foot) high-gain antenna. Researchers on Earth receive the signal as the spacecraft passes behind the rings. The reduction in Cassini's radio signal tells researchers how densely packed the ring particles are. Scientists can also learn about the size distributions of the particles from occultations. As an added (but tiny) bonus, Saturn's moon Atlas (32 kilometers, or 20 miles across) is visible as a dark speck against the planet, just outside the A ring. The image was taken in visible red light with the Cassini spacecraft wide-angle camera on Aug. 2, 2005, at a distance of approximately 617,000 kilometers (383,000 miles) from Saturn. The image scale is 37 kilometers (23 miles) per pixel. The Cassini-Huygens mission is a cooperative project of NASA, the European Space Agency and the Italian Space Agency. The Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, manages the mission for NASA's Science Mission Directorate, Washington, D.C. The Cassini orbiter and its two onboard cameras were designed, developed and assembled at JPL. The imaging operations center is based at the Space Science Institute in Boulder, Colo. For more information about the Cassini-Huygens mission visit http://saturn.jpl.nasa.gov . The Cassini imaging team homepage is at http://ciclops.org . Credit: NASA/JPL/Space Science Institute
Date	September 2, 2005

'Dancing with the Stars' Takes on a Whole New Twist

Title	'Dancing with the Stars' Takes on a Whole New Twist
General Information	What is Hubble Heritage? A monthly showcase of new and archival Hubble images. Go to the Heritage site. Two galaxies perform an intricate dance in this new Hubble Space Telescope image. The galaxies, containing a vast number of stars, swing past each other in a graceful performance choreographed by gravity. The pair, known collectively as Arp 87, is one of hundreds of interacting and merging galaxies known in our nearby universe. Arp 87 is in the constellation Leo, the Lion, approximately 300 million light-years away from Earth. These observations were taken in February 2007 with the Wide Field Planetary Camera 2.

Title	Terra Launch Animation
Description	NASA will launch and deploy the "flagship" to the Earth Observing System series of satellites, part of a precedent setting program designed to provide daily information on the health of the planet. The Terra spacecraft, formerly known as "EOS AM-1," is scheduled for launch Dec. 16, 1999. Terra begins a new generation of Earth science - one that studies the Earth's land, oceans, air, ice and life as a total global system. Terra will carry a complement of five synergistic state-of-the-art instruments. Researchers now recognize that the Earth - land, oceans, life, and atmosphere - operates as a system - one part impacting the other. EOS will help us to understand how the complex coupled Earth system of air, land, water and life is linked. A series of 10 spacecraft, known as the first EOS series, are scheduled for launch into the next decade. "After years of anxious anticipation we're extremely excited about this mission," said Dr. Ghassem Asrar, associate administrator, NASA's Earth Science Enterprise. "The Terra mission has nearly unlimited potential to improve scientific understanding of global climate change." A polar-orbiting spacecraft, Terra is scheduled for launch aboard an Atlas-Centaur IIAS expendable launch vehicle from Vandenberg Air Force Base, Calif. The 25-minute launch window opens at 1:33 p.m. EST (10:33 a.m. PST). Separation of the spacecraft from its launch vehicle will occur about 14 minutes after launch. Terra animations Terra Home Page Terra Fact Sheet Animation by Reto Stockli, NASA GSFC

Title	Dust Storm on Planet Earth
Explanation	From low Earth orbit, NASA's SeaWIFS instrument [ http://seawifs.gsfc.nasa.gov/SEAWIFS.html ] records ocean color, tracking changes in our water [ http://antwrp.gsfc.nasa.gov/apod/ap980530.html ] world's climate and biosphere [ http://seawifs.gsfc.nasa.gov/cgibrs/level3.pl?DAY=&PER=&TYP=bio ]. But even an ocean planet can have [ http://antwrp.gsfc.nasa.gov/apod/ap990809.html ] dust storms. On February 26th, SeaWIFS returned this dramatic close-up view of a vast, developing cloud of Saharan desert dust blowing [ http://pao.gsfc.nasa.gov/gsfc/weekly/weekly.htm#sahara ] from northwest Africa [ http://www.nationalgeographic.com/resources/ngo/maps/atlas/ africa/africa.html ] (lower right) a thousand miles or more out over the Atlantic Ocean. While there are indications that the planet-spanning effects of the Saharan dust events include the decline of the ecologies of coral reefs [ http://catbert.er.usgs.gov/african_dust/ ] in the Caribbean and an increased frequency of Atlantic hurricanes [ http://www.thirdworld.org/role.html ], there is also evidence that the dust provides nutrients to the Amazonian rain forests [ http://www.cotf.edu/ete/modules/troppois/tpamazon.html ]. From space-based vantage points, other satellite images have [ http://www.stvincent.ac.uk/Resources/Astro/NASA/SeaWiFS/dust.html ] also revealed storms [ http://daac.gsfc.nasa.gov/CAMPAIGN_DOCS/OCDST/asian_dust.html ] which transport massive quantities of fine sand and dust across Earth's oceans [ http://seawifs.gsfc.nasa.gov/SEAWIFS/LIVING_OCEAN/ ].

GALEX Distributes Local Galactic Treasures at AAS

Title	GALEX Distributes Local Galactic Treasures at AAS
Original Caption Released with Image	GALEX Poster From sparkling blue rings to dazzling golden disks, Galaxy Evolution Explorer (Galex) scientists are handing out a collection of their finest galactic treasures at the January 2006 American Astronomical Society meeting in Washington, D.C. Mined from the mission's Survey of Nearby Galaxies data, these cosmic gems were collected with the telescope's sensitive ultraviolet instruments. The gallery of galaxies has been made into a poster for meeting attendees visiting the mission's booth. Organized from far-ultraviolet to near-ultraviolet bright galaxies, this poster encapsulates the heart of the mission to study how galaxies and star formation rates have changed over the past 10 billion years. Events in space take millions or billions of years to unfold, which means that astronomers can't watch individual galaxies and stars age over time. Luckily, because the physics of light travel dictates that the farther away an object is from Earth, the longer it takes for its light to travel to us, the universe can be thought of as a time machine. By building telescopes sensitive enough to capture objects that are 10 billion light-years away, astronomers can essentially see an object the way it looked 10 billion years ago. Galex astronomers are using this phenomenon to their advantage by taking snapshots of different galaxies at various distances in space. By comparing portraits of numerous objects at various times in the universe's history, the team can begin to piece together the life cycle of stars and galaxies. For the poster, Galex scientists organized 196 different nearby galaxies in bins of increasing ultraviolet color. By placing the various snapshots side by side, astronomers can see how galaxies age differently. When viewed in ultraviolet, active star-forming regions in galaxies can be seen as glittering blue structures, while a soft, golden glow indicates the presence of older stars. The 196 galaxies represented in the poster were selected from more than 1,000 galaxies in the "Ultraviolet Atlas of Nearby Galaxies." So far, the Galex mission has surveyed more than 100 million galaxies.

Title	GALEX Distributes Local Galactic Treasures at AAS
Original Caption Released with Image	GALEX Poster From sparkling blue rings to dazzling golden disks, Galaxy Evolution Explorer (Galex) scientists are handing out a collection of their finest galactic treasures at the January 2006 American Astronomical Society meeting in Washington, D.C. Mined from the mission's Survey of Nearby Galaxies data, these cosmic gems were collected with the telescope's sensitive ultraviolet instruments. The gallery of galaxies has been made into a poster for meeting attendees visiting the mission's booth. Organized from far-ultraviolet to near-ultraviolet bright galaxies, this poster encapsulates the heart of the mission to study how galaxies and star formation rates have changed over the past 10 billion years. Events in space take millions or billions of years to unfold, which means that astronomers can't watch individual galaxies and stars age over time. Luckily, because the physics of light travel dictates that the farther away an object is from Earth, the longer it takes for its light to travel to us, the universe can be thought of as a time machine. By building telescopes sensitive enough to capture objects that are 10 billion light-years away, astronomers can essentially see an object the way it looked 10 billion years ago. Galex astronomers are using this phenomenon to their advantage by taking snapshots of different galaxies at various distances in space. By comparing portraits of numerous objects at various times in the universe's history, the team can begin to piece together the life cycle of stars and galaxies. For the poster, Galex scientists organized 196 different nearby galaxies in bins of increasing ultraviolet color. By placing the various snapshots side by side, astronomers can see how galaxies age differently. When viewed in ultraviolet, active star-forming regions in galaxies can be seen as glittering blue structures, while a soft, golden glow indicates the presence of older stars. The 196 galaxies represented in the poster were selected from more than 1,000 galaxies in the "Ultraviolet Atlas of Nearby Galaxies." So far, the Galex mission has surveyed more than 100 million galaxies.

Title	Diagnostic Darkness
Original Caption Released with Image	This magnificent view looks down upon, and partially through, Saturn's rings from their unlit side. The densest part of the rings occults the bright globe of Saturn. Scientists can use observations like this to determine precisely the concentration of ring particles. When the bright source is the signals coming from the spacecraft, the technique is called a 'radio occultation.' In a radio occultation measurement, a signal is beamed toward Earth from Cassini's 4-meter-wide (13-foot) high-gain antenna. Researchers on Earth receive the signal as the spacecraft passes behind the rings. The reduction in Cassini's radio signal tells researchers how densely packed the ring particles are. Scientists can also learn about the size distributions of the particles from occultations. As an added (but tiny) bonus, Saturn's moon Atlas (32 kilometers, or 20 miles across) is visible as a dark speck against the planet, just outside the A ring. The image was taken in visible red light with the Cassini spacecraft wide-angle camera on Aug. 2, 2005, at a distance of approximately 617,000 kilometers (383,000 miles) from Saturn. The image scale is 37 kilometers (23 miles) per pixel. The Cassini-Huygens mission is a cooperative project of NASA, the European Space Agency and the Italian Space Agency. The Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, manages the mission for NASA's Science Mission Directorate, Washington, D.C. The Cassini orbiter and its two onboard cameras were designed, developed and assembled at JPL. The imaging team is based at the Space Science Institute, Boulder, Colo. For more information about the Cassini-Huygens mission visit http://saturn.jpl.nasa.gov [ http://saturn.jpl.nasa.gov ]. For additional images visit the Cassini imaging team homepage http://ciclops.org [ http://ciclops.org ].

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is prepared for lifting up the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is prepared for lifting up the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. - A transporter carrying the encapsulated TDRS-J satellite makes its way to the exit. The satellite is being taken to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch aboard an Atlas IIA vehicle Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. - A transporter carrying the encapsulated TDRS-J satellite makes its way to the exit. The satellite is being taken to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch aboard an Atlas IIA vehicle Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. -- A transporter carrying the encapsulated TDRS-J satellite exits the Spacecraft Assembly and Encapsulation Facility -2. The satellite is being taken to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch aboard an Atlas IIA vehicle Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- A transporter carrying the encapsulated TDRS-J satellite exits the Spacecraft Assembly and Encapsulation Facility -2. The satellite is being taken to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch aboard an Atlas IIA vehicle Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. - The TDRS-J satellite arrives at the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. - The TDRS-J satellite arrives at the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite nears the top of the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite nears the top of the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is lifted up the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is lifted up the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. -- A transporter carrying the encapsulated TDRS-J satellite crosses a bridge heading to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- A transporter carrying the encapsulated TDRS-J satellite crosses a bridge heading to Launch Complex 36-A, Cape Canaveral Air Force Station, for a launch Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

Description	KENNEDY SPACE CENTER, FLA. - The TDRS-J satellite is lifted up the gantry on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. -- The encapsulated TDRS-J satellite is lowered toward the Atlas IIA launch vehicle on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017..

Description	KENNEDY SPACE CENTER, FLA. -- The encapsulated TDRS-J satellite is lowered toward the Atlas IIA launch vehicle on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017..
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. - On Launch Complex 36-A, Cape Canaveral Air Force Station, the Atlas IIA launch vehicle with the TDRS-J satellite aboard is ready for launch Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. - On Launch Complex 36-A, Cape Canaveral Air Force Station, the Atlas IIA launch vehicle with the TDRS-J satellite aboard is ready for launch Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the mobile service tower is rolled back to reveal the encapsulated TDRS-J satellite aboard an Atlas IIA vehicle awaiting launch on Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the mobile service tower is rolled back to reveal the encapsulated TDRS-J satellite aboard an Atlas IIA vehicle awaiting launch on Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	12/04/2002

Description	KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the mobile service tower is rolled back to reveal the encapsulated TDRS-J satellite aboard an Atlas IIA vehicle awaiting launch on Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	12/04/2002

KENNEDY SPACE CENTER, FLA. -- The encapsulated TDRS-J satellite is mated with the Atlas IIA launch vehicle on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The encapsulated TDRS-J satellite is mated with the Atlas IIA launch vehicle on Launch Complex 36-A, Cape Canaveral Air Force Station. The satellite is scheduled to be launched Dec. 4 aboard an Atlas IIA vehicle. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/25/2002

Description	KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the mobile service tower is rolled back to reveal the encapsulated TDRS-J satellite aboard an Atlas IIA vehicle awaiting launch on Dec. 4. The launch window is 9:42 to 10:22 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	12/04/2002

KENNEDY SPACE CENTER, FLA. -- TheTDRS-J satellite (left) and part of the fairing (right) are on display for the media before encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- TheTDRS-J satellite (left) and part of the fairing (right) are on display for the media before encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- The fairing (left) is moved toward the TDRS-J satellite (right) for encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The fairing (left) is moved toward the TDRS-J satellite (right) for encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- Workers keep check on the TDRS-J satellite (foreground) as the fairing (background) moves toward it for encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- Workers keep check on the TDRS-J satellite (foreground) as the fairing (background) moves toward it for encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- The second half of the fairing (right) is prepared for mating with the first half and encapsulating the TDRS-J satellite for launch. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The second half of the fairing (right) is prepared for mating with the first half and encapsulating the TDRS-J satellite for launch. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite rests inside the first half of the fairing during encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite rests inside the first half of the fairing during encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- Workers make adjustments on the first part of the fairing around the TDRS-J satellite before encapsulation continues. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- Workers make adjustments on the first part of the fairing around the TDRS-J satellite before encapsulation continues. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is fully encapsulated and ready for transport to Launch Complex 36-A, Cape Canaveral Air Force Station, Fla. There it will be mated with the Lockheed Martin Atlas IIA-Centaur rocket for launch on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite is fully encapsulated and ready for transport to Launch Complex 36-A, Cape Canaveral Air Force Station, Fla. There it will be mated with the Lockheed Martin Atlas IIA-Centaur rocket for launch on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite sits between the two halves of the fairing before encapsulation for launch. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite sits between the two halves of the fairing before encapsulation for launch. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. -- Workers move the second half of the fairing around the TDRS-J satellite to complete encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. -- Workers move the second half of the fairing around the TDRS-J satellite to complete encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

Description	KENNEDY SPACE CENTER, FLA. -- The TDRS-J satellite rests inside the first half of the fairing during encapsulation. The satellite is scheduled to be launched aboard a Lockheed Martin Atlas IIA-Centaur rocket from Launch Complex 36-A, Cape Canaveral Air Force Station, Fla., on Dec. 4. The third in a series of telemetry satellites, TDRS-J will help replenish the current constellation of geosynchronous TDRS satellites. The TDRS System is the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. It also provides communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	11/21/2002

KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the TDRS-J satellite launches aboard an Atlas IIA vehicle on Dec. 4 at the beginning of the launch window at 9:42 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.

Description	KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the TDRS-J satellite launches aboard an Atlas IIA vehicle on Dec. 4 at the beginning of the launch window at 9:42 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	12/04/2002

Description	KENNEDY SPACE CENTER, FLA. - At Launch Complex 36-A, Cape Canaveral Air Force Station, the TDRS-J satellite launches aboard an Atlas IIA vehicle on Dec. 4 at the beginning of the launch window at 9:42 p.m. EST. TDRS-J, the third in a series of telemetry satellites, will help replenish the current constellation of geosynchronous TDRS satellites that are the primary source of space-to-ground voice, data and telemetry for the Space Shuttle. The satellites also provide communications with the International Space Station and scientific spacecraft in low-Earth orbit such as the Hubble Space Telescope. This new advanced series of satellites will extend the availability of TDRS communications services until about 2017.
Release Date	12/04/2002

STS-29 Discovery, OV-103, Pilot Blaha with IMAX camera on aft flight deck

Title	STS-29 Discovery, OV-103, Pilot Blaha with IMAX camera on aft flight deck
Description	Pilot John E. Blaha balances and points IMAX motion picture camera out aft flight deck overhead window to film Earth's surface below. Blaha is surrounded by onorbit station control panels in foreground, payload station in background, and forward overhead panels above. Handbook titled "TiFFEN Formula 712" and checklists are velcroed to onorbit station panels. An open atlas freefloats just below Blaha's right elbow.
Date Taken	1989-03-18

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