TDRS-1

TDRS-1
	TDRS-1 and its IUS aboard; Challenger shortly before deployment.
Mission type	Communication
Operator	NASA
COSPAR ID	1983-026B
SATCAT no.	13969
Mission duration	Planned: 10 years; Final: 26 years, 6 months, 16 days
Spacecraft properties
Bus	TDRS
Manufacturer	TRW
Launch mass	2,268 kg (5,000 lb)
Dimensions	17.4 × 12.9 m (57 × 42 ft)
Power	1700 watts
Start of mission
Launch date	4 April 1983, 18:30:00;41 years ago UTC
Rocket	Space Shuttle Challenger ; STS-6 / IUS
Launch site	Kennedy Space Center, LC-39A
Contractor	Rockwell International
End of mission
Disposal	Retired to graveyard
Declared	21 October 2009
Deactivated	27 June 2010
Orbital parameters
Reference system	Geocentric orbit
Regime	Geostationary orbit
Epoch	1 April 1984

Last updated November 17, 2024

TDRS-1, known before launch as TDRS-A, was an American communications satellite, operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by TRW and launched by Space Shuttle Challenger on its maiden flight, STS-6.^[3]

History

While on the pad, problems were detected with Challenger main engines and repairs were begun. During this time, a severe storm caused contamination of TDRS-1 while it was in the Payload Change-out Room on the Rotating Service Structure at the launch pad. Consequently, the satellite had to be taken back to its checkout facility, where it was cleaned and rechecked.^[4]Challenger finally lifted off from Launch Complex 39A of the Kennedy Space Center at 18:30:00 UTC on 4 April 1983.^[5]

Operations

Following deployment from Challenger, TDRS-1 was to be raised to its operational geosynchronous orbit by means of an Inertial Upper Stage, which consisted of two solid rocket motors, the first used to raise the orbit's apogee, the second its perigee. The first burn was successful, however the IUS went out of control during the second burn. TDRS-1 separated from the upper stage in a lower than planned orbit. It was eventually raised to geosynchronous orbit by means of its attitude control system.^[6] In order to achieve this, a team of engineers from the Goddard Space Flight Center in Greenbelt, Maryland worked for nearly three months using six one-pound thrusters on the errant satellite to push it 8,600 miles (13,800 km) higher in space. The failure was later identified as a collapsed second-stage nozzle Techroll Seal, a flexible ring which allows the nozzle to move and provide directional control.^[7] The Goddard engineers' successful effort required 39 adjustment burns to correct the elliptical orbit to the 22,300 mi (35,900 km) high geosynchronous orbit desired for TDRS-1. In connection with this rescue, Goddard Space Flight Center on 26 November 1984 honored a group of 34 individuals with the Robert H. Goddard Award of Merit, the highest level of recognition the Goddard Space Flight Center can bestow on its employees.^[7] In 1989 its operations were affected by a geomagnetic storm.^[8]

TDRS-1 formed part of the first Pole-to-Pole phone call on 28 April 1999, with TDRS-1 being used at the South Pole, and an Iridium phone being used at the North Pole (recorded in Ripley's Believe It Or Not and Guinness World Records in April 1999).^[9]

Mission duration

TDRS-1 had a design life of ten years, however in April 2008, it was still operational on the twenty-fifth anniversary of its launch.^[10] Over the years, the orbital inclination was allowed to increase so that, for portions of the day (approximately 5 hours), it was able to be used for communications with the North and then the South Pole. Along with Marisat F2, GOES 3 and LES-9, it was one of a number of satellites that were transferred to the US National Science Foundation in 1998,^[11] for communications with the Amundsen–Scott South Pole Station.^[12] After Marisat was retired, TDRS-1 became the primary means of communication with the research station.^[12] The last functioning traveling-wave tube amplifier aboard TDRS-1 failed in October 2009,^[11] rendering the spacecraft unusable for communications purposes.

TDRS-1 proved helpful during a 1999 medical emergency at the NSF's Antarctic Amundsen–Scott South Pole Station. The satellite's high-speed Internet connectivity allowed personnel to conduct telemedicine conferences. Doctors in the United States aided Dr. Jerri Nelson, who had breast cancer, in performing a self-biopsy and administering chemotherapy. Later, in 2002, doctors used TDRS-1 to perform another telemedicine conference with the station to assist in knee surgery for a meteorologist.^[11]

Because of its orbit, the satellite was able to link the North and South Poles and relayed the first pole-to-pole phone call. TDRS-1 also transmitted the first internet connection and live webcast from the North Pole and supported the first global television event from the South Pole Station - a worldwide television broadcast to commemorate the beginning of the year 2000.^[11]

Decommissioned

The spacecraft was retired on or about 21 October 2009, after 26 years. Decommissioning was started on 5 June 2010 and passivation was completed on 27 June 2010.^[13]As of 2009^[update], NASA had repositioned TDRS-3 to assume the duties of TDRS-1.^[14]

Related Research Articles

STS-43, the ninth mission for Space Shuttle Atlantis, was a nine-day mission whose primary goal was launching the TDRS-E satellite (TDRS-5). The flight also tested an advanced heatpipe radiator for potential use on the then-future space station and conducted a variety of medical and materials science investigations.

The U.S. Tracking and Data Relay Satellite System is a network of American communications satellites and ground stations used by NASA for space communications. The system was designed to replace an existing network of ground stations that had supported all of NASA's crewed flight missions. The prime design goal was to increase the time spacecraft were in communication with the ground and improve the amount of data that could be transferred. Many Tracking and Data Relay Satellites were launched in the 1980s and 1990s with the Space Shuttle and made use of the Inertial Upper Stage, a two-stage solid rocket booster developed for the shuttle. Other TDRS were launched by Atlas IIa and Atlas V rockets.

A tracking and data relay satellite (TDRS) is a type of communications satellite that forms part of the Tracking and Data Relay Satellite System (TDRSS) used by NASA and other United States government agencies for communications to and from independent "User Platforms" such as satellites, balloons, aircraft, the International Space Station, and remote bases like the Amundsen-Scott South Pole Station. This system was designed to replace an existing worldwide network of ground stations that had supported all of NASA's crewed flight missions and uncrewed satellites in low-Earth orbits. The primary system design goal was to increase the amount of time that these spacecraft were in communication with the ground and improve the amount of data that could be transferred. These TDRSS satellites are all designed and built to be launched to and function in geosynchronous orbit, 35,786 km (22,236 mi) above the surface of the Earth.

Marisat satellites were the first mobile telecommunications satellites and were designed to provide dependable telecommunications for commercial shipping and the U.S. Navy from stable geosynchronous orbital locations over the three major ocean regions. The three Marisat satellites, F1, F2, and F3, were built by Hughes Aircraft Corporation (HAC) for COMSAT Corporation starting in 1973. The satellites were designed to provide maritime telecommunications services in three large ocean areas, the Atlantic Ocean, the Pacific Ocean, and the Indian Ocean, and were located at 72.5° East longitude, 176.5° E, and 345° E in the geosynchronous orbital arc. The three-satellite Marisat system served as the initial INMARSAT constellation.

Space Network (SN) is a NASA program that combines space and ground elements to support spacecraft communications in Earth vicinity. The SN Project Office at Goddard Space Flight Center (GSFC) manages the SN, which consists of:

TDRS-8, known before launch as TDRS-H, is an American communications satellite, of second generation, which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by Boeing and is based on the BSS-601 satellite bus.

TDRS-B was an American communications satellite, of first generation, which was to have formed part of the Tracking and Data Relay Satellite System. It was destroyed in 1986 when the Space ShuttleChallenger disintegrated 73 seconds after launch.

TDRS-5, known before launch as TDRS-E, is an American communications satellite, of first generation, which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by TRW is based on a custom satellite bus which was used for all seven first generation TDRS satellites.

<span class="mw-page-title-main">TDRS-3</span> American communications satellite

TDRS-3, known before launch as TDRS-C, is an American communications satellite, of first generation, which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by TRW, and is based on a custom satellite bus which was used for all seven first generation TDRS satellites.

TDRS-4, known before launch as TDRS-D, is an American communications satellite, of first generation, which was operated by NASA as part of the Tracking and Data Relay Satellite System from 1989 until 2011. It was constructed by TRW, based on a custom satellite bus which was used for all seven of the first generation TDRS satellites.

TDRS-6, known before launch as TDRS-F, is an American communications satellite, of first generation, which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by TRW, and is based on a custom satellite bus which was used for all seven first generation TDRS satellites.

TDRS-7, known before launch as TDRS-G, is an American communications satellite, of first generation, which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by TRW as a replacement for TDRS-B, which had been lost in the Challenger accident, and was the last first generation TDRS satellite to be launched.

<span class="mw-page-title-main">TDRS-9</span> American communications satellite

TDRS-9, known before launch as TDRS-I, was an American communications satellite which was operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by the Boeing Satellite Development Center, formerly Hughes Space and Communications, and was based on the BSS-601 satellite bus. It was the second Advanced TDRS, or second-generation Tracking and Data Relay Satellite, to be launched.

TDRS-10, known before launch as TDRS-J, is an American communications satellite which is operated by NASA as part of the Tracking and Data Relay Satellite System. It was constructed by the Boeing Satellite Development Center, formerly Hughes Space and Communications, and is based on the BSS-601 satellite bus. It was the third and final Advanced TDRS, or second-generation Tracking and Data Relay Satellite, to be launched.

GOES-2, known as GOES-B before becoming operational, was a geostationary weather satellite which was operated by the United States National Oceanic and Atmospheric Administration as part of the Geostationary Operational Environmental Satellite system. GOES-2 was built by Ford Aerospace, and was based on the satellite bus developed for the Synchronous Meteorological Satellite programme. At launch it had a mass of 295 kilograms (650 lb). It was positioned in geostationary orbit, from where it was used for weather forecasting in the United States. Following its retirement as a weather satellite, it was used as a communications satellite until its final decommissioning in 2001.

GOES-3, known as GOES-C before becoming operational, was an American geostationary weather and communications satellite. It was originally built for the National Oceanic and Atmospheric Administration as part of the Geostationary Operational Environmental Satellite system, and was launched in June 1978. It was positioned in geostationary orbit, from where it was initially used for weather forecasting in the United States. After ceasing to function as a weather satellite in 1989, it was used as a communications satellite, and spent over thirty-eight years in operation. GOES-3 was decommissioned 29 June 2016 at the Center for Southeastern Tropical Advanced Remote Sensing facility in Miami, Florida.

The Laser Communications Relay Demonstration (LCRD) is a NASA mission that will test laser communication in space for extremely long distances, between Earth and geosynchronous orbit.

TDRS-11, known before launch as TDRS-K, is an American communications satellite which is operated by NASA as part of the Tracking and Data Relay Satellite System. The eleventh Tracking and Data Relay Satellite is the first third-generation spacecraft.

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References

1 2 McDowell, Jonathan. "SATCAT". Jonathan's Space Pages. Retrieved 18 March 2014.
1 2 3 "Tracking and Data Relay Satellite (TDRS) Characteristics". NASA. 10 September 2014. Retrieved 28 July 2020.
↑ Wade, Mark. "STS-6". Encyclopedia Astronautica. Archived from the original on 15 April 2002. Retrieved 27 June 2009.
↑ Evans, Ben (2007). Space Shuttle Challenger: Ten Journeys into the Unknown . Praxis Publishing. p. 26. ISBN 978-0-387-46355-1.
↑ McDowell, Jonathan. "Launch Log". Jonathan's Space Page. Retrieved 24 June 2009.
↑ Krebs, Gunter. "TDRS 1, 2, 3, 4, 5, 6". Gunter's Space Page. Retrieved 25 June 2009.
1 2 "Tecwyn Roberts at the Network Engineering Division" llanddaniel.co.uk Retrieved: 5 May 2011.
↑ The Day the Sun Brought Darkness, Dr. Sten Odenwald, NASA, 13 March 2009
↑ "Pioneer NASA Spacecraft Celebrates 20 Years of Service" This article incorporates text from this source, which is in the public domain .
↑ "TDRS-1 Satellite Reaches 25 Years Of Age". Space Mart. 8 April 2008. Retrieved 27 June 2009.
1 2 3 4 "NASA Retires First Data Relay Satellite After Stellar Career". NASA. 25 June 2010. Retrieved 5 June 2020. This article incorporates text from this source, which is in the public domain .
1 2 "Outliving expectations: Marisat-F2 satellite held on for 32 years, served South Pole for 8". Spaceref. 12 December 2008. Retrieved 27 June 2009.
↑ "NASA Retires First Data Relay Satellite After Stellar Career". NASA. Archived from the original on 8 December 2010. Retrieved 14 January 2011. This article incorporates text from this source, which is in the public domain .
↑ Clark, Stephen. "NASA retires 'queen' of tracking satellite fleet". SpaceFlightNow. Retrieved 14 October 2009.

External links

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Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[satcat-1] 1 2 McDowell, Jonathan. "SATCAT". Jonathan's Space Pages. Retrieved 18 March 2014.

[tdrs_char-2] 1 2 3 "Tracking and Data Relay Satellite (TDRS) Characteristics". NASA. 10 September 2014. Retrieved 28 July 2020.

[3] Wade, Mark. "STS-6". Encyclopedia Astronautica. Archived from the original on 15 April 2002. Retrieved 27 June 2009.

[4] Evans, Ben (2007). Space Shuttle Challenger: Ten Journeys into the Unknown . Praxis Publishing. p. 26. ISBN 978-0-387-46355-1.

[LL-5] McDowell, Jonathan. "Launch Log". Jonathan's Space Page. Retrieved 24 June 2009.

[6] Krebs, Gunter. "TDRS 1, 2, 3, 4, 5, 6". Gunter's Space Page. Retrieved 25 June 2009.

[TDRS-7] 1 2 "Tecwyn Roberts at the Network Engineering Division" llanddaniel.co.uk Retrieved: 5 May 2011.

[8] The Day the Sun Brought Darkness, Dr. Sten Odenwald, NASA, 13 March 2009

[9] "Pioneer NASA Spacecraft Celebrates 20 Years of Service" This article incorporates text from this source, which is in the public domain .

[10] "TDRS-1 Satellite Reaches 25 Years Of Age". Space Mart. 8 April 2008. Retrieved 27 June 2009.

[NASA-11] 1 2 3 4 "NASA Retires First Data Relay Satellite After Stellar Career". NASA. 25 June 2010. Retrieved 5 June 2020. This article incorporates text from this source, which is in the public domain .

[SR-Marisat-12] 1 2 "Outliving expectations: Marisat-F2 satellite held on for 32 years, served South Pole for 8". Spaceref. 12 December 2008. Retrieved 27 June 2009.

[13] "NASA Retires First Data Relay Satellite After Stellar Career". NASA. Archived from the original on 8 December 2010. Retrieved 14 January 2011. This article incorporates text from this source, which is in the public domain .

[14] Clark, Stephen. "NASA retires 'queen' of tracking satellite fleet". SpaceFlightNow. Retrieved 14 October 2009.

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v t e Tracking and Data Relay Satellite System
Tracking and data relay satellite List of TDRS satellites
First generation	TDRS-1 TDRS-B TDRS-3 TDRS-4 TDRS-5 TDRS-6 TDRS-7
Second generation	TDRS-8 TDRS-9 TDRS-10
Third generation	TDRS-11 TDRS-12 TDRS-13
Italics denotes launch failure.

v t e ← 1982 Orbital launches in 1983 1984 →
January	Kosmos 1437 Unnamed
February	OPS 0252 OPS 0252 SSU-1 OPS 0252 SSU-2 OPS 0252 SSU-3
March	Kosmos 1443 NOAA-8
April	STS-6 (TDRS-1) OPS 2925 Soyuz T-8
May	Intelsat V F-6
June	OPS 6432 OPS 6432 SSU-1 OPS 6432 SSU-2 OPS 6432 SSU-3 ECS-1 OSCAR-10 STS-7 (Anik C2, Palapa B1, SPAS-01, OSTA-2) OPS 0721 OPS 3899 Soyuz T-9
July	OPS 7304
August	Progress 17
September	STS-8 (INSAT-1B)
October	Intelsat V F-7 Progress 18
November	STS-9
Unknown month	Kosmos 1428 Kosmos 1429 Kosmos 1430 Kosmos 1431 Kosmos 1432 Kosmos 1433 Kosmos 1434 Kosmos 1435 Kosmos 1436 IRAS PIX-2 Kosmos 1438 Sakura 2a Kosmos 1439 LIPS-2 Kosmos 1440 Kosmos 1441 Tenma Kosmos 1442 Kosmos 1444 Molniya-3 No.34 Ekran No.18L Kosmos 1445 Kosmos 1446 Molniya-1-56 Astron Kosmos 1447 Kosmos 1448 Kosmos 1449 Molniya-1 No.68 Kosmos 1450 Gran' No.23L Kosmos 1451 Satcom 1R Kosmos 1452 Rohini RS-D2 Kosmos 1453 Kosmos 1454 Kosmos 1455 Kosmos 1456 Kosmos 1457 Kosmos 1458 GOES 6 Kosmos 1459 Kosmos 1460 Kosmos 1461 Kosmos 1462 Kosmos 1463 Kosmos 1464 Kosmos 1465 Kosmos 1466 EXOSAT Kosmos 1467 Venera 15 Venera 16 Kosmos 1468 Kosmos 1469 Kosmos 1470 HILAT Kosmos 1471 Galaxy 1 Gorizont No.17L Prognoz 9 Kosmos 1472 Kosmos 1473 Kosmos 1474 Kosmos 1475 Kosmos 1476 Kosmos 1477 Kosmos 1478 Kosmos 1479 Kosmos 1480 Kosmos 1481 Kosmos 1482 OPS 7994 Molniya-1 No.66 Kosmos 1483 Kosmos 1484 Kosmos 1485 Telstar 301 Kosmos 1486 Kosmos 1487 Sakura 2b Kosmos 1488 Kosmos 1489 Kosmos 1490 Kosmos 1491 Kosmos 1492 Fanhui Shi Weixing 6 Kosmos 1493 Gran' No.24L Molniya-3 No.32 Kosmos 1494 Kosmos 1495 Kosmos 1496 Satcom 2R Kosmos 1497 Kosmos 1498 Kosmos 1499 Galaxy-2 Soyuz 7K-ST No. 16L Kosmos 1500 Ekran No.25L Kosmos 1501 Kosmos 1502 Kosmos 1503 Kosmos 1504 Kosmos 1505 Kosmos 1506 Meteor-2 No.10 Kosmos 1507 Kosmos 1508 Kosmos 1509 OPS 1294 Molniya-1 No.48 Kosmos 1510 Kosmos 1511 Gorizont No.18L Kosmos 1512 Kosmos 1513 Kosmos 1514 Kosmos 1515 Molniya-3 No.35 Kosmos 1516 Kosmos 1517 Kosmos 1518 Kosmos 1519 Kosmos 1520 Kosmos 1521
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).