PAGEOS

Passive Geodetic Earth Orbiting Satellite (PAGEOS)
	Test inflation of PAGEOS, 5 August 1965
Names	PAGEOS-A
Operator	NASA Office of Space Applications
COSPAR ID	1966-056A
SATCAT no.	02253
Spacecraft properties
Launch mass	56.7 kg (125 lb)
Dimensions	30.48 m (100.0 ft) diameter
Start of mission
Launch date	00:14:00, June 24, 1966 (UTC)
Rocket	Thrust augmented Thor-Agena D
Launch site	Vandenberg AFB
End of mission
Destroyed	partially disintegrated July 1975
Orbital parameters
Reference system	Geocentric
Eccentricity	0.00301
Perigee altitude	4,207 km (2,614 mi)
Apogee altitude	4,271 km (2,654 mi)
Inclination	87.14°
Period	181.43 min
Epoch	24 June 1966

PAGEOS (PAssive Geodetic Earth Orbiting Satellite) was a balloon satellite which was launched by NASA in June 1966.^[1] It was the first satellite specifically launched for use in geodetic surveying,^[3] or measuring the shape of the earth, by serving as a reflective and photographic tracking target. At the time, it improved on terrestrial triangulations of the globe by about an order of magnitude.^[4] The satellite, which carried no instrumentation, broke up between 1975 and 1976.^[5] One of the largest fragments of the satellite finally deorbited in 2016.^[6]

PAGEOS was part of a larger program of inflatable satellites that grew from the original concept by William J. O'Sullivan of a 30-inch diameter inflatable satellite in 1956 to measure air drag at high altitudes, called the Sub-Satellite.^[7] While the Sub-Satellite failed, the idea of a visible US satellite became very attractive after Sputnik launched in the Cold War, resulting in a program of similar, larger satellites.^[7] These included satellites Echo 1 and Echo 2 under Project Echo, which were also used for experiments in geodetic surveying;^[3] several air-density-focused Explorer satellites; and finally PAGEOS.^[7]

Design

PAGEOS had a diameter of exactly 100 feet (30.48 m), consisted of a 0.5 mils (12.7 μm) thick mylar plastic film coated with vapour deposited aluminum enclosing a volume of about 524,000 cubic feet (14,800 m³)^[8]^[9] The metal coating both reflected sunlight and protected the satellite from damaging ultraviolet waves. The satellite was launched in a canister, which explosively separated as it was ejected from the rocket. Then, the balloon was inflated through a combination of residual internal air and a mixture of benzoic acid and anthraquinone placed inside, which turned to gas when the satellite was exposed to the heat of the sun.^[9] The satellite carried no instrumentation.^[9] The study and construction of PAGEOS was done by the Schjeldahl company, which also made Echo 1.^[10]

Usage

PAGEOS was placed into a polar orbit, about 200 nautical miles above the earth, so that the U.S. Coastal and Geodetic Survey could practically apply triangulation techniques developed from experiments with Echo 1. This program was known as the "Worldwide Geometric Satellite Triangulation Program".^[11] Because of the satellite's high altitude, the sun illuminated it during the entirety of Earth night, allowing it to be picked out from a background of stars.^[4]^[10] Over five years, 16 groups conducted observations at 45 globally distributed stations, about 3000-4000 km apart from each other.^[4]^[7]^[12] 12 mobile tracking stations were used, which observed during favorable weather conditions during a few minutes of twilight each evening.^[7]^[why?]^{[clarification needed]} BC4 cameras were used to photograph the satellite.^[12] Observations were taken when the satellite was visible simultaneously to multiple stations at the same time.^[12] This resulted in the fixing of the precise locations of 38 different points around the world.^[4] This could be used to help determine the precise locations of the continents relative to each other, and to help determine the precise shape and size of the earth. Some unclassified data was used by scientists studying continental drift, and more classified data was used by US military planners studying intercontinental ballistic missiles.^[7] The observations were done with BC4 (Ballistic Camera-4) cameras, and could last more than a year at each station before satisfactory results were obtained.^[11]^[12] The network reached an accuracy about an order of magnitude better than terrestrial triangulations at the time,^[4] and was the first time that a scientific determination had been made with accuracy of a complete global polyhedron.^[12]

Orbit

The PAGEOS spacecraft was launched by a Thor-SLV2A Agena-D (Thor 473) on 24 June 1966,^[13]^{[better source needed]} and placed into a polar orbit (inclination 85–86°) with an initial height of 4200km,^[6] which had gradually lowered during its 9 years of operation.^{[citation needed]} The satellite first partly disintegrated in July 1975,^[10] which was followed by a second break-up that occurred in January 1976 resulting in the release of a large number of fragments. Most of these re-entered during the following decade.^[5]^{[better source needed]} In 2016, one of the largest fragments of PAGEOS de-orbited.^[6]

The satellite's orbital period was approximately three hours.^[2] It was about as bright as Polaris, and appeared as a slow-moving star.^[10] Thanks to its high orbit and its polar inclination, it did not pass through the Earth's shadow and was visible any time of night, unlike lower-orbit satellites which had to be viewed exclusively just before sunrise and after sunset.^[10]

References

^ ^a ^b "PAGEOS 1". National Aeronautics and Space Administration. Retrieved March 16, 2017.
^ ^a ^b "NSSDCA – PAGEOS 1 – Trajectory Details". nssdc.gsfc.nasa.gov. NASA. Retrieved June 22, 2016.
^ ^a ^b "Modern Surveying". Encyclopaedia Britannica. Retrieved March 24, 2024.
^ ^a ^b ^c ^d ^e Kleusberg, Alfred (2003). "Satelliten im Dienst der Geodäsie und Geoinformatik" (PDF). University of Stuttgart. Archived from the original (PDF) on May 23, 2006.
^ ^a ^b Krebs, Gunter D. "PAGEOS 1". Gunter's Space Page. Retrieved March 16, 2017.
^ ^a ^b ^c J.-C. Liou (February 1, 2017). "USA Space Debris Environment, Operations, and Research Updates" (PDF). 54th Session of the Scientific and Technical Subcommittee, Committee on the Peaceful Uses of Outer Space, United Nations, 30 January – 10 February 2017, Vienna. Retrieved February 5, 2017.
^ ^a ^b ^c ^d ^e ^f Hansen, James (March 12, 2013). Spaceflight Revolution: NASA Langley Research Center from Sputnik to Apollo. Cia Publishing.
^ Teichman, L. A. (June 1, 1968). "The fabrication and testing of Pageos 1". NASA Technical Reports Server
^ ^a ^b ^c "Pageos Satellite to Girdle Globe for Earth Mapping". NASA Technical Reports Server. June 19, 1966.
^ ^a ^b ^c ^d ^e Dicati, Renato (January 10, 2017). Stamping the Earth from Space. Springer. ISBN 978-3-319-20756-8.
^ ^a ^b "Entering the Space Age: The Evolution of Satellite Geodesy at the Coast and Geodetic Survey". NOAA 200th Celebration. National Oceanic and Atmospheric Administration. 2007. Retrieved June 23, 2024.
^ ^a ^b ^c ^d ^e Seeber, Günter (August 22, 2008). Satellite Geodesy: Foundations, Methods, and Applications. Walter de Gruyter. ISBN 978-3-11-020008-9.
^ Krebs, Gunter D. "Thor-SLV2A Agena-D". Gunter's Space Page. Retrieved May 9, 2024.

[nssdca-1] "PAGEOS 1". National Aeronautics and Space Administration. Retrieved March 16, 2017.

[NSSDC_Master_Catalog-2] "NSSDCA – PAGEOS 1 – Trajectory Details". nssdc.gsfc.nasa.gov. NASA. Retrieved June 22, 2016.

[:1-3] "Modern Surveying". Encyclopaedia Britannica. Retrieved March 24, 2024.

[:0-4] Kleusberg, Alfred (2003). "Satelliten im Dienst der Geodäsie und Geoinformatik" (PDF). University of Stuttgart. Archived from the original (PDF) on May 23, 2006.

[:2-5] Krebs, Gunter D. "PAGEOS 1". Gunter's Space Page. Retrieved March 16, 2017.

[deorbit-6] J.-C. Liou (February 1, 2017). "USA Space Debris Environment, Operations, and Research Updates" (PDF). 54th Session of the Scientific and Technical Subcommittee, Committee on the Peaceful Uses of Outer Space, United Nations, 30 January – 10 February 2017, Vienna. Retrieved February 5, 2017.

[:3-7] ^ ^a ^b ^c ^d ^e ^f Hansen, James (March 12, 2013). Spaceflight Revolution: NASA Langley Research Center from Sputnik to Apollo. Cia Publishing.

[8] Teichman, L. A. (June 1, 1968). "The fabrication and testing of Pageos 1". NASA Technical Reports Server

[:4-9] "Pageos Satellite to Girdle Globe for Earth Mapping". NASA Technical Reports Server. June 19, 1966.

[:5-10] Dicati, Renato (January 10, 2017). Stamping the Earth from Space. Springer. ISBN 978-3-319-20756-8.

[:7-11] "Entering the Space Age: The Evolution of Satellite Geodesy at the Coast and Geodetic Survey". NOAA 200th Celebration. National Oceanic and Atmospheric Administration. 2007. Retrieved June 23, 2024.

[:6-12] Seeber, Günter (August 22, 2008). Satellite Geodesy: Foundations, Methods, and Applications. Walter de Gruyter. ISBN 978-3-11-020008-9.

[13] Krebs, Gunter D. "Thor-SLV2A Agena-D". Gunter's Space Page. Retrieved May 9, 2024.

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v t e ← 1965 Orbital launches in 1966 1967 →
January	Kosmos 104 OPS 2394 OPS 7253 OPS 3179 Kosmos 105 Kosmos 106 OPS 1593 Luna 9
February	OPS 7291 ESSA-1 OPS 1439 Kosmos 107 Kosmos 108 OPS 1184 OPS 3011 OPS 3031 Dipason Kosmos 109 DS-K-40 No.2 Kosmos 110 ESSA-2
March	Kosmos 111 OPS 3488 GATV-5003 Gemini VIII Kosmos 112 OPS 0879 OPS 0974 Kosmos 113 N-4 No.3 OPS 1117 Molniya-1 No.5 OV1-4 OV1-5 OPS 0340 Luna 10
April	Kosmos 114 OPS 1612 Surveyor SD-3 OAO-1 OPS 0910 Kosmos 115 OV3-1 Molniya 1-03 Kosmos 116
May	OPS 1508 Kosmos 117 Kosmos 118 OPS 1950 OPS 6785 Nimbus 2 Zenit-4 GATV-5004 OPS 0082 OPS 1788 Kosmos 119 Explorer 32 Surveyor 1
June	ATDA Gemini IX-A OPS 1577 OPS 1856 OGO-3 Kosmos 120 OV3-4 FTV-1351 Secor 6 ERS-16 OPS 9311 OPS 9312 OPS 9313 OPS 9314 OPS 9315 OPS 9316 OPS 9317 GGTS Kosmos 121 OPS 1599 PAGEOS Kosmos 122
July	Explorer 33 AS-203 Proton 3 Kosmos 123 OPS 1850 OV1-7 OV1-8 Kosmos 124 GATV-5005 Gemini X Kosmos 125 Kosmos 126 OPS 3014
August	OV3-3 Kosmos 127 OPS 1545 Lunar Orbiter 1 OPS 1832 OPS 6810 Pioneer 7 OPS 2366 FTV-1352 Secor 7 ERS-15 Luna 11 IDSCP 1 IDSCP 2 IDSCP 3 IDSCP 4 IDSCP 5 IDSCP 6 IDSCP 7 GGTS Kosmos 128
September	GATV-5006 Gemini XI OPS 6026 OPS 1686 OPS 6874 Zenit-2 No.40 OPS 6026 OPS 1686 OPS 6874 OGCh No.05L Surveyor 2 OPS 1703 Ōsumi 1 OPS 4096
October	ESSA-3 FTV-1583 Secor 8 OPS 2055 OPS 5345 Kosmos 129 Molniya 1-04 Kosmos 130 Luna 12 Surveyor SM-3 Intelsat II F-1 OV3-2
November	OGCh No.06L OPS 2070 OPS 5424 OPS 0855 OV4-1R OV4-1T OV1-6 Lunar Orbiter 2 OPS 1866 GATV-5001A Gemini XII Kosmos 131 Strela-2 No.1 Kosmos 132 Kosmos 133
December	Kosmos 134 OPS 1890 ATS-1 OV1-9 OV1-10 Kosmos 135 Soyuz 7K-OK No.1 OPS 8968 Biosatellite 1 Kosmos 136 Ōsumi 2 Kosmos 137 Luna 13 OPS 1584
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).

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Design

Usage

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References

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