Starlette and Stella

Stella
Mission type	Scientific
Operator	CNES
Harvard designation	1993-061B
COSPAR ID	1993-061B
SATCAT no.	22824
Mission duration	Elasped: 30 years and 14 days
Spacecraft properties
Manufacturer	CNES
Launch mass	48 kg (106 lb)
Start of mission
Launch date	26 September 1993, 01:45:00 UTC
Rocket	Ariane 4
Launch site	Guiana Space Centre
Orbital parameters
Reference system	Geocentric
Regime	Low Earth
Eccentricity	0.0206[1]
Perigee altitude	804 km (500 mi)
Apogee altitude	812 km (505 mi)
Inclination	98.68 degrees
Period	101 minutes

Starlette
Names	Satellite de taille adaptée avec réflecteurs laser pour les études de la terre
Mission type	Scientific
Operator	CNES
Harvard designation	1975-010A
COSPAR ID	1975-010A
SATCAT no.	7646
Mission duration	Elasped: 48 years, 8 months and 4 days
Spacecraft properties
Manufacturer	CNES
Launch mass	47 kg (104 lb)
Start of mission
Launch date	6 February 1975, 16:35 UTC
Rocket	Diamant BP4
Launch site	Guiana Space Centre
Orbital parameters
Reference system	Geocentric
Regime	Low Earth
Eccentricity	0.0206[1]
Perigee altitude	812 km (505 mi)
Apogee altitude	1,114 km (692 mi)
Inclination	49.83 degrees
Period	104 minutes

Starlette (Satellite de taille adaptée avec réflecteurs laser pour les études de la terre,[1][2] or lit. 'Satellite of suitable size with laser reflectors for studies of the earth') and Stella are nearly identical French geodetic and geophysical satellites. Starlette was launched on 6 February 1975 and Stella on 26 September 1993. Starlette was the first passive laser satellite developed.

Background

Starlette's development dates back to at least 1972, when scientists at the Centre national d'études spatiales (CNES) were trying to determine a payload for the upcoming first flight of the new Diamant BP4 rocket.[3] After consulting with the Smithsonian Astrophysical Observatory, CNES scientists decided to create a small geodetic satellite optimized for tracking by laser ranging.[3] The project was approved within a few months after a feasibility study by the French atomic agency CEA determined the dense uranium core could be made nearly non-radioactive by using depleted uranium.[3][4]

The Groupe de recherches en géodésie spatiale (GRGS; Space Geodesy Research Group) first proposed Stella to provide coverage for areas missed by Starlette.[5]

Spacecraft design

Starlette and Stella are nearly identical, small spherical spacecraft measuring 24 centimetres (9.4 in) in diameter.[2] With masses of 47 kilograms (104 lb) and 48 kilograms (106 lb) respectively, the satellites are quite dense.[2] This high-density spherical design reduced the drag effect of aerobraking on the satellites as they exited Earth's atmosphere. Both satellites are covered in 60 laser retroreflectors.[1][2]

Mission and results

Starlette was launched on 6 February 1975 at 16:35 UTC[6] by a Diamant BP4 rocket from the B launch pad at the Guiana Space Centre in Korou, French Guiana.[1][2][7] It was the first flight of a Diamant BP4 launch vehicle.[1][3]

Stella was launched on 26 September 1993 at 01:45:00 UTC[6] by an Ariane 4 (Ariane 40 H-10) rocket from the ELA-2 launch pad at the Guiana Space Centre as part of a payload also containing the satellites SPOT-3, KITSAT-2, Itamsat, Eyesat-1, PoSAT-1, and Healthsat-2.[1][2][8] The payload was located in the top part of the Ariane rocket's third stage.[1]

In the 1980s, data gathered by Starlette was used to develop a model of global ocean tides.

Legacy and status

Starlette was the first passive laser satellite developed.[3] The first of two American geodetic satellites called LAGEOS followed not long after in 1976.[3]

Both satellites were in orbit as of 2023.[1] They are expected to remain in orbit up to 2000 years and to remain trackable for many decades or centuries.[3][5]

References

Kramer, Herbert J. (2002). Observation of the Earth and its Environment: Survey of Missions and Sensors (4th ed.). Berlin: Springer Verlag. ISBN 3-540-42388-5. Retrieved 18 March 2021.
Krebs, Gunther. "Starlette / Stella". Gunther's Space Page. Retrieved 18 March 2021.
Barlier, François; Lefebvre, Michel (2001). "A new look at planet Earth: Satellite geodesy and geosciences". In Bleeker, Johan A. M.; Geiss, Johannes; Huber, Martin C. E. (eds.). The Century of Space Science (PDF). Netherlands: Kluwer Academic Publishers. pp. 1623–1651. ISBN 978-94-010-0320-9. Retrieved 18 March 2021.
ILRS. "Starlette and Stella". Current Missions. International Association of Geodesy. Retrieved 3 July 2021.
"STELLA - The centimetre over centuries". Small Satellites Home Page (SSHP). 1995. Archived from the original on 28 April 2013.
McDowell, Jonathan. "Launch Log". Jonathan's Space Report. Retrieved 18 March 2021.
Wade, Mark. "Starlette". Astronautix. Archived from the original on December 21, 2016. Retrieved 18 March 2021.
Wade, Mark. "STELLA". Astronautix. Archived from the original on December 28, 2016. Retrieved 18 March 2021.

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[kramer-1] Kramer, Herbert J. (2002). Observation of the Earth and its Environment: Survey of Missions and Sensors (4th ed.). Berlin: Springer Verlag. ISBN 3-540-42388-5. Retrieved 18 March 2021.

[gunther-2] Krebs, Gunther. "Starlette / Stella". Gunther's Space Page. Retrieved 18 March 2021.

[barlier-lefebvre-3] Barlier, François; Lefebvre, Michel (2001). "A new look at planet Earth: Satellite geodesy and geosciences". In Bleeker, Johan A. M.; Geiss, Johannes; Huber, Martin C. E. (eds.). The Century of Space Science (PDF). Netherlands: Kluwer Academic Publishers. pp. 1623–1651. ISBN 978-94-010-0320-9. Retrieved 18 March 2021.

[4] ILRS. "Starlette and Stella". Current Missions. International Association of Geodesy. Retrieved 3 July 2021.

[sshp-5] "STELLA - The centimetre over centuries". Small Satellites Home Page (SSHP). 1995. Archived from the original on 28 April 2013.

[log-6] McDowell, Jonathan. "Launch Log". Jonathan's Space Report. Retrieved 18 March 2021.

[wade-starlette-7] Wade, Mark. "Starlette". Astronautix. Archived from the original on December 21, 2016. Retrieved 18 March 2021.

[wade-stella-8] Wade, Mark. "STELLA". Astronautix. Archived from the original on December 28, 2016. Retrieved 18 March 2021.

← 1992 · Orbital launches in 1993 · 1994 →
January	Kosmos 2230 Molniya 1-85 STS-54 (TDRS-6) Kosmos 2231 Soyuz TM-16 Kosmos 2232
February	USA-88 Kosmos 2233 SCD-1, Orbcomm CDS-1 Kosmos 2234, Kosmos 2235, Kosmos 2236 Asuka Progress M-16
March	Gran' No.42L EKA-1 UFO F-1 Kosmos 2237 USA-90, SEDS-1 Kosmos 2238 Progress M-17
April	Kosmos 2239 Kosmos 2240 Kosmos 2241 STS-56 (SPARTAN 201) Kosmos 2242 Molniya-3 No.57 ALEXIS, Orbcomm CDS-2 STS-55 Kosmos 2243 Kosmos 2244
May	Kosmos 2245, Kosmos 2246, Kosmos 2247, Kosmos 2248, Kosmos 2249, Kosmos 2250 Astra 1C, Arsene USA-91 Resurs-F2 No.9 Progress M-18 Molniya-1T No.81 Gorizont No.39L
June	Kosmos 2251 STS-57 Kosmos 2252, Kosmos 2253, Kosmos 2254, Kosmos 2255, Kosmos 2256, Kosmos 2257 Galaxy 4 Resurs-F1 No.57 Radcal USA-92, PMG
July	Soyuz TM-17 Kosmos 2258 Kosmos 2259 USA-93 Kosmos 2260 Hispasat 1B, INSAT-2B
August	Unnamed, Unnamed, Unnamed, SLDCOM-3 Molniya-3 No.58 NOAA-13 Kosmos 2261 Progress M-19 Resurs-F1 No.56 USA-94 Meteor-2 No.24, Temisat
September	USA-95 Kosmos 2262 STS-51 (ACTS, ORFEUS-SPAS) Kosmos 2263 Kosmos 2264 IRS-P1 SPOT-3, Stella, KITSAT-2, Itamsat, Eyesat-1, PoSAT-1, Healthsat-2 Gran' 41L
October	Landsat 6 FSW-15 Progress M-20 STS-58 Intelsat 701 Kosmos 2265 USA-96 Gorizont No.40L
November	Kosmos 2266 Kosmos 2267 Gorizont No.41L Solidaridad 2, Meteosat 6 USA-97
December	STS-61 USA-98 Telstar 401 DirecTV-1, Thaicom 1 Molniya 1-87
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).