Comparison of satellite buses

This page includes a list of satellite buses, of which multiple similar artificial satellites have been, or are being, built to the same model of structural frame, propulsion, spacecraft power and intra-spacecraft communication. Only commercially available (in present or past) buses are included, thus excluding series-produced proprietary satellites operated only by their makers.

Satellite buses

Satellite bus	Origin	Manufacturer	Maximum Satellite Payload Mass (kg)	Total Mass (fueled bus plus sat payload) (kg)	Price (Mil US$)	Launched	Status	First flight	Last flight	Comment
A2100	United States	Lockheed Martin				37[1]	Operational	1996	2013	GEO
Alphabus	France	Thales Alenia[2] and EADS Astrium		6,550 kg[citation needed]		1	Operational	2013		Alphabus
Arkyd 3	United States	Planetary Resources		11–15 kg[3][4]		1	Development[5][needs update]	2014		The first Arkyd 3 was destroyed in launch failure of Antares rocket.
Arkyd 100	United States	Planetary Resources				0	Development[5]			A prototype cubesat of just the electronics, not the optics, will be tested on the Arkyd 3 beginning in April 2015.
ATK 100[1]	United States	ATK Space Systems and Services	15 kg[6]	77 kg		5	Operational	2007	2007	used in THEMIS constellation only
ATK 200	United States	ATK Space Systems and Services	200 kg[6]	573 kg		3[7]	Operational	2000	2012	Formerly named, "Responsive Space Modular Bus";scaled-down ATK 150 option[2] is also available
ATK 500	United States	ATK Space Systems and Services	500 kg[6]			0	Development	2015		MEO/GEO/HEO/GSO; formerly named, "High End Modular Bus"; planned for DARPA Phoenix[6]
ATK 700	United States	ATK Space Systems and Services	1,700 kg[6]			0	Development			GEO/LEO/MEO/HEO/GTO; ViviSat[8]
Ball Configurable Platform 100	United States	Ball Aerospace	70 kg	180 kg		3[9]	Operational	1994[9]		BCP 100[10]
Ball Configurable Platform 300	United States	Ball Aerospace		750 kg		3[11]	Operational	1999	2009
Ball Configurable Platform 2000	United States	Ball Aerospace		2,200 kg		5[12]	Operational	1999	2011
Ball Configurable Platform 5000	United States	Ball Aerospace		2,800 kg		2	Operational	2007	2009	also WorldView-3 satellite is planned for launch in 2014
Boeing 601	United States	Boeing Satellite Development Center				76	Operational	1993	2013	4.8 kW standard, 10 kW for Boeing 601HP
Boeing 702	United States	Boeing Satellite Development Center				19[13]	Operational	1999	2013	power range 3-18 kW in four sub-models
TubeSat Kit[14]	United States	Interorbital Systems	0.5 kg	0.75 kg	0.008[15]	0	Development			LEO
CubeSat Kit[6]	United States	Pumpkin Inc.	1.65 kg	3 kg	0.194[16]	23	Operational	2007	2012	LEO;
CubeSat GOMX[17]	Denmark	GomSpace	1.50 kg	3 kg		1	Operational	2013	2013	LEO;
Eurostar	France, Great Britain,	EADS Astrium		6,400 kg		62	Operational	1990		GEO, models E1000,E2000,E2000+,E3000
HS-333	United States	Hughes Space and Communications	54 kg[18]	560 kg[19]		8[19]	Retired	1972	1979[19]	GEO; first satellite series; 300 watt, 12-channel, single-antenna
I-1K	India	Antrix Corporation/ISRO		1,425 kg[20]		4	Operational	2002	2014
I-2K	India	Antrix Corporation/ISRO	1,400 kg	2,800 kg[21]		20	Operational	1992	2014	DC power up to 3KW
I-3K	India	Antrix Corporation/ISRO		3,460 kg[22]		5	Operational	2005	2012	DC power up to 4.5KW
I-4K	India	Antrix Corporation/ISRO		4,000 kg - 5,000 kg[23][24]		0	Development	2014		DC power up to 11KW
IMS 1	India	Antrix Corporation/ISRO		100 kg		2	Operational	2008	2011	220 W power
IMS 2	India	Antrix Corporation/ISRO		450 kg[25][26][27]		1	Operational	2013	2013	800 W power
SSL 1300	United States	SSL (company)		3,000–6,700 kg (approx.)[28]		100	Operational	1984[28]	2015	GEO; previously named the LS-1300
Modular Common Spacecraft Bus	United States	NASA Ames Research Center	50	383+ kg[29]	4.0	1	Operational	2013 LADEE		Low-cost interplanetary bus.[30]
RS-300	United States	Ball Aerospace		125+ kg[31]		0	Operational (as of 2009[update])			RS-300
SI-100	Korea	Satrec		100 kg[32]		0	Development			SI-100
SI-200	Korea	Satrec		200 kg[33]		1	Operational	2009	2009	copy of RazakSAT, used in DubaiSat-1
SI-300	Korea	Satrec		300 kg[34]		2	Operational	2013	2014	SI-200 with larger battery, used for Deimos-2 and DubaiSat-2
SNC-100	United States	SNC Space Systems	100 kg[35]–172 kg[36]	116 kg-277 kg		9	Operational	2006		SNC-100A (OG2), SNC-100B, SNC-100C, Trailblazer was lost in launch failure
SNC-100-L1	United States	SNC Space Systems	100 kg[37]			0	Development			Optimized for LauncherOne[37]
Spacebus 100	France	Thales Alenia Space		1,170 kg[28]		3	Unknown[38]	1981[28]	1981	GEO
Spacebus 300	France	Thales Alenia Space	2,100 kg (approx.)[citation needed]			5	Retired	1987	1990	GEO
Spacebus 2000	France	Thales Alenia Space	1,900 kg (approx.)[citation needed]			11	Retired	1990	1998	GEO
Spacebus 3000	France	Thales Alenia Space	2,800-3200 kg (approx.)[citation needed]			27	Operational[citation needed]	1996	2010	GEO
Spacebus 4000	France	Thales Alenia Space	3,000-5700 kg (approx.)[citation needed]			29	Operational[citation needed]	2005	2012	GEO
STAR-1	United States	Orbital Sciences				1+	Retired	1997[39]	2001	GEO
STAR-2 (GEOStar-2)	United States	Orbital Sciences	500 kg	3,325 kg		33[40]	Operational	2002[39]	2013	GEO, 5550 W
GEOStar-3	United States	Orbital Sciences	800 kg	5,000 kg		0	Development			GEO, 8000 W
SSTL-70 (Microsat-70)	United Kingdom	Surrey Satellite Technology	30 kg	70 kg		16	Retired	1992	2001
SSTL-100	United Kingdom	Surrey Satellite Technology	15 kg	100 kg	10.0	8	Operational	2003	2012
SSTL-100LO	United Kingdom	Surrey Satellite Technology		100 kg[37]		0	Development			Optimized for LauncherOne[37]
SSTL-150	United Kingdom	Surrey Satellite Technology	50 kg	177 kg	16.5	11	Operational	2005	2014
SSTL-300	United Kingdom	Surrey Satellite Technology	150 kg	300 kg	23.5	1	Operational	2011	2011
SSTL-400 (Minisat-400)	United Kingdom	Surrey Satellite Technology		400 kg		1	Retired	1999	1999
SSTL-600	United Kingdom	Surrey Satellite Technology	200 kg	600 kg	36.0	1	Operational	2005	2005
Aprize	United States	SpaceQuest, Ltd.		13 kg	1.25[41]	12	Operational	2002	2014

Legend for abbreviations in the table: Template:MultiCol

• GEO - Geostationary orbit
• GSO - Geosynchronous orbit
• GTO - Geostationary transfer orbit

| class="col-break " |

• HCO - Heliocentric orbit
• HEO - High Earth orbit
• LEO - Low Earth orbit

| class="col-break " |

• MEO - Medium Earth orbit
• SSO - Sun-synchronous orbit
• TLI - Trans Lunar Injection

Template:Multicol-end

See also

• Category:Satellite buses
• Launch vehicle
• Product model

References

1. "Lockheed Martin-Built A2100 Satellite Achieves 15 Year On-Orbit Life"
2. "Alphabus development well under way". Thales Alenia Space. 2007-11-23.
3. Heater, Bryan (2013-01-21). "Planetary Resources shows off Arkyd-100 prototype, gives a tour of its workspace". Engadget. Retrieved 2013-01-23.
4. Mike Wall (2013-04-24). "Private Asteroid-Mining Project Launching Tiny Satellites in 2014". Space.com. Retrieved 2013-04-25.
5. Eric Anderson (30 Aug 2012). Eric Anderson – The Arkyd Series (video interview). moonandback.com. Retrieved 2012-09-06.
6. Werner, Debra (2012-08-13). "Builder Packing More Capability into Small Satellites". Space News. p. 13. {{cite news}}: |access-date= requires |url= (help)
7. http://cms.atk.com/SiteCollectionDocuments/ProductsAndServices/ATK-200-250-Data-Sheet.pdf
8. "ATK: Introducing the expanded product line of agile spacecraft buses". Space News. 2012-08-13. pp. 16–17. ATK A100 THEMIS; ATK A200 ORS-1, TacSat3, and EO-1; ATK A500 DARPA Phoenix; ATK A700 ViviSat
9. "Ball Aerospace Configurable Platforms" (PDF). Product Brochure. Ball Aerospace. 2014-01. Retrieved 2014-04-09. {{cite web}}: Check date values in: |date= (help)
10. "Green Propellant Infusion Mission (GPIM)". Ball Aerospace. 2014. Retrieved 2014-02-26.
11. http://www.ballaerospace.com/file/media/D1920_BCP%20SC_01_14_2.pdf
12. http://www.ballaerospace.com/file/media/D1920_BCP%20SC_01_14_2.pdf
13. http://www.boeing.com/boeing/defense-space/space/bss/factsheets/702/702fleet.page
14. http://www.interorbital.com/interorbital_03302014_002.htm
15. http://www.interorbital.com/Downloads/TubeSat%20Sales%20Brochure%20Publish%202.0.pdf
16. http://www.pumpkininc.com/content/doc/forms/pricelist.pdf
17. http://gomspace.com/index.php?p=products-platforms
18. Hughes Aircraft Corporation, Space and Communications Group, SBS F6 Prime sales brochure, 1985
19. Krebs, Gunter. "Hughes: HS-333 / HS-356". Gunter's Space Page. Retrieved 4 July 2012.
20. "SPACECRAFT SYSTEMS AND SUB SYSTEMS". Antrix Corporation. Retrieved 2013-02-02.
21. "SPACECRAFT SYSTEMS AND SUB SYSTEMS". Antrix Corporation. Retrieved 2013-02-02.
22. "SPACECRAFT SYSTEMS AND SUB SYSTEMS". Antrix Corporation. Retrieved 2013-02-02.
23. http://www.sac.gov.in/SACSITE/GSAT-11.html
24. http://www.isro.org/scripts/futureprogramme.aspx
25. http://www.isro.org/satellites/ims-1.aspx
26. http://www.isro.org/satellites/saral.aspx
27. http://www.isro.org/newsletters/contents/nnrms/NNRMS%20Bulletin%202013.pdf
28. "Space Service Loral (SSL): LS-1300". Gunter's Space Page. Retrieved 2012-08-25. Cite error: The named reference "GSP20120825" was defined multiple times with different content (see the help page).
29. Graham, William (2013-09-06). [Category:Derelict satellites orbiting Earth "Orbital's Minotaur V launches LADEE mission to the Moon"]. NASAspaceflight.com. Retrieved 2013-09-07. {{cite news}}: Check |url= value (help)
30. NASA Lunar Science Institute, Common Spacecraft Bus for Lunar Explorer Missions, includes video.
31. Krebs, Gunter. "Ball: RS-300". Gunter's Space Page. Retrieved 21 March 2011.
32. Wade, Mark. "Satrec". Encyclopedia Astronautica. Retrieved 2012-09-16.
33. Krebs, Gunter (2012-02-09). "Satrec Initiative: SI-200". Skyrocket.de (Gunter's Space Page). Retrieved 2012-09-16.
34. "Satellite System Products". Satrec Initiative. 2012. Retrieved 2012-09-16.
35. "SN-100 Small Satellite Production Line". Space News. 2012-08-13. p. 21. first 18 satellites [are] in production
36. Graham, William (2014-07-14). "SpaceX's Falcon 9 set for fourth attempt to launch Orbcomm OG2 mission". NASAspaceflight.com. Retrieved 2014-07-14.
37. "Virgin Galactic relaunches its smallsat launch business". NewSpace Journal. 2012-07-12. Retrieved 2012-08-25. develop versions of their smallsat bus optimized to the design of LauncherOne." Cite error: The named reference "nsj20120711" was defined multiple times with different content (see the help page).
38. Harland, David M; Lorenz, Ralph D. (2005). Space Systems Failures (2006 ed.). Chichester: Springer-Praxis. p. 221. ISBN 0-387-21519-0.
39. "GEOStar Brochure" (PDF). Orbital Sciences. 2012. Retrieved 2013-09-20.
40. http://www.orbital.com/SatelliteSpaceSystems/Publications/GEOStar-2_factsheet.pdf
41. http://www.astronautix.com/craft/aprzesat.htm

Notes

It is not clear from the sources if the Spacebus 100 satellite bus is still on offer.