Engineering:LARES (satellite)
From HandWiki
 LARES satellite | |
| Mission type | Laser ranging satellite Tests of general relativity[1][2] |
|---|---|
| Operator | Italian Space Agency (ASI) |
| COSPAR ID | 2012-006A |
| SATCAT no. | 38077 |
| Website | http://www.lares-mission.com/ |
| Mission duration | LARES 1: 12 years and 19 days (elapsed) LARES 2: 1 year, 7 months and 18 days (elasped) |
| Spacecraft properties | |
| Manufacturer | Carlo Gavazzi Space |
| Launch mass | 386.8 kg |
| Dimensions | 36.4 cm (diameter) |
| Start of mission | |
| Launch date | 13 February 2012, 10:00:00 UTC 14 July 2022, 13:13:43 UTC |
| Rocket | Vega VV01 Vega-C VV21 |
| Launch site | Kourou, ELA-1 |
| Contractor | Arianespace |
| Orbital parameters | |
| Reference system | Geocentric orbit[3] |
| Regime | Low Earth orbit |
| Perigee altitude | 1437 km |
| Apogee altitude | 1451 km |
| Inclination | 69.49° |
| Period | 114.75 minutes |
LARES (Laser Relativity Satellite) is a passive satellite system of the Italian Space Agency.[4]
Mission
LARES 1
LARES 1 was launched into orbit on 13 February 2012 at 10:00:00 UTC. It was launched on the first Vega rocket from the ESA Centre Spatial Guyanais in Kourou, French Guiana.[5]
Composition
The satellite is made of THA-18N, a tungsten alloy,[6] and houses 92 cube-corner retroreflectors, which are used to track the satellite via laser from stations on Earth. LARES's body has a diameter of about 36.4 centimetres (14.3 in) and a mass of about 387 kilograms (853 lb).[1][7] LARES was inserted in a nearly circular orbit near 1,451 kilometres (902 mi) and an inclination of 69.49 degrees. The satellite is tracked by the International Laser Ranging Service stations.[8]
The LARES satellite is the densest object known orbiting the Earth.[1] The high density helps reduce disturbances from environmental factors such as solar radiation pressure.[citation needed]
Scientific goals
The main scientific target of the LARES mission is the measurement of the Lense–Thirring effect with an accuracy of about 1%, according to principal investigator Ignazio Ciufolini and the LARES scientific team,[9] but the reliability of that estimate is contested.[10]
In contrast, a recent analysis of 3.5 years of laser-ranging data reported a claimed accuracy of about 4%.[11] Critical remarks appeared later in the literature.[12][clarification needed]
Beyond the project's key mission, the LARES satellite may be used for other tests of general relativity as well as measurements in the fields of geodynamics and satellite geodesy.[13]
LARES 2
A second satellite, LARES 2, was launched into orbit on 13 July 2022 at 13:13:43 UTC on a Vega-C.[14] It was originally due to launch in mid-2021.[15][16] The launch was delayed to mid-2022 due to continuing impacts from the COVID-19 pandemic.[17][18]
LARES 2 may improve the accuracy of the frame-dragging effect measurement to 0.2%.[19] Concerns about the actual possibility of reaching this goal were raised.[20] LARES 2 is made of a nickel alloy instead of a tungsten alloy.[21]
See also
- LAGEOS similar satellites launched in 1976
- List of laser ranging satellites
- List of passive satellites
- PAGEOS
- Project Echo
- Vega flight VV01
References
- ↑ 1.0 1.1 1.2 "The LAser RElativity Satellite". The LARES Team. http://www.lares-mission.com/LARES.html.
- ↑ "LARES". International Laser Ranging Service. http://ilrs.gsfc.nasa.gov/missions/satellite_missions/current_missions/lars_general.html.
This article incorporates text from this source, which is in the public domain.
- ↑ Peat, Chris (29 July 2013). "LARES - Orbit". Heavens-Above. http://www.heavens-above.com/orbit.aspx?satid=38077&lat=0&lng=0&loc=Unspecified&alt=0&tz=UCT.
- ↑ "LARES: Satellite per misure relativistiche" (in it). Agenzia Spaziale Italiana. http://www.asi.it/it/attivita/cosmologia/lares.
- ↑
- "Vega Launch Vehicle". European Space Agency. http://www.esa.int/SPECIALS/Launchers_Access_to_Space/SEMH3E67ESD_0.html.
- "Vega overview". http://www.arianespace.com/launch-services-vega/vega_overview.asp.
- "Prepping satellite to test Albert Einstein". http://www.spaceflightnow.com/vega/vv01/111207lares/.
- "Overview of ESA activities in 2012 of interest to media". http://www.esa.int/esaCP/SEMK3RGXTWG_index_0.html.
- ↑ Proceedings of "9th YSESM "Youth Symposium on Experimental Solid Mechanics". Gruppo Italiano Frattura. p. 97. ISBN 9788895940304. https://books.google.com/books?id=asVtQVkj_vIC&pg=PA79.
- ↑ Peroni, I. (2007). "The Design of LARES: A satellite for testing General Relativity". IAC-07-B4.2.07. http://www.iafastro.net/iac/archive/browse/IAC-07/B4/2/7406/.
- ↑
- "International Laser Ranging Service". http://ilrs.gsfc.nasa.gov/. This article incorporates text from this source, which is in the public domain.
- "LARES page on the ILRS Site". http://ilrs.gsfc.nasa.gov/missions/satellite_missions/current_missions/lars_general.html#info. This article incorporates text from this source, which is in the public domain.
- "International Laser Ranging Service". http://ilrs.gsfc.nasa.gov/.
- ↑
- Ciufolini, I.; Paolozzi A.; Pavlis E. C.; Ries J. C.; Koenig R.; Matzner R. A.; Sindoni G.; Neumayer H. (2009). "Towards a One Percent Measurement of Frame Dragging by Spin with Satellite Laser Ranging to LAGEOS, LAGEOS 2 and LARES and GRACE Gravity Models". Space Science Reviews 148 (1–4): 71–104. doi:10.1007/s11214-009-9585-7. Bibcode: 2009SSRv..148...71C. http://gfzpublic.gfz-potsdam.de/pubman/item/escidoc:240259.
- Ciufolini, I.; E. Pavlis; A. Paolozzi; J. Ries; R. Koenig; R. Matzner; G. Sindoni; H. Neumayer (2012). "Phenomenology of the Lense-Thirring effect in the solar system: Measurement of frame-dragging with laser ranged satellites". New Astronomy 17 (3): 341–346. doi:10.1016/j.newast.2011.08.003. Bibcode: 2012NewA...17..341C.
- Ciufolini, I.; Paolozzi A.; Pavlis E. C.; Ries J. C.; Koenig R.; Matzner R. A.; Sindoni G.; Neumayer H. (2010). "Gravitomagnetism and Its Measurement with Laser Ranging to the LAGEOS Satellites and GRACE Earth Gravity Models". General Relativity and John Archibald Wheeler. Astrophysics and Space Science Library. 367. SpringerLink. pp. 371–434. doi:10.1007/978-90-481-3735-0_17. ISBN 978-90-481-3734-3.
- Paolozzi, A.; Ciufolini I.; Vendittozzi C. (2011). "Engineering and scientific aspects of LARES satellite". Acta Astronautica 69 (3–4): 127–134. doi:10.1016/j.actaastro.2011.03.005. ISSN 0094-5765. Bibcode: 2011AcAau..69..127P.
- Ciufolini, I.; Paolozzi A.; Pavlis E. C.; Ries J.; Koenig R.; Sindoni G.; Neumeyer H. (2011). "Testing Gravitational Physics with Satellite Laser Ranging". European Physical Journal Plus 126 (8): 72. doi:10.1140/epjp/i2011-11072-2. Bibcode: 2011EPJP..126...72C.
- Ciufolini, I.; Pavlis E. C.; Paolozzi A.; Ries J.; Koenig R.; Matzner R.; Sindoni G.; Neumayer K.H. (2011-08-03). "Phenomenology of the Lense-Thirring effect in the Solar System: Measurement of frame-dragging with laser ranged satellites". New Astronomy 17 (3): 341–346. doi:10.1016/j.newast.2011.08.003. Bibcode: 2012NewA...17..341C.
- Ciufolini, I.; A. Paolozzi; C. Paris (2012). "Overview of the LARES mission: orbit, error analysis and technological aspects.". Journal of Physics. Conference Series 354 (1): 012002. doi:10.1088/1742-6596/354/1/012002. Bibcode: 2012JPhCS.354a2002C.
- Ciufolini, I.; V. G. Gurzadyan; R. Penrose; A. Paolozzi (2012). "Geodesic motion in general relativity: LARES in Earth's gravity". Low Dimensional Physics and Gauge Principles. pp. 93–97. doi:10.1142/9789814440349_0008. ISBN 978-981-4440-33-2.
- ↑ Iorio, L. (2009). "Towards a 1% measurement of the Lense-Thirring effect with LARES?". Advances in Space Research 43 (7): 1148–1157. doi:10.1016/j.asr.2008.10.016. Bibcode: 2009AdSpR..43.1148I.
- Iorio, L. (2009). "Will the recently approved LARES mission be able to measure the Lense–Thirring effect at 1%?". General Relativity and Gravitation 41 (8): 1717–1724. doi:10.1007/s10714-008-0742-1. Bibcode: 2009GReGr..41.1717I.
- Iorio, L. (2009). "An Assessment of the Systematic Uncertainty in Present and Future Tests of the Lense-Thirring Effect with Satellite Laser Ranging". Space Science Reviews 148 (1–4): 363. doi:10.1007/s11214-008-9478-1. Bibcode: 2009SSRv..148..363I.
- Lorenzo Iorio (2009). "Recent Attempts to Measure the General Relativistic Lense-Thirring Effect with Natural and Artificial Bodies in the Solar System". PoS ISFTG 017: 17. doi:10.22323/1.081.0017. Bibcode: 2009isft.confE..17I.
- Iorio, L. (2010). "On the impact of the atmospheric drag on the LARES mission". Acta Physica Polonica B 41 (4): 753–765. Bibcode: 2010AcPPB..41.4753I. http://th-www.if.uj.edu.pl/acta/vol41/pdf/v41p0753.pdf. Retrieved 2010-05-21.
- Iorio, L.; Lichtenegger, H.I.M.; Ruggiero, M.L.; Corda, C. (2011). "Phenomenology of the Lense-Thirring effect in the solar system". Astrophysics and Space Science 331 (2): 351. doi:10.1007/s10509-010-0489-5. Bibcode: 2011Ap&SS.331..351I.
- Renzetti, G. (2012). "Are higher degree even zonals really harmful for the LARES/LAGEOS frame-dragging experiment?". Canadian Journal of Physics 90 (9): 883–888. doi:10.1139/p2012-081. Bibcode: 2012CaJPh..90..883R.
- Renzetti, G. (October 2013). "First results from LARES: An analysis". New Astronomy 23-24: 63–66. doi:10.1016/j.newast.2013.03.001. Bibcode: 2013NewA...23...63R.
- Ciufolini, I.; A. Paolozzi; E. C. Pavlis; J. C. Ries; R. Koenig; R. A. Matzner; G. Sindoni; H. Neumayer (2009). "Towards a One Percent Measurement of Frame Dragging by Spin with Satellite Laser Ranging to LAGEOS, LAGEOS 2 and LARES and GRACE Gravity Models". Space Science Reviews 148 (1–4): 71–104. doi:10.1007/s11214-009-9585-7. Bibcode: 2009SSRv..148...71C. http://gfzpublic.gfz-potsdam.de/pubman/item/escidoc:240259.
- Renzetti, G. (May 2015). "On Monte Carlo simulations of the LAser RElativity Satellite experiment". Acta Astronautica 113: 164–168. doi:10.1016/j.actaastro.2015.04.009. Bibcode: 2015AcAau.113..164R.
- ↑ Ciufolini, I.; A. Paolozzi; E. C. Pavlis; R. Koenig; J. Ries; V. Gurzadyan; R. Matzner; R. Penrose et al. (March 2016). "A test of general relativity using the LARES and LAGEOS satellites and a GRACE Earth gravity model. Measurement of Earth's dragging of inertial frames". The European Physical Journal C 76 (3): 120. doi:10.1140/epjc/s10052-016-3961-8. PMID 27471430. Bibcode: 2016EPJC...76..120C.
- ↑ Iorio, L. (February 2017). "A comment on " A test of general relativity using the LARES and LAGEOS satellites and a GRACE Earth gravity model. Measurement of Earth's dragging of inertial frames", by I. Ciufolini et al.". The European Physical Journal C 77 (2): 73. doi:10.1140/epjc/s10052-017-4607-1. Bibcode: 2017EPJC...77...73I.
- ↑ Paolozzi, A.; Ciufolini, I. (2013). "LARES successfully launched in orbit: Satellite and mission description". Acta Astronautica 91: 313–321. doi:10.1016/j.actaastro.2013.05.011. Bibcode: 2013AcAau..91..313P.
- ↑ European Space Agency, ed (2022-07-13). "Vega-C successfully completes inaugural flight". https://www.esa.int/Enabling_Support/Space_Transportation/Vega/Vega-C_successfully_completes_inaugural_flight.
- ↑ Henry, Caleb (14 September 2020). "Vega C debut slips to mid-2021". SpaceNews. https://spacenews.com/vega-c-debut-slips-to-mid-2021/.
- ↑ "Launch Schedule – Spaceflight Now". 2020-09-15. https://spaceflightnow.com/launch-schedule/.
- ↑ Kanayama, Lee (2021-10-29). "Ariane 6 undergoing preparations for its 2022 debut" (in en-US). https://www.nasaspaceflight.com/2021/10/ariane-6-2022-debut/.
- ↑ "Launch Schedule – Spaceflight Now" (in en-US). https://spaceflightnow.com/launch-schedule/.
- ↑ A new laser-ranged satellite for General Relativity and space geodesy: I. An introduction to the LARES2 space experiment arXiv:1910.13818
- ↑ Iorio, L. (2023). "Limitations in Testing the Lense–Thirring Effect with LAGEOS and the Newly Launched Geodetic Satellite LARES 2". Universe 9 (5): 211. doi:10.3390/universe9050211. Bibcode: 2023Univ....9..211I.
- ↑ "Mission Lares 2" (in en-US). https://www.lares-mission.com/LARES_2.asp.
External links
- LARES Mission: official Web Site of LARES Mission.
- LARES - Testing of General Relativity on ASI's page.
- LARES - Pronto al via! article with images of LARES on ASI's site (in Italian).
- LARES Satellite Information LARES page on the ILRS Web Site.
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