PLATO (spacecraft)

PLATO
Spacecraft properties

Mission type	Space observatory
Operator	ESA
Website	sci.esa.int/plato/
Mission duration	6 years^[1]

Manufacturer	To be decided in 2016

Start of mission
Launch date	Planned for 2024
Rocket	Soyuz-ST
Launch site	Kourou ELS
Contractor	Arianespace

Orbital parameters
Reference system	Sun–Earth L₂

Main telescope
Type	Multiple refractors^[2]
Collecting area	2250 deg² ^[3]
Wavelengths	Visible spectrum:^[4] 390 to 700 nm

Planetary Transits and Oscillations of stars (PLATO) is a space observatory under development by the European Space Agency for launch around 2024. PLATO will use a group of photometers to search for planet transits, to discover and characterize rocky extrasolar planets of all sizes around red dwarf stars, yellow dwarf stars like our Sun, and subgiant stars where water can exist in liquid state.^[5] A secondary objective is to study stellar oscillations to measure stellar masses and evolution.

History

PLATO was proposed in 2007 to European Space Agency (ESA) by a team of scientists in response to the call for ESA Cosmic Vision 2015–2025.^[6] The assessment phase was completed during 2009, and in May 2010 it entered the Definition Phase. Following a call for missions in July 2010, ESA selected in February 2011 four candidates for a medium-class mission (M3 mission) for a launch opportunity in 2024.^[6]^[7] PLATO was announced on 19 February 2014 as the selected M3 class science mission for implementation as part of its Cosmic Vision Programme. Other competing concepts that were studied included the four candidate missions EChO, LOFT, MarcoPolo-R and STE-QUEST.^[1]

The design of the Telescope Optical Units is by an international team from Italy, Switzerland and Sweden and coordinated by Roberto Ragazzoni at INAF (Istituto Nazionale di Astrofisica) Osservatorio Astronomico di Padova. The design and development is funded by Italian Space Agency, Swiss Space Office and the Swedish National Space Board.^[2]

In January 2015 Thales Alenia Space was selected to conduct one out of three phase B1 studies for PLATO, defining the system, subsystem and payload aspects of the observatory.^[8]

PLATO is an acronym, but also the name of a philosopher in Classical Greece; Plato (428–348 BC) was looking for a physical law accounting for the orbit of planets (errant stars) and able to satisfy the philosopher's needs for "uniformity" and "regularity".^[6]

Objective

The goal is to find planets like Earth, not just in terms of their size but in their potential for habitability.^[5] By using 34 separate small telescopes and cameras, PLATO will search for planets around up to one million stars.^[1] The main objective of PLATO is to elucidate the conditions for planet formation and the emergence of life.^[4] To achieve this objective, the mission has these goals:^[4]

Discover and characterise a large number of close-by exoplanetary systems, with a precision in the determination of the planet mass up to 10%, of planet radius of up to 2%, and of stellar age up to 10%.
Detect Earth-sized planets in the habitable zone around solar-type stars
Detect super-Earths in the habitable zone around solar-type stars
Measure solar oscillations in the host stars of exoplanets
Measure oscillations of classical pulsators

Optics

The PLATO payload is based on a multi-telescope approach, involving a set of 32 "normal cameras" working at a readout cadence of 25 sec and monitoring stars fainter than m_V = 8 (apparent visual magnitude), plus two "fast cameras" working at a cadence of 2.5 sec, and observing stars in the magnitude range 4 to 8.^[3]^[9] The cameras are based on a fully dioptric telescope including 6 lenses; each camera has an 1100 deg² field, and a pupil diameter of 120 mm. Each camera is equipped with its own CCD focal plane array, consisting of 4 CCDs with 4510 x 4510 pixels.^[3]

The 32 'normal cameras' will be arranged in four groups of 8 cameras with their lines of sight offset by a 9.2° angle from the +ZPLM axis. This particular configuration allows surveying a total field of about 2250 deg² per pointing. The satellite will be rotated around the mean line of sight by 90° every 3 months, for a continuous survey of exactly the same region of the sky.^[3]

PLATO will differ from COROT and Kepler space telescopes in that it will study relatively bright stars (between magnitudes 4 and 10), making it easier to confirm extrasolar planets and measure their masses using follow-up radial velocity measurements on ground-based telescope. It will have a much larger field of view than the Kepler mission (which has 100 deg²) allowing PLATO to study a larger sample and brighter stars.

Launch

The satellite is planned to launch in 2024 from Guiana Space Centre with a Soyuz rocket to the Earth-Sun L2 Lagrangian point.^[1]

References

1 2 3 4 "ESA selects planet-hunting PLATO mission". European Space Agency. Retrieved 19 February 2014.
1 2 "PLATO - Camera Telescope Optical Units". INAF- Osservatorio Astrofisico di Catania. 2014. Retrieved 20 February 2014.
1 2 3 4 Pagano, Isabella. "The PLATO 2.0 Payload Module". INAF- Osservatorio Astrofisico di Catania. Retrieved 20 February 2014.
1 2 3 "PLATO Mission Summary". European Space Agency. ESA. 19 February 2014. Retrieved 19 February 2014.
1 2 Amos, Jonathan (29 January 2014). "Plato planet-hunter in pole position". BBC News. Retrieved 2014-01-29.
1 2 3 Isabella Pagano (2014). "PLATO 2.0". INAF- Osservatorio Astrofisico di Catania. Retrieved 20 February 2014.
↑ Cosmic Vision M3 candidate missions presentation event. Announcement and registration. (21 January 2014)
↑ "ESA Selects Thales Alenia Space for PLATO Phase B1 Study". Via Satellite. 12 January 2015. Retrieved 1 August 2015.
↑ PLATO: detailed design of the telescope optical units. Authors: D. Magrin, Ma. Munari, I. Pagano, D. Piazza, R. Ragazzoni, et al., in Space Telescopes and Instrumentation 2010: Optical, Infrared, and Millimeter Wave, Edited by Oschmann, Jacobus M., Jr.; Clampin, Mark C.; MacEwen, Howard A. Proceedings of the SPIE, Volume 7731, pp. 773124-8 (2010)

External links

Official website
Official gallery
The PLATO 2.0 Mission scientific paper
What can PLATO do for exoplanet astronomy?

Space observatories

Operating	AGILE AMS-02 Astrosat CALET Chandra (AXAF) DAMPE Fermi Gaia Hinode (Solar-B) HiRISE Hisaki (SPRINT-A) Hubble INTEGRAL IBEX IRIS Kepler LISA Pathfinder MAXI Mikhailo Lomonosov MOST NEOSSat NuSTAR Odin PAMELA R/HESSI SDO SOHO SOLAR Spektr-R Spitzer Swift TUGSAT-1 & UniBRITE-1 WISE XMM-Newton

Planned	HXMT (2017) ISS-CREAM (2017) NICER (2017) CHEOPS (2017) Nano-JASMINE (2017) Spektr-RG (2017) TESS (2017) James Webb (JWST) (2018) Solar Orbiter (SolO) (2018) K-EUSO (2019) iWF-MAXI (2019) Public Telescope (PST) (2019) Astro-1 Telescope (2020) Euclid (2020) Spektr-UV (2021) SVOM (2021) Space Solar Telescope Xuntian (2022) Solar-C (2023) PLATO (2024) Spektr-M (2025) ATHENA (2028) eLISA (2034)

Proposed	ATLAST Astro-H Succesor DIOS EXCEDE Fresnel Imager FINESSE FOCAL HDST Hypertelescope LiteBIRD LUVOIR NEOCam New Worlds Mission NRO donation to NASA Small-JASMINE Sentinel Solar-D SPICA THEIA WFIRST EUSO

Retired	Akari (Astro-F) (2006–11) ALEXIS (1993–2005) ATM (1973–74) ASCA (Astro-D) (1993–2000) Astro-1 (BBXRT HUT) (1990) Astro-2 (HUT) (1995) Astron (1983–89) ANS (1974–76) BeppoSAX (1996–2003) CHIPSat (2003–08) Compton (CGRO) (1991–2000) COROT (2006–13) Cos-B (1975–82) COBE (1989–93) EPOCh (2008) EPOXI (2010) EXOSAT (1983–86) EUVE (1992–2001) FUSE (1999–2007) Kvant-1 (1987–2001) GALEX (2003–13) Gamma (1990–92) Ginga (Astro-C) (1987–91) Granat (1989–98) Hakucho (CORSA-ｂ) (1979–85) HALCA (MUSES-B) (1997–2005) HEAO-1 (1977–79) Herschel (2009–13) Hinotori (Astro-A) (1981–91) HEAO-2 (Einstein Obs.) (1978–82) HEAO-3 (1979–81) HETE-2 (2000–07?) Hipparcos (1989–93) IUE (1978–96) IRAS (1983) IRTS (1995–96) ISO (1996–98) IXAE (1996–2004) Kristall (1990–2001) LEGRI (1997–2002) MSX (1996–97) OAO-2 (1968–73) OAO-3 (Copernicus) (1972–81) Orion 1/2 (1971/1973) Planck (2009–13) RELIKT-1 (1983–84) ROSAT (1990–99) RXTE (1995–2012) SAMPEX (1992–2004) SAS-B (1972–73) SAS-C (1975–79) Suzaku (Astro-EII) (2005–15) Taiyo (SRATS) (1975-80) Tenma (Astro-B) (1983–1985) Uhuru (1970–73) WMAP (2001–10) WISE (first mission: 2009–11) Yokoh (Solar-A) (1991–2001)

Hibernating (Mission completed)	SWAS (1998–2005) TRACE (1998–2010)

Lost	OAO-1/OAO-B (1966/1970) CORSA (1976) ABRIXAS (1999) HETE (1996) WIRE (1999) Astro-E (2000) Hitomi (Astro-H) (2016)

Cancelled	Astro-G Constellation-X Darwin Destiny EChO Eddington FAME GEMS IXO JDEM LOFT SIM & SIMlite SNAP TAUVEX TPF XEUS

See also	Great Observatories program List of space telescopes List of proposed space observatories

Category

Exoplanet search projects

Ground-based

Space missions

Past and current	MOST (2003–present) SWEEPS (2006) COROT (2006–13) EPOXI (2008–13) Kepler (2009–present) KOI exoplanets Gaia (2013–present)

Planned	CHEOPS (2017) TESS (2017) James Webb Space Telescope (2018) PLATO (2024) WFIRST (mid-2020s)

Proposed	ATLAST EXCEDE FINESSE New Worlds Mission PEGASE

Cancelled	Darwin EChO Eddington Space Interferometry Mission Terrestrial Planet Finder

European Space Agency

Spaceports	Guiana Space Centre Esrange

Launch vehicles	Ariane 5 Arianespace Soyuz Vega

Facilities	ESOC ESTEC ESRIN EAC ESAC ECSAT CDF ST-ECF

Communications	ESTRACK European Data Relay System

Programmes	Aurora Copernicus Sentinel Cosmic Vision EGNOS ELIPS ExoMars FLPP Galileo LPP Space Situational Awareness Programme

Predecessors	ELDO ESRO

Related topics	Arianespace ESA Television EUMETSAT European Space Camp GEWEX Planetary Science Archive

Projects and missions

Science

Solar physics	ISEE-2 (1977–1987) Ulysses (1990–2009) SOHO (1995–present) Cluster II (2000–present) Solar Orbiter (2017)

Planetary science	Giotto (1985–92) Huygens (1997–2005) SMART-1 (2003–06) Mars Express (2003–present) Rosetta/Philae (2004–2016) Venus Express (2005–2014) ExoMars Trace Gas Orbiter (2016–present) BepiColombo (2018) ExoMars rover (2020) Jupiter Icy Moons Explorer (2022)

Astronomy and cosmology	Cos-B (1975–82) IUE (1978–96) EXOSAT (1983–86) Hipparcos (1989–93) Hubble (1990–present) Eureca (1992–93) ISO (1995–98) XMM-Newton (1999–present) INTEGRAL (2002–present) COROT (2006–13) Planck (2009–13) Herschel (2009–13) Gaia (2013–present) CHEOPS (2017) James Webb (2018) Euclid (2020) PLATO (2024) ATHENA (2028) eLISA (2034)

Earth observation	Meteosat First Generation (1977–97) ERS-1 (1991–2000) ERS-2 (1995–2011) Meteosat Second Generation (2002–present) Envisat (2002–12) Double Star (2003–07) MetOp (2006–present) GOCE (2009–13) SMOS (2009–present) CryoSat-2 (2010–present) Swarm (2013–present) Sentinel-1 / 1A / 1B (2014–present) Sentinel-2 / 2A (2015–present) Sentinel-3 / 3A (2016–present) Sentinel-5 Precursor (2016) Meteosat Third Generation (Sentinel-4) (2017) ADM-Aeolus (2017) EarthCARE (2018) MetOp-SG-A (2021) SMILE (2021) MetOp-SG-B (2022) FLEX (2022)

ISS spaceflight

ISS contribution (1998–present)
Columbus (2008–present)
Jules Verne (2008)
Cupola (2010–present)
Johannes Kepler (2011)
Edoardo Amaldi (2012)
Albert Einstein (2013)
Georges Lemaître (2014)
European Robotic Arm (2017)

Telecommunications

GEOS 2 (1978)
Olympus-1 (1989–1993)
Artemis (2001–present)
GIOVE-A (2005–present)
GIOVE-B (2008–present)
HYLAS-1 (2010–present)
Galileo IOV (2011–present)
Galileo FOC (2014–present)
European Data Relay System (2016–present)

Technology
demonstrators

ARD (1998)
PROBA (2001–present)
YES2 (2007)
PROBA2 (2009–present)
Proba-V (2013–present)
IXV (2015)
LISA Pathfinder (2015–present)
OPS-SAT (2017)
Proba-3 (2018)
Lunar Lander (2018)
AIDA (2020)

Cancelled and proposed

Failed

Future missions in italics

Category
Commons
Wikinews
WikiProject

Future spaceflights

Manned

2017	Soyuz MS-04 (11 March) Soyuz MS-05 (May) Blue Origin New Shepard (Q2) Soyuz MS-06 (September) Soyuz MS-07 (November)

2018	Soyuz MS-08 (March) Soyuz MS-09 (May) SpX-DM2 (mid-year) Boe-CST (August)

TBA	Orion EM-2 (2021) Orion EM-3 (2023) SpX-ITS (2024 for 1st Mars departure)

Unmanned

2016	Echostar 21 (22 December) ERG (20 December) Hard X-ray Modulation Telescope JCSAT-15 / Star One D1 (20 December)

2017	ADM-Aeolus ASNARO-2 Boe-OFT (April) Cygnus CRS OA-7 Space Complex Alpha Chang'e 5 CHEOPS Cygnus CRS OA-8E Formosat 5 GCOM-C / SLATS Hispasat AG1 ICESat-2 Kounotori 7 Kuafu LightSail 2 (March) MX-1E Nano-JASMINE (December) Nauka (November) PRISMA Progress MS-05 (February) Progress MS-06 (May) Progress MS-07 (October) Sentinel-2B QZS-2 QZS-3 QZS-4 Sentinel-3 B Sentinel-5 Precursor SpaceX CRS-10 (January) SpaceX CRS-11 (March) SpaceX CRS-12 (June) SpaceX CRS-13 (September) Spektr-RG TESS (August) Tianzhou 1 TRICOM-1 (10 January) WGS-9

2018	BepiColombo (April) Chandrayaan-2 Chang'e 4 Cygnus CRS OA-9E Cygnus CRS OA-10E EarthCARE GOSAT-2 / KhalifaSat InSight / Mars Cube One (5 May) James Webb Space Telescope (October) Kounotori 8 MicroDragon / RISESAT / OrigamiSat-1 / AOBA-VELOX-IV Orion EM-1 (November) Lunar Flashlight NEA Scout BioSentinel SkyFire Lunar IceCube CuSP LunaH-Map EQUULEUS OMOTENASHI Progress MS-08 Progress MS-09 Progress MS-10 Progress MS-11 SpaceX Red Dragon SELENE-2 Solar Orbiter (October) Solar Probe Plus (31 July) SpaceX CRS-14 SpaceX CRS-15 SpaceX CRS-16 SpaceX CRS-17 SpaceX CRS-18 Prichal (Q3)

2019	Aditya ALOS-3 JDRS Kounotori 9 Progress MS-12 SLIM (January-February) SpaceX CRS-19 SpaceX CRS-20

2020+	AIDA (October 2020, July 2021) B330 (2020) Chang'e 6 (2020) Chinese Mars Mission (2020) Euclid (2020) ExoMars rover / surface platform (July 2020) Hope (July 2020) Mars 2020 (2020) Spektr-UV (2021) MetOp-SG (2021–22) FLEX (2022) Jupiter Icy Moon Explorer (2022) Tiangong-3 (2022) PLATO (2024) Europa Multiple-Flyby Mission (2025) Luna-Glob (2025+) Venera-D (2025+) WFIRST (mid-2020s) ATHENA (2028) eLISA (2034)

Recently

Progress MS-04 (1 December)
Göktürk-1 (5 December)
Resourcesat-2A (7 December)
WGS-8 (7 December)
Kounotori 6 (9 December)

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