PLATO (spacecraft)

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PLATO
Mission typeSpace observatory
OperatorESA
Websitesci.esa.int/web/plato/
Mission duration4 years (plus 4 years of possible mission extensions)
Spacecraft properties
ManufacturerOHB System AG
Launch mass2,134 kg (4,705 lb)[1] including 103 kg of propellant
Payload mass533 kg (1,175 lb)[1]
Power1,950 W[1]
Start of mission
Launch date2026 (planned)
RocketAriane 62[2]
Launch siteKourou ELA-4
ContractorArianespace
Orbital parameters
Reference systemSun–Earth L2
Main
TypeMultiple refractors[3]
Diameter26 telescopes, 120 mm each
Collecting area2,250 deg2
WavelengthsVisible spectrum: 500 to 1,000 nm
← SMILE
ARIEL →
 

PLAnetary Transits and Oscillations of stars (PLATO) is a space telescope under development by the European Space Agency for launch in 2026.[4] The mission goals are to search for planetary transits across up to one million stars, and to discover and characterize rocky extrasolar planets around yellow dwarf stars (like the Sun), subgiant stars, and red dwarf stars. The emphasis of the mission is on Earth-like planets in the habitable zone around Sun-like stars where water can exist in a liquid state.[5] It is the third medium-class mission in ESA's Cosmic Vision programme and is named after the influential Greek philosopher Plato. A secondary objective of the mission is to study stellar oscillations or seismic activity in stars to measure stellar masses and evolution and enable the precise characterization of the planet host star, including its age.[6]

History[edit]

PLATO was first proposed in 2007 to the European Space Agency (ESA) by a team of scientists in response to the call for ESA's Cosmic Vision 2015–2025 programme.[7] 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.[7][8] 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.[9]

In January 2015, ESA selected Thales Alenia Space,[10] Airbus DS, and OHB System AG to conduct three parallel phase B1 studies to define the system and subsystem aspects of PLATO, which were completed in 2016. On 20 June 2017, ESA adopted PLATO[11] in the Science Programme, which means that the mission can move from a blueprint into construction. Over the coming months, industry was asked to make bids to supply the spacecraft platform.

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".[7]

Management[edit]

The PLATO Mission Consortium (PMC) that is responsible for the payload and major contributions to the science operations is led by Prof. Heike Rauer at the German Aerospace Center (DLR) Institute of Planetary Research. The design of the Telescope Optical Units is made 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 Telescope Optical Unit development is funded by the Italian Space Agency, the Swiss Space Office and the Swedish National Space Board.[3] The PMC Science Management (PSM), composed of more than 500 experts, is coordinated by Prof. Don Pollacco of the University of Warwick and provides expertise for:

  • The preparation of the PLATO Input Catalogue (PIC)
  • Identifying the optimal fields for PLATO to observe
  • Coordinating follow-up observations
  • Scientifically validating PLATO's data products[12]

Objective[edit]

The objective is the detection of terrestrial exoplanets up to the habitable zone of solar-type stars and the characterization of their bulk properties needed to determine their habitability.[1][5] To achieve this objective, the mission has these goals:

  • Discover and characterize many nearby exoplanetary systems, with precision in the determination of the planets' radii of up to 3%, stellar age of up to 10%, and planet mass of up to 10% (the latter in combination with on-ground radial velocity measurements)
  • Detect and characterize Earth-sized planets and super-Earths in the habitable zone around solar-type stars
  • Discover and characterize many exoplanetary systems to study their typical architectures, and dependencies on the properties of their host stars and the environment
  • Measure stellar oscillations to study the internal structure of stars and how it evolves with age
  • Identify good targets for spectroscopic measurements to investigate exoplanet atmospheres

PLATO will differ from the CoRoT, TESS, CHEOPS, and Kepler space telescopes in that it will study relatively bright stars (between magnitudes 4 and 11), enabling a more accurate determination of planetary parameters, and making it easier to confirm planets and measure their masses using follow-up radial velocity measurements on ground-based telescopes. Its dwell time will be longer than that of the TESS NASA mission, making it sensitive to longer-period planets.

Design[edit]

Optics[edit]

The PLATO payload is based on a multi-telescope approach, involving 26 cameras in total: 24 "normal" cameras organized in 4 groups, and 2 "fast" cameras for bright stars.[1] The 24 "normal" cameras work at a readout cadence of 25 seconds and monitor stars fainter than apparent magnitude 8. The two "fast" cameras work at a cadence of 2.5 seconds to observe stars between magnitude 4 to 8.[1][13] The cameras are refracting telescopes using six lenses; each camera has a 1,100 deg2 field and a 120 mm lens diameter. Each camera is equipped with its own CCD staring array, consisting of four CCDs of 4510 x 4510 pixels.[1]

The 24 "normal cameras" will be arranged in four groups of six cameras with their lines of sight offset by a 9.2° angle from the +ZPLM axis. This particular configuration allows surveying an instantaneous field of view of about 2,250 deg2 per pointing.[1] The space observatory will rotate around the mean line of sight once per year, delivering a continuous survey of the same region of the sky.

Launch[edit]

The space observatory is planned to launch at the end of 2026 to the Sun-Earth L2 Lagrange point.[1]

Data release schedule[edit]

The public release of photometric data (including light curves) and high-level science products for each quarter will be made after six months and by one year after the end of their validation period. The data are processed by quarters because this is the duration between each 90-degree rotation of the spacecraft. For the first quarter of observations, six months are required for data validation and pipeline updates. For the next quarters, three months will be needed.[14]

A small number of stars (no more than 2,000 stars out of 250,000) will have proprietary status, meaning the data will only be accessible to the PLATO Mission Consortium members for a given time period. They will be selected using the first three months of PLATO observations for each field. The proprietary period is limited to 6 months after the completion of the ground-based observations or the end of the mission archival phase (Launch date + 7.5 years), whichever comes first.[14]

See also[edit]

References[edit]

  1. ^ a b c d e f g h i PLATO Definition Study Report. ESA-SCI(2017)1. April 2017.
  2. ^ "Mission Operations". ESA. 13 January 2021. Retrieved 5 March 2021.
  3. ^ a b "PLATO - Camera Telescope Optical Units". INAF- Osservatorio Astrofisico di Catania. 2014. Archived from the original on 25 October 2019. Retrieved 20 February 2014.
  4. ^ PLATO spacecraft to find new Earth-like exoplanets. 21 June 2017, Max Planck Society.
  5. ^ a b Amos, Jonathan (29 January 2014). "Plato planet-hunter in pole position". BBC News. Retrieved 2014-01-29.
  6. ^ "Plato". European Space Agency. European Space Agency. Retrieved 9 February 2017.
  7. ^ a b c Isabella Pagano (2014). "PLATO 2.0". INAF- Osservatorio Astrofisico di Catania. Archived from the original on 3 July 2019. Retrieved 20 February 2014.
  8. ^ Cosmic Vision M3 candidate missions presentation event. Announcement and registration. (21 January 2014)
  9. ^ "ESA selects planet-hunting PLATO mission". European Space Agency. Retrieved 19 February 2014.
  10. ^ "ESA Selects Thales Alenia Space for PLATO Phase B1 Study". Via Satellite. 12 January 2015. Retrieved 1 August 2015.
  11. ^ "Gravitational wave mission selected, planet-hunting mission moves forward". sci.esa.int. Retrieved 2017-06-21.
  12. ^ "PSM". 2018-05-03. Retrieved 2022-12-22.
  13. ^ 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)
  14. ^ a b "PLATO Science Management Plan" (PDF). ESA Cosmos. 11 October 2017. Retrieved 6 November 2019.

External links[edit]