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\t\t\t\t\t\t09\/10\/2025<\/span> By fitting its sunshield and solar panels, engineers have completed the construction of Plato, the European Space Agency\u2019s mission to discover Earth-like exoplanets. Plato is on track for the final key tests to confirm that it is fit for launch.<\/p>\n<\/div>\n The activities to complete Plato started soon after the spacecraft arrived at ESA\u2019s Test Centre in the Netherlands. On 9 September, in a dedicated clean room, engineers prepared for the delicate operation by suspending the combined sunshield and solar panel module from special lifting gear.<\/p>\n They then manoeuvred the module to precisely align it with the back of the spacecraft, and carefully mounted it in place.<\/p>\n<\/p><\/div>\n \u201cWith this operation, we have completed the Plato spacecraft. The combined sunshield and solar array module was the last remaining essential part,\u201d comments Thomas Walloschek, ESA\u2019s Plato Project Manager.<\/p>\n \u201cIt is very satisfying to have reached this moment and to see Plato in its final shape. This is the result of an excellent cooperation between ESA, the Plato Mission Consortium members and Plato’s industrial core team.\u201d<\/p>\n The sunshield and solar panels are vital elements for the Plato mission. Once in orbit, the solar array catch light from the Sun to generate the electricity needed to power the spacecraft\u2019s electronics. The sunshield keeps the scientific equipment in shadow, away from the Sun\u2019s glare.<\/p>\n \u201cOver the years we have seen what Plato would look like in countless detailed drawings and simulated images, yet seeing the real, completed spacecraft feels very special,\u201d add Ana Heras, ESA\u2019s Plato Project Scientist.<\/p>\n \u201cPlato has a distinctive design, conceived to efficiently integrate its advanced cameras within the spacecraft. Its overall layout is optimised to monitor more than 150\u00a0000 bright stars at the same time, with high precision. This will enable scientists to hunt for terrestrial planets orbiting stars similar to our Sun.\u201d<\/p>\n To spot exoplanets, Plato carries 26 advanced cameras tasked with capturing the tiniest variations in the intensity of a star\u2019s light. To achieve the necessary high sensitivity, the cameras must be kept cool, so that each camera is kept at its best-focus temperature around -80\u00b0 C.<\/p>\n Protected from sunlight by the sunshield and facing deep space, Plato\u2019s scientific instruments will cool down and stay at the required frigid temperature throughout the mission\u2019s lifetime.<\/p>\n<\/p><\/div>\n The structure supporting the solar panels and acting as a sunshield wraps around the back of the spacecraft \u2013 the part that in orbit will be facing the Sun. During launch the solar panels are kept firmly folded in. Once Plato is in space, they will unfold extending outwards\u00a0like a pair of\u00a0wings.<\/p>\n So, after mounting the combined sunshield and solar array module, engineers tested whether it could correctly deploy. They deployed the left and right wing separately, on 16 and 22 September.<\/p>\n<\/p><\/div>\n Because the solar arrays will unfold in space, the deployment test must be carried out as if gravity were absent and the panels were weightless. For this, the panels were suspended from a supporting frame with a system of pulleys that moved along as the panels smoothly unfolded.<\/p>\n Once the panels were deployed, engineers used a special lamp to simulate the effect of sunlight hitting the arrays and verified that they supplied the right level of electricity to the rest of the spacecraft.<\/p>\n This last step confirmed that the deployment was successful.<\/p>\n<\/p><\/div>\n Plato is on track to launch in December 2026, as originally planned, on an Ariane 6. But, before graduating for launch, the spacecraft will have to pass a series of tough exams.<\/p>\n These involve vigorously shaking the spacecraft and blasting it with powerful noise during vibration and acoustic tests that mimic the mechanical stresses of a rocket launch. Then, placing the spacecraft inside the\u00a0Large Space Simulator, Europe\u2019s largest cryo-vacuum chamber.<\/p>\n Therein, Plato will get its first taste of space\u2019s harsh environment and will have to demonstrate that it can work flawlessly once in orbit.<\/p>\n<\/p><\/div>\n ESA\u2019s Plato (PLAnetary Transits and Oscillations of stars)\u00a0will use 26 cameras to study terrestrial exoplanets in orbits up to the habitable zone of Sun-like stars.<\/i><\/p>\n Plato’s scientific instrumentation, consisting of the cameras and electronic units, is provided through a collaboration between ESA and the\u00a0<\/i>Plato Mission Consortium<\/i>\u00a0composed of various European research centres, institutes and industries. The spacecraft is being built and assembled by the industrial Plato Core Team led by\u00a0<\/i>OHB<\/i>\u00a0together with\u00a0<\/i>Thales Alenia Space<\/i>\u00a0and\u00a0<\/i>Beyond Gravity<\/i>.<\/i><\/p>\n Plato is a\u00a0<\/i>medium-class mission of\u00a0ESA\u2019s Cosmic Vision programme.<\/i><\/p>\n Find out more about\u00a0ESA\u2019s Science\u00a0and\u00a0ESA\u2019s Science Programme<\/p>\n Find out more about Ariane 6<\/p>\n \nContact<\/b>:
\n\t\t\t\t145<\/span> views<\/small><\/span>
\n\t\t\t\t\t\t\t\t\t\t1<\/span> likes<\/small><\/span><\/p>\n<\/header>\nPower to Plato<\/h2>\n
Tough exams ahead<\/h2>\n
\n\t\t\t\t\t\t\t\t<\/figcaption><\/figure>\n<\/p><\/div>\nAbout Plato<\/h2>\n
ESA Media Relations
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