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\nThis year, ESA’s ground station boffins are planning to deploy a new cryogenically cooled ‘antenna feed<\/a>‘ \u2013 a gizmo used to transmit and receive deep space signals \u2013 on the Agency’s three deep-space antennas.<\/a>\n<\/p>\n \nThe ground stations routinely communicate with missions like BepiColombo<\/a> \u2013 heading to Mercury, Gaia<\/a> \u2013 surveying stars in our Galaxy, and ESA’s two spacecraft at the Red Planet, Mars Express<\/a> and the ExoMars Trace Gas Orbiter<\/a>.\n<\/p>\n \nESA\u2019s 35-metre antennas receive data from working spacecraft, in what\u2019s called a \u2018downlink\u2019. As the Agency prepares to launch new missions deeper into our Solar System in the next few years, including Juice<\/a> to Jupiter and the ExoMars Rover<\/a>, as well as missions designed to generate large quantities of data, such as the future Sun-watching Lagrange<\/a> mission, use of the stations’ downlink capacity is set to grow significantly.\n<\/p>\n \nThis means the stations have to ‘up their game’, and the new antenna feed is expected improve data return by 40% at the high frequencies used for spacecraft command and control. The feed must be cooled to just 10 K (just 10 degrees from absolute zero, about -263 C) for normal operation.\n<\/p>\n \n"While receiving extremely faint signals, the new feed should be capable of transmitting command signals to spacecraft at very high power of more than 25 kilowatts", says ESA ground station engineer St\u00e9phane Halt\u00e9.\n<\/p>\n \n"This is similar to the amount of power transmitted by 25 000 mobile phones switched on simultaneously."\n<\/p>\n \nThe prototype antenna feed was mounted on NASA\u2019s Deep Space Station 13 (pictured), at NASA’s High Power Transmitter Test facility, in Goldstone, California. It was tested in December 2018 with the assistance of experts from the NASA Jet Propulsion Lab’s Deep Space Network.\n<\/p>\n \nTesting successful, this ESA\/NASA cooperation has cleared the way for the new technology to be rolled out at across ESA\u2019s deep space ground stations, part of the Estrack<\/a> network, within this year.<\/p>\n","protected":false},"excerpt":{"rendered":" \nThis year, ESA’s ground station boffins are planning to deploy a new cryogenically cooled ‘antenna feed<\/a>‘ – a gizmo used to transmit and receive deep space signals – on the Agency’s three deep-space antennas.<\/a>\n<\/p>\n \nThe ground stations routinely communicate with missions like BepiColombo<\/a> – heading to Mercury, Gaia<\/a> – surveying stars in our Galaxy, and ESA’s two spacecraft at the Red Planet, Mars Express<\/a> and the ExoMars Trace Gas Orbiter<\/a>.\n<\/p>\n \nESA’s 35-metre antennas receive data from working spacecraft, in what’s called a ‘downlink’. As the Agency prepares to launch new missions deeper into our Solar System in the next few years, including Juice<\/a> to Jupiter and the ExoMars Rover<\/a>, as well as missions designed to generate large quantities of data, such as the future Sun-watching Lagrange<\/a> mission, use of the stations’ downlink capacity is set to grow significantly.\n<\/p>\n \nThis means the stations have to ‘up their game’, and the new antenna feed is expected improve data return by 40% at the high frequencies used for spacecraft command and control. The feed must be cooled to just 10 K (just 10 degrees from absolute zero, about -263 C) for normal operation.\n<\/p>\n \n“While receiving extremely faint signals, the new feed should be capable of transmitting command signals to spacecraft at very high power of more than 25 kilowatts”, says ESA ground station engineer Stéphane Halté.\n<\/p>\n \n“This is similar to the amount of power transmitted by 25 000 mobile phones switched on simultaneously.”\n<\/p>\n \nThe prototype antenna feed was mounted on NASA’s Deep Space Station 13 (pictured), at NASA’s High Power Transmitter Test facility, in Goldstone, California. It was tested in December 2018 with the assistance of experts from the NASA Jet Propulsion Lab’s Deep Space Network.\n<\/p>\n<\/p>\n