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\t\t\t\t\t\t24\/05\/2024<\/span> An experimental flock of miniature CubeSats has survived the unexpected loss of its leader to begin monitoring water quality across Spain and Portugal.<\/p>\n<\/div>\n Named ANSER \u2013 from the Latin for the wild goose \u2013 these shoebox-sized satellites not only fly in formation like birds but also employ wing-like deployable flaps and solar panels to perform manoeuvres on a fuel-free basis, moving against the scarce air molecules found at the very top of the atmosphere.<\/p>\n \u201cThe idea behind our ANSER, Advanced Nanosatellite Systems for Earth-observation Research, mission was to try to mitigate risk in a novel way,\u201d explains Santiago Rodriguez Bustabad of INTA, the Spanish Institute of Aerospace Technology, overseeing the mission. \u201cOn a typical satellite the design incorporates redundancy \u2013 flying two or more models of the same systems to guard against something going wrong. Instead, with ANSER we decided to try a trio of satellites flying in close proximity, to work together as a cluster.<\/p>\n<\/p><\/div>\n \u201cOne satellite would work as the Leader, overseeing a pair of Followers an optimum 10 km apart so they can observe the same area at the same time. This architecture increases mission resilience, because as long as at least one satellite remains operational, the mission stays alive. That at least was the theory. Then, suddenly, mere hours after launch, we had to start making it work for real.\u201d<\/p>\n The ANSER trio of CubeSats \u2013 low-cost and size satellites built up from standardised 10 cm boxes \u2013 flew on Europe\u2019s Vega Flight VV23 launch in October 2023. But while the two Follower CubeSats made it safely into orbit, the Leader CubeSat failed to deploy, reentering soon after with the rest of the Vega upper stage.<\/p>\n The ANSER trio had suddenly become a duo. The INTA team had to scramble to save the truncated mission.<\/p>\n<\/p><\/div>\n Three become two: reworking the mission<\/b><\/p>\n All three CubeSats were equipped with spectrometers, linked together by radio links to function as a \u2018fractionated\u2019 instrument called\u00a0CINCLUS \u2013 named after another bird species. The aim was to record the detailed colours of water bodies across the Iberian Peninsula, as well as other lakes and reservoirs worldwide for comparison, to reveal harmful contents suspended within the water, including its pollution levels or the presence of toxic microorganisms such as harmful phytoplankton blooms.<\/p>\n In addition, the Leader CubeSat had been fitted with a panchromatic camera, intended for cloud mapping, so any cloud cover within a scan could be accounted for during processing. The Leader satellite was also intended to relay data to the ground and instructions to the other satellites.<\/p>\n<\/p><\/div>\n \u201cAs soon as our launch and early operations phase was complete, we began work to reconfigure Follower 1 to assume the Leader\u2019s role in the cluster,\u201d Santiago added. \u201cThis was achieved without any apparent decrease in its observation capabilities. However the Leader\u2019s cloud detection functionality cannot be replicated by a Follower satellite. Instead we make use of Copernicus Sentinel\u00a0satellite images to validate our hyperspectral data instead. This can\u2019t be done in real time, but it still works. With this new configuration, ANSER\u2019s mission is still 100% operational.\u201d<\/p>\n Following a lengthy commissioning process, the CINCULUS payload could be validated, starting with a survey of Menorca Island that shows significant differences between land and water spectra, with an even better signal to noise ratio than predicted.<\/p>\n<\/p><\/div>\n Fuel-free orbital manoeuvring<\/b><\/p>\n Next began sustained testing of ANSER\u2019s other big innovation: fuel-free orbital manoeuvring relative to each other, based on deployable flaps and solar arrays which can increase the surface area of each CubeSat more than 21-fold. Depending on their attitude, the satellite can either be dragged lower by atmospheric friction or moved sideways, out of plane \u2013 like a sailor tacking the sails of their yacht.<\/p>\n<\/p><\/div>\n \u201cLast month we deployed flaps and panels in both satellites to initiate a controlled descent to reach the nominal altitude of 500 km,\u201d adds Santiago. \u201cWe have confirmed that those drag manoeuvres are highly efficient: despite the low atmosphere density at 570 km altitude, when a satellite is in maximum drag mode, it falls 300m per day with respect to the other satellite which is flying in minimum drag mode.<\/p>\n \u201cToday, Follower 2 is 1 km lower than Follower 1; both satellites are placed in maximum drag mode to reduce the current along-track distance from 10 000 km to the nominal distance of 10 km. At the same time, they keep descending at maximum speed, so we expect to reach that nominal separation in 40 days.\u201d<\/p>\n<\/p><\/div>\n New ANSER satellite on way<\/b><\/p>\n ANSER was developed by INTA through internal funding, but gained its chance to fly through the\u00a0European Commission\u2019s In-Orbit Demonstration\/In-Orbit Validation programme, managed on behalf of the Commission by ESA\u2019s Small Satellite Platform Unit.<\/p>\n \u201cBut the ANSER story is only just starting,\u201d Santiago remarks. \u201cOur team has finished the integration of a new CubeSat \u2013 ANSER Leader-S \u2013 which will replace the original lost Leader, incorporating a new S-band radio to improve its communications capabilities with the ground. Its launch has been booked with ISILAUNCH in the Netherlands and SpaceX for next October, with a close enough orbit that if all goes well it can join the ANSER \u2013 demonstrating the innovative concept of uploading new hardware to an existing mission.\u201d<\/p>\n<\/p><\/div>\n
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