Descripción del proyecto
Cómo los radares de bolsillo a bordo de drones revolucionarán la exploración planetaria
El objetivo del proyecto FlyRadar, financiado con fondos europeos, es desarrollar un sistema de radar de baja frecuencia para instalarlo en un vehículo aéreo ligero no tripulado. El radar funcionará en dos modos: como radar de abertura sintética y como georradar. Ambos modos son adecuados para obtener imágenes y cartografiar la superficie y la subsuperficie de las cortezas de planetas y satélites. Hasta ahora, el tamaño, el peso y el consumo de energía de estos radares solo eran compatibles con el transporte mediante plataformas aéreas o de satélite. El sistema de radar de bolsillo de FlyRadar será lo suficientemente pequeño como para instalarlo en un dron eléctrico no tripulado. El sistema se probará en la Tierra, en lugares parecidos a los entornos marcianos. El sistema podría ponerse en práctica en futuras misiones de exploración de Marte o Titán.
Objetivo
The proposal deals with the production of a dual-mode, low-frequency, radar installed on board of a leight-weight UAV. The radar will operate into two modes: as Synthetic Aperture Radar (SAR) and as ground penetrating radar. Both instruments provide extremely interesting images that are extensively used in Earth and Planetary observations. However, these airborne systems are bulky and can be operated only from manned aircraft both planes and helicopters. On the other hand, the few drones that can sustain such a equipment are large and heavy. In both cases, the operations are expensive and with a complicate logistic. The quantum leap of FlyRadar consists in installing this radar system onboard a small and light electric octocopters, providing low cost utilisation and easy operations. This affordable system will enlarge the user communities generating the possibility for an extensive use of FlyRadar taking advantage of the potentiality of this long-lasting innovation. The use of SAR and penetrating radar is widespread in Earth observation spanning from geological survey to archeological prospecting, from agricultural assessment to artefact detection. However, FlyRadar could be used also in planetary exploration. The NASA mission Mars2020 will test a drone and it will pave the way for the utilisation of UAVs in the in-situ exploration of Mars and Titan. The project is split in two phase. The first half of the project will be devoted in identifying the requirement, in designing instruments and in building them. The second half will be dedicated to the evaluation of FlyRadar with three experiments lasting a month each. The tests will performed in dry desert areas to avoid the negative effect of ground water and humidity on the radar signal. The test executions will be matched by month-long joint sessions for the analysis of the data, assess the scientific value and investigate the technological aspects.
Ámbito científico
- engineering and technologyelectrical engineering, electronic engineering, information engineeringinformation engineeringtelecommunicationsradio technologyradar
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringroboticsautonomous robotsdrones
- engineering and technologymechanical engineeringvehicle engineeringaerospace engineeringaircraftrotorcraft
Palabras clave
Programa(s)
Régimen de financiación
MSCA-RISE - Marie Skłodowska-Curie Research and Innovation Staff Exchange (RISE)Coordinador
65128 Pescara
Italia
Organización definida por ella misma como pequeña y mediana empresa (pyme) en el momento de la firma del acuerdo de subvención.