European industry develops space safety radar

European industry develops space safety radar

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France: ESA will boost European industrial expertise by developing a new radar as part of the Agency’s Space Situational Awareness programme. The radar will test future debris monitoring techniques, helping European satellite operators avoid space hazards and increase safety in earth orbit.

ESA and France’s ONERA – Office National d’Etudes et Recherches Aérospatiales – research centre have signed a EUR 4 million contract that will see the French organisation and five industrial partners in France, Spain and Switzerland design a test surveillance radar and develop a demonstrator model.

“The agreement significantly increases European industrial competitiveness and capabilities in this field,” said Nicolas Bobrinsky, Head of ESA’s Space Situational Awareness (SSA) Preparatory Programme.

“The new demonstrator radar will help test and validate techniques for observing orbital debris. ESA will benefit from the strong cooperation between French, Spanish and Swiss industry.”

Early debris detection is crucial to help warn satellite operators of collision risks and enable avoidance manoeuvres to be made. The radar will make use of ‘bistatic’ technology, following an earlier, parallel contract between ESA and Spain”s Indra Espacio SA to develop a test radar that uses the ‘monostatic’ approach.

“Both radar designs will help test and validate techniques for observing orbital debris by conducting comparative testing,” said Gian Maria Pinna, Ground Segment Manager in ESA’s SSA office.

“The two radar demonstrators will be part of an initial complex network of sensors, which will also make use of optical telescopes and data processing centres for observation of debris objects in all orbital regions.

“While radar technology works most efficiently for the detection of objects in low and highly elliptical orbits, optical technology is better for objects in medium and geostationary orbits.”

Radars work by emitting radio energy at a target, and then detecting the reflected signal.

In a monostatic radar, the emitter and the receiver are at the same spot and the energy is emitted in discrete pulses.

In a bistatic radar, the emitter and receiver are set up at separate locations and the energy is emitted continuously.

Source: ESA