ESA deploys ‘big iron’ to communicate with its deep-space missions: three 35 m-diameter dishes employing some of the world’s most advanced tracking technology. And it’s about to get a boost.
ESA’s three Deep Space Antenna stations at New Norcia, Australia, Cebreros, Spain and Malargüe, Argentina, beam commands and receive data from spacecraft voyaging hundreds of millions of kilometres into our Solar System.
The trio form part of ESA’s Estrack tracking network a global system of stations providing links between satellites in orbit and the European Space Operations Centre, Darmstadt, Germany. The core network comprises 10 stations in seven countries.
The huge dishes – whose moveable structures weigh in at 620 tonnes – can be rotated, elevated and aimed with pinpoint accuracy despite high winds and heat, and transmit radio signals with up to 20 kW of power – enough to run over 20 000 domestic coffee makers .
The stations’ stellar performance, however, isn’t just about big moving, mechanical things: they make use of advanced, made-in-Europe electronics, including cryogenically cooled low-noise amplifiers and exquisitely machined mirrors made of metal.
Exploiting the fundamental physics of radio waves and properties of geometric shapes, the stations use ‘dichroic mirrors’ made of metal, not glass, to reflect and separate the transmitted and received beams.
These mirrors are a metallic latticework comprising thousands of small shapes – either rectangles or crosses – and enable the stations to differentiate between radio signals ranging in frequency from 2 GHz to 40 GHz.
Using their original mirrors and frequencies, the stations, which entered service in 2001 (Australia), 2006 (Spain) and 2013 (Argentina), have provided flawless links with multiple ESA missions, including Gaia, Mars Express and Rosetta, as well as those of partner agencies such as NASA.
But they were designed to allow future upgrades, and with ESA’s growing Solar System exploration plans, the future is here.
Tracking spacecraft deep across the void
“Future exploration missions to destinations like Jupiter, Ganymede and Mercury will deliver much more scientific data from much further away, and this requires increasing the stations’ transmit and receive capabilities,” says Pier Mario Besso, an ESA antenna engineer.
Furthermore, spaceborne observatories like Herschel/Planck in the past and Gaia today traditionally use the 8 GHz band for beaming data back, while future missions such as Euclid will move to the 26 GHz band, which offers four times more data bandwidth.
This means upgrading the current fixed, solid dichroic mirrors with newer versions that can move between various mechanical positions, and cryogenically cooling microwave components to make them more sensitive.
As a measure of how much this will improve performance, consider that the stations typically offer a download rate of 228 kbit /s from Mars Express circling the Red Planet, and 7.6 Mbit/s from Gaia, some 1.5 million km from Earth.
When complete, the station improvements will boost this to, typically, 2.2 Mbit/s for ExoMars, and a whopping 74 Mbit/s for Euclid at Gaia’s distance – about four times faster than a typical home broadband Internet connection.