ESA's Hera Satellite Trio to Use Inter-Linked Radio Technology from Tekever

ESA's Hera Satellite Trio to Use Inter-Linked Radio Technology from Tekever

ESA’s Hera mission for planetary defense involves not just one spacecraft but three: two shoebox-sized CubeSats will fly up to a few dozen kilometers from their mothership around the Didymos binary asteroid system. Keeping this trio in communication to fulfill their mission needs while ensuring their safe separation is the task of a novel inter-satellite link radio technology, produced by Tekever, a Portuguese company best known for terrestrial drone systems.Hera and its CubeSats at Didymos system 

“There are lots of systems for radio frequency communications between spacecraft and the ground, but not really between spacecraft themselves – it was something of a gap in the market,” explains Pedro Rodrigues of the Tekever company, whose head office is in Lisbon.

Started by computer science and electronics engineering students in 2001, Tekever had its initial focus on developing software to be run on multiple networked platforms, subsequently expanding into aerospace and defense markets.

Today the company has grown into one of Europe’s leading ‘surveillance-as-a-service’ UAV suppliers.

Pedro Rodrigues adds: “Back around 2009 we had software-defined radio equipment used in terrestrial tactical radios. It allowed platforms to communicate while also simultaneously exchanging ranging information, so they stay continuously aware of where they are relative to each other. We could see its wider potential, having introduced our space division at this time."

Proba-3 satellites form artificial eclipse “Its utility for ESA’s Proba-3 mission was clear, which involves two satellites flying in close formation, to line up with the Sun to create artificial solar eclipses between them. Our inter-satellite link technology provides coarse one-dimensional measurements between the pair, which can be supplemented as needed by more accurate positioning methods including cameras and laser metrology.”

The company’s inter-satellite links (ISLs) became an integral part of the Proba-3 mission, which is scheduled to be launched in November this year. In the meantime, came the Hera mission, which begged the question: if ISL worked so well for two spacecraft, could they be made to work for three?

Systems engineer Paolo Concari, based at ESA’s ESTEC technical center, worked on adapting ISL technology for both Proba-3 and Hera: “For Proba-3 it was a matter firstly of simplifying the electrical design, then to qualify the components used for the harsh environment of space, which involved a lot of radiation testing.”

Pedro Rodrigues notes: “Our design began with many commercial off-the-shelf components rather than existing space-qualified products, for the simple reason that they are more advanced and capable. We went through a lengthy screening process where we tested candidate parts for susceptibility to radiation effects.Proba-3's pair of satellites

“This took a long time because we had to go back to the design phase several times to swap unsuitable components, but this effort was essential, as the system couldn’t perform to the same standard if it relied on solely space-qualified parts.”

The advantage of reusing aboard Hera was that the hard work of qualifying the ISL design for space was already finished because the Hera ISLs are identical to their Proba-3 predecessors in terms of hardware. The only difference is that they are running a rewritten software algorithm – such easy reconfigurability being one of the main advantages of software-defined radio systems.

Testing an ISL unit at Tekever Pedro Rodrigues explains: “Hera’s ISLs provide ranging information in the same way as Proba-3’s do, but also the range rates – which means showing the spacecraft the rates at which they are moving away or towards one another. And because we are dealing with three platforms instead of two, we had to implement a networking philosophy into the system – essentially the three spacecraft share networked information, then decide whether they need to act upon it or discard it.”

The system also acquires high-rate ranging measurements to estimate slight Doppler shifts induced by the gravitational pull of both asteroids. This multi-point data will be used to calculate their mass, allowing the asteroid composition density to be determined much more accurately than Hera could achieve by itself.

Another difference with Proba-3 is that Hera’s trio will be operating much further away in space – up to 30 km distant, rather than approximately 150 m away. Inside an inter-satellite link unit 

“This led to one minor hardware modification, which is a bit more power on the amplifier,” adds Paolo Concari. “Although the main difference is in the software. If the spacecraft are talking at a far range, then the system slows down the bit rate, which gives the spacecraft more time to receive all the pieces of the message, increasing the signal to noise ratio and therefore the likelihood of correct reception.”

Because Tekever’s ISL technology was originally aimed at the small satellite market, fitting it onto Hera’s CubeSats proved relatively straightforward, because they share the same PC/104 board standard.

The ISLs were recently tested together with Hera’s main ground-to-Earth High Gain Antenna, allowing mission controllers in ESA’s European Space Operations Centre to operate the CubeSats via these links. Now this test campaign has proved successful, the next time the ISLs will be operated will be when the CubeSats are deployed around the asteroids in early 2027.Comet Interceptor 

In the meantime, ISL technology is being supplied to ESA’s Comet Interceptor, which will similarly deploy two probes from the main spacecraft – including one provided by the Japanese Aerospace Exploration Agency, JAXA.

Pedro Rodriques concludes: “Letting multiple spacecraft talk with each other like this is a game changer for science missions in particular, so Tekever is in discussion with a variety of space agencies at the point, as well as exploring commercial market opportunities.”

Click here to learn more about the Hera satellites.

Publisher: SatNow
Tags:-  SatelliteLaunchGround

GNSS Constellations - A list of all GNSS satellites by constellations

beidou

Satellite NameOrbit Date
BeiDou-3 G4Geostationary Orbit (GEO)17 May, 2023
BeiDou-3 G2Geostationary Orbit (GEO)09 Mar, 2020
Compass-IGSO7Inclined Geosynchronous Orbit (IGSO)09 Feb, 2020
BeiDou-3 M19Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M20Medium Earth Orbit (MEO)16 Dec, 2019
BeiDou-3 M21Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 M22Medium Earth Orbit (MEO)23 Nov, 2019
BeiDou-3 I3Inclined Geosynchronous Orbit (IGSO)04 Nov, 2019
BeiDou-3 M23Medium Earth Orbit (MEO)22 Sep, 2019
BeiDou-3 M24Medium Earth Orbit (MEO)22 Sep, 2019

galileo

Satellite NameOrbit Date
GSAT0223MEO - Near-Circular05 Dec, 2021
GSAT0224MEO - Near-Circular05 Dec, 2021
GSAT0219MEO - Near-Circular25 Jul, 2018
GSAT0220MEO - Near-Circular25 Jul, 2018
GSAT0221MEO - Near-Circular25 Jul, 2018
GSAT0222MEO - Near-Circular25 Jul, 2018
GSAT0215MEO - Near-Circular12 Dec, 2017
GSAT0216MEO - Near-Circular12 Dec, 2017
GSAT0217MEO - Near-Circular12 Dec, 2017
GSAT0218MEO - Near-Circular12 Dec, 2017

glonass

Satellite NameOrbit Date
Kosmos 2569--07 Aug, 2023
Kosmos 2564--28 Nov, 2022
Kosmos 2559--10 Oct, 2022
Kosmos 2557--07 Jul, 2022
Kosmos 2547--25 Oct, 2020
Kosmos 2545--16 Mar, 2020
Kosmos 2544--11 Dec, 2019
Kosmos 2534--27 May, 2019
Kosmos 2529--03 Nov, 2018
Kosmos 2527--16 Jun, 2018

gps

Satellite NameOrbit Date
Navstar 82Medium Earth Orbit19 Jan, 2023
Navstar 81Medium Earth Orbit17 Jun, 2021
Navstar 78Medium Earth Orbit22 Aug, 2019
Navstar 77Medium Earth Orbit23 Dec, 2018
Navstar 76Medium Earth Orbit05 Feb, 2016
Navstar 75Medium Earth Orbit31 Oct, 2015
Navstar 74Medium Earth Orbit15 Jul, 2015
Navstar 73Medium Earth Orbit25 Mar, 2015
Navstar 72Medium Earth Orbit29 Oct, 2014
Navstar 71Medium Earth Orbit02 Aug, 2014

irnss

Satellite NameOrbit Date
NVS-01Geostationary Orbit (GEO)29 May, 2023
IRNSS-1IInclined Geosynchronous Orbit (IGSO)12 Apr, 2018
IRNSS-1HSub Geosynchronous Transfer Orbit (Sub-GTO)31 Aug, 2017
IRNSS-1GGeostationary Orbit (GEO)28 Apr, 2016
IRNSS-1FGeostationary Orbit (GEO)10 Mar, 2016
IRNSS-1EGeosynchronous Orbit (IGSO)20 Jan, 2016
IRNSS-1DInclined Geosynchronous Orbit (IGSO)28 Mar, 2015
IRNSS-1CGeostationary Orbit (GEO)16 Oct, 2014
IRNSS-1BInclined Geosynchronous Orbit (IGSO)04 Apr, 2014
IRNSS-1AInclined Geosynchronous Orbit (IGSO)01 Jul, 2013