Airbus Demonstrates Very High-Speed Optical Link Between Space and Earth

The French Space Agency (CNES) and Airbus have announced completion of the TELEO in-orbit demonstrator designed to prove that massive, rapid ground to space data transfer is possible.
This compact ‘orbital laboratory’ is hosted onboard Arabsat’s Airbus-built Badr-8 geostationary satellite, launched in 2023. Its mission was to exchange masses of data at very high rates (10Gbps) between space and various ground stations.
CNES and Airbus have been working together since 2018 to develop terabits per second optical feeder links for future geostationary (GEO) telecommunication satellites. The successful TELEO demonstration has proven that optical links will be a competitive complementary solution, and in some cases, a real alternative to radio frequency communications, thanks to much higher capacity of transfer per link, as well as a simpler, smaller and more cost effective ground segment.
“Laser communications to and from space will reshape the telecoms market, similar to how optical fiber transformed telecoms on ground,” said Philippe Pham, Head of Telecommunications and Navigation Systems at Airbus. “TELEO is the next generation of laser satellite communication, demonstrating very high speed and resilient connectivity from GEO orbit to the ground through turbulent atmosphere. This technology is license-free, undetectable, immune to military jammers and will complement radio frequency for tomorrow’s rapid global data exchange.”
As the main partner, CNES has contributed to this demonstration right from the start. CNES also made available a prototype ground station, developed by a consortium of French industrial companies, under the lead of OGS Technologies, known as FrOGS (the French Optical Ground StationS).
The TELEO demonstration core team composed of Airbus, OGS Technologies and CNES, performed the first in orbit acquisitions and data links, from FrOGS, demonstrating TELEO’s ability to repeatedly acquire and track laser signals.
As the main partner, CNES has contributed to this demonstration right from the start. CNES also made available a prototype ground station, developed by a consortium of French industrial companies, under the lead of OGS Technologies, known as FrOGS (the French Optical Ground StationS).
The TELEO demonstration core team composed of Airbus, OGS Technologies and CNES, performed the first in orbit acquisitions and data links, from FrOGS, demonstrating TELEO’s ability to repeatedly acquire and track laser signals.

Technological Partnerships
The TELEO innovation project was initiated and incubated within Airbus UpNext starting in 2019, providing financial and technical ramp-up, during the technology maturation phase. UpNext is an Airbus subsidiary aimed at identifying disruptive trends as potential viable products and accelerating research cycles and prototyping in order to develop real-world applications for emerging aerospace technologies, for which TELEO is a perfect illustration.
CNES supports the French national optical SatCom roadmap through the development of the TELEO demonstration, the FrOGS prototype, as well as the future operational high speed OGS products. The industrial consortium includes French start-up OGS Technologies, as main contributor, who built the station, the optical instrument and the steering mechanism; Safran, as ground station prime together with ALPAO, a world leader in adaptive optics, and Airbus, as the end user, responsible for the first ground to Space demonstrations.
FrOGS is based at the côte d’Azur Observatory on the heights of Grasse, France. These activities are supported and supervised by CNES, in the frame of DYSCO and CO-OP Projects (France Relance) and national R&T.
The ESA ARTES project “FOLC2” has enabled the design, production and development of key building blocks for high-capacity optical communication systems, such as those used for the in-orbit demonstrator TELEO.
ONERA’s involvement was through its FEEder LINk Ground Station (FEELINGS), a unique research infrastructure to study the constraints of the propagation environment on optical links: atmospheric turbulence, cloud cover and aerosols and also to test innovative mitigation strategies. Propagation channel mitigation is of critical importance to reap the benefits of optical links for very high throughput data transfer.
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