Three ways R&D has shaped Galileo Second Generation

Written by Copernical Team Thursday, 05 February 2026 07:31

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Rubidium Pulsed Optically Pumped (Rb POP) atomic clock by Leonardo, Italy

Dedicated research and development, funded by European Union (EU) and European Space Agency (ESA) programmes over the years, has played a key role in Galileo Second Generation.

Among the innovations that will benefit the new satellites are the development of new atomic clocks, links that allow the satellites to ‘talk’ to one another in orbit and a prototype ground station that can precisely pinpoint satellites in the sky. These advanced technologies will ensure Galileo continues to provide world‑class positioning, navigation and timing to users worldwide.

Precisely pinpointing satellites

Accurate positioning, navigation and timing relies on knowing precisely where satellites are in their orbits.

Galileo satellites are located by tracking their L-band antenna transmissions from the ground. Each satellite also has a laser retroreflector, which allows measurement of their orbit to within a few centimetres. Known as satellite laser ranging (SLR), this method measures the time it takes for a laser pulse to make the trip from a ground station, called an SLR station, to the satellite and back, then uses these measurements to determine the satellite's orbit. Presently, SLR stations are owned and operated by scientific community users and serve multiple space missions. 

One of the challenges of current SLR is the fact that the lasers are not safe for human eyes and cannot be used if an aircraft is flying nearby as the lasers could blind the pilots. This means SLR stations must coordinate with civil aviation and may not be allowed to use all parts of the sky. SLR stations also have limited availability due to local atmospheric conditions (clear skies are key), and low levels of automation (intensive need for human operators).