Litcius/Paper detail

COMPASSO mission and its iodine clock: outline of the clock design

Frederik Kuschewski, Jan Wüst, Markus Oswald, Tim Blomberg, Martin Gohlke, Jonas Bischof, Alex Boac, Tasmim Alam, André Bußmeier, Klaus Abich, Niklas Röder, Klaus Döringshoff, Jan Hrabina, Miroslava Holá, Jindřich Oulehla, Thilo Schuldt, Claus Braxmaier

2023GPS Solutions13 citationsDOIOpen Access PDF

Abstract

Abstract One of the limiting factors for GNSS geolocation capabilities is the clock technology deployed on the satellites and the knowledge of the satellite position. Consequently, there are numerous ongoing efforts to improve the stability of space-deployable clocks for next-generation GNSS. The COMPASSO mission is a German Aerospace Center (DLR) project to demonstrate high-performance quantum optical technologies in space with two laser-based absolute frequency references, a frequency comb and a laser communication and ranging terminal establishing a link with the ground station located in Oberpfaffenhofen, Germany. A successful mission will strongly improve the timing stability of space-deployable clocks, demonstrate time transfer between different clocks and allow for ranging in the mm-range. Thus, the technology is a strong candidate for future GNSS satellite clocks and offers possibilities for novel satellite system architectures and can improve the performance of scientific instruments as well. The COMPASSO payload will be delivered to the international space station in 2025 for a mission time of 2 years. In this article, we will highlight the key systems and functionalities of COMPASSO, with the focus set to the absolute frequency references.

Topics & Concepts

GNSS applicationsPayload (computing)SatelliteComputer scienceAtomic clockGalileo (satellite navigation)Satellite laser rangingSatellite systemRemote sensingSystems engineeringAerospace engineeringTelecommunicationsEngineeringLaser rangingGeographyLaserPhysicsComputer securityNetwork packetAtomic physicsOpticsAdvanced Frequency and Time StandardsAtomic and Subatomic Physics ResearchCardiovascular Syncope and Autonomic Disorders