VIBES: Visionary Ingenuity Boosting European Spacecraft. Managing microvibrations for the future of spaceflight

Antonio Garcia; Tim Gust; Enes Basata; Tim Gersting; Michal Deka; Sven Thiele; Mohammad Salah; Matias Bestard Koerner; Torben Runte; Miguel Gonzalez

doi:10.24425/ame.2023.144819

Archive of Mechanical Engineering (Apr 2023)

VIBES: Visionary Ingenuity Boosting European Spacecraft. Managing microvibrations for the future of spaceflight

Antonio Garcia,
Tim Gust,
Enes Basata,
Tim Gersting,
Michal Deka,
Sven Thiele,
Mohammad Salah,
Matias Bestard Koerner,
Torben Runte,
Miguel Gonzalez

Affiliations

Antonio Garcia: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Tim Gust: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Enes Basata: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Tim Gersting: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Michal Deka: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Sven Thiele: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Mohammad Salah: City University of Applied Sciences Bremen, Institute of Aerospace Technologies, Bremen, Germany
Matias Bestard Koerner: German Aerospace Center – DLR, Institute of Space Systems. Guidance, Navigation and Control Systems. Bremen, Germany
Torben Runte: OHB System AG, Bremen, Germany
Miguel Gonzalez: OHB System AG, Bremen, Germany

DOI: https://doi.org/10.24425/ame.2023.144819
Journal volume & issue: Vol. vol. 70, no. No 2
pp. 183 – 197

Abstract

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Microvibrations are mechanical oscillations caused by components such as the reaction wheels of an attitude control system of a spacecraft. These microvibrations are transferred through the spacecraft structure onto important instruments (e.g., optical instruments), causing those to produce diminished results (e.g., reduced image quality, imprecise geolocation etc.). At the present state, microvibrations in spacecraft cannot be actively controlled because their very high frequencies of up to 1000 Hz are above the control bandwidth a current attitude control system can provide. However, being able to reduce the effects of microvibrations on a space mission is becoming increasingly more critical as the envelope of future optical satellite missions expands. Furthermore, the advancements made in the performance of small satellites as well as the growing interest in laser and quantum communication call for a cost-efficient solution for managing microvibrations. This paper describes how cheap MEMS-based measurement systems have already proven that they are a potential solution. Showing high sensitivity and low-noise performance while allowing fast and easy prototyping.

Published in Archive of Mechanical Engineering

ISSN: 2300-1895 (Online)
Publisher: Polish Academy of Sciences
Country of publisher: Poland
LCC subjects: Technology: Engineering (General). Civil engineering (General): Mechanics of engineering. Applied mechanics
Website: https://www.journals.pan.pl/ame

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