Mass variation observing system by high low inter-satellite links (MOBILE) – a new concept for sustained observation of mass transport from space

Pail R.; Bamber J.; Biancale R.; Bingham R.; Braitenberg C.; Eicker A.; Flechtner F.; Gruber T.; Güntner A.; Heinzel G.; Horwath M.; Longuevergne L.; Müller J.; Panet I.; Savenije H.; Seneviratne S.; Sneeuw N.; van Dam T.; Wouters B.

doi:10.1515/jogs-2019-0006

Journal of Geodetic Science (Oct 2019)

Mass variation observing system by high low inter-satellite links (MOBILE) – a new concept for sustained observation of mass transport from space

Pail R.,
Bamber J.,
Biancale R.,
Bingham R.,
Braitenberg C.,
Eicker A.,
Flechtner F.,
Gruber T.,
Güntner A.,
Heinzel G.,
Horwath M.,
Longuevergne L.,
Müller J.,
Panet I.,
Savenije H.,
Seneviratne S.,
Sneeuw N.,
van Dam T.,
Wouters B.

Affiliations

Pail R.: Technical University of Munich, Institute of Astronomical and Physical Geodesy, Munich, Germany
Bamber J.: University of Bristol, School of Geographical Sciences, Bristol, UK
Biancale R.: Centre National d’Études Spatiales (CNES), Toulouse, France
Bingham R.: University of Bristol, School of Geographical Sciences, Bristol, UK
Braitenberg C.: University of Trieste, Dptm. of Mathematics & Earth Sciences, Trieste, Italy
Eicker A.: HafenCity Univ. Hamburg, Geodesy and Adjustment Theory, Hamburg, Germany
Flechtner F.: GFZ & Technische Univ. Berlin, Chair of Physical Geodesy, Berlin, Germany
Gruber T.: Technical University of Munich, Institute of Astronomical and Physical Geodesy, Munich, Germany
Güntner A.: Deutsches GeoForschungsZentrum Potsdam, Sect. Hydrology, Potsdam, Germany
Heinzel G.: AEI, Max Planck Inst. for Gravitational Physics, Hannover, Germany
Horwath M.: Technische Universität Dresden, Inst. of Planetary Geodesy, Dresden, Germany
Longuevergne L.: Université Rennes, CNRS, Géosciences, Rennes, France
Müller J.: Leibniz Universität Hannover, Institute of Geodesy, Hannover, Germany
Panet I.: Institut National de l’Information Géographique et Forestière, Paris, France
Savenije H.: Technical University Delft, Water Resources Section, Delft, Netherlands
Seneviratne S.: ETH Zürich, Institute for Atmospheric and Climate Science, Zürich, Switzerland
Sneeuw N.: Universität Stuttgart, Institute of Geodesy, Stuttgart, Germany
van Dam T.: University of Luxembourg, FSTC, Luxembourg
Wouters B.: Univ. Utrecht, Institute for Marine and Atmospheric Research, Utrecht, Netherlands

DOI: https://doi.org/10.1515/jogs-2019-0006
Journal volume & issue: Vol. 9, no. 1
pp. 48 – 58

Abstract

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As changes in gravity are directly related to mass variability, satellite missions observing the Earth’s time varying gravity field are a unique tool for observing mass transport processes in the Earth system, such as the water cycle, rapid changes in the cryosphere, oceans, and solid Earth processes, on a global scale. The observation of Earth’s gravity field was successfully performed by the GRACE and GOCE satellite missions, and will be continued by the GRACE Follow-On mission. A comprehensive team of European scientists proposed the next-generation gravity field mission MOBILE in response to the European Space Agency (ESA) call for a Core Mission in the frame of Earth Explorer 10 (EE10). MOBILE is based on the innovative observational concept of a high-low tracking formation with micrometer ranging accuracy, complemented by new instrument concepts. Since a high-low tracking mission primarily observes the radial component of gravity-induced orbit perturbations, the error structure is close to isotropic. This geometry significantly reduces artefacts of previous along-track ranging low-low formations (GRACE, GRACE-Follow-On) such as the typical striping patterns. The minimum configuration consists of at least two medium-Earth orbiters (MEOs) at 10000 km altitude or higher, and one low-Earth orbiter (LEO) at 350-400 km. The main instrument is a laser-based distance or distance change measurement system, which is placed at the LEO. The MEOs are equipped either with passive reflectors or transponders. In a numerical closed-loop simulation, it was demonstrated that this minimum configuration is in agreement with the threshold science requirements of 5 mm equivalent water height (EWH) accuracy at 400 km wavelength, and 10 cm EWH at 200 km. MOBILE provides promising potential future perspectives by linking the concept to existing space infrastructure such as Galileo next-generation, as future element of the Copernicus/Sentinel programme, and holds the potential of miniaturization even up to swarm configurations. As such MOBILE can be considered as a precursor and role model for a sustained mass transport observing system from space.

Published in Journal of Geodetic Science

ISSN: 2081-9943 (Online)
Publisher: De Gruyter
Country of publisher: Poland
LCC subjects: Science: Astronomy: Geodesy
Website: http://www.degruyter.com/view/j/jogs

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