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Airborne Absolute Gravimetry With a Quantum Sensor, Comparison With Classical Technologies

Yannick Bidel, Nassim Zahzam, Alexandre Bresson, C. Blanchard, Alexis Bonnin, Jeanne Bernard, Malo Cadoret, Tim Jensen, R. Forsberg, Corinne Salaün, S. Lucas, Marie‐Françoise Lequentrec‐Lalancette, Didier Rouxel, G. Gabalda, Lucía Seoane, D.T. Vu, Sean Bruinsma, Sylvain Bonvalot

2023Journal of Geophysical Research Solid Earth48 citationsDOIOpen Access PDF

Abstract

Abstract We report an airborne gravity survey with an absolute gravimeter based on atom interferometry and two relative gravimeters: a classical LaCoste&Romberg (L&R) and a novel iMAR strapdown Inertial Measurement Unit. We estimated measurement errors for the quantum gravimeter ranging from 0.6 to 1.3 mGal depending on the flight conditions and the filtering used. Similar measurement errors are obtained with iMAR strapdown gravimeter, but the long‐term stability is five times worse. The traditional L&R platform gravimeter shows larger measurement errors (3–4 mGal). Airborne measurements have been compared to marine, land, and altimetry‐derived gravity data. We obtain a good agreement for the quantum gravimeter with standard deviations and means on differences below or equal to 2 mGal. This study confirms the potential of quantum technology for absolute airborne gravimetry, which is particularly interesting for mapping shallow water or mountainous areas and for linking ground and satellite measurements with homogeneous absolute referencing.

Topics & Concepts

GravimeterGravimetryGeodesyRemote sensingInertial measurement unitAltimeterInterferometryGeologyEnvironmental sciencePhysicsOpticsComputer scienceArtificial intelligenceGeophysics and Gravity MeasurementsGNSS positioning and interferenceClimate variability and models
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