Journal
JOURNAL OF GEODESY
Volume 96, Issue 10, Pages -Publisher
SPRINGER
DOI: 10.1007/s00190-022-01659-0
Keywords
Satellite geodesy; Gravity measurements; Accelerometers; Drag compensation
Categories
Funding
- NASA Earth Science Technology Office (ESTO) [80NSSC20K0324]
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This article introduces a simplified gravitational reference sensor (S-GRS) for future Earth geodesy missions. The S-GRS is more sensitive than current accelerometers and can be used on microsatellites, reducing costs and improving the temporal resolution of gravity field maps.
A simplified gravitational reference sensor (S-GRS) is an ultra-precise inertial sensor for future Earth geodesy missions. These sensors measure or compensate for all non-gravitational accelerations of the host spacecraft to remove them in the data analysis and recover spacecraft motion due to Earth's gravity field. Low-low satellite-to-satellite tracking missions like GRACE-FO that use laser ranging interferometers (LRI) are limited by the acceleration noise performance of their electrostatic accelerometers and temporal aliasing associated with Earth's gravity field. The current accelerometers, used in the GRACE missions, have a limited sensitivity of similar to 10(-10) M/s(2)/Hz(1/2) around 1 mHz. The S-GRS is estimated to be at least 40 times more sensitive than the GRACE accelerometers and over 500 times more sensitive if operated on a drag-compensated platform. This improvement is enabled by increasing the mass of the sensor's test mass, increasing the gap between the test mass and its electrode housing, removing the grounding wire used in GRACE, and replacing it with a UV LED-based charge management system. This allows future missions to take advantage of the sensitivity of the GRACE-FO LRI in the gravity recovery analysis. The S-GRS concept is a simplified version of the flight-proven LISA Pathfinder (LPF) GRS. Performance estimates are based on models vetted during the LPF flight and the expected spacecraft environment based on GRACE-FO data. The relatively low volume (similar to 10(4) cm(3)), mass (similar to 13 kg), and power (similar to 20 W) enable the use of S-GRS on microsatellites, reducing launch costs and allowing more satellite pairs to improve the temporal resolution of gravity field maps. The S-GRS design and analysis, as well as its gravity recovery performance in two candidate mission architectures, are discussed in this article.
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