Data

GRACE ANU Accelerometer data corrected for thermal effects

The Australian National University
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ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.25911/619dcd194df44&rft.title=GRACE ANU Accelerometer data corrected for thermal effects&rft.identifier=10.25911/619dcd194df44&rft.publisher=The Australian National University&rft.description=The precise calculation of GRACE and GRACE-FO satellite orbits is reliant on knowledge of accurate non-gravitational accelerations acting on the spacecraft. These are measured by the on-board accelerometers that require a thermal environment stabilised to 0.1°C per revolution. However, during periods of the GRACE mission with reduced thermal control, internal temperature variations reached up to 10°C within a revolution, causing low-frequency and non-linear drifts in the accelerometer observations. Additionally, accelerometer bias drifts occurred throughout the GRACE mission as changes in the orientation of the orbital plane with respect to the Earth-to-Sun vector caused the satellites to absorb more or less solar energy. These temperature-induced drifts degrade the quality of mass change estimates, particularly during the latter half of the GRACE mission after thermal control of the satellites was terminated. We filter (in the frequency domain) the accelerometer observations to remove these low-frequency components ( 0.045 mHz). The bias drift removed from the cross-track is then scaled to derive a thermally-based correction for the highly sensitive along-track observations. We then estimate temporal gravity fields using the ANU GRACE software, our filtered accelerometer observations and the range acceleration as the inter-satellite observation. The use of our thermally-corrected accelerometer measurements significantly improves the accuracy of both orbit modelling and gravity field estimation. The research was funded in part by the Australian Research Council (DP0985080, DP130101766, DP190102382) and an Australian Space Research Project. A single tar file is provided, containing daily files for GRACE A and GRACE B accelerometer data in Level-1B format. Files are called ACF1B. This research was published in an article in Advances in Space Research: McGirr, R., P. Tregoning, S. Allgeyer, H. McQueen, A. Purcell (2021), Mitigation of thermal noise in GRACE accelerometer observations, and can be accessed at https://doi.org/10.1016/j.asr.2021.10.055 Please cite this article when using the filtered ACF1B data provided here. GRACE Accelerometer observations corrected for thermal effects&rft.creator=Anonymous&rft.date=2021&rft_rights= http://legaloffice.weblogs.anu.edu.au/content/copyright/&rft_rights=&rft_subject=Philosophy not elsewhere classified&rft_subject=PHILOSOPHY AND RELIGIOUS STUDIES&rft_subject=PHILOSOPHY&rft_subject=GRACE&rft.type=dataset&rft.language=English Access the data
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Postal Address:
Research School of Earth Sciences The Australian National University

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Ph: +61261255510

paul.tregoning@anu.edu.au

Full description

The precise calculation of GRACE and GRACE-FO satellite orbits is reliant on knowledge of accurate non-gravitational accelerations acting on the spacecraft. These are measured by the on-board accelerometers that require a thermal environment stabilised to 0.1°C per revolution. However, during periods of the GRACE mission with reduced thermal control, internal temperature variations reached up to 10°C within a revolution, causing low-frequency and non-linear drifts in the accelerometer observations. Additionally, accelerometer bias drifts occurred throughout the GRACE mission as changes in the orientation of the orbital plane with respect to the Earth-to-Sun vector caused the satellites to absorb more or less solar energy. These temperature-induced drifts degrade the quality of mass change estimates, particularly during the latter half of the GRACE mission after thermal control of the satellites was terminated. We filter (in the frequency domain) the accelerometer observations to remove these low-frequency components ( 0.045 mHz). The bias drift removed from the cross-track is then scaled to derive a thermally-based correction for the highly sensitive along-track observations. We then estimate temporal gravity fields using the ANU GRACE software, our filtered accelerometer observations and the range acceleration as the inter-satellite observation. The use of our thermally-corrected accelerometer measurements significantly improves the accuracy of both orbit modelling and gravity field estimation.

The research was funded in part by the Australian Research Council (DP0985080, DP130101766, DP190102382) and an Australian Space Research Project.

A single tar file is provided, containing daily files for GRACE A and GRACE B accelerometer data in Level-1B format. Files are called "ACF1B".

This research was published in an article in Advances in Space Research:

McGirr, R., P. Tregoning, S. Allgeyer, H. McQueen, A. Purcell (2021), Mitigation of thermal noise in GRACE accelerometer observations,

and can be accessed at https://doi.org/10.1016/j.asr.2021.10.055

Please cite this article when using the filtered ACF1B data provided here.

Notes

one tarfile containing daily GRACE A and GRACE B accelerometer data files, which we call ACF1B, akin to the ACC1B Level-1B files.
64 GB.

Significance statement

GRACE Accelerometer observations corrected for thermal effects

Created: 2021-11

Subjects
GRACE | Philosophy | Philosophy and Religious Studies | Philosophy Not Elsewhere Classified |

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