Released
DatasetGOCE ML-calibrated magnetic field data
Cite as:
Styp-Rekowski, Kevin; Michaelis, Ingo; Stolle, Claudia; Baerenzung, Julien; Korte, Monika; Kao, Odej (2022): GOCE ML-calibrated magnetic field data. V. 0301. GFZ Data Services. https://doi.org/10.5880/GFZ.2.3.2022.002Status
I N R E V I E W : Styp-Rekowski, Kevin; Michaelis, Ingo; Stolle, Claudia; Baerenzung, Julien; Korte, Monika; Kao, Odej (2022): GOCE ML-calibrated magnetic field data. V. 0301. GFZ Data Services. https://doi.org/10.5880/GFZ.2.3.2022.002
Abstract
The Gravity field and steady-state ocean circulation explorer (GOCE) satellite mission carries three platform magnetometers. After careful calibration, the data acquired through these can be used for scientific purposes by removing artificial disturbances from other satellite payload systems. This dataset is based on the dataset provided by Michaelis and Korte (2022) and uses a similar format. The platform magnetometer data has been calibrated against CHAOS7 magnetic field model predictions for core, crustal and large-scale magnetospheric field (Finlay et al., 2020) and is provided in the ‘chaos’ folder. The calibration results using a Machine Learning approach are provided in the ‘calcorr’ folder. Michaelis’ dataset can be used as an extension to this dataset for additional information, as they are connected using the same timestamps to match and relate the same data points. The exact approach based on Machine Learning is described in the referenced publication. The data is provided in NASA CDF format (https://cdf.gsfc.nasa.gov/) and accessible at: ftp://isdcftp.gfz-potsdam.de/platmag/MAGNETIC_FIELD/GOCE/ML/v0204/ and further described in a README.
Additional Information
Version history22 May 2022: release of version 204
21 September 2022: addition of the key reference (Styp-Rekowski et al., 2022) to the DOI landing page, data description (PDF) and README.
12 December 2022: publication of version 301
Methods
The data was recorded onboard the GOCE satellite mission with varying time intervals of the differ-ent subsystems measuring. The magnetometer measurements (16s intervals) were aligned to match the closest position measurement (1s intervals) and interpolated accordingly. All other avail-able data of different intervals was interpolated and aligned to the same timestamps.The data was calibrated using a Machine Learning approach involving Neural Networks, the whole method of calibration is described precisely in the referenced publication. The data was mainly processed for its calibration which yields a lower residual compared to a refer-ence model than the uncalibrated data, more details about the many steps involved can be found in the referenced publication.
Authors
- Styp-Rekowski, Kevin
;TU Berlin, Berlin, Germany;GFZ German Research Centre for Geosciences, Potsdam. Germany - Michaelis, Ingo;GFZ German Research Centre for Geosciences, Potsdam. Germany
- Stolle, Claudia;IAP - Leibniz Institute of Atmospheric Physics at the University of Rostock, Kühlungsborn, Germany
- Baerenzung, Julien;GFZ German Research Centre for Geosciences, Potsdam. Germany
- Korte, Monika;GFZ German Research Centre for Geosciences, Potsdam. Germany
- Kao, Odej;TU Berlin, Berlin, Germany
Contact
- Styp-Rekowski (Research Associate) ; TU Berlin, GFZ Potsdam;
Contributors
Styp-RekowskiKeywords
GOCE satellite, machine learning, platform magnetometers, calibrationGCMD Science Keywords
- EARTH SCIENCE > SOLID EARTH > GEOMAGNETISM > MAGNETIC FIELD
- EARTH SCIENCE > SUN-EARTH INTERACTIONS > IONOSPHERE/MAGNETOSPHERE DYNAMICS
- Earth Observation Satellites > Earth Explorers > GOCE
- Earth Remote Sensing Instruments > Passive Remote Sensing > Magnetic Field/Electric Field Instruments > MAGNETOMETERS
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