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Research progress on in-flight calibration of the magnetometer in deep space exploration
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Research progress on in-flight calibration of the magnetometer in deep space exploration
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Journal Article
Research progress on in-flight calibration of the magnetometer in deep space exploration
2024
Overview
Magnetic field measurements play a crucial role in deep space exploration, contributing significantly to our understanding of planetary habitability and the space plasma environment. Among the various instruments employed in space exploration missions, the fluxgate magnetometer stands out as a widely used tool. However, its zero offset undergoes gradual changes, necessitating regular in-flight calibration. This article comprehensively reviews in-flight calibration methods for spaceborne magnetometers in deep space exploration, leveraging physical phenomena inherent to the space environment. The methods for calculating the zero offset can be divided into two categories. The first group employs formulas, including the Belcher method, Hedgecock method, Davis-Smith method, and both one-dimensional and three-dimensional mirror mode methods. Notably, the Davis-Smith method emerges as the optimal choice among these approaches. The second group employs probability-based solutions, constituting the in-flight calibrati
Publisher
Editorial Office of Reviews of Geophysics and Planetary Physics
