Solar radiation pressure modeling and application of BDS satellite

doi:10.11947/j.AGCS.2019.20180097

Abstract

Abstract:

Solar radiation pressure (SRP) model is the basis of high precise orbit determination and positioning of navigation satellites. At present, it is not uncommon for the study of SRP model of BDS satellite. However, the establishment and application of comprehensive analytical SRP model based on satellite physical parameters are rare. Different from other conservative force and non-conservative force, SRP is closely related to the satellite's physical parameters and in-orbit state, which has obviously individual differences. On the basis of the physical mechanism of solar radiation, BDS satellite physical parameters, in-orbit attitude control mode, and so on, comprehensive analytical model has been modeled in this paper. Based on precise ephemeris and laser ranging data, the precision of comprehensive analytical model has been verified. And the precision of orbit determination is decimeter using this comprehensive analytical SRP model. According to the satellite conservation theorem of angular momentum and change of in-orbit telemetry parameters, the difference between comprehensive analytical model and actual in-orbit interference force has been analyzed and calculated. The addition of empirical items on the comprehensive analytical model has been proposed in section 4. Taking C08, C10 satellite of BDS as an example, the precision of satellite laser ranging (SLR) checking precision of them is 0.078 m and 0.084 m respectively. Compared with using the improved CODE empirical model, precision orbit accuracy of them has increased by 0.021 m and 0.045 m respectively.

Key words: BDS satellite, solar radiation pressure, comprehensive analytical model, experience correction item, precise orbit determination

CLC Number:

P228

CHEN Qiuli, YANG Hui, CHEN Zhonggui, WANG Haihong, WANG Chen. Solar radiation pressure modeling and application of BDS satellite[J]. Acta Geodaetica et Cartographica Sinica, 2019, 48(2): 169-175.

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