Centimeter-Level Precise Orbit Determination for the Luojia-1A Satellite Using BeiDou Observations

Luojia-1A is a scientific experimental satellite operated by Wuhan University, which is the first low earth orbiter (LEO) navigation signal augmentation experimental satellite. The precise orbit is the prerequisite of augmenting existing Global Navigation Satellite System (GNSS) performance and impr...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2020-06, Vol.12 (12), p.2063
Main Authors: Wang, Lei, Xu, Beizhen, Fu, Wenju, Chen, Ruizhi, Li, Tao, Han, Yi, Zhou, Haitao
Format: Article
Language:English
Subjects:
Antennas
Augmentation
BeiDou Navigation Satellite System
BeiDou observations
Data processing
Earth orbits
Elevation
Global navigation satellite system
Ground stations
Investigations
Low earth orbit satellites
Low earth orbits
Luojia-1A satellite
navigation augmentation
Orbit determination
precise orbit determination
Receivers & amplifiers
reduce-dynamic
Remote sensing
Satellite communications
Satellite navigation systems
Satellite observation
Satellite tracking
Satellites
Stochasticity
Weight reduction
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Summary:Luojia-1A is a scientific experimental satellite operated by Wuhan University, which is the first low earth orbiter (LEO) navigation signal augmentation experimental satellite. The precise orbit is the prerequisite of augmenting existing Global Navigation Satellite System (GNSS) performance and improves users’ positioning accuracy. Meanwhile, LEO precise orbit determination (POD) with BeiDou-2 observations is particularly challenging since it only provides regional service. In this study, we investigated the method of precise orbit determination (POD) for Luojia-1A satellite with the onboard BeiDou observation to establish the high-precision spatial datum for the LEO navigation augmentation (LEO-NA) system. The multipath characteristic of the BeiDou System (BDS) observations from Luojia-1A satellite is analyzed, and the elevation-dependent BeiDou code bias is estimated with the LEO onboard observations. A weight reduction strategy is adopted to mitigate the negative effect of poor BeiDou-2 geostationary earth orbit (GEO) satellites orbit quality, and the Luojia-1A orbit precision can be improved from 6.3 cm to 2.3 cm with the GEO weighting strategy. The precision improvement of the radial direction, along-track, and out-of-plane directions are 53.47%, 47.29%, and 76.2%, respectively. Besides, tuning the pseudo-stochastic parameters is also beneficial for improving orbit precision. The experiment results indicate that about 2 cm overlapping orbit accuracy are achievable with BeiDou observations from Luojia-1A satellite if proper data processing strategies are applied.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs12122063