Abstract
For ultra-rapid orbits provided by the Global Navigation Satellite System (GNSS), the key parameters, accuracy and timeliness, must be taken into consideration in real-time and near real-time applications. However, insufficient observations in later epochs appear to generate low accuracy in observed orbits, for which a correlation between the Dilution of Precision (DOP) of the orbit parameters and their accuracy is found. To correct the observed GNSS ultra-rapid orbit, a correction method based on the DOP values is proposed by building the function models between DOP values and the orbit accuracy. With 10-day orbit determination experiments, the results show that the observed ultra-rapid-orbit errors, generated by insufficient observations, can be corrected by 12–22% for the last three hours of the observed orbits. Moreover, considering the timeliness constraints in ultra-rapid-orbit determination, a DOP amplification factor is defined to weight the contribution of each tracking station and optimize the station distribution in the orbit determination procedure. Finally, six schemes are designed to verify the method and strategy in determining the ultra-rapid orbit based on one-month observations. The orbit accuracy is found to decrease by 1.27–6.34 cm with increasing amplification factor from 5–20%. Thus, the observed ultra-orbit correction method proposed is ideal when considering accuracy and timeliness in ultra-rapid orbit determination.
Highlights
The analysis center (AC) of a Global Navigation Satellite System (GNSS) provides ultra-rapid, rapid, and final products and services, such as orbits and clocks, to GNSS users, of which the ultra-rapid orbit plays an important role in real-time and near real-time applications
One-month of ultra-rapid orbits from day of year (DOY) 168 to 197, 2017 of WHU were selected in the orbit accuracy analysis
The ultra-rapid orbit is an important product for GNSS users, the accuracy of which directly affects real-time or near real-time applications
Summary
The analysis center (AC) of a Global Navigation Satellite System (GNSS) provides ultra-rapid, rapid, and final products and services, such as orbits and clocks, to GNSS users, of which the ultra-rapid orbit plays an important role in real-time and near real-time applications. The three-dimensional root-mean-square errors (3D RMS) of GPS ultra-rapid predicted orbits within the 6- and 24-h periods may be up to 41.7 mm and 80.2 mm, respectively (IGS mail 6053), which lags behind the final precise orbit of the International GNSS Service (IGS) and does not meet with the high-precision requirements of GNSS users. High-precision GNSS ultra-rapid orbits for different navigation satellite systems are prerequisite in the expansion to fast high-precision GNSS services with the flourishing development of the GNSS, which includes the “three-step” strategy of the BeiDou satellite system (BDS) [8]
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