Impact analysis of arc length in multi-GNSS ultra-rapid orbit determination based on the one-step method

Ye, Fei; Yuan, Yunbin; Bao-Cheng, Zhang

doi:10.1088/1361-6501/ab69d4

Cited by 4 publications

(2 citation statements)

References 23 publications

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“…GNSS satellite ultra-rapid orbit is the key in determining real-time precise orbits and achieving real-time precision point positioning (PPP) [4,5]. The accuracy and stability of GNSS satellite ultra-rapid orbit determination directly or indirectly affects and limits the performance and promotion of real-time PPP and related applications [6][7][8]. UT1 is the angle of the Earth's rotation about the CIP (Celestial Intermediate Pole) axis defined by its conventional linear relation to the Earth Rotation Angle (ERA), and UT1-UTC is the difference between the UT1 parameter derived from observations and UTC (Coordinated Universal Time) [9].…”

Section: Introductionmentioning

confidence: 99%

Improved Ultra-Rapid UT1-UTC Determination and Its Preliminary Impact on GNSS Satellite Ultra-Rapid Orbit Determination

Yuan

Deng

2020

Remote Sensing

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Errors in ultra-rapid UT1-UTC primarily affect the overall rotation of spatial datum expressed by GNSS (Global Navigation Satellite System) satellite ultra-rapid orbit. In terms of existing errors of traditional strategy, e.g., piecewise linear functions, for ultra-rapid UT1-UTC determination, and the requirement to improve the accuracy and consistency of ultra-rapid UT1-UTC, the potential to improve the performance of ultra-rapid UT1-UTC determination based on an LS (Least Square) + AR (Autoregressive) combination model is explored. In this contribution, based on the LS+AR combination model and by making joint post-processing/rapid UT1-UTC observation data, we propose a new strategy for ultra-rapid UT1-UTC determination. The performance of the new strategy is subsequently evaluated using data provided by IGS (International GNSS Services), iGMAS (international GNSS Monitoring and Assessment System), and IERS (International Earth Rotation and Reference Systems Service). Compared to the traditional strategy, the numerical results over more than 1 month show that the new strategy improved ultra-rapid UT1-UTC determination by 29–43%. The new strategy can provide a reference for GNSS data processing to improve the performance of ultra-rapid products.

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Section: Introductionmentioning

confidence: 99%

Improved Ultra-Rapid UT1-UTC Determination and Its Preliminary Impact on GNSS Satellite Ultra-Rapid Orbit Determination

Yuan

Deng

2020

Remote Sensing

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“…Precise ephemeris information is typically obtained using GNSS observations and initial trajectories with poor accuracy [13,14]. In addition, based on the precise ephemeris, high-precision prediction values can be extrapolated in a short period of time, and the accuracy will decrease significantly as the extrapolation time increases [15,16].…”

Section: Introductionmentioning

confidence: 99%

Analysis and improvement of the Bancroft algorithm for GNSS satellite orbit determination

Chen¹,

Sheng²,

Yi³

et al. 2022

Meas. Sci. Technol.

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Satellite orbit information is crucial for ensuring that global navigation satellite systems (GNSSs) provide appropriate positioning, navigation and timing services. Typically, users can obtain access to orbit information of a specific accuracy level from navigation messages or precise ephemeris products. Without this information, a system will not be able to provide normal service. In response to this problem, initial orbit information of a certain level of precision must be obtained to support subsequent applications, such as broadcasting or precise ephemeris calculations, thereby ensuring the successful subsequent operation of the navigation system. One of two ways to calculate the initial orbit of a GNSS satellite is to utilize ground tracking stations to observe satellite vector information in the geocentric inertial system; the second way is to utilize GNSS range observations and known orbit information from other satellites. For the second approach, some researchers use the Bancroft algorithm combined with receiver clock offset to determine the initial orbit of GNSS satellites. Because this method requires an additional known receiver clock offset, we study the dependence of the Bancroft algorithm on clock offset in GNSS orbit determination. By assessing the impact of errors of different magnitude on the accuracy of the orbit results, we obtain experimental conclusions. After comprehensively analyzing various errors, we determine the accuracy level that the Bancroft algorithm can achieve for orbit determination without considering receiver clock correction. Dual-frequency and single-frequency pseudorange data from IGS stations are used in orbit determination experiments. When a small receiver clock offset is considered and no correction is made, the deviations in the calculated satellite positions in three dimensions are approximately 979.3 and 1118.1 meters (dual and single frequency); with a satellite clock offset, these values are approximately 928.8 and 1062.7 meters (dual and single frequency).

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A modified stochastic model for LS+AR hybrid method and its application in polar motion short-term prediction

Ye,

Yuan

2024

Geodesy and Geodynamics

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Impact analysis of arc length in multi-GNSS ultra-rapid orbit determination based on the one-step method

Cited by 4 publications

References 23 publications

Improved Ultra-Rapid UT1-UTC Determination and Its Preliminary Impact on GNSS Satellite Ultra-Rapid Orbit Determination

Improved Ultra-Rapid UT1-UTC Determination and Its Preliminary Impact on GNSS Satellite Ultra-Rapid Orbit Determination

Analysis and improvement of the Bancroft algorithm for GNSS satellite orbit determination

A modified stochastic model for LS+AR hybrid method and its application in polar motion short-term prediction

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