Abstract

Positioning of spacecraft (e.g., geostationary orbit (GEO), high elliptical orbit (HEO), and lunar trajectory) is crucial for mission completion. Instead of using ground control systems, global navigation satellite system (GNSS) can be an effective approach to provide positioning, navigation and timing service for spacecraft. In 2020, China finished the construction of the third generation of BeiDou navigation satellite system (BDS-3); this global coverage system will contribute better sidelobe signal visibility for spacecraft. Meanwhile, with more than 100 GNSS satellites, multi-GNSS navigation performance on the spacecraft is worth studying. In this paper, instead of using signal-in-space ranging errors, we simulate pseudorange observations with measurement noises varying with received signal powers. Navigation performances of BDS-3 and its combinations with other systems were conducted. Results showed that, owing to GEO and inclined geosynchronous orbit (IGSO) satellites, all three types (GEO, HEO, and lunar trajectory) of spacecraft received more signals from BDS-3 than from other navigation systems. Single point positioning (SPP) accuracy of the GEO and HEO spacecraft was 17.7 and 23.1 m, respectively, with BDS-3 data alone. Including the other three systems, i.e., GPS, Galileo, and GLONASS, improved the SPP accuracy by 36.2% and 19.9% for GEO and HEO, respectively. Navigation performance of the lunar probe was significantly improved when receiver sensitivity increased from 20 dB-Hz to 15 dB-Hz. Only dual- (BDS-3/GPS) or multi-GNSS (BDS-3, GPS, Galileo, GLONASS) could provide continuous navigation solutions with a receiver threshold of 15 dB-Hz.

Highlights

  • Accepted: 9 January 2022Global navigation satellite system (GNSS)-based real-time navigation for spacecraft is expected to increase satellite autonomy and ensure continuous navigation solutions [1,2].This approach has been widely used for low earth orbit (LEO) satellites, where rich global navigation satellite system (GNSS) signals can be received since its altitude is lower than GNSS orbit [3,4]

  • Navigation performance of the lunar probe was significantly improved when receiver sensitivity increased from 20 dB-Hz to 15 dB-Hz

  • Conclusions pseudorange observations were simulated for three classical types of orbits, including geostationary orbit (GEO), explore navigation performance of BeiDou navigation satellite System (BDS)-3 and the contribution of multi-GNSS, HEOTo and lunarthe trajectory

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Summary

Introduction

Global navigation satellite system (GNSS)-based real-time navigation for spacecraft is expected to increase satellite autonomy and ensure continuous navigation solutions [1,2]. This approach has been widely used for low earth orbit (LEO) satellites, where rich GNSS signals can be received since its altitude is lower than GNSS orbit [3,4]. With the increasing interest in the Earth’s space science and lunar exploration, extending the use of GNSSbased navigation for satellites whose altitudes are higher than GNSS has drawn attention. In 2018, the International Committee on Global Navigation Satellite Systems (ICG) Working Group-B (WG-B) officially released the booklet named “The Interoperable Global Navigation Satellite Systems Space Service

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