Abstract
Abstract The revived interest of many countries and the growing number of ongoing and scheduled missions to the Moon increases the significance of supporting navigation system development. A number of publications are based on multi-Global Navigation Satellite System (GNSS) signal reception from the opposite side of the Earth using high-gain antennas and lunar augmentation constellations. While the accuracy of such systems could be sufficient, the positioning, navigation, and timing (PNT) service dependency on circumterestrial navigation sources prevents the use of advanced navigation technologies honed in circumlunar space for further Mars and other celestial body missions, which is one of the major goals of lunar exploration. Moreover, orbit determination and time synchronization (ODTS) method descriptions and estimations are usually skipped in the studies of lunar augmentations. An alternative concept of the Lunar Navigation Satellite System (LNSS) is proposed based on Earth-dependency reduction principal and on-board ODTS. The advantage of the proposed approach is that LNSS-like systems could be adapted for other celestial bodies taking into account aspects such as their shape, dynamics, perturbations, as well as exploration priority regions. The baseline LNSS constellation of three circular orbits with three satellites each has been chosen as the result of multicriterion analysis of orbital stability and geometry. Station keeping requires less than 15 m/s for 10 years without significant changes in navigation performance in the prioritized Polar Regions. The full cycle of LNSS operation from ODTS and signal generation to its reception, processing, and obtaining navigation solutions has been simulated to obtain positioning accuracy for different types of users. Positioning accuracy of space users in approach/departure phases, in near-lunar orbits, as well as static users on a lunar surface is confirmed on a level of a few tens of meters. The same accuracy is achievable by dynamic users on a lunar surface during route stops or also in motion in case of LNSS constellation expansion or deployment of ground-based augmentation beacons in on-site exploration zones.
Highlights
Ground-based radio facilities are traditionally used for deep space missions’ navigation
In the proposed Lunar Navigation Satellite System (LNSS) concept, the minimum onboard equipment of self-sufficient orbit determination and time synchronization (ODTS) is chosen to augment the intersatellite link (ISL) with the range measurements to the passive lunar reflectors left from the previous missions
Navigation signals broadcast by beacons should have different bands to avoid interference with LNSS satellites and should have time or frequency divisions to avoid interference within the beacon network, considering possible scenarios of strong distance and signal power differences from beacons in user receivers
Summary
Ground-based radio facilities are traditionally used for deep space missions’ navigation. One of the main goals of lunar exploration is the testing of key technologies for further Mars and other celestial body missions This requires the PNT data sources to be less dependent on Earth. In this case, augmentation systems should become a self-sufficient Lunar Navigation Satellite System (LNSS), based on on-board algorithms of orbit determination and time synchronization (ODTS), planning, and self-control. Augmentation systems should become a self-sufficient Lunar Navigation Satellite System (LNSS), based on on-board algorithms of orbit determination and time synchronization (ODTS), planning, and self-control The basics of such system were presented in 2012 (Bolkunov et al 2012) and after years of study in 2017–2020 the chosen LNSS concept was provided in a paper along with the simulation results.
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