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Session F3a: Lunar Positioning, Navigation, and Timing

Autonomous Navigation of a Lunar Relay Using GNSS and Other Measurements
Benjamin W. Ashman, Luke B. Winternitz, Nathan I. Stacey, NASA Goddard Space Flight Center; Anne C. Long, Michael C. Schmidt, a.i. solutions, Inc.; Grant A. Ryden, Andrew J. Liounis, Samuel R. Price, NASA Goddard Space Flight Center; William A. Bamford, Relative Dynamics, Inc.; Sun H. Hur-Diaz, Munther A. Hassouneh, NASA Goddard Space Flight Center; Liam A. Greenlee, Aurora Engineering
Date/Time: Thursday, Sep. 19, 9:20 a.m.

NASA’s Lunar Communications Relay and Navigation Systems (LCRNS) project will establish a relay constellation at the Moon to provide the south pole region with communications and position, navigation, and time (PNT) services. These services will require highly accurate knowledge of position, velocity, and time (PVT) for each relay. This paper explores one approach for performing onboard PVT estimation, the LCRNS PNT Instrument (LPI). This paper considers different configurations of the instrument, specifically different measurement types and clocks, and the resulting navigation performance. Simulation results are first shown for an instrument configuration that uses GPS pseudorange and Doppler measurements with a highly sensitive GPS receiver (i.e., an acquisition and tracking threshold of 23 dB-Hz) and a chip-scale atomic clock (CSAC). The importance of Doppler, clock quality, receiver sensitivity, and optical navigation is examined through comparison of these results to other instrument configurations. Clock quality (i.e., stability) is the strongest determinant of achievable performance, and the inclusion of GPS Doppler also has a significant effect. Finally, simulation results are compared to two laboratory tests: first a case that includes GPS receiver hardware in the loop, then a case that includes optical navigation and filter flight software in the loop. These agree closely with the simulation results and provide evidence the simulation is accurately modeling the instrument under development.



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