Developments Toward a Disciplined Timekeeping System for Lunar and Planetary Navigation

Abstract: The future of both lunar and planetary missions will involve the use of an increasing number of orbiters, landers and robotic rovers with ever expanding objectives over greater land area range. The coordination of these individual assets into a system capable of supporting complex exploration activities will necessarily require a local timekeeping system able to directly assist navigation, event synchronization and trunk communication back to Earth.The Johns Hopkins University Applied Physics Laboratory (JHU/A… Show more

“…Our research into USO-based timekeeping shows that incorporating an in-situ control system for removing USO deterministic frequency drift and error bias, based on a multi-variance method with a Bayesian maximum likelihood estimator (MLE) process, should mitigate post-processing dependency and enhance local navigation autonomy. This work is a continuation of the work presented in [7] and showed, through simulation with archived USO test data, a possible 1000 fold improvement of USO timekeeping performance of < 1 μs over 30 to 70 days of autonomous operation (no ground clock update).…”

“…The composite clock architecture is entirely similar to the system described in Fig. 10 of [7]. In fact, the method for atomic frequency discrimination used in the CSAC is based on coherent population trapping, as also described in [7].…”

Composite USO/CSAC timekeeping system

“…Our research into USO-based timekeeping shows that incorporating an in-situ control system for removing USO deterministic frequency drift and error bias, based on a multi-variance method with a Bayesian maximum likelihood estimator (MLE) process, should mitigate post-processing dependency and enhance local navigation autonomy. This work is a continuation of the work presented in [7] and showed, through simulation with archived USO test data, a possible 1000 fold improvement of USO timekeeping performance of < 1 μs over 30 to 70 days of autonomous operation (no ground clock update).…”

“…The composite clock architecture is entirely similar to the system described in Fig. 10 of [7]. In fact, the method for atomic frequency discrimination used in the CSAC is based on coherent population trapping, as also described in [7].…”

Composite USO/CSAC timekeeping system

“…Accurate position and time estimates are important for a variety of smallsat missions. Examples of missions, which require high performance timekeeping, are deep space missions using one‐way ranging (Imken et al., 2017; Wallis et al., 2005; Weaver & Kantsiper, 2007), small satellite constellations functioning as sensor arrays for astronomy (Engelen et al., 2013; Rajan et al., 2015), low Earth orbit (LEO) constellations for Global Positioning System (GPS) augmentation and improved positioning (Ge et al., 2018; Reid et al., 2018), and Earth observation missions which require accurate position and time information for imagery and science data.…”

A low complexity smoothing algorithm for improved GPS point solutions on board LEO spacecraft

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