Kalman-Filter Based Hybridization of Classic and Cold Atom Interferometry Accelerometers for Future Satellite Gravity Missions

HosseiniArani, Alireza; Tennstedt, Benjamin; Schilling, Manuel; Knabe, Annike; Wu, Hu; Schön, Steffen; Müller, Jürgen

doi:10.1007/1345_2022_172

Cited by 2 publications

(1 citation statement)

References 28 publications

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“…In general, the combined solution benefits from the superior long-term stability of the CAI, as discussed in . This solution was further evaluated for applications on low Earth orbit satellites (HosseiniArani et al, 2022), where the electrostatic accelerometer in use has a lower white noise density than the CAI, but a larger long-term drift.…”

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Atom Strapdown: Toward Integrated Quantum Inertial Navigation Systems

Tennstedt

Rajagopalan

Weddig

et al. 2023

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Atom interferometry is a highly precise technique for inertial sensing (Kasevich et al., 1991). By interrogating a free-evolving atom wave packet with a series of laser pulses, information about accelerations and turn rates can be extracted, allowing the calculation of a complete navigation solution (position, velocity, and attitude). Applications of this technique for accelerometers (Barrett et al., 2014), gyroscopes (Gauguet et al., 2009;Schubert et al., 2021), and complete inertial measurement units (IMUs) (Gebbe et al., 2021;Gersemann et al., 2020) based on Bose-Einstein condensates are currently under research. The potential position accuracy reaches 5 m after 1 h of inertial navigation (Jekeli, 2005), which makes atom interferometry a highly promising technique for navigation in global navigation satellite system (GNSS)-denied environments.Commercial options are already available for static settings, i.e., quantum gravimeters (Vermeulen et al., 2018), and have an accuracy and long-term stability comparable or even superior to those of other high-end conventional sensors

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confidence: 99%

Atom Strapdown: Toward Integrated Quantum Inertial Navigation Systems

Tennstedt

Rajagopalan

Weddig

et al. 2023

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Analysis of Novel Sensors and Satellite Formation Flights for Future Gravimetry Missions

Kupriyanov,

Reis,

Knabe

et al. 2024

International Association of Geodesy Symposia

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Accelerometers (ACCs) in low-low satellite-to-satellite gravimetry missions measure the non-gravitational forces acting on the spacecraft that have to be taken into account to derive the gravitational contribution in the distance variations. Multiple ACCs form a so-called gradiometer that measure the gravity gradient. In satellite gravimetry up to now, only electrostatic ACCs were used, which are one of the main instrumental limitations due to their error contribution at low frequencies, known as drift.In this paper, we compare the performance of electrostatic ACCs at low Earth orbits with other sensors, i.e. so-called Optical ACCs based on flight heritage of the LISA-Pathfinder mission, and theoretical ACC concepts, for example Cold Atom Interferometer (CAI) ACCs and hybridized sensors (combination of electrostatic and CAI ACCs) in terms of static gravity field recovery. Under our assumptions, in particular that high-frequency variations of the gravity field can be perfectly modeled and removed during gravity field recovery, the results may be limited in the future by the performance of the LRI.We also discuss the outcomes from the various novel satellite formation flights (SFF) that utilize two orbits that differ either by right ascension of the ascending node (RAAN) or by inclination in order to acquire ranging information in the cross-track direction. The closed-loop simulations from both scenarios showed significantly lower order of magnitude of the residuals w.r.t. reference gravity field than from the anticipated future performance of the solely in-line GRACE-like satellite pair. Moreover, these triple satellite formations provide better multi-directionality of the retrieved data, avoiding the North-South striping behavior. However, it is worth noting that in such formations significant modifications are needed in the satellite bus, ACC test mass readout, LRI beam steering mechanism, etc. in order to be capable of measuring the cross-track range changes at higher range rates w.r.t. in-line GRACE-like configuration. In addition, a substantial reduction of costs in building and launching only three satellites rather than four as in double-pair constellations could be an advantage for such formations.

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Kalman-Filter Based Hybridization of Classic and Cold Atom Interferometry Accelerometers for Future Satellite Gravity Missions

Cited by 2 publications

References 28 publications

Atom Strapdown: Toward Integrated Quantum Inertial Navigation Systems

Atom Strapdown: Toward Integrated Quantum Inertial Navigation Systems

Analysis of Novel Sensors and Satellite Formation Flights for Future Gravimetry Missions

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