Improving measurement performance via fusion of classical and quantum accelerometers

Xuezhi Wang; Allison Kealy; Christopher Gilliam; Simon Haine; John Close; Bill Moran; Kyle Talbot; Simon Williams; Kyle Hardman; Chris Freier; Paul Wigley; Angela White; Stuart Szigeti; Sam Legge

doi:10.1017/S0373463322000637

Improving measurement performance via fusion of classical and quantum accelerometers

Xuezhi Wang^*, Allison Kealy, Christopher Gilliam, Simon Haine, John Close, Bill Moran, Kyle Talbot, Simon Williams, Kyle Hardman, Chris Freier, Paul Wigley, Angela White, Stuart Szigeti, Sam Legge

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

While quantum accelerometers sense with extremely low drift and low bias, their practical sensing capabilities face at least two limitations compared with classical accelerometers: a lower sample rate due to cold atom interrogation time; and a reduced dynamic range due to signal phase wrapping. In this paper, we propose a maximum likelihood probabilistic data fusion method, under which the actual phase of the quantum accelerometer can be unwrapped by fusing it with the output of a classical accelerometer on the platform. Consequently, the recovered measurement from the quantum accelerometer is used to estimate bias and drift of the classical accelerometer which is then removed from the system output. We demonstrate the enhanced error performance achieved by the proposed fusion method using a simulated 1D accelerometer precision test scenario. We conclude with a discussion on fusion error and potential solutions.

Original language	English
Article number	The Journal of Navigation (2023), 76
Pages (from-to)	91-102
Number of pages	12
Journal	Journal of Navigation
Volume	76
Issue number	1
DOIs	https://doi.org/10.1017/S0373463322000637
Publication status	Published - 26 Jan 2023

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Wang, X., Kealy, A., Gilliam, C., Haine, S., Close, J., Moran, B., Talbot, K., Williams, S., Hardman, K., Freier, C., Wigley, P., White, A., Szigeti, S., & Legge, S. (2023). Improving measurement performance via fusion of classical and quantum accelerometers. Journal of Navigation, 76(1), 91-102. Article The Journal of Navigation (2023), 76. https://doi.org/10.1017/S0373463322000637

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title = "Improving measurement performance via fusion of classical and quantum accelerometers",

abstract = "While quantum accelerometers sense with extremely low drift and low bias, their practical sensing capabilities face at least two limitations compared with classical accelerometers: a lower sample rate due to cold atom interrogation time; and a reduced dynamic range due to signal phase wrapping. In this paper, we propose a maximum likelihood probabilistic data fusion method, under which the actual phase of the quantum accelerometer can be unwrapped by fusing it with the output of a classical accelerometer on the platform. Consequently, the recovered measurement from the quantum accelerometer is used to estimate bias and drift of the classical accelerometer which is then removed from the system output. We demonstrate the enhanced error performance achieved by the proposed fusion method using a simulated 1D accelerometer precision test scenario. We conclude with a discussion on fusion error and potential solutions.",

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note = "Publisher Copyright: Copyright {\textcopyright} The Author(s), 2023. Published by Cambridge University Press on behalf of The Royal Institute of Navigation.",

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Wang, X, Kealy, A, Gilliam, C, Haine, S , Close, J, Moran, B, Talbot, K, Williams, S, Hardman, K, Freier, C, Wigley, P, White, A, Szigeti, S & Legge, S 2023, 'Improving measurement performance via fusion of classical and quantum accelerometers', Journal of Navigation, vol. 76, no. 1, The Journal of Navigation (2023), 76, pp. 91-102. https://doi.org/10.1017/S0373463322000637

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T1 - Improving measurement performance via fusion of classical and quantum accelerometers

AU - Wang, Xuezhi

AU - Kealy, Allison

AU - Gilliam, Christopher

AU - Haine, Simon

AU - Close, John

AU - Moran, Bill

AU - Talbot, Kyle

AU - Williams, Simon

AU - Hardman, Kyle

AU - Freier, Chris

AU - Wigley, Paul

AU - White, Angela

AU - Szigeti, Stuart

AU - Legge, Sam

PY - 2023/1/26

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N2 - While quantum accelerometers sense with extremely low drift and low bias, their practical sensing capabilities face at least two limitations compared with classical accelerometers: a lower sample rate due to cold atom interrogation time; and a reduced dynamic range due to signal phase wrapping. In this paper, we propose a maximum likelihood probabilistic data fusion method, under which the actual phase of the quantum accelerometer can be unwrapped by fusing it with the output of a classical accelerometer on the platform. Consequently, the recovered measurement from the quantum accelerometer is used to estimate bias and drift of the classical accelerometer which is then removed from the system output. We demonstrate the enhanced error performance achieved by the proposed fusion method using a simulated 1D accelerometer precision test scenario. We conclude with a discussion on fusion error and potential solutions.

AB - While quantum accelerometers sense with extremely low drift and low bias, their practical sensing capabilities face at least two limitations compared with classical accelerometers: a lower sample rate due to cold atom interrogation time; and a reduced dynamic range due to signal phase wrapping. In this paper, we propose a maximum likelihood probabilistic data fusion method, under which the actual phase of the quantum accelerometer can be unwrapped by fusing it with the output of a classical accelerometer on the platform. Consequently, the recovered measurement from the quantum accelerometer is used to estimate bias and drift of the classical accelerometer which is then removed from the system output. We demonstrate the enhanced error performance achieved by the proposed fusion method using a simulated 1D accelerometer precision test scenario. We conclude with a discussion on fusion error and potential solutions.

KW - maximum likelihood estimation

KW - phase unwrapping

KW - quantum accelerometer

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Improving measurement performance via fusion of classical and quantum accelerometers

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