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Enhancing the sensitivity of atom-interferometric inertial sensors using robust control

Author

Listed:
  • Jack C. Saywell

    (Q-CTRL)

  • Max S. Carey

    (Q-CTRL)

  • Philip S. Light

    (Q-CTRL)

  • Stuart S. Szigeti

    (Q-CTRL)

  • Alistair R. Milne

    (Q-CTRL)

  • Karandeep S. Gill

    (Q-CTRL)

  • Matthew L. Goh

    (Q-CTRL)

  • Viktor S. Perunicic

    (Q-CTRL)

  • Nathanial M. Wilson

    (Q-CTRL)

  • Calum D. Macrae

    (Q-CTRL)

  • Alexander Rischka

    (Q-CTRL)

  • Patrick J. Everitt

    (Q-CTRL)

  • Nicholas P. Robins

    (Q-CTRL)

  • Russell P. Anderson

    (Q-CTRL)

  • Michael R. Hush

    (Q-CTRL)

  • Michael J. Biercuk

    (Q-CTRL)

Abstract

Atom-interferometric quantum sensors could revolutionize navigation, civil engineering, and Earth observation. However, operation in real-world environments is challenging due to external interference, platform noise, and constraints on size, weight, and power. Here we experimentally demonstrate that tailored light pulses designed using robust control techniques mitigate significant error sources in an atom-interferometric accelerometer. To mimic the effect of unpredictable lateral platform motion, we apply laser-intensity noise that varies up to 20% from pulse-to-pulse. Our robust control solution maintains performant sensing, while the utility of conventional pulses collapses. By measuring local gravity, we show that our robust pulses preserve interferometer scale factor and improve measurement precision by 10× in the presence of this noise. We further validate these enhancements by measuring applied accelerations over a 200 μg range up to 21× more precisely at the highest applied noise level. Our demonstration provides a pathway to improved atom-interferometric inertial sensing in real-world settings.

Suggested Citation

  • Jack C. Saywell & Max S. Carey & Philip S. Light & Stuart S. Szigeti & Alistair R. Milne & Karandeep S. Gill & Matthew L. Goh & Viktor S. Perunicic & Nathanial M. Wilson & Calum D. Macrae & Alexander , 2023. "Enhancing the sensitivity of atom-interferometric inertial sensors using robust control," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-43374-0
    DOI: 10.1038/s41467-023-43374-0
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    References listed on IDEAS

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    1. Jongmin Lee & Roger Ding & Justin Christensen & Randy R. Rosenthal & Aaron Ison & Daniel P. Gillund & David Bossert & Kyle H. Fuerschbach & William Kindel & Patrick S. Finnegan & Joel R. Wendt & Micha, 2022. "A compact cold-atom interferometer with a high data-rate grating magneto-optical trap and a photonic-integrated-circuit-compatible laser system," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    2. R. Geiger & V. Ménoret & G. Stern & N. Zahzam & P. Cheinet & B. Battelier & A. Villing & F. Moron & M. Lours & Y. Bidel & A. Bresson & A. Landragin & P. Bouyer, 2011. "Detecting inertial effects with airborne matter-wave interferometry," Nature Communications, Nature, vol. 2(1), pages 1-7, September.
    3. T. Kovachy & P. Asenbaum & C. Overstreet & C. A. Donnelly & S. M. Dickerson & A. Sugarbaker & J. M. Hogan & M. A. Kasevich, 2015. "Quantum superposition at the half-metre scale," Nature, Nature, vol. 528(7583), pages 530-533, December.
    4. Y. Bidel & N. Zahzam & C. Blanchard & A. Bonnin & M. Cadoret & A. Bresson & D. Rouxel & M. F. Lequentrec-Lalancette, 2018. "Absolute marine gravimetry with matter-wave interferometry," Nature Communications, Nature, vol. 9(1), pages 1-9, December.
    5. Brynle Barrett & Laura Antoni-Micollier & Laure Chichet & Baptiste Battelier & Thomas Lévèque & Arnaud Landragin & Philippe Bouyer, 2016. "Dual matter-wave inertial sensors in weightlessness," Nature Communications, Nature, vol. 7(1), pages 1-9, December.
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