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Published April 15, 2025 | Supplemental material
Journal Article Open

Experimental and on-sky demonstration of spectrally dispersed wavefront sensing using a photonic lantern

Lin, Jonathan1 ORCID icon
Fitzgerald, Michael P.1 ORCID icon
Xin, Yinzi2 ORCID icon
Jung Kim, Yoo1 ORCID icon
Guyon, Olivier3, 4 ORCID icon
Norris, Barnaby5 ORCID icon
Betters, Christopher6 ORCID icon
Leon-Saval, Sergio6 ORCID icon
Ahn, Kyohoon3, 7 ORCID icon
Deo, Vincent3 ORCID icon
Lozi, Julien3 ORCID icon
Vievard, Sébastien3 ORCID icon
Levinstein, Daniel8
Sallum, Steph8 ORCID icon
Jovanovic, Nemanja2 ORCID icon
  • 1. ROR icon University of California, Los Angeles
  • 2. ROR icon California Institute of Technology
  • 3. ROR icon National Astronomical Observatory of Japan
  • 4. ROR icon University of Arizona
  • 5. Sydney Institute for Astronomy
  • 6. ROR icon University of Sydney
  • 7. ROR icon Korea Astronomy and Space Science Institute
  • 8. ROR icon University of California System

Abstract

Adaptive optics (AO) systems are critical in any application where highly resolved imaging or beam control must be performed through a dynamic medium. Such applications include astronomy and free-space optical communications, where light propagates through the atmosphere, as well as medical microscopy and vision science, where light propagates through biological tissues. Recent works have demonstrated common-path wavefront sensors (WFSs) for adaptive optics using the photonic lantern (PL), a slowly varying waveguide that can efficiently couple multi-moded light into single-mode fibers (SMFs). We use the SCExAO astrophotonics platform at the 8 m Subaru Telescope to show that spectral dispersion of lantern outputs can improve correction fidelity, culminating with an on-sky demonstration of real-time wavefront control. This is the first, to the best of our knowledge, result for either a spectrally dispersed or a photonic lantern wavefront sensor. Combined with the benefits offered by lanterns in precision spectroscopy, our results suggest the future possibility of a unified wavefront sensing spectrograph using compact photonic devices.

Copyright and License (English)

© 2025 Optica Publishing Group. All rights, including for text and data mining (TDM), Artificial Intelligence (AI) training, and similar technologies, are reserved.

Acknowledgement (English)

The authors would like to thank S. Cunningham, who supported this work as the Subaru Telescope operator. The authors wish to recognize and acknowledge the very significant cultural role and reverence that the summit of Maunakea has always had within the indigenous Hawaiian community and are most fortunate to have the opportunity to conduct observations from this mountain.

Supplemental Material

Supplemental document on experimental setup, software tools used, and calibration process.
Supplement 1: https://doi.org/10.6084/m9.figshare.28650392

Funding

National Science Foundation (DGE-203483, 2109231, 2109232, 2308360, 2308361); Japan Society for the Promotion of Science (23340051, 26220704, 23103002, 19H00703, 19H00695).

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July 15, 2025
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July 15, 2025