Hardware simulation of real-time wavelength corrected phase projection

Paul G. Sibley; Noah Baldwin; Michael J. Ireland; Chathura P. Bandutunga

doi:10.1364/AO.540085

Hardware simulation of real-time wavelength corrected phase projection

Paul G. Sibley^*, Noah Baldwin, Michael J. Ireland, Chathura P. Bandutunga

^*Corresponding author for this work

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

Abstract

We demonstrate the real-time signal processing operation of a dispersion-free phase projection algorithm intended for atmospheric correction of multi-aperture optical phased arrays. It uses interferometric phase measurements at multiple sensing wavelengths, offset by 50 GHz, to compute a phase correction at a third, remote wavelength. This is useful where phase sensing cannot be implemented at the wavelength of interest, enabling interferometric level control from wavelength offset targeting beacons or guidestars. The digital signal processing implementation we demonstrate has a residual temporal phase error of 4 × 10^-4 rad/√Hz while being capable of 100 MHz throughput with 0.53 µs latency, making it a viable approach for either feedback or feed-forward atmospheric correction in segmented piston-phase control systems.

Original language	English
Pages (from-to)	8951-8958
Number of pages	8
Journal	Applied Optics
Volume	63
Issue number	35
DOIs	https://doi.org/10.1364/AO.540085
Publication status	Published - 10 Dec 2024

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title = "Hardware simulation of real-time wavelength corrected phase projection",

abstract = "We demonstrate the real-time signal processing operation of a dispersion-free phase projection algorithm intended for atmospheric correction of multi-aperture optical phased arrays. It uses interferometric phase measurements at multiple sensing wavelengths, offset by 50 GHz, to compute a phase correction at a third, remote wavelength. This is useful where phase sensing cannot be implemented at the wavelength of interest, enabling interferometric level control from wavelength offset targeting beacons or guidestars. The digital signal processing implementation we demonstrate has a residual temporal phase error of 4 × 10-4 rad/√Hz while being capable of 100 MHz throughput with 0.53 µs latency, making it a viable approach for either feedback or feed-forward atmospheric correction in segmented piston-phase control systems.",

author = "Sibley, {Paul G.} and Noah Baldwin and Ireland, {Michael J.} and Bandutunga, {Chathura P.}",

note = "Publisher Copyright: {\textcopyright} 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.",

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AU - Sibley, Paul G.

AU - Baldwin, Noah

AU - Ireland, Michael J.

AU - Bandutunga, Chathura P.

PY - 2024/12/10

Y1 - 2024/12/10

N2 - We demonstrate the real-time signal processing operation of a dispersion-free phase projection algorithm intended for atmospheric correction of multi-aperture optical phased arrays. It uses interferometric phase measurements at multiple sensing wavelengths, offset by 50 GHz, to compute a phase correction at a third, remote wavelength. This is useful where phase sensing cannot be implemented at the wavelength of interest, enabling interferometric level control from wavelength offset targeting beacons or guidestars. The digital signal processing implementation we demonstrate has a residual temporal phase error of 4 × 10-4 rad/√Hz while being capable of 100 MHz throughput with 0.53 µs latency, making it a viable approach for either feedback or feed-forward atmospheric correction in segmented piston-phase control systems.

AB - We demonstrate the real-time signal processing operation of a dispersion-free phase projection algorithm intended for atmospheric correction of multi-aperture optical phased arrays. It uses interferometric phase measurements at multiple sensing wavelengths, offset by 50 GHz, to compute a phase correction at a third, remote wavelength. This is useful where phase sensing cannot be implemented at the wavelength of interest, enabling interferometric level control from wavelength offset targeting beacons or guidestars. The digital signal processing implementation we demonstrate has a residual temporal phase error of 4 × 10-4 rad/√Hz while being capable of 100 MHz throughput with 0.53 µs latency, making it a viable approach for either feedback or feed-forward atmospheric correction in segmented piston-phase control systems.

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EP - 8958

JO - Applied Optics

JF - Applied Optics

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Hardware simulation of real-time wavelength corrected phase projection

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