Characterization of heterodyne optical phase locking for relative laser frequency noise suppression in differential measurement

A. Kulur Ramamohan; S. S.Y. Chua; Y. Zhang; M. J. Yap; J. Wright; N. A. Holland; P. W.F. Forsyth; B. J.J. Slagmolen

doi:10.1364/OE.532797

Characterization of heterodyne optical phase locking for relative laser frequency noise suppression in differential measurement

A. Kulur Ramamohan^*, S. S.Y. Chua, Y. Zhang, M. J. Yap, J. Wright, N. A. Holland, P. W.F. Forsyth, B. J.J. Slagmolen

^*Corresponding author for this work

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

Abstract

Laser frequency noise is particularly challenging to mitigate in low Fourier frequency measurement. For differential measurement schemes using heterodyne optical phase-locked loops, this noise can be common-mode suppressed in the final readout while maintaining a flexible frequency offset and a large frequency-shift dynamic range. We demonstrate simultaneous optical phase-locked loops using digital servo systems, with up to 300 MHz offset frequency range, 250 dB open-loop gain at 0.1 Hz, and control timescales suitable for low-frequency measurement. We also detail a four-laser differential measurement intended for use in a precision measurement device that uses_ optical phase-locked loops, suppressing relative free-running noise to reach below 0.1 Hz/^√Hz at 0.1 Hz in the measurement readout.

Original language	English
Pages (from-to)	39793-39803
Number of pages	11
Journal	Optics Express
Volume	32
Issue number	22
DOIs	https://doi.org/10.1364/OE.532797
Publication status	Published - 21 Oct 2024

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title = "Characterization of heterodyne optical phase locking for relative laser frequency noise suppression in differential measurement",

abstract = "Laser frequency noise is particularly challenging to mitigate in low Fourier frequency measurement. For differential measurement schemes using heterodyne optical phase-locked loops, this noise can be common-mode suppressed in the final readout while maintaining a flexible frequency offset and a large frequency-shift dynamic range. We demonstrate simultaneous optical phase-locked loops using digital servo systems, with up to 300 MHz offset frequency range, 250 dB open-loop gain at 0.1 Hz, and control timescales suitable for low-frequency measurement. We also detail a four-laser differential measurement intended for use in a precision measurement device that uses_ optical phase-locked loops, suppressing relative free-running noise to reach below 0.1 Hz/√Hz at 0.1 Hz in the measurement readout.",

author = "Ramamohan, {A. Kulur} and Chua, {S. S.Y.} and Y. Zhang and Yap, {M. J.} and J. Wright and Holland, {N. A.} and Forsyth, {P. W.F.} and Slagmolen, {B. J.J.}",

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AU - Ramamohan, A. Kulur

AU - Chua, S. S.Y.

AU - Zhang, Y.

AU - Yap, M. J.

AU - Wright, J.

AU - Holland, N. A.

AU - Forsyth, P. W.F.

AU - Slagmolen, B. J.J.

PY - 2024/10/21

Y1 - 2024/10/21

N2 - Laser frequency noise is particularly challenging to mitigate in low Fourier frequency measurement. For differential measurement schemes using heterodyne optical phase-locked loops, this noise can be common-mode suppressed in the final readout while maintaining a flexible frequency offset and a large frequency-shift dynamic range. We demonstrate simultaneous optical phase-locked loops using digital servo systems, with up to 300 MHz offset frequency range, 250 dB open-loop gain at 0.1 Hz, and control timescales suitable for low-frequency measurement. We also detail a four-laser differential measurement intended for use in a precision measurement device that uses_ optical phase-locked loops, suppressing relative free-running noise to reach below 0.1 Hz/√Hz at 0.1 Hz in the measurement readout.

AB - Laser frequency noise is particularly challenging to mitigate in low Fourier frequency measurement. For differential measurement schemes using heterodyne optical phase-locked loops, this noise can be common-mode suppressed in the final readout while maintaining a flexible frequency offset and a large frequency-shift dynamic range. We demonstrate simultaneous optical phase-locked loops using digital servo systems, with up to 300 MHz offset frequency range, 250 dB open-loop gain at 0.1 Hz, and control timescales suitable for low-frequency measurement. We also detail a four-laser differential measurement intended for use in a precision measurement device that uses_ optical phase-locked loops, suppressing relative free-running noise to reach below 0.1 Hz/√Hz at 0.1 Hz in the measurement readout.

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Characterization of heterodyne optical phase locking for relative laser frequency noise suppression in differential measurement

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