Weak-light phase tracking with a low cycle slip rate

Samuel P. Francis; Timothy T.Y. Lam; Kirk McKenzie; Andrew J. Sutton; Robert L. Ward; David E. McClelland; Daniel A. Shaddock

doi:10.1364/OL.39.005251

Weak-light phase tracking with a low cycle slip rate

Samuel P. Francis^*, Timothy T.Y. Lam, Kirk McKenzie, Andrew J. Sutton, Robert L. Ward, David E. McClelland, Daniel A. Shaddock

^*Corresponding author for this work

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

32 Citations (Scopus)

Abstract

The Gravity Recovery and Climate Experiment Follow-On mission will use a phase-locked loop to track changes in the phase of an optical signal that has been transmitted hundreds of kilometers between two spacecraft. Beam diffraction significantly reduces the received signal power, making it difficult to track, as the phase-locked loop is more susceptible to cycle slips. The lowest reported weak-light phase locking is at 40 fW with a cycle slip rate of 1 cycle per second. By selecting a phase-locked loop bandwidth that minimized the signal variance due to shot noise and laser phase fluctuations, a 30 fW signal has been tracked with a cycle slip rate less than 0.01 cycles per second. This is tracking at a power 25% lower with a 100-fold improvement in the cycle slip rate. This capability will enable a new class of missions, opening up new opportunities for space-based interferometry.

Original language	English
Pages (from-to)	5251-5254
Number of pages	4
Journal	Optics Letters
Volume	39
Issue number	18
DOIs	https://doi.org/10.1364/OL.39.005251
Publication status	Published - 15 Sept 2014

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title = "Weak-light phase tracking with a low cycle slip rate",

abstract = "The Gravity Recovery and Climate Experiment Follow-On mission will use a phase-locked loop to track changes in the phase of an optical signal that has been transmitted hundreds of kilometers between two spacecraft. Beam diffraction significantly reduces the received signal power, making it difficult to track, as the phase-locked loop is more susceptible to cycle slips. The lowest reported weak-light phase locking is at 40 fW with a cycle slip rate of 1 cycle per second. By selecting a phase-locked loop bandwidth that minimized the signal variance due to shot noise and laser phase fluctuations, a 30 fW signal has been tracked with a cycle slip rate less than 0.01 cycles per second. This is tracking at a power 25% lower with a 100-fold improvement in the cycle slip rate. This capability will enable a new class of missions, opening up new opportunities for space-based interferometry.",

author = "Francis, {Samuel P.} and Lam, {Timothy T.Y.} and Kirk McKenzie and Sutton, {Andrew J.} and Ward, {Robert L.} and McClelland, {David E.} and Shaddock, {Daniel A.}",

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T1 - Weak-light phase tracking with a low cycle slip rate

AU - Francis, Samuel P.

AU - Lam, Timothy T.Y.

AU - McKenzie, Kirk

AU - Sutton, Andrew J.

AU - Ward, Robert L.

AU - McClelland, David E.

AU - Shaddock, Daniel A.

PY - 2014/9/15

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N2 - The Gravity Recovery and Climate Experiment Follow-On mission will use a phase-locked loop to track changes in the phase of an optical signal that has been transmitted hundreds of kilometers between two spacecraft. Beam diffraction significantly reduces the received signal power, making it difficult to track, as the phase-locked loop is more susceptible to cycle slips. The lowest reported weak-light phase locking is at 40 fW with a cycle slip rate of 1 cycle per second. By selecting a phase-locked loop bandwidth that minimized the signal variance due to shot noise and laser phase fluctuations, a 30 fW signal has been tracked with a cycle slip rate less than 0.01 cycles per second. This is tracking at a power 25% lower with a 100-fold improvement in the cycle slip rate. This capability will enable a new class of missions, opening up new opportunities for space-based interferometry.

AB - The Gravity Recovery and Climate Experiment Follow-On mission will use a phase-locked loop to track changes in the phase of an optical signal that has been transmitted hundreds of kilometers between two spacecraft. Beam diffraction significantly reduces the received signal power, making it difficult to track, as the phase-locked loop is more susceptible to cycle slips. The lowest reported weak-light phase locking is at 40 fW with a cycle slip rate of 1 cycle per second. By selecting a phase-locked loop bandwidth that minimized the signal variance due to shot noise and laser phase fluctuations, a 30 fW signal has been tracked with a cycle slip rate less than 0.01 cycles per second. This is tracking at a power 25% lower with a 100-fold improvement in the cycle slip rate. This capability will enable a new class of missions, opening up new opportunities for space-based interferometry.

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Weak-light phase tracking with a low cycle slip rate

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