Incorporating an Optical Clock into a Time Scale

Jian Yao; Thomas E. Parker; Neil Ashby; Judah Levine

doi:10.1109/TUFFC.2017.2773530

Incorporating an Optical Clock into a Time Scale

Jian Yao, Thomas E. Parker, Neil Ashby, Judah Levine

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

24 Scopus citations

Abstract

This paper discusses the results of a simulation of a time scale based on continuously operating commercial hydrogen masers and an optical frequency standard that does not operate continuously as a clock. The simulation compares the performance of this time scale with one that is based on the same commercial devices but incorporates a continuously operating cesium fountain instead of the optical standard. The results are independent of the detailed characteristics of the optical frequency standard; the only requirement is that the optical device be much more stable than the masers in the ensemble. We discuss two methods for realizing the results of this simulation in an operational time scale.

Original language	English
Article number	8107555
Pages (from-to)	127-134
Number of pages	8
Journal	IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control
Volume	65
Issue number	1
DOIs	https://doi.org/10.1109/TUFFC.2017.2773530
State	Published - Jan 2018
Externally published	Yes

Keywords

Cs fountain
Kalman filter
hydrogen maser
optical clock
time scale

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10.1109/TUFFC.2017.2773530

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title = "Incorporating an Optical Clock into a Time Scale",

abstract = "This paper discusses the results of a simulation of a time scale based on continuously operating commercial hydrogen masers and an optical frequency standard that does not operate continuously as a clock. The simulation compares the performance of this time scale with one that is based on the same commercial devices but incorporates a continuously operating cesium fountain instead of the optical standard. The results are independent of the detailed characteristics of the optical frequency standard; the only requirement is that the optical device be much more stable than the masers in the ensemble. We discuss two methods for realizing the results of this simulation in an operational time scale.",

keywords = "Cs fountain, Kalman filter, hydrogen maser, optical clock, time scale",

author = "Jian Yao and Parker, \{Thomas E.\} and Neil Ashby and Judah Levine",

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AU - Ashby, Neil

AU - Levine, Judah

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N2 - This paper discusses the results of a simulation of a time scale based on continuously operating commercial hydrogen masers and an optical frequency standard that does not operate continuously as a clock. The simulation compares the performance of this time scale with one that is based on the same commercial devices but incorporates a continuously operating cesium fountain instead of the optical standard. The results are independent of the detailed characteristics of the optical frequency standard; the only requirement is that the optical device be much more stable than the masers in the ensemble. We discuss two methods for realizing the results of this simulation in an operational time scale.

AB - This paper discusses the results of a simulation of a time scale based on continuously operating commercial hydrogen masers and an optical frequency standard that does not operate continuously as a clock. The simulation compares the performance of this time scale with one that is based on the same commercial devices but incorporates a continuously operating cesium fountain instead of the optical standard. The results are independent of the detailed characteristics of the optical frequency standard; the only requirement is that the optical device be much more stable than the masers in the ensemble. We discuss two methods for realizing the results of this simulation in an operational time scale.

KW - Cs fountain

KW - Kalman filter

KW - hydrogen maser

KW - optical clock

KW - time scale

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Incorporating an Optical Clock into a Time Scale

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Keywords

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