Remote atomic clock synchronization via satellites and optical fibers

Piester, D.; Rost, M.; Fujieda, Miho; Feldmann, Thorsten; Bauch, A.

doi:10.5194/ars-9-1-2011

Cited by 44 publications

(24 citation statements)

References 15 publications

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“…It is based on a frequency comparison between two remote optical clocks via optical fibers (see Sec. III.B) or free-space microwave (Salomon et al, 2001Levine, 2008Piester et al, 2011;Delva et al, 2012;Fujieda et al, 2014) or optical (Fujiwara et al, 2007;Djerroud et al, 2010;Exertier et al, 2013;Giorgetta et al, 2013) satellite links to provide a direct height difference measurement between two remote locations. Alternatively, a mobile clock (operating during transport) together with careful modeling of its speed and geopotential trajectory can be used.…”

Section: Optical Clocks For Geodetic Applicationsmentioning

confidence: 99%

Optical atomic clocks

et al. 2015

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Optical atomic clocks represent the state of the art in the frontier of modern measurement science. In this article a detailed review on the development of optical atomic clocks that are based on trapped single ions and many neutral atoms is provided. Important technical ingredients for optical clocks are discussed and measurement precision and systematic uncertainty associated with some of the best clocks to date are presented. An outlook on the exciting prospect for clock applications is given in conclusion.

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Section: Optical Clocks For Geodetic Applicationsmentioning

confidence: 99%

Optical atomic clocks

et al. 2015

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“…In these applications, the local optical time scale would be either compared against or synchronized to a distant time scale via terrestrial or satellite free-space links. Existing rf-based techniques can support time transfer over free-space links but are limited to 10-to 100-ps accuracy and ∼1-ps stability, 100 to 1000 times worse than optical oscillators [21][22][23]. The highest performance rf system to date is planned for the ACES mission and will support 300-fs timing stability at 300-s integration and <6-ps timing stability over days from ground to space [24,25].…”

Section: Introductionmentioning

confidence: 99%

Synchronization of Distant Optical Clocks at the Femtosecond Level

et al. 2016

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The use of optical clocks or oscillators in future ultraprecise navigation, gravitational sensing, coherent arrays, and relativity experiments will require time comparison and synchronization over terrestrial or satellite free-space links. Here, we demonstrate full unambiguous synchronization of two optical time scales across a free-space link. The time deviation between synchronized time scales is below 1 fs over durations from 0.1 to 6500 s, despite atmospheric turbulence and kilometer-scale path length variations. Over 2 days, the time wander is 40 fs peak to peak. Our approach relies on the two-way reciprocity of a single-spatial-mode optical link, valid to below 225 attoseconds across a turbulent 4-km path. This femtosecond level of time-frequency transfer should enable optical networks using state-of-the-art optical clocks or oscillators.

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“…Frequency synchronization is also required by mobile system to facilitate handover between base stations and meet the regulatory requirement [12]. Currently, the base stations are usually equipped with the global navigation satellite system (GNSS) equipment, which can support sub-microsecond accuracy for general receivers [13], and reach a accuracy of less than 5 ns with respect to UTC with dual-frequency receivers for time-keeping purposes [14]. Although most synchronization requirements can be easily satisfied by using GNSS signals, the reception of GNSS antenna needs a good view of sky.…”

Section: Evolving Telecom Synchronization Networkmentioning

confidence: 99%

Precise UTC dissemination through future telecom synchronization networks

Tseng

Siu

Lin

et al. 2015

2015 Joint Conference of the IEEE International Frequency Control Symposium &Amp; The European Frequency and Time Forum

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Precise time has become an essential service for most critical infrastructures. The development of telecommunication synchronization networks may facilitate the use of precise time, which will be a great benefit to a large number of devices connected to the Internet. This paper introduces our preliminary work to evaluate the dissemination of precise time reference through a potential telecom synchronization network. With synchronous Ethernet and IEEE1588v2 on-path support (including Telecom Boundary Clocks), time transfer can be accurate at the level of 100 ns. The other challenges of compensating network asymmetry and establishing traceability to Coordinated Universal Time (UTC) are discussed.

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Remote atomic clock synchronization via satellites and optical fibers

Cited by 44 publications

References 15 publications

Optical atomic clocks

Optical atomic clocks

Synchronization of Distant Optical Clocks at the Femtosecond Level

Precise UTC dissemination through future telecom synchronization networks

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