Low-loss microwave photonics links using hollow core fibres
Low-loss microwave photonics links using hollow core fibres
There are a host of applications in communications, sensing, and science, in which analogue signal transmission is preferred over today’s dominant digital transmission. In some of these applications, the advantage is in lower cost, while in others, it lies in superior performance. However, especially for longer analogue photonics links (up to 10 s of km), the performance is strongly limited by the impairments arising from using standard single-mode fibres (SSMF). Firstly, the three key metrics of analogue links (loss, noise figure, and dynamic range) tend to improve with received power, but this is limited by stimulated Brillouin scattering in SSMF. Further degradation is due to the chromatic dispersion of SSMF, which induces radio-frequency (RF) signal fading, increases even-order distortions, and causes phase-to-intensity-noise conversion. Further distortions still, are caused by the Kerr nonlinearity of SSMF. We propose to address all of these shortcomings by replacing SSMFs with hollow-core optical fibres, which have simultaneously six times lower chromatic dispersion and several orders of magnitude lower nonlinearity (Brillouin, Kerr). We demonstrate the advantages in this application using a 7.7 km long hollow-core fibre sample, significantly surpassing the performance of an SSMF link in virtually every metric, including 15 dB higher link gain and 6 dB lower noise figure.
Zhang, Xi
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Feng, Zitong
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Marpaung, David
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Numkam Fokoua, Eric
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Sakr, Hesham
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Hayes, John R.
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Poletti, Francesco
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Richardson, David J.
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Slavík, Radan
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7 July 2022
Zhang, Xi
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Feng, Zitong
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Marpaung, David
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Numkam Fokoua, Eric
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Sakr, Hesham
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Hayes, John R.
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Poletti, Francesco
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Richardson, David J.
ebfe1ff9-d0c2-4e52-b7ae-c1b13bccdef3
Slavík, Radan
2591726a-ecc0-4d1a-8e1d-4d0fd8da8f7d
Zhang, Xi, Feng, Zitong, Marpaung, David, Numkam Fokoua, Eric, Sakr, Hesham, Hayes, John R., Poletti, Francesco, Richardson, David J. and Slavík, Radan
(2022)
Low-loss microwave photonics links using hollow core fibres.
Light: Science & Applications, 11 (1), [213].
(doi:10.1038/s41377-022-00908-3).
Abstract
There are a host of applications in communications, sensing, and science, in which analogue signal transmission is preferred over today’s dominant digital transmission. In some of these applications, the advantage is in lower cost, while in others, it lies in superior performance. However, especially for longer analogue photonics links (up to 10 s of km), the performance is strongly limited by the impairments arising from using standard single-mode fibres (SSMF). Firstly, the three key metrics of analogue links (loss, noise figure, and dynamic range) tend to improve with received power, but this is limited by stimulated Brillouin scattering in SSMF. Further degradation is due to the chromatic dispersion of SSMF, which induces radio-frequency (RF) signal fading, increases even-order distortions, and causes phase-to-intensity-noise conversion. Further distortions still, are caused by the Kerr nonlinearity of SSMF. We propose to address all of these shortcomings by replacing SSMFs with hollow-core optical fibres, which have simultaneously six times lower chromatic dispersion and several orders of magnitude lower nonlinearity (Brillouin, Kerr). We demonstrate the advantages in this application using a 7.7 km long hollow-core fibre sample, significantly surpassing the performance of an SSMF link in virtually every metric, including 15 dB higher link gain and 6 dB lower noise figure.
Text
s41377-022-00908-3
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e-pub ahead of print date: 7 July 2022
Published date: 7 July 2022
Additional Information:
Funding Information:
This work was financially supported by Engineering and Physical Sciences Research Council (EP/P030181/1), European Research Council (682724) and Royal Academy of Engineering.
Publisher Copyright:
© 2022, The Author(s).
Identifiers
Local EPrints ID: 467996
URI: http://eprints.soton.ac.uk/id/eprint/467996
ISSN: 2095-5545
PURE UUID: 3ff8cbea-9786-4dbd-afbf-2487b225558b
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Date deposited: 27 Jul 2022 16:59
Last modified: 17 Mar 2024 03:49
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Author:
Xi Zhang
Author:
Zitong Feng
Author:
David Marpaung
Author:
Eric Numkam Fokoua
Author:
John R. Hayes
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