Terabit FSO communication based on a soliton microcomb

Wen SHAO; Yang WANG; Shuaiwei JIA; Zhuang XIE; Duorui GAO; Wei WANG; Dongquan ZHANG; Peixuan LIAO; Brent E. LITTLE; SAI T. CHU; Wei ZHAO; Wenfu ZHANG; Weiqiang WANG; Xiaoping XIE

doi:10.1364/PRJ.473559

Terabit FSO communication based on a soliton microcomb

Wen SHAO, Yang WANG, Shuaiwei JIA, Zhuang XIE, Duorui GAO, Wei WANG, Dongquan ZHANG, Peixuan LIAO, Brent E. LITTLE, SAI T. CHU, Wei ZHAO, Wenfu ZHANG, Weiqiang WANG^*, Xiaoping XIE^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

33 Citations (Scopus)

115 Downloads (CityUHK Scholars)

Abstract

Free-space optical (FSO) communication technology is a promising approach to establish a secure wireless link, which has the advantages of excellent directionality, large bandwidth, multiple services, low mass and less power requirements, and easy and fast deployments. Increasing the communication capacity is the perennial goal in both scientific and engineer communities. In this paper, we experimentally demonstrate a Tbit/s parallel FSO communication system using a soliton microcomb as a multiple wavelength laser source. Two communication terminals are installed in two buildings with a straight-line distance of ∼1 km. 102 comb lines are modulated by 10 Gbit/s differential phase-shift keying signals and demodulated using a delay-line interferometer. When the transmitted optical power is amplified to 19.8 dBm, 42 optical channels have optical signal-to-noise ratios higher than 27 dB and bit error rates less than 1 × 10^-9. Our experiment shows the feasibility of a wavelength-division multiplexing FSO communication system which suits the ultra-high-speed wireless transmission application scenarios in future satellite-based communications, disaster recovery, defense, last mile problems in networks and remote sensing, and so on.

Original language	English
Pages (from-to)	2802-2808
Journal	Photonics Research
Volume	10
Issue number	12
Online published	22 Nov 2022
DOIs	https://doi.org/10.1364/PRJ.473559
Publication status	Published - 1 Dec 2022

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED FINAL PUBLISHED VERSION FILE: SHAO, W., WANG, Y., JIA, S., XIE, Z., GAO, D., WANG, W., ZHANG, D., LIAO, P., LITTLE, B. E., CHU, SAI. T., ZHAO, W., ZHANG, W., WANG, W., & XIE, X. (2022). Terabit FSO communication based on a soliton microcomb. Photonics Research, 10(12), 2802-2808. https://doi.org/10.1364/PRJ.473559. © 2022 Chinese Laser Press.

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title = "Terabit FSO communication based on a soliton microcomb",

abstract = "Free-space optical (FSO) communication technology is a promising approach to establish a secure wireless link, which has the advantages of excellent directionality, large bandwidth, multiple services, low mass and less power requirements, and easy and fast deployments. Increasing the communication capacity is the perennial goal in both scientific and engineer communities. In this paper, we experimentally demonstrate a Tbit/s parallel FSO communication system using a soliton microcomb as a multiple wavelength laser source. Two communication terminals are installed in two buildings with a straight-line distance of ∼1 km. 102 comb lines are modulated by 10 Gbit/s differential phase-shift keying signals and demodulated using a delay-line interferometer. When the transmitted optical power is amplified to 19.8 dBm, 42 optical channels have optical signal-to-noise ratios higher than 27 dB and bit error rates less than 1 × 10-9. Our experiment shows the feasibility of a wavelength-division multiplexing FSO communication system which suits the ultra-high-speed wireless transmission application scenarios in future satellite-based communications, disaster recovery, defense, last mile problems in networks and remote sensing, and so on.",

author = "Wen SHAO and Yang WANG and Shuaiwei JIA and Zhuang XIE and Duorui GAO and Wei WANG and Dongquan ZHANG and Peixuan LIAO and LITTLE, {Brent E.} and CHU, {SAI T.} and Wei ZHAO and Wenfu ZHANG and Weiqiang WANG and Xiaoping XIE",

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AU - SHAO, Wen

AU - WANG, Yang

AU - JIA, Shuaiwei

AU - XIE, Zhuang

AU - GAO, Duorui

AU - WANG, Wei

AU - ZHANG, Dongquan

AU - LIAO, Peixuan

AU - LITTLE, Brent E.

AU - CHU, SAI T.

AU - ZHAO, Wei

AU - ZHANG, Wenfu

AU - WANG, Weiqiang

AU - XIE, Xiaoping

PY - 2022/12/1

Y1 - 2022/12/1

N2 - Free-space optical (FSO) communication technology is a promising approach to establish a secure wireless link, which has the advantages of excellent directionality, large bandwidth, multiple services, low mass and less power requirements, and easy and fast deployments. Increasing the communication capacity is the perennial goal in both scientific and engineer communities. In this paper, we experimentally demonstrate a Tbit/s parallel FSO communication system using a soliton microcomb as a multiple wavelength laser source. Two communication terminals are installed in two buildings with a straight-line distance of ∼1 km. 102 comb lines are modulated by 10 Gbit/s differential phase-shift keying signals and demodulated using a delay-line interferometer. When the transmitted optical power is amplified to 19.8 dBm, 42 optical channels have optical signal-to-noise ratios higher than 27 dB and bit error rates less than 1 × 10-9. Our experiment shows the feasibility of a wavelength-division multiplexing FSO communication system which suits the ultra-high-speed wireless transmission application scenarios in future satellite-based communications, disaster recovery, defense, last mile problems in networks and remote sensing, and so on.

AB - Free-space optical (FSO) communication technology is a promising approach to establish a secure wireless link, which has the advantages of excellent directionality, large bandwidth, multiple services, low mass and less power requirements, and easy and fast deployments. Increasing the communication capacity is the perennial goal in both scientific and engineer communities. In this paper, we experimentally demonstrate a Tbit/s parallel FSO communication system using a soliton microcomb as a multiple wavelength laser source. Two communication terminals are installed in two buildings with a straight-line distance of ∼1 km. 102 comb lines are modulated by 10 Gbit/s differential phase-shift keying signals and demodulated using a delay-line interferometer. When the transmitted optical power is amplified to 19.8 dBm, 42 optical channels have optical signal-to-noise ratios higher than 27 dB and bit error rates less than 1 × 10-9. Our experiment shows the feasibility of a wavelength-division multiplexing FSO communication system which suits the ultra-high-speed wireless transmission application scenarios in future satellite-based communications, disaster recovery, defense, last mile problems in networks and remote sensing, and so on.

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JO - Photonics Research

JF - Photonics Research

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Terabit FSO communication based on a soliton microcomb

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