Adaptive beam shaping for enhanced underwater wireless optical communication

Jiewen Nie; Lei Tian; Haozhi Wang; Long Chen; Zhuoran Li; Song Yue; Zichen Zhang; Haining Yang

doi:10.1364/OE.434387

Adaptive beam shaping for enhanced underwater wireless optical communication

Jiewen Nie
, Lei Tian
, Haozhi Wang
, Long Chen
, Zhuoran Li
, Song Yue
, Zichen Zhang
, Haining Yang

Southeast University, Nanjing
CAS - Institute of Microelectronics

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

34 Scopus citations

Abstract

In this paper, we proposed and experimentally verified a diffraction-based optical beam shaping technique for underwater optical communication (UWOC) applications. The proposed method aimed to address the key issue in UWOC links, i.e., the high propagation loss experienced by the launched optical beam. It enabled a significantly higher portion of the launched signal to be collected by the receiver. The optimal transmission distance could also be fine-tuned by the software configuration. In a proof-of-concept demonstration based on the off-the-shelf components, 100 Mbps transmission was achieved over 15-meter distance and a significant enhancement in the transmission quality was observed. There is a huge scope for further improvement in the transmission distance and data rate when the proposed technique was used with purpose-built optical components and advanced coding schemes.

Original language	English
Pages (from-to)	26404-26417
Number of pages	14
Journal	Optics Express
Volume	29
Issue number	17
DOIs	https://doi.org/10.1364/OE.434387
State	Published - 16 Aug 2021
Externally published	Yes

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title = "Adaptive beam shaping for enhanced underwater wireless optical communication",

abstract = "In this paper, we proposed and experimentally verified a diffraction-based optical beam shaping technique for underwater optical communication (UWOC) applications. The proposed method aimed to address the key issue in UWOC links, i.e., the high propagation loss experienced by the launched optical beam. It enabled a significantly higher portion of the launched signal to be collected by the receiver. The optimal transmission distance could also be fine-tuned by the software configuration. In a proof-of-concept demonstration based on the off-the-shelf components, 100 Mbps transmission was achieved over 15-meter distance and a significant enhancement in the transmission quality was observed. There is a huge scope for further improvement in the transmission distance and data rate when the proposed technique was used with purpose-built optical components and advanced coding schemes.",

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T1 - Adaptive beam shaping for enhanced underwater wireless optical communication

AU - Nie, Jiewen

AU - Tian, Lei

AU - Wang, Haozhi

AU - Chen, Long

AU - Li, Zhuoran

AU - Yue, Song

AU - Zhang, Zichen

AU - Yang, Haining

PY - 2021/8/16

Y1 - 2021/8/16

N2 - In this paper, we proposed and experimentally verified a diffraction-based optical beam shaping technique for underwater optical communication (UWOC) applications. The proposed method aimed to address the key issue in UWOC links, i.e., the high propagation loss experienced by the launched optical beam. It enabled a significantly higher portion of the launched signal to be collected by the receiver. The optimal transmission distance could also be fine-tuned by the software configuration. In a proof-of-concept demonstration based on the off-the-shelf components, 100 Mbps transmission was achieved over 15-meter distance and a significant enhancement in the transmission quality was observed. There is a huge scope for further improvement in the transmission distance and data rate when the proposed technique was used with purpose-built optical components and advanced coding schemes.

AB - In this paper, we proposed and experimentally verified a diffraction-based optical beam shaping technique for underwater optical communication (UWOC) applications. The proposed method aimed to address the key issue in UWOC links, i.e., the high propagation loss experienced by the launched optical beam. It enabled a significantly higher portion of the launched signal to be collected by the receiver. The optimal transmission distance could also be fine-tuned by the software configuration. In a proof-of-concept demonstration based on the off-the-shelf components, 100 Mbps transmission was achieved over 15-meter distance and a significant enhancement in the transmission quality was observed. There is a huge scope for further improvement in the transmission distance and data rate when the proposed technique was used with purpose-built optical components and advanced coding schemes.

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Adaptive beam shaping for enhanced underwater wireless optical communication

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