Real-Time and High-Speed Underwater Photon-Counting Communication Based on SPAD and PPM Symbol Synchronization

Huang, Jun; Li, Changkun; Dai, Jiansheng; Shu, Rong; Zhang, Liang; Wang, Yunlong

doi:10.1109/jphot.2021.3113659

Cited by 15 publications

(10 citation statements)

References 19 publications

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“…In 2021 [43] , Pengcheng Lab's SiPM-based receivers can support 11.6 attenuation lengths at 1Gbps. In the same year [44] , the Shanghai Institute of Technology and Physics achieved a communication sensitivity of 1.35 photos/bit using photon counting reception technology. In 2022 [45] , the Xi'an Institute of Optics and Mechanics analyzed and compared the communication performance of various intensity modulations based on photon counting communication systems.…”

Section: Underwater High-sensitivity Optical Signal Processing Techni...mentioning

confidence: 99%

The research progress in underwater wireless optical communication technology

Han¹,

Nie²,

Chang³

et al. 2023

First International Conference on Spatial Atmospheric Marine Environmental Optics (SAME 2023)

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Underwater wireless optical communication, which is an effective technical way to build a high-speed and flexible underwater wireless communication network due to its large bandwidth, good confidentiality and low time delay, is widely regarded as a complementary communication way to hydroacoustic communication. The newest research progress and main technical specification in the current technology of underwater wireless optical communication are introduced, the characteristics of the current underwater wireless optical communication technology are summarized in this paper. A series of improvement measures are proposed for the problems of short communication distance and low robustness in underwater wireless optical communication system, which can provide references for underwater wireless optical communication technology research and engineering project development.

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Section: Underwater High-sensitivity Optical Signal Processing Techni...mentioning

confidence: 99%

The research progress in underwater wireless optical communication technology

Han¹,

Nie²,

Chang³

et al. 2023

First International Conference on Spatial Atmospheric Marine Environmental Optics (SAME 2023)

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show abstract

“…The blue laser diode (LD), with high power, is gradually becoming the mainstream as the light source in the long-distance UWOC system [5][6][7][8][9][10] . Besides, many researchers employed high-sensitivity optical detectors such as a multi-pixel photon counter (MPPC), single-photon avalanche diode (SPAD), and photomultiplier tube (PMT) as receivers to detect weak optical signals [6][7][8][9][10][11] .…”

Section: Introductionmentioning

confidence: 99%

“…In 2021, a real-time UWOC system based on SPAD and pulseposition modulation (PPM) was conducted at a data rate of 6.21 Mbit/s when the received optical power was only −84.3 dBm [11] . However, due to the high implementation cost of real-time communication systems and the absence of detectors with high bandwidth and sensitivity, few real-time UWOC systems support a high data rate of hundreds of megabits per second with a transmission distance of dozens of meters, hindering the practical implementation of UWOC systems.…”

Section: Introductionmentioning

confidence: 99%

“…Spatial summing is effective in improving the performance, which has been widely used in the visible light communication (VLC) system to mitigate the nonlinear effect. [12] LD/APD 60 (tap water) / / 2.5 Gbit/s OOK AWG/OSC 2019 [5] LD/APD 56 (tap water) 0.0876 m −1 4.9056 3.31 Gbit/s QAM AWG/OSC 2020 [13] LD/MPPC 100 (pool water) 0.24 m −1 24 8.4 Mbit/s OOK AWG/OSC 2020 [6] LD/PMT 100 (pool water) 0.0585 m −1 5.85 200 Mbit/s OOK AWG/OSC 2021 [7] LD/PMT 150 (pool water) 0.053 m −1 8.775 500 Mbit/s PAM AWG/OSC 2021 [8] LD/PMT 200 (pool water) 0.0325 m −1 6.5 500 Mbit/s PAM AWG/OSC 2021 [9] LD/PMT 100.6 (tap water) 0.0658 m −1 6.6195 3 Gbit/s OOK AWG/OSC 2022 [10] LD/PMT 5 (turbid water) / / 10 Mbit/s PPM FPGA 2016 [14] LD/PIN 3 (artificial seawater) 0.481 m −1 1.443 50 Mbit/s QAM FPGA 2019 [15] LED/PIN 1.2 (tap water) / / 2.34 Gbit/s DMT FPGA 2020 [16] LED/APD 10 (tap water) 0.056 m −1 0.56 1 Mbit/s FSK FPGA 2020 [17] LD/APD 3.6 (tap water) / / 2.2 Gbit/s OFDM FPGA 2020 [18] LD/SPAD 2 (tap water) / / 6.21 Mbit/s PPM FPGA 2021 [11] LD/PMT 50 (pool water) 0.1307 m −1 In 2013, a VLC transmitter employing discrete power level stepping was proposed to address the nonlinearity, restricted dynamic range, and complex system designs of the conventional optical transmitters [22] . In 2017, a highly compact array of micro-LED pixels was proposed to generate a discrete optical signal, which achieved a data rate up to 200 Mbit/s [23] .…”

Section: Introductionmentioning

confidence: 99%

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50 m/187.5 Mbit/s real-time underwater wireless optical communication based on optical superimposition

et al. 2023

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In this paper, an optical pulse amplitude modulation with 4 levels (PAM-4) using a fiber combiner is proposed to enhance the data rate of a field-programmable gate-array-based long-distance real-time underwater wireless optical communication system. Two on-off keying signals with different amplitudes are used to modulate two pigtailed laser diodes, respectively, and the generated optical signals are superimposed into optical PAM-4 signals by a fiber combiner. The optical PAM-4 scheme can effectively alleviate the nonlinearity, although it reduces the peak-to-peak value of the emitting optical power by 25%. A real-time data rate of 187.5 Mbit/s is achieved by using the optical PAM-4 with a transmission distance of 50 m. The data rate is increased by about 25% compared with the conventional electrical PAM-4 in the same condition.

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“…Another recent development in the field of underwater communication is the use of single-photon avalanche diode (SPAD) [8][9][10] and silicon photomultiplier (SiPM) [11][12][13][14] receivers. Being sensitive to the arrival of single photons, SPAD and SiPM have exceptional sensitivity and noise performance compared to standard avalanche photodiodes (APD) and are instrumental to achieving new range records in underwater optical communications.…”

Section: Introductionmentioning

confidence: 99%

Short-range medium-rate fleet communications using SPAD arrays

Chia

Motani

2023

Unmanned Systems Technology XXV

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We present a novel approach to underwater fleet communication using single-photon avalanche diode (SPAD) arrays on the receiver. Using a large array and a focusing lens, the array can be spatially allocated to different sectors within the lens's field of view. This eliminates the need for precise pointing of the receiver towards the transmitter and enables simultaneous reception of multiple transmitters across the entire array. We demonstrate the feasibility of our approach through a prototype receiver that utilizes a 7x7 SPAD array, a wide field-of-view lens and FPGA processing. We were able to achieve a raw data rate of 6 Mbps across a folded 25m clear water channel. Through the use of artificial attenuation with ND filters, we estimate that the achievable distance for a raw data rate of 6 Mbps in clear water with a BER of 10 -3 is approximately 400m. In over-the-air testing, we were able to achieve simultaneous communication over the entire 7x7 array at 6 Mbps.

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Real-Time and High-Speed Underwater Photon-Counting Communication Based on SPAD and PPM Symbol Synchronization

Cited by 15 publications

References 19 publications

The research progress in underwater wireless optical communication technology

The research progress in underwater wireless optical communication technology

50 m/187.5 Mbit/s real-time underwater wireless optical communication based on optical superimposition

Short-range medium-rate fleet communications using SPAD arrays

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