Experimental demonstration of a transmitter with a 50° divergence angle, 50  Mbps rate, and 476  mW optical power for underwater wireless optical communication based on an engineered diffuser

Han, Biao; Yang, Jingchuan; Sun, Keyan; Sun, Yuhui

doi:10.1364/ao.452733

Cited by 6 publications

(3 citation statements)

References 19 publications

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“…For the maximum communication distance, it is determined by the emitting power of the transmitter, the signal loss in the transmitting channel, and the sensitivity of the receiver. The signal power arrived at the receiver is estimated by the following equation: 24 P(S)=P0ηTηWηSηR=P0ηTηSηR exp(−cS).…”

Section: Experimental Demonstration Of Half-duplex Uwoc With Led Illu...mentioning

confidence: 99%

Experimental demonstration of half-duplex underwater wireless optical communication when light emitting diode illumination noise exists

Han,

Li,

Huang

et al. 2023

Opt. Eng.

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Underwater wireless optical communication (UWOC) is useful for transmitting data short distances in the ocean. In most cases, such devices are placed on underwater vehicles to make it easier to establish a communication link. However, the vehicle often works in dark water. Thus it needs a light emitting diode (LED) as an illuminant for its camera to observe the surroundings, but this is noise to the UWOC system. Although such noise could be eliminated by inserting an optical filter in the UWOC receiver, the effectiveness depends on the incident angle of light into the filter. Because the illumination distribution of LED is quite complicated, there are some special requirements for UWOC systems to eliminate such noise. First, we simulate the incident angle distribution of LED illumination noise into the receivers of a bidirectional UWOC system with the Monte Carlo method. Then we analyze its influence to design an UWOC system. The results show that the wavelength of UWOC should be shorter than that of the LED illuminant to make them work simultaneously. Under the condition that the noise can be eliminated effectively, the spectrum width of the communication signal and the optical filter should be wider to enlarge the receiving field. According to the theoretical conclusion, we experimentally demonstrate a halfduplex UWOC system with an LED illuminant in dark water, where the attenuation coefficient is about 0.20 m −1 . In the system, each terminal has a white LED illuminant with 6.01 W optical power, a blue LED illuminant with 7.72 W optical power, and a UWOC transmitter based on a purple LED with about 1.25 W optical power. The UWOC realized a 27.78 Mbps rate and 19 m distance when the illuminants were open. The proposed UWOC system and its design criteria are useful for UWOC applications.

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Section: Experimental Demonstration Of Half-duplex Uwoc With Led Illu...mentioning

confidence: 99%

Experimental demonstration of half-duplex underwater wireless optical communication when light emitting diode illumination noise exists

Han,

Li,

Huang

et al. 2023

Opt. Eng.

Self Cite

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“…P T is the initial transmitting power at the transmitting terminal; P R is the optical power received by the light-sensitive component at the receiving terminal; η t , as explained above, is the electrical-to-optical conversion loss of the transmitter; η r reflects the efficiency of the receiver in converting incoming optical signals back into electrical signals; η d is geometry loss, which is inversely proportional to the square of the communication range [17]; K(λ) is the attenuation coefficient of the transmission channels of seawater, which can be expressed as the sum of the absorption and scattering effects, yielding the equation,…”

Section: Communication Range Model Of Uwocmentioning

confidence: 99%

Research on Underwater Wireless Optical Communication Channel Model and Its Application

Sun,

Li,

Han

2023

Applied Sciences

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Underwater wireless optical communication (UWOC) is an emerging technology with wide-ranging applications in marine exploration, offshore industries, environmental monitoring, and underwater robotics. In order to investigate the application of UWOC in environments of different water quality, this study establishes a model of an optical communication channel and analyzes the impact of water quality on communication range. Our experimental design is employed to validate the effectiveness of the model and analyze the sources of model errors. Furthermore, this research introduces the concept of an “effective communication space” for underwater optical wireless communication and constructs an experimental platform to test the effective communication space under various water quality conditions. In addition, the application methods and workflow of wireless optical communication on underwater mobile platforms are discussed, and field tests are conducted in a practical lake environment to verify the application value of the effective communication space. This research offers valuable guidance for advancing the study and engineering applications of UWOC technology.

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“…To establish optical communication link, there are two schemes. The first one is enlarging the angle of divergence of the transmitter, and the field of view of receiver [12][13][14][15][16]. It reduces the requirement to align the UWOC transmitter and receiver, but increases the energy loss in the transmission link.…”

Section: Introductionmentioning

confidence: 99%

Experimental demonstration of measuring angle of incidence for light into receiver in underwater laser communication system based on four-quadrant detector

Peng,

Li,

Kang

et al. 2024

Sixth Conference on Frontiers in Optical Imaging and Technology: Novel Technologies in Optical Systems

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Underwater wireless optical communication (UWOC) is an useful way to transmit date in ocean with short distance, because it has high speed. In application, the first challenge for this technology is establishing optical link underwater. There are two schemes to deal with this issue. The first one is enlarging the angle of divergence of the transmitter, and the field of view of receiver, which reduces the requirement to align the UWOC transmitter and receiver. However, the energy loss is increased in the transmission link. The other method needs a pointing, acquisition, and tracking (PAT) system to establish optical link. The angle of divergence of the transmitter is quite small in this way, which is helpful to reduce energy loss in the transmission link. However, in order to make the optical link stable, the receiver should measure the angle of incident of communication light all the time to provide feedback parameters to PAT system. In this work, a method is presented and demonstrated based on four-quadrant detector (QD) for such issue. It shows that the tested error for pitch angle and azimuth angle is less than 1°, as the communication system could still work with 50Kbps communication rate and 2m distance. It has demonstrated the feasibility of the method.

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Experimental demonstration of a transmitter with a 50° divergence angle, 50 Mbps rate, and 476 mW optical power for underwater wireless optical communication based on an engineered diffuser

Cited by 6 publications

References 19 publications

Experimental demonstration of half-duplex underwater wireless optical communication when light emitting diode illumination noise exists

Experimental demonstration of half-duplex underwater wireless optical communication when light emitting diode illumination noise exists

Research on Underwater Wireless Optical Communication Channel Model and Its Application

Experimental demonstration of measuring angle of incidence for light into receiver in underwater laser communication system based on four-quadrant detector

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