Monte-Carlo-Based Impulse Response Modeling for Underwater Wireless Optical Communication

An important step in the design of receiver aperture and optimal spacing of the diversity scheme for an underwater laser communication system is to accurately characterize the two-dimensional (2D) spatial distribution of laser beam intensity. In this paper, the 2D optical intensity distribution and 3 dB optical intensity spot radius (OISR) are investigated due to the dominating optical intensity of laser beam being within the 3 dB OISR. By utilizing the Henyey–Greenstein function to compute the scattering angles of photons, the effects of the scattering underwater optical channel and optical system parameters on 3 dB OISR are examined based on the Monte Carlo simulation method. We have shown for the first time that in the channel with a high density of scattering particles, the divergence angle of the laser source plays a negligible role in 3 dB OISR. This is an interesting phenomenon and important for optical communication as this clearly shows that the geometric loss is no longer important for the design of receiver aperture and optimal spacing of the diversity scheme for the underwater laser communication system in the highly scattering channel.

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“…[20] MC CIR and normalized received optical power. [21] MC Different effects of two scattering angle computational principle on CIR.…”

Section: Ref Nomentioning

confidence: 99%

Investigation of 3 dB Optical Intensity Spot Radius of Laser Beam under Scattering Underwater Channel

Wang

Rajbhandari

et al. 2020

Sensors

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“…The integration is often divided into forward scattering and backward scattering. Normalizing V(ϕ) by b(λ) gives the scattering phase function (SPF), i.e., P(ϕ) [32]- [34]. The Henyey Greenstein parameter which is represented by g is the average cosine of the scattering angle over all directions.…”

Section: Bsf Prelimnariesmentioning

confidence: 99%

“…The overall effect of background noise, thermal noise, and dark current in the photodetector which is modeled as additive white Gaussian noise (AWGN) is represented by n, with σ 2 n variance. By substituting (33) in (34), the overall SNR of the system is then calculated as:…”

Section: B Calculation Of Snrmentioning

confidence: 99%

A Simplified Form of Beam Spread Function in Underwater Wireless Optical Communication and its Applications

Saxena

Bhatnagar

2019

IEEE Access

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Underwater wireless optical communication (UWOC) refers to the transmission of data in unguided water medium through optical carriers. Beam spread function (BSF) characterizes the amount of light irradiance received at the receiver as a function of receiver's distance from main beam axis for a particular link length. The existing form of BSF includes multiple integrals which are burdensome to use for mathematical analysis. Because of this, it gets very difficult to employ the existing form of BSF to derive non-integral expressions for bit error rate (BER), capacity, and outage probability of UWOC systems. Moreover, it is very difficult to find any insight into the UWOC systems based on this integral form of BSF. In this paper, we derive a simplified power series expression of BSF by solving the existing integral form. Closed-form expressions of BSF with some approximations, which simplify the derived power series expression, are also provided as special cases. Important insights regarding the behavior of BSF are also obtained from the derived simplified forms. Furthermore, closed-form expressions of BER, capacity, and outage probability of the UWOC system, taking the effect of scattering, absorption, and misalignment in consideration, are also derived. INDEX TERMS Beam spread function, bit error rate, capacity, log-normal distribution, outage probability, scattering phase function, underwater optical communication, volume scattering function. I. INTRODUCTION Since earth's surface is mainly water, we need technologies that can help with communications inside water. Underwater wireless communication (UWC) systems are very useful for study of the environment inside the ocean [1]. Further, UWC systems are very helpful in vehicle-to-vehicle communication inside water. Many technologies such as radio frequency (RF) communication [2], [3] and underwater acoustic communication (UWAC) [4], [5] are widely being used for wireless communication inside water. Despite strong attenuation, acoustic waves can travel a distance of about 10-90 km inside water [6], [7]; the attenuation gets stronger The associate editor coordinating the review of this manuscript and approving it for publication was Miaowen Wen.

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“…In terms of experimental channel measurement, researchers in [13] established an experimental testbed to study the LD-UOWC channel characteristics by measuring the intensity of the light transmitted through different types of water. To overcome these limitations, the Monte Carlo numerical simulation method was developed to solve RTE and model the underwater channel; several works were reported in [14][15][16][17][18][19]. In [14], a Monte Carlo (MC) based approach was proposed to investigate the light attenuation and time-domain broadening effects in different types of seawater channels, the impact of the water quality, communication distance, and receiver aperture were also analyzed.…”

Section: Introductionmentioning

confidence: 99%

“…In [15,16], authors used the MC method and single-parameter chlorophyll concentration model to study the LED-UOWC scattering channel, the IOP, and path loss in different waters and different ranges were evaluated under various conditions. Authors in [17] adopted a double gamma function to fit the numerical simulation results of channel impulse response and investigated the fitting performance in coastal and harbor water. Using the Monte Carlo statistical method, authors in [18] simulated and analyzed the laser spot-expansion and time-domain broadening characteristics of the UOWC link.…”

Section: Introductionmentioning

confidence: 99%

Performance Analysis and Design Considerations of the Shallow Underwater Optical Wireless Communication System with Solar Noises Utilizing a Photon Tracing-Based Simulation Platform

2021

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The performance of the underwater optical wireless communication (UOWC) system is highly affected by seawater´s inherent optical properties and the solar radiation from sunlight, especially for a shallow environment. The multipath effect and degradations in signal-to-noise ratio (SNR) due to absorption, scattering, and ambient noises can significantly limit the viable communication range, which poses key challenges to its large-scale commercial applications. To this end, this paper proposes a unified model for underwater channel characterization and system performance analysis in the presence of solar noises utilizing a photon tracing algorithm. Besides, we developed a generic simulation platform with configurable parameters and self-defined scenarios via MATLAB. Based on this platform, a comprehensive investigation of underwater channel impairments was conducted including temporal and spatial dispersion, illumination distribution pattern, and statistical attenuation with various oceanic types. The impact of ambient noise at different operation depths on the bit error rate (BER) performance of the shallow UOWC system was evaluated under typical specifications. Simulation results revealed that the multipath dispersion is tied closely to the multiple scattering phenomenon. The delay spread and ambient noise effect can be mitigated by considering a narrow field of view (FOV) and it also enables the system to exhibit optimal performance on combining with a wide aperture.

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Monte-Carlo-Based Impulse Response Modeling for Underwater Wireless Optical Communication

Cited by 17 publications

References 17 publications

Investigation of 3 dB Optical Intensity Spot Radius of Laser Beam under Scattering Underwater Channel

Investigation of 3 dB Optical Intensity Spot Radius of Laser Beam under Scattering Underwater Channel

A Simplified Form of Beam Spread Function in Underwater Wireless Optical Communication and its Applications

Performance Analysis and Design Considerations of the Shallow Underwater Optical Wireless Communication System with Solar Noises Utilizing a Photon Tracing-Based Simulation Platform

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