Modeling turbulence in underwater wireless optical communications based on Monte Carlo simulation

Zahra Vali; Asghar Gholami; Zabih Ghassemlooy; David G. Michelson; Masood Omoomi; Hamed Noori

doi:10.1364/JOSAA.34.001187

Journal of the Optical Society of America A
Vol. 34,
Issue 7,
pp. 1187-1193
(2017)
•https://doi.org/10.1364/JOSAA.34.001187

Modeling turbulence in underwater wireless optical communications based on Monte Carlo simulation

Zahra Vali, Asghar Gholami, Zabih Ghassemlooy, David G. Michelson, Masood Omoomi, and Hamed Noori

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Zahra Vali, Asghar Gholami, Zabih Ghassemlooy, David G. Michelson, Masood Omoomi, and Hamed Noori, "Modeling turbulence in underwater wireless optical communications based on Monte Carlo simulation," J. Opt. Soc. Am. A 34, 1187-1193 (2017)

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Table of Contents Category
- Atmospheric and Oceanic Optics
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About this Article
History
- Original Manuscript: February 28, 2017
- Revised Manuscript: May 21, 2017
- Manuscript Accepted: May 31, 2017
- Published: June 23, 2017

Abstract

Turbulence affects the performance of underwater wireless optical communications (UWOC). Although multiple scattering and absorption have been previously investigated by means of physical simulation models, still a physical simulation model is needed for UWOC with turbulence. In this paper, we propose a Monte Carlo simulation model for UWOC in turbulent oceanic clear water, which is far less computationally intensive than approaches based on computational fluid dynamics. The model is based on the variation of refractive index in a horizontal link. Results show that the proposed simulation model correctly reproduces lognormal probability density function of the received intensity for weak and moderate turbulence regimes. Results presented match well with experimental data reported for weak turbulence. Furthermore, scintillation index and turbulence-induced power loss versus link span are exhibited for different refractive index variations.

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Corrections

Zahra Vali, Asghar Gholami, Zabih Ghassemlooy, David G. Michelson, Masood Omoomi, and Hamed Noori, "Modeling turbulence in underwater wireless optical communications based on Monte Carlo simulation: erratum," J. Opt. Soc. Am. A 38, 1130-1130 (2021)
https://opg.optica.org/josaa/abstract.cfm?uri=josaa-38-8-1130

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Parameter	Value
$λ$	520 nm
$T$	23°C–29°C
$S$	36.1–36.8 ppm
$P$	0–10 dbar
Maximum $Δ n$	0.0008
Link span	100 m
Laser beam divergence (half-angle)	0.00075 rad
Beam width	15 mm
Rx aperture diameter	100 mm
Number of transmitted photons	$1 e 4$
Number of channel realizations	$1 e 3$
$Δ z$	50 cm
Number of layers	200
$θ_{\max}$	45°

SI	PDF	$R^{2}$
0.039	Lognormal	0.9440
0.086	Lognormal	0.9765
0.53	Lognormal	0.9313
0.68	Lognormal	0.8975

Parameter	Value
$λ$	520 nm
$T$	23°C–29°C
$S$	36.1–36.8 ppm
$P$	0–10 dbar
Maximum $Δ n$	0.0008
Link span	100 m
Laser beam divergence (half-angle)	0.00075 rad
Beam width	15 mm
Rx aperture diameter	100 mm
Number of transmitted photons	$1 e 4$
Number of channel realizations	$1 e 3$
$Δ z$	50 cm
Number of layers	200
$θ_{\max}$	45°

SI	PDF	$R^{2}$
0.039	Lognormal	0.9440
0.086	Lognormal	0.9765
0.53	Lognormal	0.9313
0.68	Lognormal	0.8975

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