Wireless-optical-communication-based cooperative IoT and IoUT system for ocean monitoring applications

Ramavath Prasad Naik; G. D. Goutham Simha; Prabu Krishnan

doi:10.1364/AO.435887

Applied Optics
Vol. 60,
Issue 29,
pp. 9067-9073
(2021)
•https://doi.org/10.1364/AO.435887

Wireless-optical-communication-based cooperative IoT and IoUT system for ocean monitoring applications

Ramavath Prasad Naik, G. D. Goutham Simha, and Prabu Krishnan

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Ramavath Prasad Naik, G. D. Goutham Simha, and Prabu Krishnan, "Wireless-optical-communication-based cooperative IoT and IoUT system for ocean monitoring applications," Appl. Opt. 60, 9067-9073 (2021)

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Table of Contents Category
- Atmospheric and Oceanic Optics
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About this Article
History
- Original Manuscript: July 5, 2021
- Revised Manuscript: September 13, 2021
- Manuscript Accepted: September 13, 2021
- Published: October 5, 2021

Abstract

This paper proposes the idea of a new cooperative communication between the Internet of Things (IoT) and the Internet of Underwater Things (IoUT) using wireless optical connectivity for ocean monitoring applications. We considered IoT communication using a hybrid radio frequency (RF)/free space optical (FSO) link and IoUT using a underwater wireless optical communication (UWOC) link. Channel models for RF, FSO, and UWOC links are considered to be Rayleigh, Malaga with pointing errors, and hyperbolic tangent log-normal distributions, respectively. The outage probability and the bit error rate (BER) expressions for the proposed system are derived over the combined channel model, which includes the effects of attenuation, turbulence, and pointing errors. The BER results are plotted for various binary digital modulation schemes such as on–off keying, binary phase-shift keying, binary frequency-shift keying, and differential phase-shift keying over UWOC, hybrid RF/FSO and RF-UWOC, FSO-UWOC with end-to-end systems. BER results are extended for various turbulence regions and pointing errors of the FSO link. Monte Carlo simulation results authenticate the correctness of the results.

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Symbols	Definition
$A_{0}$	Loss due to pointing errors
$γ_{1}$	SNR of hybrid RF-FSO link
$γ_{r f}$	SNR of RF link
$γ_{f s o}$	SNR of FSO link
$γ_{2}$	SNR of the UWOC system
$n_{1}$ , $n_{2}$	Additive white Gaussian noise
$h$	Fading parameter
$h_{1}$	Hybrid RF/FSO fading parameter
$h_{2}$	UWOC fading parameter
$E (\cdot)$	Expectation operator
$s$	Information source
$γ$	The overall received SNR of the end-to-end system
$G$	Rayleigh random variable
$k$	Frequency, polarization state
$ξ$	Elevation angle
$R$	Rainfall rate
${\bar{γ}}_{r f}$	Average SNR of the RF link
$g$	Ratio of beam width to the standard deviation
$b_{0}$	Half of average of total scattering power
$ρ$	Scattering power
$σ_{s}$	Standard deviation of jitter
$Ω$	Line-of-sight component
$α$	Large-scale turbulence
$β$	Fading parameter
$ζ$	Ratio of aperture radius to beam width
$a$	Shaping parameter of HTLN
$b$	Scaling parameter of HTLN
$p$	Modulation parameter
$q$	Modulation parameter
$G_{\cdot}^{\cdot} (\begin{matrix} \cdot \\ \cdot \end{matrix} \| \cdot)$	Meijer-G function
$Γ (\cdot)$	Gamma function
$W T$	Weak turbulence
$S T$	Strong turbulence
$P E$	Pointing errors
$min (\cdot)$	Minimum operator

Ramavath Prasad Naik	https://orcid.org/0000-0002-9878-2295
G. D. Goutham Simha	https://orcid.org/0000-0002-3908-3566

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