Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System

Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System

With the rapid evolution of communication technologies, high-speed optical wireless applications under the water surface as a replacement or complementary to the conventional radio frequency (RF) and acoustic technologies are attracting significant attention from the researchers. Since underwater tu...

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Main Authors: A. S. M. Badrudduza, Md. Ibrahim, S. M. Riazul Islam, Md. Shakhawat Hossen, Milton Kumar Kundu, Imran Shafique Ansari, Heejung Yu
Format: Article
Language:English
Published: IEEE 2021-01-01
Series:IEEE Access
Subjects:
Eavesdropper
optical wireless communication
physical layer security
under water turbulence
Online Access:https://ieeexplore.ieee.org/document/9330523/
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spelling doaj-c3463303d1574a96902e29b655452b932021-03-30T15:25:21ZengIEEEIEEE Access2169-35362021-01-019181231813610.1109/ACCESS.2021.30533239330523Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed SystemA. S. M. Badrudduza0https://orcid.org/0000-0003-0895-4450Md. Ibrahim1S. M. Riazul Islam2https://orcid.org/0000-0003-2968-9561Md. Shakhawat Hossen3https://orcid.org/0000-0003-1305-6962Milton Kumar Kundu4https://orcid.org/0000-0001-5151-8545Imran Shafique Ansari5https://orcid.org/0000-0001-8461-6547Heejung Yu6https://orcid.org/0000-0001-8046-2376Department of Electronics and Telecommunication Engineering, Rajshahi University of Engineering and Technology (RUET), Rajshahi, BangladeshDepartment of Electrical and Electronic Engineering, Rajshahi University of Engineering and Technology (RUET), Rajshahi, BangladeshDepartment of Computer Science and Engineering, Sejong University, Seoul, South KoreaDepartment of Electronics and Telecommunication Engineering, Rajshahi University of Engineering and Technology (RUET), Rajshahi, BangladeshDepartment of Electrical and Computer Engineering, Rajshahi University of Engineering and Technology (RUET), Rajshahi, BangladeshJames Watt School of Engineering, University of Glasgow, Glasgow, U.KDepartment of Electronics and Information Engineering, Korea University, Sejong, South KoreaWith the rapid evolution of communication technologies, high-speed optical wireless applications under the water surface as a replacement or complementary to the conventional radio frequency (RF) and acoustic technologies are attracting significant attention from the researchers. Since underwater turbulence (UWT) is an inevitable impediment for a long distance underwater optical wireless communication (UOWC) link, mixed RF-UOWC is being considered as a more feasible solution by the research community. This article deals with the secrecy performance of a variable gain relay-based mixed dual-hop RF-UOWC framework under the intercepting attempt of a potential eavesdropper. The RF link undergoes Generalized Gamma (GG) fading distribution, whereas the UOWC link is subjected to mixture Exponential Generalized Gamma (mEGG) distribution. The eavesdropper is capable of wiretapping via a RF link that also experiences the GG fading. The secrecy analysis incorporates the derivations of closed-form expressions for strictly positive secrecy capacity, average secrecy capacity, and exact as well as lower bound of secrecy outage probability in terms of univariate and bivariate Meijer's G and Fox's H functions. Based on these expressions, impacts of heterodyne and intensity modulation/direct detection techniques along with weak, moderate, and severe UWT conditions due to air bubbles, temperature, and salinity gradients are quantified. To the best of authors' knowledge, the proposed model is the first of its kind that addresses the secrecy analysis of a temperature gradient RF-UOWC system along with air bubbles, as opposed to the existing models that considered thermally uniform scenarios only. Finally, the derived expressions are verified via Monte-Carlo simulations.https://ieeexplore.ieee.org/document/9330523/Eavesdropperoptical wireless communicationphysical layer securityunder water turbulence
collection DOAJ
language English
format Article
sources DOAJ
author A. S. M. Badrudduza
Md. Ibrahim
S. M. Riazul Islam
Md. Shakhawat Hossen
Milton Kumar Kundu
Imran Shafique Ansari
Heejung Yu
spellingShingle A. S. M. Badrudduza
Md. Ibrahim
S. M. Riazul Islam
Md. Shakhawat Hossen
Milton Kumar Kundu
Imran Shafique Ansari
Heejung Yu
Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
IEEE Access
Eavesdropper
optical wireless communication
physical layer security
under water turbulence
author_facet A. S. M. Badrudduza
Md. Ibrahim
S. M. Riazul Islam
Md. Shakhawat Hossen
Milton Kumar Kundu
Imran Shafique Ansari
Heejung Yu
author_sort A. S. M. Badrudduza
title Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
title_short Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
title_full Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
title_fullStr Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
title_full_unstemmed Security at the Physical Layer Over GG Fading and mEGG Turbulence Induced RF-UOWC Mixed System
title_sort security at the physical layer over gg fading and megg turbulence induced rf-uowc mixed system
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2021-01-01
description With the rapid evolution of communication technologies, high-speed optical wireless applications under the water surface as a replacement or complementary to the conventional radio frequency (RF) and acoustic technologies are attracting significant attention from the researchers. Since underwater turbulence (UWT) is an inevitable impediment for a long distance underwater optical wireless communication (UOWC) link, mixed RF-UOWC is being considered as a more feasible solution by the research community. This article deals with the secrecy performance of a variable gain relay-based mixed dual-hop RF-UOWC framework under the intercepting attempt of a potential eavesdropper. The RF link undergoes Generalized Gamma (GG) fading distribution, whereas the UOWC link is subjected to mixture Exponential Generalized Gamma (mEGG) distribution. The eavesdropper is capable of wiretapping via a RF link that also experiences the GG fading. The secrecy analysis incorporates the derivations of closed-form expressions for strictly positive secrecy capacity, average secrecy capacity, and exact as well as lower bound of secrecy outage probability in terms of univariate and bivariate Meijer's G and Fox's H functions. Based on these expressions, impacts of heterodyne and intensity modulation/direct detection techniques along with weak, moderate, and severe UWT conditions due to air bubbles, temperature, and salinity gradients are quantified. To the best of authors' knowledge, the proposed model is the first of its kind that addresses the secrecy analysis of a temperature gradient RF-UOWC system along with air bubbles, as opposed to the existing models that considered thermally uniform scenarios only. Finally, the derived expressions are verified via Monte-Carlo simulations.
topic Eavesdropper
optical wireless communication
physical layer security
under water turbulence
url https://ieeexplore.ieee.org/document/9330523/
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