MOHAMMAD F U R Q A N ALI
MOHAMMAD FURQAN ALI is working as a research engineer and
pursuing Ph.D. in Computer Science and Wireless Communication
Engineering from the School of Computer Science and Robotics, National
Research Tomsk Polytechnic University, Russia. He received M.Sc. degree
(Distinction & Gold medalist) from “National Research Tomsk Polytechnic
University Russia” in 2018, and B.Tech (Bachelor of Technology) degree
in 2013 from “UP Technical University Lucknow, India. His research
interests include Optical communication, Underwater Visible light
communication (UVLC), 5G wireless networking, Internet of Things
(IoTs) and Hybrid-cooperative underwater wireless communication.
Supervisors: Dushantha Nalin K. Jayakody
Phone: +79955336181
Address: 703A
H.No-15B, National Research Tomsk Polytechnic University, Russian Federation
pursuing Ph.D. in Computer Science and Wireless Communication
Engineering from the School of Computer Science and Robotics, National
Research Tomsk Polytechnic University, Russia. He received M.Sc. degree
(Distinction & Gold medalist) from “National Research Tomsk Polytechnic
University Russia” in 2018, and B.Tech (Bachelor of Technology) degree
in 2013 from “UP Technical University Lucknow, India. His research
interests include Optical communication, Underwater Visible light
communication (UVLC), 5G wireless networking, Internet of Things
(IoTs) and Hybrid-cooperative underwater wireless communication.
Supervisors: Dushantha Nalin K. Jayakody
Phone: +79955336181
Address: 703A
H.No-15B, National Research Tomsk Polytechnic University, Russian Federation
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Papers by MOHAMMAD F U R Q A N ALI
(UOWCs) are promising and potential wireless carriers
to envisage underwater phenomenal activities for various
applications towards the futuristic 5G and beyond (5GB)
wireless systems. The main challenges to deploy underwater
applications are the physicochemical properties and strong
turbulence channel conditions. In this regard, the end-to-end
(E2E) performance analysis of a dual-hop mixed FSO/UVLC
system under the intensity modulation/direct detection (IM/DD)
technique in consideration of pulse amplitude modulation
(PAM) scheme is investigated. Throughout this study, to tackle
the issues of moderate-to-strong turbulence channel conditions,
this work deploys the Gamma-Gamma (GG) distribution
fading model and the links are designed by unifying plane
wave models in the corresponding links, respectively. This
investigation outperforms higher achievable data rate with
minimal delay response and enhance network connectivity in
real-time monitoring scenarios as compared with the traditional
underwater wireless communication technologies. In more
contrast, the probability distribution function (PDF), cumulative
distribution function (CDF), and closed-form expression of
the system are derived and presented in terms of Meijer-G
function as well as Extended Generalized Bivariate Meijer-G
Function (EGBMGF). The significant E2E performance metrics
are obtained by employing the decode-and-forward (DF) relay
protocol in hostile channel conditions. In aggregating this work,
we combine the analytical expressions that present an efficient
tool to depict the impact of channel parameters on the system.
The simulation results are plausible of the system performance
metrics as average BER (ABER) and outage probability (Pout)
in the presence of pointing and without pointing error events.
Finally, in this work, we use the Monte-Carlo approach for the
best fitting curves and validate the numerical expression yields
simulation results.
found and covered more than seventy percent with it. Monitoring
different phenomenal activities in an underwater environment,
such as environmental impact surveillance, marine life, oil and
gas exploration is essential in underwater. In this regard, underwater wireless communication (UWC) has become a significant
field. Optical, acoustic and electromagnetic waves have been
widely used for data transmission in UWC. Investigation of
possible UWC techniques has an influential impact on wireless
communications. Nowadays, UWC is being used for experimental observation, oceanographic data collection and analysis,
underwater navigation, disaster prevention and early detection
warning of a tsunami. This work presents an overview, main
initiatives and up-to-date contributions of the most widely used
UWC techniques, i.e, underwater wireless optical, acoustic and
electromagnetic communications. In addition, we summarize
emerging technologies in the UWC, future research directions
and recommendations using fifth generation (5G) communication
techniques.
Transfer (SWIPT) technique is introduced in Radio Frequency
(RF) communication to carry both information and power in
same medium. In this approach, the energy can be harvested
while decoding the information carries in an RF wave. Recently,
the same concept applied in Visible Light Communication
(VLC) namely Simultaneous Light Wave Information
and Power Transfer (SLIPT), which is highly recommended in
an indoor applications to overcome the problem facing in RF
communication. Thus, SLIPT is introduced to transmit the power
through a Light Emitting Diode (LED) luminaries. In this work,
we compare both SWIPT and SLIPT technologies and realize
SLIPT technology archives increased performance in terms of
the amount of harvested energy, outage probability and error
rate performance
by water in the form of oceans. The oceans are unexplored
and very far-fetched to investigate due to distinct phenomenal
activities in the underwater environment. Underwater wireless
communication (UWC) plays a significant role in observation
of marine life, water pollution, oil and gas rig exploration,
surveillance of natural disasters, naval tactical operations for
coastal securities and to observe the changes in the underwater
environment. In this regard, the widespread adoption of UWC
has become a vital field of study to envisage various military
and commercial applications that have been growing interest to
explore the underwater environment for numerous applications.
Acoustic, Optical and RF wireless carriers have been chosen to
be used for data transmission in an underwater environment.
The internet of underwater things (IoUT) and next-generation
(5G) networks have a great impact on UWC as they support the
improvement of the data rate, connectivity, and energy efficiency.
In addition to the potential emerging UWC techniques, assisted
by 5G network and improve existing work is also focusing
in this study. This survey presents a comprehensive overview
of existing UWC techniques, with possible future directions
and recommendations to enable the next generation wireless
networking systems in the underwater environment. The current
project schemes, applications and deployment of latest amended
UWC techniques are also discussed. The main initiatives and
contributions of current wireless communication schemes in
underwater for improving quality of service (QoS) and quality
of energy (QoE) of the system over long distances are also
mentioned.
(UOWCs) are promising and potential wireless carriers
to envisage underwater phenomenal activities for various
applications towards the futuristic 5G and beyond (5GB)
wireless systems. The main challenges to deploy underwater
applications are the physicochemical properties and strong
turbulence channel conditions. In this regard, the end-to-end
(E2E) performance analysis of a dual-hop mixed FSO/UVLC
system under the intensity modulation/direct detection (IM/DD)
technique in consideration of pulse amplitude modulation
(PAM) scheme is investigated. Throughout this study, to tackle
the issues of moderate-to-strong turbulence channel conditions,
this work deploys the Gamma-Gamma (GG) distribution
fading model and the links are designed by unifying plane
wave models in the corresponding links, respectively. This
investigation outperforms higher achievable data rate with
minimal delay response and enhance network connectivity in
real-time monitoring scenarios as compared with the traditional
underwater wireless communication technologies. In more
contrast, the probability distribution function (PDF), cumulative
distribution function (CDF), and closed-form expression of
the system are derived and presented in terms of Meijer-G
function as well as Extended Generalized Bivariate Meijer-G
Function (EGBMGF). The significant E2E performance metrics
are obtained by employing the decode-and-forward (DF) relay
protocol in hostile channel conditions. In aggregating this work,
we combine the analytical expressions that present an efficient
tool to depict the impact of channel parameters on the system.
The simulation results are plausible of the system performance
metrics as average BER (ABER) and outage probability (Pout)
in the presence of pointing and without pointing error events.
Finally, in this work, we use the Monte-Carlo approach for the
best fitting curves and validate the numerical expression yields
simulation results.
found and covered more than seventy percent with it. Monitoring
different phenomenal activities in an underwater environment,
such as environmental impact surveillance, marine life, oil and
gas exploration is essential in underwater. In this regard, underwater wireless communication (UWC) has become a significant
field. Optical, acoustic and electromagnetic waves have been
widely used for data transmission in UWC. Investigation of
possible UWC techniques has an influential impact on wireless
communications. Nowadays, UWC is being used for experimental observation, oceanographic data collection and analysis,
underwater navigation, disaster prevention and early detection
warning of a tsunami. This work presents an overview, main
initiatives and up-to-date contributions of the most widely used
UWC techniques, i.e, underwater wireless optical, acoustic and
electromagnetic communications. In addition, we summarize
emerging technologies in the UWC, future research directions
and recommendations using fifth generation (5G) communication
techniques.
Transfer (SWIPT) technique is introduced in Radio Frequency
(RF) communication to carry both information and power in
same medium. In this approach, the energy can be harvested
while decoding the information carries in an RF wave. Recently,
the same concept applied in Visible Light Communication
(VLC) namely Simultaneous Light Wave Information
and Power Transfer (SLIPT), which is highly recommended in
an indoor applications to overcome the problem facing in RF
communication. Thus, SLIPT is introduced to transmit the power
through a Light Emitting Diode (LED) luminaries. In this work,
we compare both SWIPT and SLIPT technologies and realize
SLIPT technology archives increased performance in terms of
the amount of harvested energy, outage probability and error
rate performance
by water in the form of oceans. The oceans are unexplored
and very far-fetched to investigate due to distinct phenomenal
activities in the underwater environment. Underwater wireless
communication (UWC) plays a significant role in observation
of marine life, water pollution, oil and gas rig exploration,
surveillance of natural disasters, naval tactical operations for
coastal securities and to observe the changes in the underwater
environment. In this regard, the widespread adoption of UWC
has become a vital field of study to envisage various military
and commercial applications that have been growing interest to
explore the underwater environment for numerous applications.
Acoustic, Optical and RF wireless carriers have been chosen to
be used for data transmission in an underwater environment.
The internet of underwater things (IoUT) and next-generation
(5G) networks have a great impact on UWC as they support the
improvement of the data rate, connectivity, and energy efficiency.
In addition to the potential emerging UWC techniques, assisted
by 5G network and improve existing work is also focusing
in this study. This survey presents a comprehensive overview
of existing UWC techniques, with possible future directions
and recommendations to enable the next generation wireless
networking systems in the underwater environment. The current
project schemes, applications and deployment of latest amended
UWC techniques are also discussed. The main initiatives and
contributions of current wireless communication schemes in
underwater for improving quality of service (QoS) and quality
of energy (QoE) of the system over long distances are also
mentioned.