TY - GEN
T1 - On UWOC Uplink Transmission with Spatially Random Underwater Sensors
AU - Deng, Hang
AU - Si, Yanci
AU - Liu, Jingjing
AU - Tian, Yu
AU - Pan, Gaofeng
AU - Wang, Shuai
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - As a promising technology, underwater wireless optical communication (UWOC) offers several advantages over traditional underwater acoustic communication, including higher bandwidth, greater security, and lower latency. Optical communication enables real-time image or video transmission, facilitating aquatic resource exploration and sensing applications. In this work, we investigate the outage performance of a UWOC transmission system consisting of multiple underwater sensors uniformly distributed in a specific water area and a relay floating on the water surface. The outage probability of the considered system is affected by various factors, including the location randomness of the sensors and the propagation loss and turbulence-induced fading. Thus, the impacts of these factors are modeled by integrating geometric probability theory in this work to establish a framework for theoretical analysis of UWOC end-to-end performance. Numerical results show that the increase in the number of underwater sensors can lower the outage probability, and turbulence-induced fading has a positive effect on outage performance compared to the scenario without fading for the considered transmit power range in this work.
AB - As a promising technology, underwater wireless optical communication (UWOC) offers several advantages over traditional underwater acoustic communication, including higher bandwidth, greater security, and lower latency. Optical communication enables real-time image or video transmission, facilitating aquatic resource exploration and sensing applications. In this work, we investigate the outage performance of a UWOC transmission system consisting of multiple underwater sensors uniformly distributed in a specific water area and a relay floating on the water surface. The outage probability of the considered system is affected by various factors, including the location randomness of the sensors and the propagation loss and turbulence-induced fading. Thus, the impacts of these factors are modeled by integrating geometric probability theory in this work to establish a framework for theoretical analysis of UWOC end-to-end performance. Numerical results show that the increase in the number of underwater sensors can lower the outage probability, and turbulence-induced fading has a positive effect on outage performance compared to the scenario without fading for the considered transmit power range in this work.
KW - geometric probability
KW - outage probability
KW - turbulence-induced fading
KW - underwater wireless optical communication
UR - http://www.scopus.com/inward/record.url?scp=85179000020&partnerID=8YFLogxK
U2 - 10.1109/ICCSN57992.2023.10297367
DO - 10.1109/ICCSN57992.2023.10297367
M3 - Conference contribution
AN - SCOPUS:85179000020
T3 - 2023 15th International Conference on Communication Software and Networks, ICCSN 2023
SP - 286
EP - 290
BT - 2023 15th International Conference on Communication Software and Networks, ICCSN 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 15th International Conference on Communication Software and Networks, ICCSN 2023
Y2 - 21 July 2023 through 23 July 2023
ER -