Plain Text:
A. K. Mandal, S. Misra, T. Ojha, M. K. Dash and M. S. Obaidat, "Effects of Wind-Induced Near-Surface Bubble Plumes on the Performance of Underwater Wireless Acoustic Sensor Networks," in IEEE Sensors Journal, vol. 16, no. 11, pp. 4092-4099, June1, 2016.
doi: 10.1109/JSEN.2015.2443012
keywords: {acoustic wave absorption;acoustic wave scattering;bubbles;energy consumption;error statistics;telecommunication power management;underwater acoustic communication;wind;wireless sensor networks;wind-induced near-surface bubble plume effects;underwater wireless acoustic sensor network performance;UWASN overall performance analysis;subsurface ocean water column;surface ocean water column;windy oceanic environment;acoustic signal propagation;scattering effects;network protocol;absorption effects;acoustic communication media;packet delivery ratio reduction;energy consumption per node improvement;signal-to-interference-plus-noise ratio reduction;bit error rate improvement;Wind speed;Sea surface;Sensors;Mathematical model;Spectral shape;Underwater wireless acoustic sensor networks;bubble plumes;path loss;acoustic communication;Underwater wireless acoustic sensor networks;bubble plumes;path loss;acoustic communication},
URL: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7120073&isnumber=7462310
BibTeX:
@ARTICLE{7120073,
author={A. K. {Mandal} and S. {Misra} and T. {Ojha} and M. K. {Dash} and M. S. {Obaidat}},
journal={IEEE Sensors Journal},
title={Effects of Wind-Induced Near-Surface Bubble Plumes on the Performance of Underwater Wireless Acoustic Sensor Networks},
year={2016},
volume={16},
number={11},
pages={4092-4099},
keywords={acoustic wave absorption;acoustic wave scattering;bubbles;energy consumption;error statistics;telecommunication power management;underwater acoustic communication;wind;wireless sensor networks;wind-induced near-surface bubble plume effects;underwater wireless acoustic sensor network performance;UWASN overall performance analysis;subsurface ocean water column;surface ocean water column;windy oceanic environment;acoustic signal propagation;scattering effects;network protocol;absorption effects;acoustic communication media;packet delivery ratio reduction;energy consumption per node improvement;signal-to-interference-plus-noise ratio reduction;bit error rate improvement;Wind speed;Sea surface;Sensors;Mathematical model;Spectral shape;Underwater wireless acoustic sensor networks;bubble plumes;path loss;acoustic communication;Underwater wireless acoustic sensor networks;bubble plumes;path loss;acoustic communication},
doi={10.1109/JSEN.2015.2443012},
ISSN={2379-9153},
month={June},}