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Abstract
This paper presents  design and implementation of underwater optical communication system . The system consists of transmitter, water channel, and receiver. The laser diode used as a transmitter at 530 – 540 nm wavelength in CW mode with 100 mw power. The channel is about glass pool its dimensions (1m, 0.5m, 0.5m) with different samples of water . The receiver consists of photodiode detector and amplification circuit. This system transmits data from PC to another PC through water channel at different samples. The result shows the difference in the received signal at different tested water samples..
Index Term: optical communication, laser diode, LED , amplification.Â##plugins.themes.academic_pro.article.details##
How to Cite
Raipure, P. A. V., Dhande, D. A. P., & Deshmukh, D. S. M. (2015). Design and Analysis of Optical Communication for Underwater Applications. International Journal of Emerging Trends in Science and Technology, 2(06). Retrieved from https://igmpublication.org/ijetst.in/index.php/ijetst/article/view/721
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3. M. Doniec and D. Rus, "BiDirectional optical communication with AquaOptical II," in Communication Systems (ICCS), 2010 IEEE International Conference on, pp. 390-394, 2010.
4. R. J. Green and M. G. McNeill, "Bootstrap transimpedence amplifier: a new configuration," Circuits, Devices and Systems, IEEE Proceedings G, vol. 136, pp. 57-61, 1989.
5. I. Vasilescu, C. Detweiler and D. Rus, "AquaNodes: An underwater sensor network," in Proceedings of the Second Workshop on Underwater Networks, Montreal, QC, Canada, pp. 85-88, Sept. 9-14 2007.
6. J. Simpson, "A 1 Mbps Underwater Communications System using LEDs and Photodiodes with Signal Processing Capability," M.S. thesis, Dept. of Elec. and Comp. Eng., North Carolina State University,Raleigh, NC, 2007.
7. W. Cox, "A 1 Mbps Underwater Communication System Using a 405 Laser Diode and Photomultiplier Tube," M.S. thesis, Dept. of Elec. and Comp. Eng., North Carolina State University, Raleigh, NC, 2007.
8. F. Hanson and S. Radic, "High bandwidth underwater optical communication," Appl. Opt., vol. 47, no. 2, pp. 277-283, Jan. 08.
9. B. Cochenour, L. Mullen and A. Laux, "Phase coherent digital communications for wireless optical links in turbid underwater environments," in Oceans 07, Vancouver, BC, Canada, Oct. 2-3 07.
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11. C.Detweiller, I. Vasilescu, and D. Rus, ―AquaNodes:an underwater sensor network,‖ in Proc. Second Int.Workshop on Underwater Networks, pp. 85–88, IEEE (2007).
12. D. Kedar and S. Arnon, ―Subsea ultraviolet solarblind broadband free-space optics communication,‖ Opt.Eng. 48(4), 046001(2009).
13. S. Jaruwatanadilok, ―Underwater wireless optical communication channel modelling and performance evaluation using vector radiative Transfer theory,‖ IEEE J. Sel. Areas Commun.