350 rub
Journal Radioengineering №11 for 2016 г.
Article in number:
Wireless system of high-speed underwater optical communication for real time transmission of video data
Keywords:
underwater optical communication
video data transmission
underwater images
processing of images
Authors:
S.N. Kirillov - Dr. Sc. (Eng.), Professor, Head of Department of Radio Management and Communication, Ryazan State Radio Engineering University
E-mail: kirillov.lab@mail.ru
I.V. Kostkin - Ph. D. (Eng.), Associate Professor, Department of Radio Management and Communication, Ryazan State Radio Engineering University
E-mail: kost_vk@mail.ru
Abstract:
The model of laser radiation propagation in the aqueous medium has been developed. It allows calculating and choosing main elements for the system of wireless high-speed underwater optical communication. Prototype of the optical receive/transmit module for wireless transmission of video data from a board of a submersible in the real time mode has been developed. Laboratory and field tests of the developed prototype of the system of wireless high-speed underwater optical communication have been executed. As a result, the researches have shown that under fixed possibility of a bit error the developed prototype ensures transmission speed up to 100 Mb/s and communication range 100−150 m that exceeds foreign analogues.
Pages: 80-89
References
- Francois R.E. et al. Unmanned Arctic research submersible (UARS) system development and test report // Technical Report. Applied Physics Laboratory, University of Washington. 1972. № APL-UW 7219.
- Bellingham J.G. Streitlien K., Overland J., Rajan S., Stein P., Stannard J., Kirkwood W., Yoerger D. An Arctic Basin observation capability using AUVs// Oceanography. 2000. V. 13. № 2. P. 4−70.
- Doronin JU.P. Fizika okeana. SPb.: Gidrometeoizdat. 1978. 296 s.
- SHifrin K.S. Vvedenie v optiku okeana. SPb.: Gidrometeoizdat. 1983. 281 s.
- Pratt V. Lazernye sistemy svjazi: Per. s angl. pod red. A.G. SHeremeteva. M.: Svjaz. 1972. 232 s.
- Heather Brundage. Designing a Wireless Underwater Optical Communication System. Master of Science in Mechanical Engineering at the Massachusetts Institute of Technology. 2010. 87 p.
- Shlomi Arnon. Underwater optical wireless communication network // Journal of optical engineering. January 2010. 110 p.
- Hanson, Frank andStojan Radic. High bandwidth underwater optical communication // Optical Society of America. 10 January 2008. Applied Optics. V. 47. 90 p.
- Kirillov S.N., Baljuk S.A., Kuznecov S.N., Esenin A.S. Razrabotka modeli rasprostranenija opticheskogo signala v vodnojj srede dlja podvodnykh sistem peredachi informacii // Vestnik RGRTU (Rjazan). 2012. № 2 (vyp. 40). S. 3−8.
- Kostkin I.V., Pushkin V.A., Locmanov A.A., Korsukov D.I. Algoritm uluchshenija kachestva podvodnykh izobrazhenijj // Vestnik RGRTU (Rjazan). 2012. № 40. S. 40−46.
- Garcia R., Nicosevici T., Cufi X. On the way to solve lighting problems in underwater imaging// IEEE OCEAN. 02 October 2002. P. 1018−1024.
- McGlamery B.L. A computer model for underwater camera system // Proc. SPIE. 1979. P. 221−231.
- Kirillov S.N., Kostkin I.V., Dmitriev V.T. Opticheskijj kanal peredachi videoizobrazhenijj s podvodnykh mobilnykh robotov dlja raznykh tipov vod i klimaticheskikh zon // Morskie informacionno-upravljajushhie sistemy. 2014. № 3 (6) S. 44−51.
- Liu Z., Y. Yu, Zhang K., Huang H. Underwater image transmission and blurred image restoration // SPIE Journal of optical Engineering. June 2001. V. 40(6). P. 1125−1131.
- Sidorov D.N., ANil C. Kokaram. Suppression of moir´e patterns via spectral analysis // Proceedings of SPIE in Visual Communications and Image Processing. January 2002. P. 475−493.
- Adelson E.H. Lightness perception and lightness illusions // The New Cognitive Neurisciences. Cambridge: MIT. 2000. P. 201−247.
- Kostkin I.V. Algoritm vejjvlet-szhatija nepodvizhnykh cifrovykh izobrazhenijj // Vestnik RGRTU (Rjazan). 2007. № 20. S. 114−117.
- Kirillov S.N., Kostkin I.V. Algoritm ehkvalizacii na osnove mnogokomponentnogo beta-raspredelenija jarkosti izobrazhenija // Vestnik RGRTU (Rjazan). 2007. № 21. S. 12−15.
- Bekhtin Y.S. Onboard joint nondestructive despeckling and wavelet-based data compression of multilook synthetic aperture radar images using reordered spatial orient trees // Journal of Applied Remote Sensing. 2015. V. 9(1). P. 097494. doi:10.1117/1.JRS.9.097494.
- Catipovic J. Performance Limitation in Underwater Acoustic Telemetry // IEEE J. Oceanic Eng. July 1990. P. 205−216.
- Ahlen J. Color correction of underwater images using spectral data // Thesis of Uppsala University: Centre for Image Analysis. 2005. P. 114−123.
- Snow J.B., Flatley J.P., Freeman D.E., Landry M.A., Lindstrom C.E., Longacre J.E., Shwartz J.A. Underwater propagation of high data rate laser communication pulses // SPIE 1750. 1992. P. 419−427.
- Bales J.W. and Chryssostomidis C. High handwidth, low-power, shot range optical communications under-water // International Symposium on Unhanned Untethered Submersible Technology. 1995. № 9. P. 406−415.
- Chancey M.A. Short range underwater communication links // Master thesis, North Carolina state University. 2005.
- Pat. RF na izobretenie № 2526207. Apparatura podvodnojj opticheskojj svjazi / Dmitriev V.T., Kirillov S.N., Kuznecov S.N., Locmanov A.A., Poljakov S.JU. Patentoobladatel: Federalnoe gosudarstvennoe bjudzhetnoe obrazovatelnoe uchrezhdenie vysshego professionalnogo obrazovanija «Rjazanskijj gosudarstvennyjj radiotekhnicheskijj universitet». Data publikacii patenta: 20.08.2014.
- Kirillov S.N., Kostkin I.V., Pushkin V.A. Algoritm predskazanija videoposledovatelnosti na osnove metoda bisekcijj // Vestnik RGRTU (Rjazan). 2013. № 4−1 (46). S. 38−41.