DOI QR코드

DOI QR Code

Verification of Practicality for the SSBL and Pinger Synchronizing Biotelemetry Method and System through the Tracking of Fish

어류의 행동추적에 의한 SSBL · 핑거동기 바이오텔레메터리 방식과 시스템의 실용성 검증

  • Published : 2004.02.01

Abstract

The new biotelemetry method and system that the installation and the treatment of equipment is convenient and the instantaneously detailed position of the fish attached a pinger is able to track comparatively easily had been developed, an practicality of it were verified in the water tank and the small sea port through the tracking of fish. The biotelemetry method had been gotten the three dimensional locations of fish to the receiving transducer by combining of the super short base line (SSBL) method to detect the direction of pinger and the pinger synchronizing method to measure the range from receiving transducer to pinger. The receiving system had been designed to realize the high precision or wide detection range by application of the basic design method for receiving system of biotelemetry and the hydrophone array configuration. From tracking test of carp in the water tank, the migration course and the velocity of carp was investigated and the observed migration course was compared with measurement. The measured migration course of carp coincided with the observation in the main and the position of carp was able to track three dimensionally. The velocity of carp measured by the moving average method was 11.2cm/s. From tracking test of yellowtail in the small sea port, the migration course and the velocity of yellowtail was investigated at natural condition. The position of yellowtail was able to track three dimensionally and the velocity of it measured by moving average method was 43.9cm/s.

Keywords

biotelemetry;SPB method;SSBL method;pinger synchronizing method;three dimensional tracking

References

  1. Freon, P., Gerlotto, F., and Soria, M. (1993) : Variability of Harengula spp. school reactions to boats or predators in shallow water, ICES. mar. Sci. Symp., 196, 30-35
  2. Gerlotto, F., Soria, M., and Freon, P. (1999) : From two dimensions to three: the use of multibeam sonar for a new approach in fisheries acoustics, Can. J. Fish. Aquat. Sci., 56, 6-12 https://doi.org/10.1139/cjfas-56-1-6
  3. Gilchrist, I., MacDonald, A.G., and Priede, I. (1983) : Divers, submersibles and unmanned vehicles. In : MacDonald, A.G. and Priede, I.G. (eds)Experimental biology at sea, Academic Press, London, 367-386
  4. Klepaker, R.A, Vestgard, K., Hallset, J.O., and Knudsen, F.T. (1986) : A free swimming ROV. In: Wernli, R.L. and Chapman, R. (eds) Remotely operated vehicles: Technology requirement present and future, Graham & Trotmarn, London, 273-282
  5. Metcalfe, J.D. and Arnold, G.P. (1997) : Tracking fish with electronic tags, Nature, 387, 665-666 https://doi.org/10.1038/42622
  6. Misund, O.A (1993): Dynamics of moving masses: variability in packing density, shape, and size among herring, sprat, and saithe schools, ICES J. mar. Sci., 50, 145-160 https://doi.org/10.1006/jmsc.1993.1016
  7. Nielsen, L.A. (1992): Methods of marking fish and shellfish, Aamerican Fisheries Society Special Publication, 23, 208
  8. Niezgoda, G.H., McKinley, R.S., White, D., Anderson, G., and Cote, D. (1998) : A dynamic combined acoustic and radio transmitting tag for diadromous fish, Hydrobiologia, 371/372, 47-52 https://doi.org/10.1023/A:1017010802404
  9. O'Dor, R.K. and Webber, D.M. (1998): A brief history of marine fish and invertebrate tagging. In: Stone, G.S., Tausig, H.C., and Schubel, J.R. (eds) Marine Animal Telemetry Tags, New England Aquarium, Boston, 17 -27
  10. Stasko, A.B. and Pincock, D.G. (1977) : Review of underwater biotelemetry, with emphasis on ultrasonic techniques, J. Fish. Res. Board Can., 34, 1261-1285
  11. Traynor, J.J. and Ehrenberg, J.E. (1990) : Fish and standard-sphere target-strength measurements obtained with a dual-beam and split-beam echosounding system, Rapp. P. -v. Reun. Cons. int. Explor. Mer, 189, 325-335
  12. Urquhart, G.G. and Stewart, P.A.M. (1993) : A review of techniques for the observation of fish behaviour in the sea, ICES mar. Sci. Symp., 196, 135-139
  13. 能勢幸雄, 羽生功, 岩井保, 淸水誠 (1989) : 魚の 事典, 東京堂出版, 東京, 363-364
  14. 古澤昌彦 澤田造一 (1991) : スプリシ卜ビーム方 式に 測角誤差, 海洋音響學會講演論 文集, 835-836
  15. 古澤昌彦 澤田造一, 有路寶, 山谷恭三, 創都建治 (1994) : 計量魚探機用複合ビーム送受波 器の開發, 海洋音響學會講演論文集, 63-66
  16. 朴住三, 古澤昌彦 (2002) : 超音波バイオテレメトリの音響系 評價および設計方法, 日本水 産學會誌, 68, 334-344
  17. 早乙女造一 (1996) : 標識技術現狀. '月刊海洋 種苗放流をめぐる諸問題' (櫻井識人, 櫻井 辭人編), 海洋出版柱式會社, 東京, 610-616
  18. 李遺元, 向井撤, 飯田浩二 (2000) :スキヤニング ンーナーを用いた船舶の接近に對する魚群 行動評價法, 日本水産學會誌, 66, 825-832
  19. 박주삼, 古澤昌彦 (2003a) : SSBL 방식과 핑거동기 방식을 조합한 바이오텔레메터리 방식의 개발(1) -시스템의 설계 및 제작-, 한국어업기술학회지, 39, 218-229
  20. 박주삼, 古澤昌彦 (2003b) : SSBL 방식과 핑거동기 방식을 조합한 바이오텔레메터리 방식의 개발(2) -시스템이 정도 평가-, 한국어업기술학회지, 39, 318-325