Korean Journal of Fisheries and Aquatic Sciences (한국수산과학회지)

The Korean Society of Fisheries and Aquatic Science (한국수산과학회)
권호 표지
DOI QR코드

DOI QR Code

Characteristics of Spectral Irradiance Based on the Distance from the Light Source and Operating Method for Fishing Lamps with a Combined Light Source

이종(異種) 광원 조합에 의한 복수 광원의 분광 방사특성과 광달(光達) 거리 및 집어등 운용방법

  • Choi, Sok-Jin (Machinery & Metals and Construction Examinations Bureau, Korean Intellectual Property Office)
  • 최석진 (특허청 기계금속건설심사국)
  • Published : 2009.12.31
Download PDF
⟨ Previous Next ⟩

Abstract

Characteristics of spectral irradiance based on the distance from the light source, which combined metal halide lamp and high-luminance light-emitting diode (LED) light, were studied to investigate a suitable operating method for fishing lamps of the next generation. A 380-780 nm wavelength radiation was superior when using 1 W electrical power in the order of metal halide lamp, blue LED, white LED, and combined LED lights. The wavelengths at which the irradiance was at a maximum were fixed to 581 nm for the light source, which was combined for each ratio. If the irradiance characteristics at 300-1100 nm wavelengths were set as 100%, the irradiance rates at 400-599 nm were 100%, 72.7%, 88.9%, and 69.5% for the blue, white, combined LED lights, and metal halide lamp, respectively. This indicated that the color rendering of the LED lights was dependent on the metal halide lamp light source. When the horizontal profiles (450-550 nm wavelength) of irradiances were compared to a different type of light source in the ratio white LED: combined LED lights: blue LED: metal halide lamp, the irradiated area of more than $0.01\;{\mu}mol/s/m^2/nm$ was in the ratio 1.0 : 1.3 : 1.7 : 37.3, respectively. Based on the radiation characteristics and irradiance according to the distance from the light source, LED lights have an estimated economic efficiency if used before and after operation of a metal halide lamp.

Keywords

References

  1. An YI, Jeong HG and Jung BM. 2009. Behaviroal reaction of common squid Todarodes pacificus to different colors of LED light. J Korean Fish Tech 45, 135-143 https://doi.org/10.3796/KSFT.2009.45.3.135
  2. Arakawa H, Choi SJ, Arimoto T and Nakamura Y. 1998. Relationship between underwater irradiance and distribution of Japanese common squid under fishing lights of a squid jigging boat. Fisheries Science 64, 553-557
  3. Bae BS, Jeong EC, Park HH, Chang DS and Yang YS. 2008. Behaviroal characteristic of Japanese flying squid Todarodes pacificus to LED light. J Korean Fish Tech 44, 294-303 https://doi.org/10.3796/KSFT.2008.44.4.294
  4. Bae BS, Park BJ, Jeong EC, Yang YS, Park HH, Chun YY and Chang DS. 2009. Design and performance evaluation of fish-luring system using the air cooled LED lamp for jigging and angling boat. J Korean Fish Tech 45, 85-95 https://doi.org/10.3796/KSFT.2009.45.2.085
  5. Choi SJ and Arimoto T. 1996. Corroborative field research, In: Report of rationalization of the light power on small-type squid jigging boat. National federation of fisheries co-operative associations, Tokyo, Japan, 1-14
  6. Choi SJ. 1997. Rationalization of the light power output on small-size squid jigging boat. Ph.D. Thesis, Tokyo University of Fisheries, Tokyo, Japan
  7. Choi SJ, Nakamura Y and Arimoto T. 1997. Hrizontal illuminance of line source model for fishing lamps around the coastal squid jigging boats. Nippon Suisan Gakkaishi 63, 160-165 https://doi.org/10.2331/suisan.63.160
  8. Choi SJ, Arakawa H, Nakamura Y and Arimoto T. 1998. Transmittance characteristics of fishing light according to the optical water type in the squid jigging ground of the Sea of Japan. Nippon Suisan Gakkaishi 64, 650-657 https://doi.org/10.2331/suisan.64.650
  9. Choi SJ and Arakawa H. 2001. Relationship between the Catch of Squid, Todarodes pacificus Steenstrup, according to the Jigging Depth of Hooks and Underwater Illumination in Squid Jigging Boat. J Korean Fish Soc 34, 624-631
  10. Choi SJ, Kim DA and Kim DS. 2002a. Present state and future prospect of Korean squid jigging fishery. Technical Report of National Research Institude of Fisheries Engineering 24, 1-13
  11. Choi SJ, Watanabe T and Honda N. 2002b. Abstract, Ann Meet Jap Soc Fish 113
  12. Choi SJ, Arakawa H, Arimoto T and Nakamura Y. 2003c. Underwater illuminance of line light source model for fishing lamps of coastal squid jigging boats. Nippon Suisan Gakkaishi 69, 44-51 https://doi.org/10.2331/suisan.69.44
  13. Choi SJ and Nakamura Y. 2003a. Analysis of the optimum light source output and lighting management in coastal squid jigging boat. Fisheries engeering 40, 39-46
  14. Choi SJ and Nakamura Y. 2003b. Spatial distribution of squid jigging boats and shortest distance between boats in fishing ground of the Japan Sea in the summer season by radar observation. Nippon Suisan Gakkaishi 69, 584-590 https://doi.org/10.2331/suisan.69.584
  15. Choi SJ and Shin JC. 2003. Color Engineering. Kukje publish, Seoul, Korea, 71-124
  16. Choi SJ. 2006. Radiation and underwater transmission characteristics of a high-luminance light emitting diode as the light source for fishing lamp. J Kor Fish Soc 39, 480-486
  17. Choi SJ. 2008. Comparison of Radiation Characteristics and Radiant Quantities per unit Electrical Power between High Luminance Light Emitting Diode and Fishing Lamp Light Source. J Kor Fish Soc 41, 511-517
  18. Choi SJ. 2009. Spectral Irradiance and Underwater Transmission Characteristics of a Combined High-Luminance Light-Emitting Diodes as the Light Source for Fishing Lamps. J Kor Fish Soc 42, 703-710
  19. Hara T. 1968. Photosensitive Pigments in the Cephalopod Retina. Zoological Magazine 77, 99-108
  20. Hasegawa E. 1998. Study on measurement of spectral sensitive under scotopic conditions using optomoter reaction in fishes. NipponSuisan Gakkaishi 64, 626-630
  21. Inada H, Inoue D, Sato M, Miyagi Y, Inoue S, Watanabe T, Sano E, Noda M, Hamade S and Fuzihara S. 2006. Abstract, Ann Meet Jap Soc Fish 7
  22. Inoue D, Inada H, Miyagi Y, Inoue S, Watanabe T. Sano E, Noda M, Yamamoto T and Hamade S. 2006. Abstract, Ann. Meet. Jap Soc Fish 8
  23. Jerlov NG. 1964. Optical classification of ocean water, In: Physical aspects of light in the sea. Hawaii University Press, Honolulu, pp. 45-49
  24. Kuroki T. 1989. Measurement of Ocean environment, Kouseisya, Tokyo, Japan, pp. 18-70
  25. Okamoto K, Kato D, Morimoro K, Yanagi T and Ochi T. 2001. Development of fishing lamp using bluish-color light emitting diode, 2001 National Convention Record I.E.E. Japan, 373
  26. Ohta N. 1993. Color Engineering. Tokyo Denki University Press, Tokyo, Japan, 115-170
  27. Osaka N. 1998. Handbook of color science. The Color Science Association of Japan, University of Tokyo Press, Tokyo, Japan, pp. 1-85
  28. Park C, Choi Y and Kim C. 2008. Study on consumption improvement in SI engine with EGR for hybrid electric vehicle. Transactions of KSAE 16, 128-135
  29. Son WK. 2009. Development condition and business trend of illumination LED markets. IT Comin mailzine 29, 20-26
  30. Yamaguchi S. 1987. Lighting Handbook. The Illuminating Engineering Institute of Japan, Ohmsha, Tokyo, Japan, pp. 609

Cited by

  1. Simulation of undewater irradiance distribution in coastal squid jigging vessel using the LED and metal halide fishing lamp combination vol.50, pp.4, 2014, https://doi.org/10.3796/KSFT.2014.50.4.511
  2. The Optical Characteristics of 240 W High Power LED Fish Luring Lamp vol.19, pp.6, 2013, https://doi.org/10.7837/kosomes.2013.19.6.681
  3. Computational Modeling of a Sliding Type LED Fishing Lamp Mounting System for Dynamic Stress Analysis vol.17, pp.2, 2009, https://doi.org/10.17958/ksmt.17.2.201504.341
  4. Preliminary Study on Development of Ship-Rolling-Motion-Adaptive LED Fishing Lamp System vol.34, pp.8, 2009, https://doi.org/10.7736/kspe.2017.34.8.563
  5. Optimization of LED fishing lamp allocation based on numerical modeling in Pacific saury fishery vol.87, pp.3, 2021, https://doi.org/10.1007/s12562-021-01513-w