| 光谱学与光谱分析 |
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| Improvement of Light Source for Algae Fluorescence Imaging System |
| WANG Min |
| School of Physics and Opto-Electronics Technology,Fujian Normal University,Fuzhou 350007,China |
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Abstract A real time algae fluorescence imaging system is introduced in the present paper. The light source is an important part of algae fluorescence imaging system. Algae image definition is directly influenced by the light source of red tide monitor system,and different red tide algae has different texture character,which decides the nicety of recognizing harmful algae and category. For solving the definition of algae imaging,the authors analyzed and compared images with different light sources using the fluorescence imaging system designed ourselves. The result shows that near infrared light source can effectively show algae texture,so that the image processing is more effective and easier.
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Received: 2007-05-10
Accepted: 2007-08-20
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Corresponding Authors:
WANG Min
E-mail: mwang@fjnu.edu.cn
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[1] http://www.gd.xinhuanet.com/newscenter/ztbd/2003-08/08/content_797851.htm.
[2] GU De-yu,XU De-wei,CHEN Hai-ying(顾德宇,许德伟,陈海颖). Remote Sensing Technology and Application(遥感技术与应用),2003,18(6):434.
[3] ZHANG Qian-qian,WANG Xiu-lin,ZHU Chen-jian(张前前,王修林,祝陈坚). Marine Environmental Science(海洋环境科学),2004,23(1):73.
[4] LI Chun-qiang,LIU Zhi-xin,CHANG Ming-jin,et al(李春强,刘志昕,常明进,等). Journal of South China University of Tropical Agriculture(华南热带农业大学学报),2006,12(3):63.
[5] Walker R F,Ishikawa K,Kumagai M. Journal of Microbiological Methods,2002,51:149.
[6] http://www.coi.gov.cn/hyzh/ccao/redtide/index.html.
[7] LIU Feng-jun,CAO Hong-bao,WANG Xue-min,et al(刘凤军,曹红宝,王学民,等). Journal of Tianjin University(天津大学学报),2005,38(12):1073.
[8] CUI Ting-wei,ZHANG Jie,MA Yi,et al(崔廷伟,张 杰,马 毅,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(5): 884.
[9] CHEN Jia-bi(陈家璧). Laser Theory & Application(激光原理及应用). Beijing:Publishing House of Electronics Industry(北京: 电子工业出版社),2006. 185.
[10] XU Lei,YU Lian-sheng(徐 雷,于连生). Ocean Technology(海洋技术),2003,22(3):43. |
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