Observation of aquatic biota in eutrophied pond using stationary acoustic monitoring system

2013 IEEE International Underwater Technology Symposium (UT) Pub Date : 2013-03-05 DOI:10.1109/UT.2013.6519813

K. Mizuno, K. Abukawa, T. Kashima, A. Asada, T. Ura, Y. Fujimoto, T. Shimada

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Abstract

Active acoustic monitoring system using a dual frequency identification sonar (DIDSON) is applied for the follow-up observation of aquatic biota after Hydrilla verticillata planting. The field experiment was performed in a small pond adjacent to Lake Izunuma (northern latitude of 38.43 degrees and east longitude of 141.04 degrees; surface area, 1,584 m2), and 24 Hydrilla verticillata were prepared and planted at the pond bottom. The DIDSON unit was mounted on an original frame with a 3 degree concentrator lens. The data were collected at 1.8 MHz (high-frequency mode) and at a maximum range of 3.0 m from the imaging sonar. The frame rate was 2 fps and the recording time was about 20 hours. Successfully, we found out the cause of plants disappearance by the acoustic imaging data. All Hydrilla verticillata were disappeared in a day and strongly affected by the predation pressure of crayfish, and whole scene of feeding was recorded. Other aquatic creatures, such as snail, frog, and several species of fish, were also appeared in the acoustic images. Then, we have originally developed an image processing program and quantified the biological features of the aquatic creatures for the better understanding of aquatic biota in freshwater environment.

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固定式声学监测系统对富营养化池塘水生生物群的观察

采用双频识别声呐(DIDSON)主动声监测系统对水螅种植后水生生物群进行跟踪观察。野外试验在出津沼湖附近的一个小池塘(北纬38.43度，东经141.04度)进行;池底种植水蛭24株，面积1584 m2)。DIDSON单元安装在原始框架上，带有3度聚光镜头。数据采集频率为1.8 MHz(高频模式)，距离成像声纳最大距离为3.0 m。帧率为2fps，录制时间约为20小时。我们成功地利用声成像数据找出了植物消失的原因。受小龙虾捕食压力的影响，水螅在1天内全部消失，并记录了整个摄食过程。其他水生生物，如蜗牛、青蛙和几种鱼类，也出现在声学图像中。然后，我们首先开发了图像处理程序，并对水生生物的生物学特征进行了量化，以便更好地了解淡水环境中的水生生物群。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 IEEE International Underwater Technology Symposium (UT)

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