Characterization of bigeye tuna habitat in the Southern Waters off Java-Bali using remote sensing data

Martiwi Diah Setiawati; Abu Bakar Sambah; Fusanori Miura; Tasuku Tanaka; Abd. Rahman As-syakur

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Characterization of bigeye tuna habitat in the Southern Waters off Java-Bali using remote sensing data

机译：利用遥感数据表征爪哇-巴厘岛南部水域大眼金枪鱼栖息地

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摘要

Bigeye tuna (Thunnus obesus) habitat was investigated based on catch data and environmental satellite data, such as sea surface temperature (SST), sea surface chlorophyll (SSC), and sea surface height deviation (SSHD) data in the Southern Waters off Java and Bali. First, we obtained daily fish catch data and monthly satellite data for SST, SSC, and SSHD for 2006-2010. Then, we analyzed the relationship between daily catch data and satellite data by combining the statistical method of generalized additive model (GAM) and geographic information system (GIS). Seven GAM models were generated with the number of bigeye tuna as a response variable, and SST, SSC, and SSHD as predictor variables. All of the predictors of SST, SSC, and SSHD were highly significant (P ＜ 0.001) to the number of bigeye tuna. Values of SST, SSHD, and SSC in bigeye tuna habitat ranged from 24.8 to 28.7 ℃, -3 to 7 cm, and 0.05 to 0.17 mg/m~3, respectively. Validation of the predicted number of bigeye tuna with the observed value was significant (P ＜ 0.05, r~2 = 0.56). SST was the most important environmental variable to the number of bigeye tuna caught, followed by SSHD and SSC.

机译：根据捕获数据和环境卫星数据（例如，爪哇岛南部水域的海表温度（SST），海表叶绿素（SSC）和海表高度偏差（SSHD））数据，对大眼金枪鱼（Thunnus obesus）栖息地进行了调查。巴厘岛首先，我们获得了2006-2010年SST，SSC和SSHD的每日渔获量数据和每月卫星数据。然后，我们结合广义可加模型（GAM）和地理信息系统（GIS）的统计方法，分析了每日捕获数据与卫星数据之间的关系。生成了七个GAM模型，其中大眼金枪鱼的数量为响应变量，SST，SSC和SSHD为预测变量。 SST，SSC和SSHD的所有预测指标对大眼金枪鱼数量均具有极高的显着性（P ＜0.001）。大眼金枪鱼栖息地的SST，SSHD和SSC值分别在24.8至28.7℃，-3至7 cm和0.05至0.17 mg / m〜3之间。用观测值对大眼金枪鱼预测数量的验证具有统计学意义（P ＜0.05，r〜2 = 0.56）。 SST是捕获的大眼金枪鱼数量最重要的环境变量，其次是SSHD和SSC。

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来源
《Advances in space research 》 |2015年第2期| 732-746| 共15页
作者
Martiwi Diah Setiawati; Abu Bakar Sambah; Fusanori Miura; Tasuku Tanaka; Abd. Rahman As-syakur;
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作者单位

Graduate School of Science and Engineering, Department of Environmental Science and Engineering, Yamaguchi University, 2-16-1 Tokiwadai, Ube 755-8611, Japan,Center for Remote Sensing and Ocean Science (CReSOS), Udayana University, Sudirman Campus, Post Building (3rd Fl), Jl. P.B. Sudirman, Denpasar-Bali 80232, Indonesia;

Graduate School of Science and Engineering, Department of Environmental Science and Engineering, Yamaguchi University, 2-16-1 Tokiwadai, Ube 755-8611, Japan,Marine Science Department, Faculty of Fisheries and Marine Science, Brawijaya University, Jl. Veteran, Malang 65145, Indonesia;

Graduate School of Science and Engineering, Department of Environmental Science and Engineering, Yamaguchi University, 2-16-1 Tokiwadai, Ube 755-8611, Japan;

Center for Remote Sensing and Ocean Science (CReSOS), Udayana University, Sudirman Campus, Post Building (3rd Fl), Jl. P.B. Sudirman, Denpasar-Bali 80232, Indonesia;

Center for Remote Sensing and Ocean Science (CReSOS), Udayana University, Sudirman Campus, Post Building (3rd Fl), Jl. P.B. Sudirman, Denpasar-Bali 80232, Indonesia,Marine Science Department, Faculty of Marine and Fisheries, Udayana University, Bukit Jimbaran Campus, Bali 80361, Indonesia,Center for Remote Sensing and Ocean Science (CReSOS), Udayana University, Sudirman Campus, Post Building (3rd Fl), Jl. P.B. Sudirman, Denpasar-Bali 80113 Indonesia;

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正文语种 eng
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关键词
Bigeye tuna; SST; SSC; SSHD; GAM; Remote sensing;

机译：大眼金枪鱼;SST;SSC;SSHD;GAM;遥感;

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Characterization of bigeye tuna habitat in the Southern Waters off Java-Bali using remote sensing data

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