Mapping Seagrass Biodiversity Indicators of Pari Island using Multiple WorldView-2 Bands Derivatives

Geosfera Indonesia Pub Date : 2023-08-29 DOI:10.19184/geosi.v8i2.41214

P. Wicaksono, S. D. Harahap

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Abstract

Comprehensive information on seagrass biodiversity indicators, such as species composition, percentage cover, and biomass carbon stock, remains limited across various regions globally. Mapping these indicators using remote sensing images requires extracting maximum information from the input images to achieve effective results. This study aims to map seagrass distribution, percent cover (PC), and aboveground carbon stock (AGC) as biodiversity indicators in the optically shallow waters surrounding Pari Island. We integrate WorldView-2 (WV2) derivatives, field seagrass data, and RF classification and regression algorithms to accomplish this objective. The WV2 image derivatives encompass surface reflectance bands, band ratios, mean and variance co-occurrence texture bands, and principle component bands. These inputs are used individually and collectively for mapping, employing a random forest algorithm trained with field seagrass data. Our results demonstrate that the most accurate benthic habitat map achieves an overall accuracy (OA) of 65.2%, with a user's accuracy of 65.2% and a producer's accuracy of 72.8% for the seagrass-dominated class. Seagrass PC mapping yields a root mean square error (RMSE) of 17.1%, with an average PC of 47.4 ± 9.9%. Seagrass AGC mapping achieves an RMSE of 5.0 g C m-2, with an average AGC range of 6.2 – 29.1 g C m-2, estimating the study area's aboveground biomass carbon stock at 27.9 tons C. Combined inputs produce the most accurate results for all biodiversity indicators, emphasizing the importance of utilizing combined bands from SR band derivatives to maximize information input for training mapping algorithms, instead of using derivative bands individually or as replacements for the initial SR bands. Keywords : Seagrass; Biodiversity; Mapping; WorldView-2; Pari Island Copyright (c) 2023 Geosfera Indonesia and Department of Geography Education, University of Jember This work is licensed under a Creative Commons Attribution-Share A like 4.0 International License

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利用多个WorldView-2波段衍生物绘制巴黎岛海草生物多样性指标

在全球不同地区，关于海草生物多样性指标(如物种组成、覆盖百分比和生物量碳储量)的综合信息仍然有限。利用遥感图像绘制这些指标需要从输入图像中提取最大限度的信息，以获得有效的结果。本研究旨在绘制Pari岛周围光浅水域的海草分布、覆盖百分比(PC)和地上碳储量(AGC)作为生物多样性指标。我们整合了WorldView-2 (WV2)衍生工具、野外海草数据以及RF分类和回归算法来实现这一目标。WV2图像导数包括表面反射率波段、波段比、均方差共现纹理波段和主成分波段。这些输入被单独和集体用于制图，采用经过实地海草数据训练的随机森林算法。结果表明，最精确的底栖生物栖息地地图总体精度(OA)为65.2%，其中用户精度为65.2%，生产者精度为72.8%。海草PC图谱的均方根误差(RMSE)为17.1%，平均PC值为47.4±9.9%。海草AGC制图的RMSE为5.0 g C m-2，平均AGC范围为6.2 ~ 29.1 g C m-2，估计研究区地上生物量碳储量为27.9 t C。综合输入对所有生物多样性指标产生最准确的结果，强调利用SR波段衍生的组合波段来最大化训练制图算法的信息输入的重要性，而不是单独使用衍生波段或替代初始SR波段。关键词:海草;生物多样性;映射;WorldView-2;版权所有(c) 2023 Geosfera Indonesia and Department of Geography Education, University of Jember本作品采用知识共享署名共享4.0国际许可协议

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Geosfera Indonesia

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16 weeks