Abstract
Seagrass meadows are one of the blue carbon ecosystems that continue to decline worldwide. Frequent mapping is essential to monitor seagrass meadows for understanding change processes including seasonal variations and influences of meteorological and oceanic events such as typhoons and cyclones. Such mapping approaches may also enhance seagrass blue carbon strategy and management practices. Although unmanned aerial vehicle (UAV) aerial photography has been widely conducted for this purpose, there have been challenges in mapping accuracy, efficiency, and applicability to subtidal water meadows. In this study, a novel method was developed for mapping subtidal and intertidal seagrass meadows to overcome such challenges. Ground truth seagrass orthophotos in four seasons were created from the Futtsu tidal flat of Tokyo Bay, Japan, using vertical and oblique UAV photography. The feature pyramid network (FPN) was first applied for automated seagrass classification by adjusting the spatial resolution and normalization parameters and by considering the combinations of seasonal input data sets. The FPN classification results ensured high performance with the validation metrics of 0.957 overall accuracy (OA), 0.895 precision, 0.942 recall, 0.918 F1-score, and 0.848 IoU, which outperformed the conventional U-Net results. The FPN classification results highlighted seasonal variations in seagrass meadows, exhibiting an extension from winter to summer and demonstrating a decline from summer to autumn. Recovery of the meadows was also detected after the occurrence of Typhoon No. 19 in October 2019, a phenomenon which mainly happened before summer 2020.
Highlights
Coastal blue carbon ecosystems, such as mangroves, salt marshes, and seagrass meadows, play a crucial role in supplying environmental functions such as providing shelter for fisheries, performing water purification, enhancing soil stability, decreasing coastal erosion, supplementing nutrients, protecting coastlines [1], and mitigating climate change by sequestering carbon from the atmosphere [2]
Value increased with a decrease in the resolution from 0.05 to 2 m and decreased, with the highest overall accuracy (OA) value of 0.971 achieved at a 2 m resolution, a finding which is consistent with the previous cognition for drone image classifications [56]
The seagrass area significantly increased from winter to summer andfor seagrass classification [26], and our results revealed that the feature pyramid network (FPN) was more suitable decreased from summer to autumn
Summary
Coastal blue carbon ecosystems, such as mangroves, salt marshes, and seagrass meadows, play a crucial role in supplying environmental functions such as providing shelter for fisheries, performing water purification, enhancing soil stability, decreasing coastal erosion, supplementing nutrients, protecting coastlines [1], and mitigating climate change by sequestering carbon from the atmosphere [2]. They are regarded as the most efficient ecosystem for carbon storage but are the most rapidly disappearing ecosystem worldwide. Passive remote sensing (Quickbird2 [12], IKONOS [13], Landsat 5, and Landsat 7 [14]) and active remote sensing
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