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http://hdl.handle.net/10553/130733
Title: | Detection of Coastal Erosion and Progradation in the Colombian 'Atrato River' Delta by Using Sentinel-1 Synthetic Aperture Radar Data | Authors: | Vasquez Salazar, Ruben Dario Cardona Mesa, Ahmed Alejandro Valdes-Quintero, Juan Olmos-Severiche, Cesar Gomez, Luis Travieso-González, Carlos M. Diaz-Paz, Jean Pierre Espinosa-Ovideo, Jorge Ernesto Diez-Rendon, Lorena Garavito-Gonzalez, Andres F. Vasquez-Cano, Esteban |
UNESCO Clasification: | 3325 Tecnología de las telecomunicaciones | Keywords: | South-America Water Synthetic Aperture Radar (Sar) Speckle Computer Vision, et al |
Issue Date: | 2024 | Journal: | Remote Sensing | Abstract: | This paper presents a methodology to detect the coastal erosion and progradation effects in the 'Atrato River' delta, located in the Gulf of Uraba in Colombia, using SAR (Synthetic Aperture Radar) images. Erosion is the physical-mechanical loss of the soil that affects its functions and ecosystem services while producing a reduction in its productive capacity. Progradation is the deposition of layers in the basinward direction while moving coastward. Other studies have investigated these two phenomena using optical images, encountering difficulties due to the persistent presence of clouds in this region. In order to avoid the cloud effects, in this study, we used 16 Sentinel 1 SAR images with two different polarizations between 2016 and 2023. First, each image was rescaled from 0 to 255, then the image was despeckled by a deep learning (DL) model. Afterwards, a single RGB image was composed with the filtered polarizations. Next, a classifier with 99% accuracy based on Otsu's method was used to determine whether each pixel was water or not. Then, the classified image was registered to a reference one using Oriented FAST and Rotated BRIEF (ORB) descriptor. Finally, a multitemporal analysis was performed by comparing every image to the previous one to identify the studied phenomena, calculating areas. Also, all images were integrated to obtain a heatmap that showed the overall changes across eight years (2016-2023) in a single image. The multitemporal analysis performed found that the newly created mouth is the most active area for these processes, coinciding with other studies. In addition, a comparison of these findings with the Oceanic Nino Index (ONI) showed a relative delayed coupling to the erosion process and a coupling of progradation with dry and wet seasons. | URI: | http://hdl.handle.net/10553/130733 | DOI: | 10.3390/rs16030552 | Source: | Remote Sensing,v. 16 (3), (Febrero 2024) |
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