2017
DOI: 10.3390/rs9090885
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Comparing Fuzzy Sets and Random Sets to Model the Uncertainty of Fuzzy Shorelines

Abstract: This paper addresses uncertainty modelling of shorelines by comparing fuzzy sets and random sets. Both methods quantify extensional uncertainty of shorelines extracted from remote sensing images. Two datasets were tested: pan-sharpened Pleiades with four bands (Pleiades) and pan-sharpened Pleiades stacked with elevation data as the fifth band (Pleiades + DTM). Both fuzzy sets and random sets model the spatial extent of shoreline including its uncertainty. Fuzzy sets represent shorelines as a margin determined … Show more

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Cited by 4 publications
(2 citation statements)
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References 52 publications
(78 reference statements)
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“…The coastline can also be built based on tidecoordinated coastline, for example, by referring to the mean high water line whose information is obtained, for example using LIDAR data or field measurements (Liu, 2008;Kim, Lee and Min, 2017). Furthermore, the coastline can also be generated by classifying beach features using remote sensing images, namely by extracting water and non-water pixels, for example from multispectral, radar and hyperspectral images (Al Fugura, Billa and Pradhan, 2011;Dewi, Bijker and Stein, 2017).…”
Section: Integrating Elevation and Bathymetry Extracting Coastlinesmentioning
confidence: 99%
“…The coastline can also be built based on tidecoordinated coastline, for example, by referring to the mean high water line whose information is obtained, for example using LIDAR data or field measurements (Liu, 2008;Kim, Lee and Min, 2017). Furthermore, the coastline can also be generated by classifying beach features using remote sensing images, namely by extracting water and non-water pixels, for example from multispectral, radar and hyperspectral images (Al Fugura, Billa and Pradhan, 2011;Dewi, Bijker and Stein, 2017).…”
Section: Integrating Elevation and Bathymetry Extracting Coastlinesmentioning
confidence: 99%
“…The second category consisted of image-based methods, which extracted instantaneous shoreline data from images whose acquisition time was correlated with tidal data-for instance, shoreline mapping from digital photogrammetry [13] and remote sensing imagery [14]. Since remotely sensed images record a shoreline at a particular instant, modelling shoreline with remote sensing images should include estimation of its uncertainty [15,16]. The uncertainty in shoreline modelling can arise, due to an inherent variability in nature, such as variation of a shoreline over time and the presence of gradual transitions between land and water [17,18].…”
Section: Introductionmentioning
confidence: 99%