Abstract
Mapping of subtidal banks in mud-dominated coastal systems is crucial as they influence not only shoreline and ecosystem dynamics but also economic activities and livelihoods of local communities. Due to associated spatiotemporal variations in suspended particulate matter concentrations, subtidal mudbanks are often confined by diffuse and rapidly changing boundaries. To avoid inaccurate representations of these mudbanks in remote sensing images, it is necessary to unmix distinctive reflectance signals into representative landcover fractions. Yet, extracting mud fractions, in order to characterize such diffuse boundaries, is challenging because of the spectral similarity between subtidal- and intertidal features. Here we show that an unsupervised decision tree, used to derive spatially explicit and spectrally coherent image endmembers, facilitates robust linear spectral unmixing on an image-to-image basis, enabling the separation of these coastal features. We found that resulting abundance maps represent cross-shore gradients of vegetation, water and mud fractions present at the coast of Suriname. Furthermore, we confirmed that it is possible to separate land, water and an initial estimate of intertidal zones on individual images. Thus, spectral signatures of end-member candidates, determined from relevant index histograms within these initial estimates, are consistent. These results demonstrate that spectral information from well-defined spatial neighbourhoods facilitates the detection of diffuse boundaries of mudbanks with a spectral unmixing approach.
Highlights
Mapping boundaries of geomorphological landforms in mud-dominated coasts is crucial for integrated coastal management, and for understanding landscape evolution in these dynamic areas (Koo hafkan and Gibson, 2018)
We found that the canny edge algorithm complemented with buffer and length filters results in a consistent, spatially explicit and robust neighbourhood zone when the minimum gradient (MG) and Gaussian pre-filter (GPF) are set appropriately
We developed a data-driven method that facilitates the detection of diffuse boundaries of subtidal banks along mud-dominated coastlines, as exemplified for a section of the Suriname coast
Summary
Mapping boundaries of geomorphological landforms in mud-dominated coasts is crucial for integrated coastal management, and for understanding landscape evolution in these dynamic areas (Koo hafkan and Gibson, 2018). These landforms are often associated with the distribution of large sediment concentrations, originating from highdischarge rivers such as the Amazon, Mississippi and Yangtze rivers (Murray et al, 2019). In some settings the presence of fluid mud can trigger the formation of subtidal mudbanks along open coasts (Anthony et al, 2010) These banks are associated with extreme spatiotemporal variations in suspended particulate matter (SPM) concentrations in the water col umn (Gratiot and Anthony, 2016). It is vital to monitor mud-bank dynamics, to support adaptive coastal management- and conservation strategies that account for material exchange between these banks and the coastline
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