Masters Degrees (Geography and Environmental Studies)
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Browsing Masters Degrees (Geography and Environmental Studies) by Author "Bessinger, Mariel"
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- ItemFlood mapping in the Zambezi Region using Synthetic Aperture Radar(Stellenbosch : Stellenbosch University, 2016-03) Bessinger, Mariel; Kemp, Jaco; Luck-Vogel, Melanie; Stellenbosch University. Faculty of Arts and Social Sciences. Dept. of Geography and Environmental Studies.ENGLISH ABSTRACT: Floods occur annually in the Zambezi Region during the rainy seasons, causing economic losses and social disruption. Projected changes in climate and land use could worsen the effects of floods. SAR sensors are active sensors and operate in the microwave region and are therefore not restricted by time of day or inclement weather, making them well-suited for flood monitoring. The aim of this research is to examine the use of ASAR and PALSAR images (with acquisition dates ranging from 17 March 2009 to 30 May 2009) to determine flood extent by classifying open water bodies in the Zambezi Region using two different approaches: binary thresholding and active contour models (ACMs) using the Canny edge detector as initial contour. Classified images were then statistically and visually compared to Landsat images. For ASAR images, overall accuracies ranged between 70% and 99% for the threshold classification method and 58% and 98% for ACMs. For PALSAR images, overall accuracy ranged between 54% and 91% for the threshold classification method and between 60% and 96% for ACMs. Results obtained were adequate for both methods of classification, with thresholds only slightly outperforming ACMs for ASAR images, and ACMs only slightly outperforming thresholds for PALSAR images. These methods are binary classifications, which was acceptable for delineating open water bodies, but flooded vegetation areas were present and methods need to be extended to include these areas. Sensor properties such as wavelength, incidence angle and polarisation have an effect on the effectiveness of identifying flooded water bodies. Longer wavelengths are better suited for open water detection than shorter wavelengths, because of better penetration capabilities than shorter wavelengths. Shallower incidence angles are better suited for open water detection, but steeper incidence angles are better suited for flooded vegetation. HH-polarised imagery performed the best for open water body detection when open water surfaces were smooth, but cross-polarisations performed best when surface roughness was present. Therefore, HH- and HV- polarisations should provide sufficient discriminatory power required for open water and flooded vegetation regions.