Abstract
ABSTRACTEarth observation has rapidly evolved into a state-of-the-art technology providing new capabilities and a wide variety of sensors; nevertheless, it is still a challenge for practitioners external to a specialized community of experts to select the appropriate sensor, define the imaging mode requirements, and select the optimal classifier or retrieval method for the task at hand. Especially in wetland mapping, studies have relied largely on vegetation indices and hyperspectral data to capture vegetation attributes. In this study, we investigate the capabilities of a concurrently acquired very high spatial resolution airborne hyperspectral and lidar data set at the peak of aquatic vegetation growth in a nature reserve at Lake Balaton, Hungary. The aim was to examine to what degree the different remote-sensing information sources (i.e. visible and near-infrared hyperspectral, vegetation indices and lidar) are contributing to an accurate aquatic vegetation map. The results indicate that de-noised hyperspectral information in the visible and very near-infrared bands (400–1000 nm) is performing most accurately. Inclusion of lidar information, hyperspectral infrared bands (1000–2500 nm), or extracted vegetation indices does not improve the classification accuracy. Experimental results with algorithmic comparisons show that in most cases, the Support Vector Machine classifier provides a better accuracy than the Maximum Likelihood.
Highlights
In situ data are the most reliable source of information for aquatic species vegetation mapping; a proximate field collection scheme for a large geographic area at frequent intervals is a cumbersome task, if not impossible
The maps contain solely classes of emergent macrophytes typically encountered around Lake Balaton
The overall accuracy ranges from 41.79% for the lidar data set with Maximum Likelihood (ML) classification to 88.64% for the Eagle data set with Support Vector Machine (SVM)
Summary
In situ data are the most reliable source of information for aquatic species vegetation mapping; a proximate field collection scheme for a large geographic area at frequent intervals is a cumbersome task, if not impossible. Spatial structure and a lack of crisp boundaries between habitat types. This high variability of plant species and their spatial distribution requires information acquired at a fine scale and with a high radiometric discriminatory capability. Such a case is the aquatic vegetation around Lake Balaton, Hungary, which is the largest (596 km2) freshwater lake in Central Europe (Virág 1997). It encompasses a total area of approximately 11 km of reeds stretching along 112 km of the shoreline and has suffered intense reed dieback from 1970s onwards (Kovács et al 1989)
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