Abstract
We presented a methodology to accurately classify mountainous regions in the tropics. These landscapes are complex in terms of their geology, ecosystems, climate and land use. Obtaining accurate maps to assess land cover change is essential. The objectives of this study were to (1) map vegetation using the Random Forest Classifier (RFC), spectral vegetation index (SVI), and ancillar geographic data (2) identify important variables that help differentiate vegetation cover, and (3) assess the accuracy of the vegetation cover classification in hard-to-reach Ecuadorian mountain region. We used Landsat 7 ETM+ satellite images of the entire scene, a RFC algorithm, and stratified random sampling. The altitude and the two band enhanced vegetation index (EVI2) provide more information on vegetation cover than the traditional and often use normalized difference vegetation index (NDVI) in other settings. We classified the vegetation cover of mountainous areas within the 1016 km2 area of study, at 30 m spatial resolution, using RFC that yielded a land cover map with an overall accuracy of 95%. The user´s accuracy and the half-width of the confidence interval for 95% of the basic map units, forest (FOR), páramo (PAR), crop (CRO) and pasture (PAS) were 95.85% ± 2.86%, 97.64% ± 1.24%, 91.53% ± 3.35% and 82.82% ± 7.74%, respectively. The overall disagreement was 4.47%, which results from adding 0.43% of quantity disagreement and 4.04% of allocation disagreement. The methodological framework presented in this paper and the combined use of SVIs, ancillary geographic data, and the RFC allowed the accurate mapping of hard-to-reach mountain landscapes as well as uncovering the underlying factors that help differentiate vegetation cover in the Ecuadorian mountain geosystem.
Highlights
Vegetation cover is the set of biophysical attributes of a land surface; its behavior is the cumulative result of several factors that exert control, including climate, soil, altitude gradients, physiography, Geosciences 2017, 7, 34; doi:10.3390/geosciences7020034 www.mdpi.com/journal/geosciencesGeosciences 2017, 7, 34 and biological aspects
This hierarchical framework must be taken with caution because the correlation among the variables could have had an impact on the relative assessment of importance but do not affect the predictive performance of a Random Forest Classifier (RFC)
EVI2 provide more information on vegetation cover than the traditional normalized difference vegetation index (NDVI) and soil adjusted vegetation index (SAVI), when the reflectance of red is low, and the NDVI is “saturated”, as it occurs in conditions of high chlorophyll production
Summary
Vegetation cover is the set of biophysical attributes of a land surface; its behavior is the cumulative result of several factors that exert control, including climate, soil, altitude gradients, physiography, Geosciences 2017, 7, 34; doi:10.3390/geosciences7020034 www.mdpi.com/journal/geosciencesGeosciences 2017, 7, 34 and biological aspects. The information obtained from monitoring changes in vegetation cover and land use can quantify the effects of primary sources of soil degradation such as deforestation, and the dynamic alteration and transformation of land use over time. This information can serve as essential input in an early warning system for the possible occurrence of potential and irreversible changes in the functionalities of a mountain ecosystem. The ability to remotely map the vegetation cover of mountain geosystems makes it possible to perform environmental analyses that cannot be conducted in the field while monitoring changes in land use. Vegetation cover analysis is based on defining a classification scheme and a categorization method that allows the identification of primary units
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