Abstract
Abstract. Vegetation includes a significant class of terrestrial ecosystem. Information on tree species categorization is important for environmentalists, foresters, agriculturist, urban managers, landscape architects and biodiversity conservationist. The traditional methods of measuring and identifying tree species (i.e., through field-based survey) are time taking, laborious and costly. Remote sensing data provides an opportunity to identify and classify vegetation species over a large spatial extent. Hyperspectral remote sensing can detect the sublet spectral details among species classes and thus make it possible to differentiate vegetation species based on these subtle variations. This research examines the thermal infrared (2.5 to 14.0 μm) hyperspectral emissivity spectra (comprised of 3456 spectral bands) for the classification of thirteen different plant species. The use of thermal infrared hyperspectral emissivity spectra for the identification of vegetation species is very rare. Three different machine learning methods including support vector machine (SVM), artificial neural network (ANN) and convolutional neural network (CNN) are used to classify thirteen vegetation species and their performance is assessed based on their overall accuracy. The accuracy obtained by CNN, ANN and SVM is 99%, 94% and 91%, respectively. Each classifier was also tested for the advantage associated with increase in training samples or object segmentation size. Increase in the training samples improved the performance of SVM. In a nutshell, all comparative machine learning methods provide very high classification accuracy and CNN outperformed the comparative methods. This study concludes that thermal infrared hyperspectral emissivity data has the potential to discern vegetation species using state of the art machine learning and deep learning methods.
Highlights
1.1 BackgroundIdentifying tree species through statistical classification is an essential step to manage, store, and guard forestry resources
This study provides machine learning approach for identifying certain vegetation species using hyperspectral data in the thermal infrared band
Duro et al Experienced similar issues with their classification, highlighting that limited test samples can result in incorrect classification accuracies in the same way, Congalton explains that a large quantity of zeroes within the confusion matrix could mean that the test sample size is inadequate or classification very successful
Summary
Identifying tree species through statistical classification is an essential step to manage, store, and guard forestry resources. Satellite images comprise pixels showing different ground objects with identifiable brightness values, letting the statistical classification of objects like vegetation and shrubs, due to their spectral signs. Imagery type is a key feature in classification because the spectral and spatial resolutions can affect the classification accuracy. Three to around eight image stacks of multispectral bands are usually utilized for distinguishing land covers or forest cover (broadleaf, conifer) classification. Hyperspectral stack of data comprises many (usually around 64 to 256) successive thinner bands, giving more details that permits the classification of small spectral differences among forest covers. Even with more quantity of information present in hyperspectral imagery, discerning the identical genus species might be tough, often reducing the classification accuracy. Clark et al observes that the use of hyperspectral data essentially performs better than the use of multispectral data
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