Abstract
Abstract. Automatic image classification is one of the fundamental problems of remote sensing research. The classification problem is even more challenging in high-resolution images of urban areas, where the objects are small and heterogeneous. Two questions arise, namely which features to extract from the raw sensor data to capture the local radiometry and image structure at each pixel or segment, and which classification method to apply to the feature vectors. While classifiers are nowadays well understood, selecting the right features remains a largely empirical process. Here we concentrate on the features. Several methods are evaluated which allow one to learn suitable features from unlabelled image data by analysing the image statistics. In a comparative study, we evaluate unsupervised feature learning with different linear and non-linear learning methods, including principal component analysis (PCA) and deep belief networks (DBN). We also compare these automatically learned features with popular choices of ad-hoc features including raw intensity values, standard combinations like the NDVI, a few PCA channels, and texture filters. The comparison is done in a unified framework using the same images, the target classes, reference data and a Random Forest classifier.
Highlights
Automatic image classification is one of the fundamental problems of remote sensing research
Note that the widely used per-pixel principal component analysis (PCA) projection is different from the PCAfeatures listed below
The aim of the present study has been to evaluate the influence of different image features on land-cover classification in images of high spatial resolution
Summary
Automatic image classification is one of the fundamental problems of remote sensing research. The classification of urban areas in high-resolution images is even more challenging, because many relevant objects are small, and because at small ground sampling distance (GSD) fine texture details become visible, such that the spectral variation within one class increases. Remote sensing of urban areas is becoming more important (Yang, 2011), since nowadays more and more people live in cities. There is an increased need for geo-spatial data to support the management of urban zones. The classification process involves two steps: first, one has to derive features from raw observations in order to represent local radiometric properties. Classification method which, given the previously extracted features, estimates the most likely landcover class, has to be applied
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