Abstract
Abstract. Tree segmentation is an active and ongoing research area in the field of photogrammetry and remote sensing. It is more challenging due to both intra-class and inter-class similarities among various tree species. In this study, we exploited various statistical features for extraction of hazelnut trees from 1 : 5000 scaled digital orthophoto maps. Initially, the non-vegetation areas were eliminated using traditional normalized difference vegetation index (NDVI) followed by application of mean shift segmentation for transforming the pixels into meaningful homogeneous objects. In order to eliminate false positives, morphological opening and closing was employed on candidate objects. A number of heuristics were also derived to eliminate unwanted effects such as shadow and bounding box aspect ratios, before passing them into the classification stage. Finally, a knowledge based decision tree was constructed to distinguish the hazelnut trees from rest of objects which include manmade objects and other type of vegetation. We evaluated the proposed methodology on 10 sample orthophoto maps obtained from Giresun province in Turkey. The manually digitized hazelnut tree boundaries were taken as reference data for accuracy assessment. Both manually digitized and segmented tree borders were converted into binary images and the differences were calculated. According to the obtained results, the proposed methodology obtained an overall accuracy of more than 85 % for all sample images.
Highlights
Photogrammetry and remote sensing techniques have widely been used to obtain spatial distribution information of tree species over large geographic areas
A dataset consisting of 10 digital orthophoto maps was used for evaluation of the proposed methodology
All available bands (R, G, B, and near infrared (NIR)) as well as normalized difference vegetation index (NDVI) index were used for classification
Summary
Photogrammetry and remote sensing techniques have widely been used to obtain spatial distribution information of tree species over large geographic areas. The information can be used for better understanding of the tree species ecology and their contribution to the ecosystem functions (Fassnacht et al, 2016) Various applications, such as forest management (Schultz, Verbesselt, Avitabile, Souza, & Herold, 2016), biodiversity monitoring (van Ewijk, Randin, Treitz, & Scott, 2014), environment monitoring (Zhou, Divakarla, Liu, Weng, & Goldberg, 2016) etc. Zhang et al, 2008) This response can be used to distinguish between various types of land surface objects such as build area, vegetation, bare land, water bodies etc. These characteristics have been successfully employed for forest cover type classification e.g. These characteristics have been successfully employed for forest cover type classification e.g. (Immitzer, Atzberger, & Koukal, 2012; Laliberte & Rango, 2006; Y. Zhang, 2001)
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