Abstract
Individual tree extraction is an important process for forest resource surveying and monitoring. To obtain more accurate individual tree extraction results, this paper proposed an individual tree extraction method based on transfer learning and Gaussian mixture model separation. In this study, transfer learning is first adopted in classifying trunk points, which can be used as clustering centers for tree initial segmentation. Subsequently, principal component analysis (PCA) transformation and kernel density estimation are proposed to determine the number of mixed components in the initial segmentation. Based on the number of mixed components, the Gaussian mixture model separation is proposed to separate canopies for each individual tree. Finally, the trunk stems corresponding to each canopy are extracted based on the vertical continuity principle. Six tree plots with different forest environments were used to test the performance of the proposed method. Experimental results show that the proposed method can achieve 87.68% average correctness, which is much higher than that of other two classical methods. In terms of completeness and mean accuracy, the proposed method also outperforms the other two methods.
Highlights
As a new active remote sensing technology, Light Detection and Ranging (LiDAR)technology has been developing very rapidly in recent years
This paper proposed an individual tree extraction method based on the transfer learning and Gaussian mixture model separation
Two individual tree point clouds with label information are used as the transfer learning source domain
Summary
As a new active remote sensing technology, Light Detection and Ranging (LiDAR)technology has been developing very rapidly in recent years. As a new active remote sensing technology, Light Detection and Ranging (LiDAR). Compared with the traditional passive optical remote sensing measurements, LiDAR technology can obtain data quickly and accurately [1]. It is less affected by the external light conditions and can obtain laser pulses from the earth around 24 h [2,3,4]. The three-dimensional (3D) structure of the canopy and the terrain under the forest can be measured [7,8,9]. LiDAR technology has more advantages in detecting the structure and function of the forest ecosystem. Terrestrial LiDAR has become an important technique for forest resource surveying and monitoring [10,11,12,13]
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