Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Gominski, Dimitri, Brandt, Martin, Tong, Xiaoye, Liu, Siyu, Mugabowindekwe, Maurice, Li, Sizhuo, Reiner, Florian, Davies, Andrew, Fensholt, Rasmus
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2508.21437
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866912558911324160
author Gominski, Dimitri
Brandt, Martin
Tong, Xiaoye
Liu, Siyu
Mugabowindekwe, Maurice
Li, Sizhuo
Reiner, Florian
Davies, Andrew
Fensholt, Rasmus
author_facet Gominski, Dimitri
Brandt, Martin
Tong, Xiaoye
Liu, Siyu
Mugabowindekwe, Maurice
Li, Sizhuo
Reiner, Florian
Davies, Andrew
Fensholt, Rasmus
contents Trees are key components of the terrestrial biosphere, playing vital roles in ecosystem function, climate regulation, and the bioeconomy. However, large-scale monitoring of individual trees remains limited by inadequate modelling. Available global products have focused on binary tree cover or canopy height, which do not explicitely identify trees at individual level. In this study, we present a deep learning approach for detecting large individual trees in 3-m resolution PlanetScope imagery at a global scale. We simulate tree crowns with Gaussian kernels of scalable size, allowing the extraction of crown centers and the generation of binary tree cover maps. Training is based on billions of points automatically extracted from airborne lidar data, enabling the model to successfully identify trees both inside and outside forests. We compare against existing tree cover maps and airborne lidar with state-of-the-art performance (fractional cover R$^2 = 0.81$ against aerial lidar), report balanced detection metrics across biomes, and demonstrate how detection can be further improved through fine-tuning with manual labels. Our method offers a scalable framework for global, high-resolution tree monitoring, and is adaptable to future satellite missions offering improved imagery.
format Preprint
id arxiv_https___arxiv_org_abs_2508_21437
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Trees as Gaussians: Large-Scale Individual Tree Mapping
Gominski, Dimitri
Brandt, Martin
Tong, Xiaoye
Liu, Siyu
Mugabowindekwe, Maurice
Li, Sizhuo
Reiner, Florian
Davies, Andrew
Fensholt, Rasmus
Computer Vision and Pattern Recognition
Trees are key components of the terrestrial biosphere, playing vital roles in ecosystem function, climate regulation, and the bioeconomy. However, large-scale monitoring of individual trees remains limited by inadequate modelling. Available global products have focused on binary tree cover or canopy height, which do not explicitely identify trees at individual level. In this study, we present a deep learning approach for detecting large individual trees in 3-m resolution PlanetScope imagery at a global scale. We simulate tree crowns with Gaussian kernels of scalable size, allowing the extraction of crown centers and the generation of binary tree cover maps. Training is based on billions of points automatically extracted from airborne lidar data, enabling the model to successfully identify trees both inside and outside forests. We compare against existing tree cover maps and airborne lidar with state-of-the-art performance (fractional cover R$^2 = 0.81$ against aerial lidar), report balanced detection metrics across biomes, and demonstrate how detection can be further improved through fine-tuning with manual labels. Our method offers a scalable framework for global, high-resolution tree monitoring, and is adaptable to future satellite missions offering improved imagery.
title Trees as Gaussians: Large-Scale Individual Tree Mapping
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2508.21437