Estimating Canopy Height at Scale

Jan Pauls, Max Zimmer, Una M. Kelly, Martin Schwartz, Sassan Saatchi, Philippe Ciais, Sebastian Pokutta, Martin Brandt, Fabian Gieseke

ICML 2024 pp. 39972-39988

/icml/2024/pauls2024icml-estimating/

Abstract

We propose a framework for global-scale canopy height estimation based on satellite data. Our model leverages advanced data preprocessing techniques, resorts to a novel loss function designed to counter geolocation inaccuracies inherent in the ground-truth height measurements, and employs data from the Shuttle Radar Topography Mission to effectively filter out erroneous labels in mountainous regions, enhancing the reliability of our predictions in those areas. A comparison between predictions and ground-truth labels yields an MAE/RMSE of 2.43 / 4.73 (meters) overall and 4.45 / 6.72 (meters) for trees taller than five meters, which depicts a substantial improvement compared to existing global-scale products. The resulting height map as well as the underlying framework will facilitate and enhance ecological analyses at a global scale, including, but not limited to, large-scale forest and biomass monitoring.

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Cite

Text

Pauls et al. "Estimating Canopy Height at Scale." International Conference on Machine Learning, 2024.

Markdown

[Pauls et al. "Estimating Canopy Height at Scale." International Conference on Machine Learning, 2024.](https://mlanthology.org/icml/2024/pauls2024icml-estimating/)

BibTeX

@inproceedings{pauls2024icml-estimating,
  title     = {{Estimating Canopy Height at Scale}},
  author    = {Pauls, Jan and Zimmer, Max and Kelly, Una M. and Schwartz, Martin and Saatchi, Sassan and Ciais, Philippe and Pokutta, Sebastian and Brandt, Martin and Gieseke, Fabian},
  booktitle = {International Conference on Machine Learning},
  year      = {2024},
  pages     = {39972-39988},
  volume    = {235},
  url       = {https://mlanthology.org/icml/2024/pauls2024icml-estimating/}
}