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Main Authors: Janetzky, Pascal, Gallusser, Florian, Hentschel, Simon, Hotho, Andreas, Krause, Anna
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.18438
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author Janetzky, Pascal
Gallusser, Florian
Hentschel, Simon
Hotho, Andreas
Krause, Anna
author_facet Janetzky, Pascal
Gallusser, Florian
Hentschel, Simon
Hotho, Andreas
Krause, Anna
contents Accurate vegetation models can produce further insights into the complex interaction between vegetation activity and ecosystem processes. Previous research has established that long-term trends and short-term variability of temperature and precipitation affect vegetation activity. Motivated by the recent success of Transformer-based Deep Learning models for medium-range weather forecasting, we adapt the publicly available pre-trained FourCastNet to model vegetation activity while accounting for the short-term dynamics of climate variability. We investigate how the learned global representation of the atmosphere's state can be transferred to model the normalized difference vegetation index (NDVI). Our model globally estimates vegetation activity at a resolution of \SI{0.25}{\degree} while relying only on meteorological data. We demonstrate that leveraging pre-trained weather models improves the NDVI estimates compared to learning an NDVI model from scratch. Additionally, we compare our results to other recent data-driven NDVI modeling approaches from machine learning and ecology literature. We further provide experimental evidence on how much data and training time is necessary to turn FourCastNet into an effective vegetation model. Code and models will be made available upon publication.
format Preprint
id arxiv_https___arxiv_org_abs_2403_18438
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Global Vegetation Modeling with Pre-Trained Weather Transformers
Janetzky, Pascal
Gallusser, Florian
Hentschel, Simon
Hotho, Andreas
Krause, Anna
Machine Learning
Accurate vegetation models can produce further insights into the complex interaction between vegetation activity and ecosystem processes. Previous research has established that long-term trends and short-term variability of temperature and precipitation affect vegetation activity. Motivated by the recent success of Transformer-based Deep Learning models for medium-range weather forecasting, we adapt the publicly available pre-trained FourCastNet to model vegetation activity while accounting for the short-term dynamics of climate variability. We investigate how the learned global representation of the atmosphere's state can be transferred to model the normalized difference vegetation index (NDVI). Our model globally estimates vegetation activity at a resolution of \SI{0.25}{\degree} while relying only on meteorological data. We demonstrate that leveraging pre-trained weather models improves the NDVI estimates compared to learning an NDVI model from scratch. Additionally, we compare our results to other recent data-driven NDVI modeling approaches from machine learning and ecology literature. We further provide experimental evidence on how much data and training time is necessary to turn FourCastNet into an effective vegetation model. Code and models will be made available upon publication.
title Global Vegetation Modeling with Pre-Trained Weather Transformers
topic Machine Learning
url https://arxiv.org/abs/2403.18438