Details zur Publikation |
| Kategorie | Datenpublikation |
| DOI | 10.57967/hf/7838 |
| Lizenz |
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| Titel (primär) | Dist_Uncertainty – Hyperspectral Case Studies for Plant Trait Uncertainty Assessment |
| Autor | Cherif, E.; Kattenborn, T.; Brown, L.A.; Ewald, M.; Berger, K.; Dao, P.D.; Hank, T.B.; Laliberté, E.; Lu, B.; Feilhauer, H. |
| Quelle | Hugging Face Hub |
| Erscheinungsjahr | 2026 |
| Department | RS |
| Sprache | englisch |
| Topic | T5 Future Landscapes |
| Abstract | Large-scale mapping of plant biophysical and biochemical traits is essential for ecological and environmental applications. Given their finer spectral resolution and unprecedented data availability, hyperspectral data, in concert with machine and particularly deep learning models, have emerged as a promising, non-destructive tool for accurately retrieving these traits. However, when deploying these methods on a large scale, reliably quantifying the associated uncertainty remains a critical challenge, especially when models encounter out-of-domain (OOD) data, i.e., samples that differ substantially from those of the training data, such as unseen geographical regions, species, biomes, data acquisition modalities, or scene components (e.g., clouds and water bodies). Traditional uncertainty quantification methods for deep learning models, including deep ensembles (deterministic and probabilistic) and Monte Carlo dropout, rely on the variance of predictions but often fail to capture uncertainty in OOD scenarios, leading to overly optimistic and possibly misleading uncertainty estimates. To address this limitation, we propose a distance-based uncertainty estimation method (Dis_UN) that quantifies prediction uncertainty by measuring the dissimilarity in the predictor space (spectral inputs) and embedding space (features learned by the deep model) between the training and test data. Dis_UN leverages residuals as a proxy for uncertainty and employs dissimilarity indices in data manifolds to estimate worst-case errors via 95-quantile regression. We evaluate Dis_UN using a pretrained deep learning model to predict multiple plant traits from hyperspectral images, analyzing its performance across OOD data, such as pixels containing spectral variations from urban surfaces, bare ground, water, clouds, or open surface waters. In this study, we target six leaf and canopy traits: leaf mass per area, chlorophylls, carotenoids, nitrogen content, equivalent water thickness, and leaf area index. Compared to scaled variance-based methods, Dis_UN provides (1) a superior estimation of uncertainty in OOD scenarios, achieving 36 % higher contrast (KS distances: 0.648 vs. 0.475) between non-vegetation pixels, particularly under mixed-pixel conditions at medium resolution (30 m); (2) uncertainty quantification without requiring normality or symmetry assumptions, accommodating asymmetric error patterns; (3) enhanced interpretability of uncertainty sources, as uncertainty is directly linked to sample dissimilarity from the training data; and (4) computational efficiency at inference (2.6–7.7× faster), requiring only a single forward pass compared to multiple passes for ensemble-based methods. Challenges remain for traits that are affected by spectral saturation. These findings highlight the advantages of distance-aware uncertainty quantification methods and underscore the necessity of diverse training datasets to minimize sampling biases and enhance model robustness. The proposed framework improves the reliability of uncertainty estimation in vegetation monitoring and offers a promising approach for broader applications. |
| Verknüpfte UFZ-Textpublikationen | |
| Cherif, E., Kattenborn, T., Brown, L.A., Ewald, M., Berger, K., Dao, P.D., Hank, T.B., Laliberté, E., Lu, B., Feilhauer, H. (2026): Dist_Uncertainty – Hyperspectral Case Studies for Plant Trait Uncertainty Assessment Hugging Face Hub 10.57967/hf/7838 |
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