Mapping the local variability of Natura 2000 habitats with remote sensing
Article first published online: 10 JUN 2014
© 2014 International Association for Vegetation Science
Applied Vegetation Science
Volume 17, Issue 4, pages 765–779, October 2014
How to Cite
Feilhauer, H., Dahlke, C., Doktor, D., Lausch, A., Schmidtlein, S., Schulz, G., Stenzel, S. (2014), Mapping the local variability of Natura 2000 habitats with remote sensing. Applied Vegetation Science, 17: 765–779. doi: 10.1111/avsc.12115
- Issue published online: 24 SEP 2014
- Article first published online: 10 JUN 2014
- Manuscript Accepted: 9 APR 2014
- Manuscript Received: 21 JAN 2014
- German Aerospace Center on behalf of the German Federal Ministry of Economics and Technology. Grant Number: #50EE1033
- German Research Foundation. Grant Number: FE1331/2-1
- Continuous fields;
- Imaging spectroscopy;
- Poor fen;
- Raised bog
Can we map both discrete Natura 2000 habitat types and their floristic variability using multispectral remote sensing data? How do these data perform compared to full range imaging spectroscopy data? Which spectral and spatial characteristics of remote sensing data are important for accurate mapping of habitats and their variability?
A mire complex in Bavaria, southern Germany.
To compare the performance of imaging spectroscopy and multispectral remote sensing data, airborne spectroscopy data (AISA Dual) were spectrally and spatially resampled to the characteristics of two state-of-the-art multispectral sensors (RapidEye and Sentinel-2), resulting in three data sets with different spectral and spatial resolution. Based on the three data sets, we used a combination of field surveys, ordination techniques (non-metric multidimensional scaling), as well as regression and classification techniques (Random Forests) to derive maps of the distribution of Natura 2000 habitat types and their compositional variability. Subsequently, we analysed effects of the spatial and spectral image resolution and spectral coverage on the mapping performance.
Mire habitat types and their floristic composition could be accurately mapped with multispectral remote sensing data. In the case of accentuated floristic differences between habitats, the fits of the models for the three sensors differed only marginally. These effects and the importance of the spatial resolution are discussed.
The results are encouraging and confirm that multispectral data may allow the combined mapping of discrete habitats and their local variability. Still, questions with respect to the transferability of the approach to habitat types with less pronounced spectral differences, and with regard to bridging the gap between fine-scale vegetation records and coarse resolution imagery remain open.