Discrimination of vegetation types in alpine sites with ALOS PALSAR-, RADARSAT-2-, and lidar-derived information |
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Authors: | Gaia Vaglio Laurin Fabio Del Frate Luca Pasolli Claudia Notarnicola Leila Guerriero Riccardo Valentini |
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Affiliation: | 1. Department of Civil Engineering and Computer Science Engineering , Tor Vergata University of Rome 00133 , Italy;2. CMCC – Centro Euro-Mediterraneo per i Cambiamenti Climatici (Euro- Mediterranean Center for Climate Change), via Augusto Imperatore , Lecce , 73100 , Italy laurin@disp.uniroma2.it;4. Department of Civil Engineering and Computer Science Engineering , Tor Vergata University of Rome 00133 , Italy;5. EURAC Research Institute for Applied Remote Sensing , Viale Druso , 1 I-39100 , Bolzano , Italy;6. Department of Forest Resources and Environment , University of Tuscia , Viterbo , I-01100 , Italy;7. CMCC – Centro Euro-Mediterraneo per i Cambiamenti Climatici (Euro- Mediterranean Center for Climate Change), via Augusto Imperatore , Lecce , 73100 , Italy |
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Abstract: | Natural vegetation monitoring in the alpine mountain range is a priority in the European Union in view of climate change effects. Many potential monitoring tools, based on advanced remote sensing sensors, are still not fully integrated in operational activities, such as those exploiting very high-resolution synthetic aperture radar (SAR) or light detection and ranging (lidar) data. Their testing is important for possible incorporation in routine monitoring and to increase the quantity and quality of environmental information. In this study the potential of ALOS PALSAR and RADARSAT-2 SAR scenes' synergic use for discrimination of different vegetation types was tested in an alpine heterogeneous and fragmented landscape. The integration of a lidar-based canopy height model (CHM) with SAR data was also tested. A SPOT image was used as a benchmark to evaluate the results obtained with different input data. Discrimination of vegetation types was performed with maximum likelihood classification and neural networks. Six tested data combinations obtained more than 85% overall accuracy, and the most complex input which integrates the two SARs with lidar CHM outperformed the result based on SPOT. Neural network algorithms provided the best results. This study highlights the advantages of integrating SAR sensors with lidar CHM for vegetation monitoring in a changing environment. |
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