Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning
Abstract
:1. Introduction
2. Materials and Methods
2.1. Study Site and Methodological Approach
2.2. Fire Hazard Evaluation
2.2.1. Fuel Mapping and Landscape File Generation
Calculation of Canopy Base Height Variable
if Hm <= 5 m: Hc = β1 × Hm
Calculation of Canopy Bulk Density Variable
Fuel Models Assignation
2.2.2. Generation of Meteorological Scenarios
3. Results
3.1. Geodatabase and Modelled Maps
3.2. Data Server
4. Data Use and Future Development
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
IFN4 Code | Tree Specie | Mean Canopy Depth (Hc, m) | |
---|---|---|---|
024 | Pinus halepensis | Hm > 5 m → Hc = 1.106 + (0.421 × Hm) | Hm < 5 m → Hc = 0.421 × Hm |
021 | Pinus sylvestris | Hm > 5 m → Hc = 1.201 + (0.391 × Hm) | Hm < 5 m → Hc = 0.391 × Hm |
045 | Quercus ilex ilex | Hm > 5 m → Hc = −0.328 + (0.640 × Hm) | Hm < 5 m → Hc = 0.640 × Hm |
025 | Pinus nigra | Hm > 5 m → Hc = 0.432 + (0.426 × Hm) | Hm < 5 m → Hc = 0.426 × Hm |
049 | Quercus ilex ballota | Hm > 5 m → Hc = −0.328 + (0.640 × Hm) | Hm < 5 m → Hc = 0.640 × Hm |
022 | Pinus uncinata | Hm > 5 m → Hc = 1.401 + (0.476 × Hm) | Hm < 5 m → Hc = 0.476 × Hm |
046 | Quercus suber | Hm > 5 m → Hc = −0.328 + (0.640 × Hm) | Hm < 5 m → Hc = 0.640 × Hm |
243 | Quercus humilis | Hm > 5 m → Hc = −0.429 + (0.629 × Hm) | Hm < 5 m → Hc = 0.629 × Hm |
050 | Riverbank forests | Hm > 5 m → Hc = 2.121 + (0.375 × Hm) | Hm < 5 m → Hc = 0.375 × Hm |
044 | Quercus faginea | Hm > 5 m → Hc = 0.348 + (0.326 × Hm) | Hm < 5 m → Hc = 0.326 × Hm |
023 | Pinus pinea | Hm > 5 m → Hc = 0.265 + (0.465 × Hm) | Hm < 5 m → Hc = 0.465 × Hm |
071 | Fagus sylvatica | Hm > 5 m → Hc = −0.428 + (0.667 × Hm) | Hm < 5 m → Hc = 0.667 × Hm |
042 | Quercus petraea | Hm > 5 m → Hc = −0.688 + (0.624 × Hm) | Hm < 5 m → Hc = 0.624 × Hm |
026 | Pinus pinaster | Hm > 5 m → Hc = 1.750 + (0.321 × Hm) | Hm < 5 m → Hc = 0.321 × Hm |
031 | Abies alba | Hm > 5 m → Hc = −0.040 + (0.708 × Hm) | Hm < 5 m → Hc = 0.708 × Hm |
072 | Castanea Sativa | Hm > 5 m → Hc = −0.131 + (0.592 × Hm) | Hm < 5 m → Hc = 0.592 × Hm |
051 | Populus sp. | Hm > 5 m → Hc = −1.609 + (0.769 × Hm) | Hm < 5 m → Hc = 0.769 × Hm |
373 | Betula pendula | Hm > 5 m → Hc = −0.455 + (0.653 × Hm) | Hm < 5 m → Hc = 0.653 × Hm |
041 | Quercus robur | Hm > 5 m → Hc = −0.688 + (0.624 × Hm) | Hm < 5 m → Hc = 0.624 × Hm |
255 | Fraxinus excelsior | Hm > 5 m → Hc = 2.121 + (0.375 × Hm) | Hm < 5 m → Hc = 0.375 × Hm |
061 | Eucalyptus sp. | Hm > 5 m → Hc = −0.131 + (0.592 × Hm) | Hm < 5 m → Hc = 0.592 × Hm |
079 | Platanus x hybrida | Hm > 5 m → Hc = 1.391 + (0.443 × Hm) | Hm < 5 m → Hc = 0.443 × Hm |
028 | Pinus radiata | Hm > 10 m → Hc = 3.279 + (0.444 × Hm) | Hm < 10 m → Hc = 0.444 × Hm |
034 | Pseudotsuga menziesii | Hm > 10 m → Hc = 6.247 + (0.250 × Hm) | Hm < 10 m → Hc = 0.250 × Hm |
047 | Quercus canariensis | Hm > 5 m → Hc = −1.166 + (0.885 × Hm) | Hm < 5 m → Hc = 0.885 × Hm |
043 | Quercus pyrenaica | Hm > 5 m → Hc = −1.166 + (0.885 × Hm) | Hm < 5 m → Hc = 0.885 × Hm |
035 | Larix sp. | Hm > 10 m → Hc = 6.247 + (0.250 × Hm) | Hm < 10 m → Hc = 0.250 × Hm |
917 | Cedrus sp. | Hm > 10 m → Hc = 6.247 + (0.250 × Hm) | Hm < 10 m → Hc = 0.250 × Hm |
033 | Picea sp. | Hm > 10 m → Hc = 6.247 + (0.250 × Hm) | Hm < 10 m → Hc = 0.250 × Hm |
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Variable | Unit | Data Processing |
---|---|---|
Forest canopy cover (FCC) | % | Original data, not processed |
Standard height (SH) | meters | Original data, not processed |
Canopy base height (CBH) | meters | Parameterized and (geospatially) modelled |
Canopy bulk density (CBD) | kg/m3 | Parameterized and (geospatially) modelled |
Fuel models (FM) | Categories | Parameterized and (geospatially) modelled |
Digital Terrain Model (DTM) | meters | Original data, not processed |
Slope (SL) | % | Geospatially transformed |
Aspect (ASP) | degrees | Geospatially transformed |
Vegetation Types | Fuel Type by Scott and Burgan [63] |
---|---|
Wooded forest area | Slash-Blowdown (SB), Timber Litter (TL), Timber Litter (TL) |
Regenerated forest | Shrub (SH) |
Scrubland | Grass-Shrub (GS), Shrub (SH) |
Grassland | Grass (GR) |
Non-burnable | Non-burnable (NB) |
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Krsnik, G.; Busquets Olivé, E.; Piqué Nicolau, M.; Larrañaga, A.; Cardil, A.; García-Gonzalo, J.; González Olabarría, J.R. Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning. Remote Sens. 2020, 12, 4124. https://doi.org/10.3390/rs12244124
Krsnik G, Busquets Olivé E, Piqué Nicolau M, Larrañaga A, Cardil A, García-Gonzalo J, González Olabarría JR. Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning. Remote Sensing. 2020; 12(24):4124. https://doi.org/10.3390/rs12244124
Chicago/Turabian StyleKrsnik, Goran, Eduard Busquets Olivé, Míriam Piqué Nicolau, Asier Larrañaga, Adrián Cardil, Jordi García-Gonzalo, and José Ramón González Olabarría. 2020. "Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning" Remote Sensing 12, no. 24: 4124. https://doi.org/10.3390/rs12244124
APA StyleKrsnik, G., Busquets Olivé, E., Piqué Nicolau, M., Larrañaga, A., Cardil, A., García-Gonzalo, J., & González Olabarría, J. R. (2020). Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning. Remote Sensing, 12(24), 4124. https://doi.org/10.3390/rs12244124