An easy, accurate and efficient procedure to create forest fire risk maps using the SEXTANTE plugin Modeler

Lia Duarte; Ana Cláudia Teododo

doi:10.1007/s11676-016-0267-5

Journal of Forestry Research ›› 2016, Vol. 27 ›› Issue (6) : 1361 -1372. DOI: 10.1007/s11676-016-0267-5

Original Paper

An easy, accurate and efficient procedure to create forest fire risk maps using the SEXTANTE plugin Modeler

Lia Duarte ¹^,²
, Ana Cláudia Teododo ¹^,²^,^b

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Abstract

To prevent, detect, and protect against forest fires, forest personnel need to define rules for determining forest fire risk. In Portugal, all municipalities must annually produce forest fire risk (FFR) maps. To produce more reliable FFR maps more easily, we developed an open source model using the Modeler plugin of SEXTANTE in the program QGIS version 2.0 Dufour. The model provides all the maps involved in the FFR model (susceptibility map, hazard map, vulnerability map, economic value map, and potential loss map) and was produced according to Portuguese Forest Authority’s (AFN, Autoridade Florestal Nacional) rules for determining the FFR. This model was tested for the Portuguese municipality Santa Maria da Feira, where 40 % of the total municipality area falls in the category “very high” or “high” fire risk. The “very high” fire risk area is mainly classified as broad-leaved forest and has the steepest slopes (>15 %). The distance of burned areas to roads was also analyzed; the proportion of burned areas increased with increasing distance to the main roads. In addition, 92.6 % of the “high” and “very high” risk zones were located in areas with lower elevation. These results confirmed that forest fire is strongly influenced not only by environmental factors but also by anthropogenic factors. The procedure implemented here was compared with our open source application already available in QGIS and also to the same procedure implemented in GIS proprietary software. Although the results were obviously the same, the model developed here presents several advantages over the other two approaches. Besides being faster, it is easy to change the model parameters according to user needs (i.e., to the rules of different countries), and can be modified and adapted to other variables and other areas to create risk maps for different natural phenomena (e.g., floods, earthquakes, landslides). The model is easy to use and to create risk and hazard maps rapidly in a free, open source environment that does not require any programming knowledge.

Keywords

Forest fire risk (FFR) maps / SEXTANTE / Modeler / QGIS / Open source

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Lia Duarte, Ana Cláudia Teododo. An easy, accurate and efficient procedure to create forest fire risk maps using the SEXTANTE plugin Modeler. Journal of Forestry Research, 2016, 27(6): 1361-1372 DOI:10.1007/s11676-016-0267-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Castro FX, Tudela A, Sebastia MT. Modelling moisture content in shrubs to predict fire risk in Catalonia (Spain). Agric For Meteorol, 2003, 116: 49-59.

[2]	Catry F, Rego F, Bacao F, Moreira F. Modelling and mapping wildfire ignition risk in Portugal. Int J Wildland Fire, 2009, 18(8): 921-931.

[3]	Chen D, Shams S, Carmona-Moreno C, Leone A. Assessment of open GIS software for water resources management in developing countries. J Hydro Environ Res, 2010, 4: 253-264.

[4]	Chuvieco E, Congalton RG. Application of remote sensing and geographic information systems to forest fire hazard mapping. Remote Sens Environ, 1989, 29: 147-159.

[5]	Chuvieco E, Salas FJ. Mapping the spatial distribution of forest fire danger using GIS. Int J Geogr Inf Sci, 1996, 10: 333-345.

[6]

Chuvieco E, Aguado I, Yebra M, Nieto H, Salas J, Martín MP, Vilar L, Martínez J, Martín S, Ibarra P, Riva J, Baeza J, Rodríguez F, Molina JR, Herrera MA, Zamora R. Development of a framework for fire risk assessment using remote sensing and geographic information system technologies. Ecol Model, 2010, 221: 46-58.

[7]	DFCI (2008) Plano Municipal da Defesa da Floresta Contra Incêndios [online]. Technical report. http://www.icnf.pt/portal/florestas/dfci/planos-dfci. Accessed Mar 2014

[8]	Dıaz-Delgado R, Lloret F, Pons X. Spatial patterns of fire occurrence in Catalonia, NE, Spain. Landsc Ecol, 2004, 19(7): 731-745.

[9]	Duguy B, Alloza JÁ, Baeza MJ, Riva JD, Echeverrı M, Ibarra P, Llovet J, Cabello, Rovira FP, Ramon VV. Modelling the ecological vulnerability to forest fires in Mediterranean ecosystems using geographic information technologies. Environ Manag, 2012, 50: 1012-1026.

[10]	Gould JS, McCaw W, Cheney NP. Quantifying fine fuel dynamics and structure in dry eucalypt forest (Eucalyptus marginata) in western Australia for fire management. For Ecol Manag, 2011, 262(3): 531-546.

[11]	GRASS GIS (2014) The world’s leading free GIS software. http://grass.osgeo.org/grass64/manuals/v.surf.rst.html. Accessed April 2014

[12]	Jaehoon J, Changjae K, Shanmuganathan J, Seongsam K, Soohee H, Dong HK, Joon H. Forest fire risk mapping of Kolli Hills, India, considering subjectivity and inconsistency issues. Nat Hazards, 2013, 65: 2129-2146.

[13]	Johnson EA. Fire and vegetation dynamics: studies from the North American boreal forest. 1992, Cambridge: Cambridge University Press

[14]	Kushla JD, Ripple WJ. The role of terrain in a fire mosaic of a temperate coniferous forest. For Ecol Manag, 1997, 95: 97-107.

[15]	Lloret F, Calvo E, Pons X, Diaz-Delgado R. Wildfires and landscape patterns in the Eastern Iberian Peninsula. Landsc Ecol, 2002, 17(8): 745-759.

[16]	Malowerschnig B, Sass O. Long-term vegetation development on a wildfire slope in Innerzwain (Styria, Austria). J For Res, 2013, 25(1): 103-111.

[17]	Marques S, Borges JG, Garcia-Gonzalo J, Moreira F, Carreiras JMB, Oliveira MM, Cantarinha A, Botequim B, Pereira JC. Characterization of wildfires in Portugal. Eur J For Res, 2011, 130(5): 775-784.

[18]	Mermoz M, Kitzberger T, Veblen TT. Landscape influences on occurrence and spread of wildfires in Patagonian forests and shrublands. Ecology, 2005, 86: 2705-2715.

[19]	Mohammadi F, Bavaghar MP, Shabanian N. Forest fire risk zone modeling using logistic regression and GIS: an Iranian case study. Small Scale For, 2014, 13: 117-125.

[20]	Moreira F, Rego FC, Ferreira PG. Temporal (1958–1995) pattern of change in a cultural landscape of northwestern Portugal: implications for fire occurrence. Landsc Ecol, 2001, 16: 555-567.

[21]	Moretti M, Obrist MK, Duelli P. Arthropod biodiversity after forest fires: winners and losers in the winter fire regime of the southern Alps. Ecography, 2004, 27: 173-186.

[22]	Nelson RM Jr. Johnson E, Miyanishi K. Water relations of forest fuels. Forest fires. Behaviour and ecological effects. 2001, San Diego: Academic Press, 79 149

[23]	Pausas JP, Llovet J, Rodrigo A, Vallejo R. Are wildfires a disaster in the Mediterranean basin: a review. Int J Wildland Fire, 2008, 17(6): 713-723.

[24]	Peragón JM, Delgado A, Pérez-Latorre FJ. A GIS-based quality assessment model for olive tree irrigation water in southern Spain. Agric Water Manag, 2015, 148: 232-240.

[25]	Pereira MG, Trigo RM, DaCamara CC, Pereira JMC, Leite SM. Synoptic patterns associated with large summer forest fires in Portugal. Agric For Meteorol, 2005, 129: 11-25.

[26]	Rodriguez-Trejo DA, Fulé PZ. Fire ecology of Mexican pines and fire management proposal. Int J Wildl Fire, 2003, 12: 23-37.

[27]	Romero-Calcerrada R, Barrio-Parra F, Millington JDA, Novillo CJ. Spatial modelling of socioeconomic data to understand patterns of human- caused wildfire ignition risk in the SW of Madrid (central Spain). Ecol Model, 2010, 221: 34-45.

[28]	SAGA (2014) System for automated geoscientific analyses [online]. http://www.saga-gis.org/. Accessed April 2014

[29]	Sebastian-Lopez A, Salvador-Civil R, Gonzalo-Jimenez J, SanMiguel-Ayanz J. Integration of socio-economic and environmental variables for modelling long-term fire danger in Southern Europe. Eur J For Res, 2008, 127: 149-163.

[30]	SEXTANTE (2013) The SEXTANTE framework. http://www.sextantegis.com/. Accessed April 2014

[31]	Silva JS, Moreira F, Vaz P, Catry F, Godinho-Ferreira P. Assessing the relative fire proneness of different forest types in Portugal. Plant Biosyst, 2009, 173(3): 597-608.

[32]	Sivrikaya F, Sağlam B, Akay AE, Bozali B. Evaluation of forest fire risk with GIS. Pol J Environ Stud, 2014, 23(1): 187-194.

[33]	Stallman P (2007) Why ‘open source’ misses the point of free software [online]. GNU operating system. http://www.gnu.org/philosophy/open-sourcemisses-the-point.html. Accessed March 2014

[34]	Stephenson NL. Actual evapotranspiration and deficit: biologically meaningful correlates of vegetation distribution across spatial scales. J Biogeogr, 1998, 25: 855-870.

[35]	Swetnam TW. Fire history and climate change in giant sequoia groves. Science, 1993, 262: 885-889.

[36]	Teodoro AC, Duarte L. Forest fire risk maps: a GIS open source application—a case study in Norwest of Portugal. Int J Geogr Inf Sci, 2013, 27(4): 699-720.

[37]	Van Wagner CE. Effect of slope on fire spread. Canadian Forest Services. Bimon Res Notes, 1977, 33: 7-8.

[38]	Viney NR. A review of fine fuel moisture modelling. Int J Wildl Fire, 1991, 1: 215-223.

[39]	Westerling AL, Gershunov A, Brown TJ, Cayan DR, Dettinger MD. Climate and wildfire in the western United States. Bull Am Meteorol Soc, 2003, 84: 595-604.