Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
Shopping Cart: ( empty )
You are here: Home > Journals > WF > WF04008
RESEARCH ARTICLE
Contents Vol 15(2)

Spatial distribution of ignitions in Mediterranean periurban and rural areas: the case of Catalonia

Anna Badia-Perpinyà A B and Montserrat Pallares-Barbera A
+ Author Affiliations
- Author Affiliations

A Department of Geography, Universitat Autònoma de Barcelona, Barcelona, Spain.

B Corresponding author. Email: anna.badia@uab.es

International Journal of Wildland Fire 15(2) 187-196 https://doi.org/10.1071/WF04008
Submitted: 3 February 2004  Accepted: 30 January 2006   Published: 31 May 2006

Abstract

Fire prevention requires a specific treatment subject to the innate characteristics of a territory and to the social interaction that takes place there. The present article deals with very different fire behaviors in two neighboring environments, in which unequal ignitory patterns have been identified. The analyzed environments constitute two prototypes of Mediterranean landscape in the region of Catalonia (Spain). The periurban-fire pattern is identified with the Metropolitan Area of Barcelona. The rural-fire pattern is observed in the county of Bages, with a far more sparse population structure. Sample observations were drawn from databases containing a compilation of ignitions occurring in these two environments during the period from 1987 to 1998. Analysis shows that the distribution of ignitions in the more urban areas is much more concentrated, whereas ignitions in rural areas are far more dispersed, and therefore more difficult to detect. The importance of the present article lies in the identification of the factors determining the patterns of development of ignitions in two very different territories, affected by diverse external pressures. Finally, guidelines for preventive policies adapted to these situations are given, taking into account the specific and differentiated characteristics relevant to each case.

Additional keywords: chi-square test; geographic information systems; human and territorial factors; Mediterranean forest areas; wildland–urban interface.


References


Alcázar J, Vega-García C, Grauet M, Pelmán J, Fernández A (1998) Human risk and fire danger estimation through multicriteria evaluation methods for forest fire prevention in Barcelona, Spain. In ‘Third International Conference on Forest Fire Research, 14th Conference on Forest Fire Meteorology’. Vol. I (Ed. DX Viegas) Luso, 16–20 November 1998. pp. 2379–2387. (Coimbra)

Badia A (2001) La incidència dels incendis a l’Àrea Metropolitana de Barcelona i a la comarca del Bages durant el període 1987–1998. PhD Thesis, Universitat Autònoma of Barcelona, Bellaterra.

Badia A, Saurí D, Cerdan R , Llurdés JC (2002) La simulació dels incendis forestals al Bages com a mètode de planificació territorial de la prevenció i de l’extinció. Treballs de la Societat Catalana de Geografia, Barcelona  53–54, 81–97.
Blalock HM (1979) ‘Social statistics.’ 2nd edn. (McGraw-Hill: New York)

Bovio G , Camia A (1997) Land zoning based on fire history. International Journal of Wildland Fire  7, 249–258.
Crossref | GoogleScholarGoogle Scholar | Burton I, Kates R, While G (1978) ‘The environment as hazard.’ (Oxford University Press: New York)

Castellnou M, Rovira J, Alcaraz J, Rodríguez F, Espadas J, Queralt D , Rius J (1999) El projecte GRAF, una nova eina per als boscos. Silvicultura  25, 1–4.
Chuvieco E (1998) ‘Megafires Project, Final Report.’ (University of Alcalà de Henares: Alcalà de Henares)

Chuvieco E , Congalton RG (1989) Application of remote sensing and geographical information systems to forest fire hazard mapping. Remote Sensing of Environment  29, 147–159.
Crossref | GoogleScholarGoogle Scholar | Chuvieco E, Salas J, Barredo JI, Carvacho L, Karteris M, Koutsias N (1998) Global patterns of large fires occurrence in the European Mediterranean Basin: A GIS analysis. In ‘Third International Conference on Forest Fire Research, 14th Conference on Forest Fire Meteorology’. Vol. I (Ed. DX Viegas) Luso, 16–20 November 1998. pp. 2447–2462. (Coimbra)

Cunningham AA , Martell DL (1973) A stochastic model for the occurrence of man-caused forest fires. Canadian Journal of Forest Research  3, 282–287.
Finney MA (1998) ‘FARSITE: Fire Area Simulator – Model development and evaluation.’ USDA Forest Service Research Paper RMRS-RP-447. (Ogden, UT)

Folch R (1996) Sociologia dels incendis forestals. In ‘Ecologia del foc’. (Coord. J Terrades) pp. 255–261. (Proa: Barcelona)

Ibáñez JJ, Pons X, Castro FX (1996) La predicció del risc: models de risc i propagació. In ‘Ecologia del foc’. (Coord. J Terrades) pp. 96–108. (Proa: Barcelona)

ICC (1990) Mapa de risc d'incendi forestal. Catalunya 1 : 250 000, Institut Cartogràfic de Catalunya, Generalitat de Catalunya, Departament d'Agricultura Ramadaria i Pesca, Direcció General de Medi Natural; Departament de Política Territorial i Obres Públiques.

IDESCAT (2002) Institut d’Estadística de Catalunya, Generalitat de Catalunya. Available at http://www.idescat.net [Verified 20 March 2006]

Keeley JE, Fotheringham CJ , Morais M (1999) Re-examining fire suppression impacts on brushland fire regimes. Science  284, 1829–1832.
Crossref | GoogleScholarGoogle Scholar | PubMed | Langhart R, Bachmann A, Allgöwer B (1992) Temporal and spatial patterns of wildfire occurrence (Canton of Grison, Switzerland). In ‘Third International Conference on Forest Fire Research, 14th Conference on Forest Fire Meteorology’. Vol. I (Ed. DX Viegas) Luso, 16–20 November 1998. pp. 2279–2292. (Coimbra)

Martell DL , Bevilacqua E (1989) Modelling seasonal variation in daily people-caused forest fire occurrence. Canadian Journal of Forest Research  19, 1555–1563.
Peix J (1999) Foc Verd II. Programa de gestió del risc d’incendi forestal. (Departament d’Agricultura, Ramadaria i Pesca: Barcelona)

Piñol J, Terrades J , Lloret F (1998) Climate warming, wildfire hazard, and wildfire occurrence in coastal eastern Spain. Climatic Change  38, 345–357.
Crossref | GoogleScholarGoogle Scholar | Pyne S (1997) ‘World fire. The culture of fire on Earth.’ (University of Washington Press: Seattle)

Rothermel RC (1972) ‘A mathematical model for predicting fire spread in wildland fuels.’ USDA Forest Service, Intermountain Research Station General Technical Report INT-115. (Ogden, UT)

Salas JChuvieco E (1990) Dónde arderá el bosque? Previsión de incendios forestales mediante un SIG. In ‘Actas I Congres AESIGIT’. pp. 430–446. (AESIGIT: Madrid)

Trabaud L (1989) ‘Les Feux de Forêts: Mécanismes, comportement et environnement.’ (France-Selection: Aubervilliers)

Vega-Garcia C, Woodard PM, Lee BS (1993) Geographic and temporal factors that seem to explain human-caused fire occurrence in Whitecourt Forest, Alberta. GIS’93 Symposium, February 1993, Vancouver, British Columbia.

Viegas DX (1997) General features of forest fires. In ‘Forest fire risk and management’. (Eds P Balabanis, G Eftichidis, R Fantechi) Proceedings of the European School of Climatology and Natural Hazards course, 24 May to 4 June 1992, Porto Carras, Halkidiki, Greece, D.G. XII, Commission of the European Communities, pp. 5–13.




1 Understood as the probability that a fire is produced successfully (Merril and Alexander 1987).

2 Understood here as the probability that a fire will be produced, depending on causative agents.

3 Local institution of the Catalan Government.

4 Determined in the same way as with the MAB, whereby the number of fires takes into account the municipality of origin, but the burnt surface area only takes into account that which actually affects the municipality.

5 Insolation is taken from DEM, following standard procedure calculation, which is the mean for June, July, August, and September of each year.

6 The use of this method is always controversial because of the opacity in the way in which the results are calculated.