Abstract
The aim of this paper is to disseminate knowledge in the seismic science community about a possible tool which is not largely popular, despite its potential usefulness. In this paper it will be shown how satellite remotely sensed images may represent a powerful source of information where traditional sources of information are unable to deliver it, or at least to do so timely. Even when traditional information flow can ensure delivery, an advantage may still be found in terms of sooner availability and smaller amount of labour required. In the case shown here a vulnerability study was made on a vast industrial area in the gulf of Siracusa, Sicily, Italy. A series of concurrent factors made it particularly troublesome to obtain information on the structures found in the site (tanks, pipes, chimneys, roads, ...), required to suitably carry out the study. Satellite images were then acquired to obtain the information needed. Processing of the images was carried out relying on in-house software formerly developed for similar information extraction issues, and integrated with new, specifically developed elements, some pieces of information were obtained useful for seismic risk evaluation. In particular, location, footprint, elevation of significant structures (e.g. tanks, chimneys) could be evaluated, obtaining results in a format compatible with the most widespread GIS (Geographic Information System) standards. Such compatibility allowed a considerable savings on labour time required to lay a GIS of the area, which is a fundamental tool for risk and vulnerability analyses.
Similar content being viewed by others
References
API 650 (1998) Welded steel tanks for oil Storage. American Petroleum Institute, Washington DC
Caltagirone F, Spera P, Gallon A, Manoni G, Bianchi L (2001) COSMO-SkyMed: a dual use earth observation constellation. In: Proceedings of the 2nd international workshop on satellite constellation and formation flying, pp 87–94
CICIND (2005) The cicind chimney book—industrial chimneys of concrete or steel. International Committee on Industrial Chimneys, Zurich
Clough DP (1977) Experimental evaluation of seismic design methods for broad cylinder tanks. UCB/EERC-77/10, PB-272 280
CNR-UNI 10011 (1988) Costruzioni in acciaio: istruzioni per il calcolo, l’esecuzione, il collaudo e la manutenzione. Italian Code
Decreto Ministeriale 14.02.1992 (1992) Norme tecniche per l’esecuzione delle opere in cemento armato e precompresso e per le strutture metalliche. Suppl. Ord. n. 55 alla G.U. 18.03.1992 n. 65
Decreto Ministeriale 16.01.1996 (1996) Norme tecniche per le costruzioni in zone sismiche. G. U. 05.02.1996, n. 29
Eidinger JM (2001) Earthquake fragility formulation for water system. ASCE-TCLEE
Eurocode 8—UNI ENV (1998) Design of structures for earthquake resistance—Part 4: Silos, tanks and pipelines. CEN Brussels
FEMA: (1999) HAZUS 99. Earthquake loss estimation methodology. Technical manual. Federal Emergency Management Agency, Washington DC
Gamba P, Dell’Acqua F, Lisini G (2009) BREC: The built-up area RECognition tool. In: Proceedings of the 2009 joint urban remote sensing event, May 20–22, 2009, Shanghai
GEO (2005) The group on earth observations, http://www.earthobservations.org/
Hartl P, Cheng F (1995) Delimiting the building heights in a city from the shadow on a panchromatic SPOT-image: Part 2: Test of a complete city. Int J Remote Sens 16(15): 2829–2842
Lee HY, Kim T, Park W, Lee HK (2003) Extraction of digital elevation models from satellite stereo images through stereo matching based on epipolarity and scene geometry. Image Vis Comput 21(9): 789–796
Malhotra PK, Wenk T, Wieland M (2000) Simple procedure for seismic analysis of liquid-storage tanks. Struct Eng Int N° 3: 197–201
Migliore Stass—Studi Associati (2006) http://www.estructura.it/documenti/
NTC08 (2008) Norme tecniche per le costruzioni. D.M. 14.01.2008, Suppl. Ord. alla G.U. 4.2.2008 n. 30
Polli D, Dell’Acqua F, Gamba P (2009) First steps towards a framework for earth observation (EO)—based seismic vulnerability evaluation. Environ Semeiot 2(1): 16–30. doi:10.3383/es.2.1.2
Polli D, Dell’Acqua F, Gamba P (2010) Seismic vulnerability assessment in the framework of GEO: a case study on Messina, Italy. In: Proceedings of the 6th international symposium on geo-information for disaster management (Gi4DM), February 2–4, 2010.Turin, Italy
Priestley MJN, Davidson BJ, Honey GD, Hopkins DC, Martin RJ, Ramsay G, Vassey JV, Wood JH (1986) Seismic design of storage tanks—recommendations of a study group of the New Zealand National Society for Earthquake Engineering
Sarabandi P, Kiremidjian A (2008) Building inventory information extraction from remote sensing data and statistical models. In: Proceedings of the 14th world conference on earthquake engineering, October 12–17, 2008. Beijing, China. Paper No. 11-0136
SOCAL (1976) Recommended practice no. 11, wind and earthquake design standards. Standard Oil of California Board of Engineers
Tucker CJ (1979) Red and photographic infrared linear combinations for monitoring vegetation. Remote Sens Environ 8(2): 127–150
UBC (1982) Uniform building code. In: International conference of building officials, Whittier, California
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Borzi, B., Dell’Acqua, F., Faravelli, M. et al. Vulnerability study on a large industrial area using satellite remotely sensed images. Bull Earthquake Eng 9, 675–690 (2011). https://doi.org/10.1007/s10518-010-9211-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10518-010-9211-9