https://www.scipedia.com/wd/index.php?action=history&feed=atom&title=A._Gonzalez_2021aA. Gonzalez 2021a - Revision history2026-04-18T20:22:58ZRevision history for this page on the wikiMediaWiki 1.27.0-wmf.10https://www.scipedia.com/wd/index.php?title=A._Gonzalez_2021a&diff=232611&oldid=prevScipediacontent: Scipediacontent moved page Draft Content 206171738 to A. Gonzalez 2021a2021-11-30T11:50:34Z<p>Scipediacontent moved page <a href="/public/Draft_Content_206171738" class="mw-redirect" title="Draft Content 206171738">Draft Content 206171738</a> to <a href="/public/A._Gonzalez_2021a" title="A. Gonzalez 2021a">A. Gonzalez 2021a</a></p>
<table class="diff diff-contentalign-left" data-mw="interface">
<tr style='vertical-align: top;' lang='en'>
<td colspan='1' style="background-color: white; color:black; text-align: center;">← Older revision</td>
<td colspan='1' style="background-color: white; color:black; text-align: center;">Revision as of 11:50, 30 November 2021</td>
</tr><tr><td colspan='2' style='text-align: center;' lang='en'><div class="mw-diff-empty">(No difference)</div>
</td></tr></table>Scipediacontenthttps://www.scipedia.com/wd/index.php?title=A._Gonzalez_2021a&diff=232610&oldid=prevScipediacontent: Created page with "== Abstract == Seismic vulnerability assessment of buildings is a process of paramount importance for identifying those areas in a city demanding higher attention..."2021-11-30T11:50:31Z<p>Created page with "== Abstract == Seismic vulnerability assessment of buildings is a process of paramount importance for identifying those areas in a city demanding higher attention..."</p>
<p><b>New page</b></p><div>== Abstract ==<br />
<br />
Seismic vulnerability assessment of buildings is a process of paramount importance <br />
for identifying those areas in a city demanding higher attention with respect to potential <br />
earthquake attacks. Methods for evaluating seismic vulnerability require a more or less <br />
accurate survey of the buildings geometrical and mechanical features, as well as of the <br />
structural systems, in order to identify the vulnerability classes to which they belong. However, <br />
even for relatively small-sized cities, the task of deriving vulnerability maps may be truly time <br />
consuming. Therefore, the development of automatic tools for mapping vulnerabilities of urban <br />
areas is necessary to reduce this effort significantly. <br />
QGIS (www.qgis.org) is a free open source software which includes a large number of peculiar <br />
packages, that make it a powerful tool and that can be well integrated or adapted with new components or plugins. In this paper, a plugin for assisting in the generation of vulnerability <br />
maps of an urban area is shown. The presented QGIS tool is applied to a case study, the historic <br />
city centre of Popoli, in the Abruzzi region (Central Italy), which belongs to a relevant <br />
earthquake-prone area and that was affected by two major seismic sequences in 2009 and in <br />
2016-2017. Potential damage scenarios are presented and discussed, deriving useful <br />
information that could be applied in risk mitigation strategies.<br />
<br />
== Full document ==<br />
<pdf>Media:Draft_Content_206171738p876.pdf</pdf><br />
== References ==<br />
<br />
[1] Bommer, J.J., Crowley, H., and Pinho, R. A risk-mitigation approach to the management of induced seismicity, Journal of Seismology (2015) 19: 623-646. <br />
<br />
[2] Environmental Hazards Methodologies for Risk Assessment and Management (2017) Dalezios N.R. (Ed.) IWA Publishing. <br />
<br />
[3] Rapone, D., Brando, G., Spacone, E. and De Matteis G. Seismic vulnerability assessment of historic centers: description of a predictive method and application to the case study of scanno (Abruzzi, Italy) International Journal of Architectural Heritage (2018) 12: 1171- 1195. <br />
<br />
[4] Basaglia A., Aprile, A., Spacone, E. and Pilla, F. Performance-based Seismic Risk Assessment of Urban Systems. International Journal of Architectural Heritage (2018) 12: 1131-1149. <br />
<br />
[5] De Matteis, G., Brando, G. and Corlito, V. Predictive model the seismic vulnerability assessment of churches based on the 2009 L’Aquila earthquake. Bulletin of Earthquake Engineering (2019) 17: 4909-4936. <br />
<br />
[6] Brando, G., De Matteis, G. and Spacone, E. Predictive model for the seismic vulnerability assessment of small historic centres: Application to the inner Abruzzi Region in Italy. Engineering Structures (2017) 153: 81-96. <br />
<br />
[7] Sandi, H., Floricel, I. Analysis of seismic risk affecting the existing building stock. In: Proceedings of the 10th European conference on earthquake engineering (1994) Vienna, 2, pp. 1105-1110. <br />
<br />
[8] Grünthal, G. European Macroseismic Scale 1998. Cahiers du Centre Europeen de Geodynamique et de Seismologie (1998) 15: 1-99. <br />
<br />
[9] Porter, K. Beginner’s guide to fragility, vulnerability, and risk. Encyclopedia of earthquake engineering (2015): 235-260. <br />
<br />
[10] Pitilakis, K., Crowley, H., and Kaynia, A.M. (Eds) SYNER-G: Typology definition and fragility functions for physical elements at seismic risk: buildings, lifelines, transportation networks and critical facilities. Springer Science and Business Media (2014) 27 <br />
<br />
[11] Federal Emergency Management Agency (2003) Hazus®–MH 2.1Technical Manual. Available at: https://www.fema.gov/media-library/assets/documents/24609. <br />
<br />
[12] Longley P. Geographic information systems and science 4thedition. (2015) John Wiley &amp; Sons. <br />
<br />
[13] Bindi, D., Pacor, F., Luzi, L., Puglia, R., Massa, M., Ameri G. and Paolucci R. Ground motion prediction equations derived from the Italian strong motion database. Bulletin of Earthquake Engineering, 9(6): 1899-1920. <br />
<br />
[14] Chopra S., Choudhury P. A study of response spectra for different geological conditions in Gujarat, India. Soil Dynamics and Earthquake Engineering,(2011) 31(11):1551-1564, DOI: 10.1016/j.soildyn.2011.06.+007 <br />
<br />
[15] Kircher, C. A., Reitherman, R. K., Whitman, R. V. and Arnold, C. Estimation of earthquake losses to buildings. Earthquake spectra (1997) 13: 703-720. <br />
<br />
[16] Dolce, M. and Manfredi, G. Libro bianco sulla ricostruzione privata fuori dai centri storici nei comuni colpiti dal sisma dell'Abruzzo del 6 aprile 2009. Doppiavoce Edizioni (2015). Italian. <br />
<br />
[17] Di Ludovico, M., Prota, A., Moroni, C., Manfredi, G., and Dolce, M. Reconstruction process of damaged residential buildings outside historical centres after the L’Aquila earthquake: part I- "light damage" reconstruction. Bulletin of Earthquake Engineering (2017) 15: 667-692. <br />
<br />
[18] Di Ludovico, M., Prota, A., Moroni, C., Manfredi, G., and Dolce, M. Reconstruction process of damaged residential buildings outside historical centres after the L’Aquila earthquake: part II- “heavy damage” reconstruction. Bulletin of Earthquake Engineering (2017) 15: 693-729. <br />
<br />
[19] De Martino, G., Di Ludovico, M., Prota, A., Moroni, C., Manfredi, G. and Dolce M. Estimation of repair costs for RC and masonry residential buildings based on damage data collected by post-earthquake visual inspection. Bulletin of Earthquake Engineering (2017) 15: 1681–1706. <br />
<br />
[20] Zuccaro, G. and Cacace, F. Seismic casualty evaluation: The Italian model, an application to the L’Aquila 2009 event. In: R. Spence et al. (Eds): Human casualties in earthquakes, Springer, Dordrecht (2011), pp. 171-184. <br />
<br />
[21] Chiarabba, C., Amato, A., Anselmi, M., et al. The 2009 L'Aquila (central Italy) MW6. 3 earthquake: Main shock and aftershocks. Geophysical Research Letters (2009) 36:L18308. <br />
<br />
[22] Livio, F.A., Michetti, A.M, Vittori E., et al. (2016) Surface faulting during the August 24, 2016, Central Italy earthquake (Mw 6.0): preliminary results. Annals of geophysics (2016) 59(5). <br />
<br />
[23] Smith, R.W. (1987). Department of Defense World Geodetic System 1984: its definition and relationships with local geodetic systems. Defense Mapping Agency.</div>Scipediacontent