Performance-based earthquake engineering (PBEE) has become an important framework for quantifying seismic losses. However, due to its computationally expensive implementation through a typically detailed component-based approach (i.e. Federal Emergency Management Agency (FEMA) P-58), it has primarily been used within academic research and specific studies. A simplified alternative more desirable for practitioners is based on story loss functions (SLFs), which estimate a building’s expected monetary loss per story due to seismic demand. These simplified SLFs reduce the data required compared to a detailed study, which is especially true at a design stage, where detailed component information is likely yet to be defined. This article proposes a Python-based toolbox for the development of user-specific and customizable SLFs for use within seismic design and assessment of buildings. It outlines the implementation procedure alongside a comparative demonstration of its application where dependency and correlation of damage states between different components are considered. Finally, a comparison of SLF-based and component-based loss estimation approaches is carried out through the application to a real case study school building. The agreement and consistency of the attained loss metrics demonstrate the quality and ease of the SLF-based approach in achieving accurate results for a more expedite assessment of building performance.
CardoneD (2016) Fragility curves and loss functions for RC structural components with smooth rebars. Earthquakes and Structures10(5): 1181–1212.
6.
CardoneDPerroneG (2015) Developing fragility curves and loss functions for masonry infill walls. Earthquakes and Structures9(1): 257–279.
7.
ChiozziAMirandaE (2017) Fragility functions for masonry infill walls with in-plane loading. Earthquake Engineering & Structural Dynamics46(15): 2831–2850.
8.
Comité Européen de Normalisation (CEN) EN 1998-1 (2004) Eurocode 8: Design of Structures for Earthquake Resistance—Part 1: General Rules, Seismic Actions and Rules for Buildings. Brussels: CEN.
9.
CornellCA (1996) Calculating building seismic performance reliability: A basis for multi-level design norms. In: Proceedings of the 11th world conference on earthquake engineering, Acapulco, Mexico, 23–28 June, p. 8. Oxford: Pergamon Press.
10.
CornellCAKrawinklerH (2003) Progress and Challenges in Seismic Performance Assessment. Berkeley, CA: Pacific Earthquake Engineering Research Center (PEER), University of California, Berkeley.
11.
Del GaudioCDe RisiMTRicciPVerderameGM (2019) Empirical drift-fragility functions and loss estimation for infills in reinforced concrete frames under seismic loading. Bulletin of Earthquake Engineering17(3): 1285–1330.
12.
Del VecchioCDi LudovicoMProtaA (2020) Repair costs of reinforced concrete building components: From actual data analysis to calibrated consequence functions. Earthquake Spectra36(1): 353–377.
13.
Federal Emergency Management Agency (FEMA) P-58-1 (2012a) Seismic Performance Assessment of Buildings: Volume 1—Methodology. Washington, DC: FEMA.
KennedyRCShortSA (1994) Basis for Seismic Provisions of DOE-STD-1020. Livermore, CA: Lawrence Livermore National Laboratory.
16.
KrawinklerHZareianFMedinaRAIbarraLF (2006) Decision support for conceptual performance-based design. Earthquake Engineering & Structural Dynamics35(1): 115–133.
17.
LucoNEllingwoodBRHamburgerROHooperJDKimballJKKircherCA (2007) Risk-targeted versus current seismic design maps for the conterminous United States. In: Structural Engineers Association of California (SEAOC) 2007 convention proceedings, Squaw Creek, CA, 26–29 September, pp. 1–13. Sacramento, CA: SEAOC.
O’ReillyGJSullivanTJ (2018) Quantification of modelling uncertainty in existing Italian RC frames. Earthquake Engineering & Structural Dynamics47(4): 1054–1074.
21.
O’ReillyGJPerroneDFoxMMonteiroRFiliatraultA (2018) Seismic assessment and loss estimation of existing school buildings in Italy. Engineering Structures168: 142–162.
22.
O’ReillyGJPerroneDFoxMMonteiroRFiliatraultALaneseIPaveseA (2019) System identification and seismic assessment modeling implications for Italian school buildings. Journal of Performance of Constructed Facilities33(1): 04018089.
23.
O’ReillyGJSullivanTJFiliatraultA (2017) Implications of a more refined damage estimation approach in the assessment of RC frames. In: Proceedings of the 16th world conference on earthquake engineering, Santiago, 9–13 January.
24.
OttonelliDCattariSLagomarsinoS (2020) Displacement-based simplified seismic loss assessment of masonry buildings. Journal of Earthquake Engineering24: 23–59.
25.
PapadopoulosANVamvatsikosDKazantziAK (2019) Development and application of FEMA P-58 compatible story loss functions. Earthquake Spectra35(1): 95–112.
26.
PerroneGCardoneDO’ReillyGJSullivanTJ (2019) Developing a direct approach for estimating expected annual losses of Italian buildings. Journal of Earthquake Engineering. Epub ahead of print 19September. DOI: 10.1080/13632469.2019.1657988.
27.
RamirezCMMirandaE (2009) Building-specific loss estimation methods & tools for simplified performance-based earthquake engineering. Blume Center report, Blume Center, Stanford University, Stanford, CA, May.
28.
RamirezCMMirandaE (2012) Significance of residual drifts in building earthquake loss estimation. Earthquake Engineering & Structural Dynamics41: 1477–1493.
29.
Ruiz-GarcíaJNegreteM (2009) Drift-based fragility assessment of confined masonry walls in seismic zones. Engineering Structures31(1): 170–181.
30.
SassunKSullivanTJMorandiPCardoneD (2016) Characterising the in-plane seismic performance of infill masonry. Bulletin of the New Zealand Society for Earthquake Engineering49(1): 98–115.
31.
ShahnazaryanDO’ReillyGJMonteiroR (2021) Storey loss function generator. DOI: 10.5281/zenodo.4897798.
32.
ShahnazaryanDO’ReillyGJ (2021) Integrating expected loss and collapse risk in performance-based seismic design of structures. Bulletin of Earthquake Engineering19(2): 987–1025.
33.
SilvaACastroJMMonteiroR (2020a) A rational approach to the conversion of FEMA P-58 seismic repair costs to Europe. Earthquake Spectra36(3): 1607–1618.
34.
SilvaAMacedoLMonteiroRCastroJM (2020b) Earthquake-induced loss assessment of steel buildings designed to Eurocode 8. Engineering Structures208: 110244.
35.
SullivanTJ (2016) Use of limit state loss versus intensity models for simplified estimation of expected annual loss. Journal of Earthquake Engineering20(6): 954–974.
36.
VamvatsikosDAschheimMA (2016) Performance-based seismic design via yield frequency spectra‡. Earthquake Engineering & Structural Dynamics45(11): 1759–1778.
37.
ŽižmondJDolšekM (2019) Formulation of risk-targeted seismic action for the force-based seismic design of structures. Earthquake Engineering & Structural Dynamics48: 1406–1428.
