Comparative Assessment of CMR in Steel Seismic Force-Resisting Systems: A FEMA P-695 Statistical Analysis

Document Type : Original Article

Authors

Faculty of Civil, Water and Environmental Engineering, Shahid Beheshti University, Tehran, Iran

10.48308/ijce.2026.107088

Abstract

Evaluating the seismic collapse performance of steel structural systems is one of the primary objectives of the FEMA P-695 guideline. In this guideline, the collapse margin ratio (CMR) is defined as a quantitative measure of collapse capacity. Despite extensive research on the seismic performance of steel structural systems, a systematic statistical comparison among special moment-resisting frames (SMFs), special concentrically braced frames (SCBFs), and eccentrically braced frames (EBFs) has not yet been reported within the FEMA P-695 framework. To address this gap, 108 steel archetypes corresponding to a common seismic hazard level (SMT = 0.5g) are selected and evaluated. The collapse margin ratio (CMR) values are statistically examined using descriptive and inferential statistical methods to identify significant differences in collapse performance among the three structural systems. Using one-way analysis of variance (ANOVA) and Tukey’s post-hoc test, the differences in mean CMR among the three systems are examined. Results indicated that the effect of structural system type on CMR is statistically significant (F = 8.19, p < 0.001, η² =0.135). The mean CMR values for SMF, SCBF, and EBF are found to be 2.34, 2.06, and 1.79, respectively. Tukey’s test revealed that only the difference between SMF and EBF is significant at the 95% confidence level, while SCBF exhibits an intermediate performance. These findings underscore the importance of selecting an appropriate structural system during the preliminary design phase and can serve as a quantitative basis for revising Iran’s seismic design provisions.

Keywords

References

Asjodi, A. H., & Dolatshahi, K. M. (2023). Extended fragility surfaces for unreinforced masonry walls using vision-derived damage parameters. Engineering Structures, 278, 115467.
Azhari, S., & Hamidia, M. (2025). Probabilistic postearthquake ASCE 41-17 compliant performance level identification for shear-dominated RC shear walls via crack image analysis. Journal of Structural Engineering, 151(1), 04024185.
American Society of Civil Engineers. (2022). Minimum design loads and associated criteria for buildings and other structures (ASCE/SEI 7-22).
Adam, C., Ibarra, L. F., & Krawinkler, H. (2004). Evaluation of P-delta effects in non-deteriorating MDOF structures from equivalent SDOF systems. Technical report, Pacific Earthquake Engineering Research Center.
Baker, J. W. (2007). Quantitative classification of near-fault ground motions using wavelet analysis. Bulletin of the Seismological Society of America, 97(5), 1486–1501.
Bernal, D. (1987). Amplification factors for inelastic dynamic P–Δ effects in earthquake analysis. Earthquake Engineering & Structural Dynamics, 15(5), 635–651.
Bakhshivand, E., Amiri, H. A., & Maleki, S. (2022). Evaluation of seismic performance factors for dual steel SMF-SCBF systems using FEMA P695 methodology. Soil Dynamics and Earthquake Engineering, 163, 107506.
Bohlouli, Z., & Poursha, M. (2024). Effects of P-delta and spectral shape of ground motion records on strength reduction factor and inelastic displacement ratio of SDOF systems with deterioration. Structures, 69, 107410.
Chen, C. H., Lai, J. W., & Mahin, S. (2008, April 24–26). Numerical modelling and performance assessment of concentrically braced steel frames. In Structures Congress 2008: Crossing Borders (pp. 1–10). American Society of Civil Engineers.
Chen, C. H., & Mahin, S. (2010, May 12–15). Seismic collapse performance of concentrically steel braced frames. In Structures Congress 2010 (pp. 1265–1274). American Society of Civil Engineers.
Cheng, Q., Su, M., Lian, M., Zhang, H., Guan, B., & Gong, H. (2020). Cyclic behavior of high-strength steel framed-tube structures with bolted replaceable shear links. Engineering Structures, 210, 110395.
Coburn, A., & Spence, R. (2002). Earthquake protection (2nd ed.). John Wiley & Sons.
Chicco, D., Sichenze, A., & Jurman, G. (2025). A simple guide to the use of Student’s t-test, Mann–Whitney U test, Chi-squared test, and Kruskal–Wallis test in biostatistics. BioData Mining, 18(1), 56.
Ding, J. W., Lu, D. G., & Cao, Z. G. (2025). Risk assessment of spatially distributed assets with generalized seismic fragility models based on machine learning. Soil Dynamics and Earthquake Engineering, 198, 109533.
Dolatshahi, K. M., Vafaei, A., Kildashti, K., & Hamidia, M. (2019). Displacement ratios for structures with material degradation and foundation uplift. Bulletin of Earthquake Engineering, 17(9), 5133–5157.
Federal Emergency Management Agency. (2009). Quantification of building seismic performance factors (FEMA P-695).
Guo, Y., Lian, M., & Cheng, Q. (2024). Performance-based plastic design of high-strength steel framed-tube structures fused with replaceable shear links. Journal of Constructional Steel Research, 212, 108291.
Guo, Y., Lian, M., & Su, M. (2025). Response modification factor of high-strength steel frame-tube structures with replaceable shear links. Journal of Constructional Steel Research, 229, 109510.
Ghobarah, A. (2001). Performance-based design in earthquake engineering: State of development. Engineering Structures, 23(8), 878–884.
Gastwirth, J. L., Gel, Y. R., & Miao, W. (2009). The impact of Levene’s test of equality of variances on statistical theory and practice. Statistical Science, 24(3), 343–360.
Hamidia, M., Shokrollahi, N., & Ardakani, R. R. (2022). The collapse margin ratio of steel frames considering the vertical component of earthquake ground motions. Journal of Constructional Steel Research, 188, 107054.
Hadinejad, A., Asghari, A., & Marefat, M. S. (2025). Evaluation of FEMA P695 methodology for quantification of seismic performance factors in dual steel SCBF-SMF structures. Structures, 71, 108172.
Henson, R. N. (2015). Analysis of variance (ANOVA). In Brain mapping (pp. 477–481).
Jamshidian, S., Azhari, S., & Hamidia, M. (2024). Rapid post-earthquake loss quantification using crack patterns of reinforced concrete columns. Structures, 69, 107372.
Kasai, K., & Popov, E. P. (1986). A study of seismically resistant eccentrically braced steel frame systems (Report No. UCB/EERC-86/01). University of California, Berkeley.
Kiani, A., Yang, T. Y., Kheyroddin, A., Kafi, M. A., & Naderpour, H. (2024). Quantification of seismic performance factors of mixed concrete/steel buildings using FEMA P695 methodology. Structures, 61, 106144.
Kircher, C., Deierlein, G., Hooper, J., Krawinkler, H., Mahin, S., Shing, B., & Wallace, J. (2010). Evaluation of the FEMA P-695 methodology for quantification of building seismic performance factors. Earthquake Spectra, 26(4), 1012–1025.
Kircher, C., Deierlein, G., Hooper, J., Krawinkler, H., Mahin, S., Shing, B., & Wallace, J. (2010). Evaluation of the FEMA P-695 methodology for quantification of building seismic performance factors. Earthquake Spectra, 26(4), 1012–1025.
Kim, H. Y. (2014). Analysis of variance (ANOVA) comparing means of more than two groups. Restorative Dentistry & Endodontics, 39(1), 74–77.
Kaufmann, J., & Schering, A. G. (2007). Analysis of variance ANOVA. In Wiley encyclopedia of clinical trials (pp. 1–6).
Larson, M. G. (2008). Analysis of variance. Circulation, 117(1), 115–121.
Lignos, D. G., Krawinkler, H., & Whittaker, A. S. (2011). Prediction and validation of sidesway collapse of two scale models of a 4-story steel moment frame. Earthquake Engineering & Structural Dynamics, 40(7), 807–825.
Lignos, D. G., & Krawinkler, H. (2013). Development and utilization of structural component databases for performance-based earthquake engineering. Journal of Structural Engineering, 139(8), 1382–1394.
Lignos, D. G., & Krawinkler, H. (2011). Deterioration modeling of steel components in support of collapse prediction of steel moment frames under earthquake loading. Journal of Structural Engineering, 137(11), 1291–1302.
Liapopoulou, M., Stafford, P. J., & Elghazouli, A. Y. (2024). Duration-dependent seismic collapse capacity prediction for steel moment-resisting frames. Journal of Building Engineering, 86, 108810.
Lilliefors, H. W. (1967). On the Kolmogorov-Smirnov test for normality with mean and variance unknown. Journal of the American Statistical Association, 62(318), 399–402.
Liel, A. B., Haselton, C. B., & Deierlein, G. G. (2011). Seismic collapse safety of reinforced concrete buildings. II: Comparative assessment of nonductile and ductile moment frames. Journal of Structural Engineering, 137(4), 492–502.
Malley, J. O., & Popov, E. P. (1983). Design considerations for shear links in eccentrically braced frames (Report No. UCB/EERC-83/24). University of California, Berkeley.
Mansour, N., Christopoulos, C., & Tremblay, R. (2011). Experimental validation of replaceable shear links for eccentrically braced steel frames. Journal of Structural Engineering, 137(10), 1141–1152.
Malakoutian, M., Berman, J. W., & Dusicka, P. (2013). Seismic response evaluation of the linked column frame system. Earthquake Engineering & Structural Dynamics, 42(6), 795–814.
Men, J., Xiong, L., Wang, J., & Zhang, Q. (2022). Experimental and numerical study on the behavior of novel multi-segment replaceable steel shear links. Journal of Constructional Steel Research, 194, 107314.
Mortazavi, P., Lee, E., Binder, J., Kwon, O. S., & Christopoulos, C. (2023). Large-scale experimental validation of optimized cast steel replaceable modular yielding links for eccentrically braced frames. Journal of Structural Engineering, 149(7), 04023071.
Mortazavi, P., Binder, J., Kwon, O. S., & Christopoulos, C. (2023). Ductility-targeted design of cast steel replaceable modular yielding links and their experimental validation through large-scale testing. Journal of Structural Engineering, 149(7), 04023080.
McKight, P. E., & Najab, J. (2010). Kruskal–Wallis test. In The Corsini encyclopedia of psychology.
Nakashima, M., Roeder, C. W., & Maruoka, Y. (2000). Steel moment frames for earthquakes in United States and Japan. Journal of Structural Engineering, 126(8), 861–868.
Nordstokke, D. W., & Zumbo, B. D. (2010). A new nonparametric Levene test for equal variances. Psicológica, 31(2), 401–430.
Okoye, K., & Hosseini, S. (2024). Mann–Whitney U test and Kruskal–Wallis H test statistics in R. In R programming: Statistical data analysis in research (pp. 225–246). Springer Nature Singapore.
O’Reilly, G. J., Goggins, J., & Mahin, S. A. (2012, September 24–28). Behaviour and design of a self-centering concentrically braced steel frame system. Paper presented at the 15th World Conference on Earthquake Engineering, Lisbon, Portugal.
Özkılıç, Y. O., & Topkaya, C. (2021). Extended end-plate connections for replaceable shear links. Engineering Structures, 240, 112385.
Pacific Earthquake Engineering Research Center. (2010). Guidelines for performance-based seismic design of tall buildings (PEER Report No. 2010/05).
Popov, E. P., & Engelhardt, M. D. (1988). Seismic eccentrically braced frames. Journal of Constructional Steel Research, 10, 321–354.
Ricles, J. M., & Popov, E. P. (1987). Experiments on eccentrically braced frames with composite floors (Report No. UCB/EERC-87/06). University of California, Berkeley.
Rezaei, S., Dolatshahi, K. M., & Asjodi, A. H. (2023). Multivariable fragility curves for unreinforced masonry walls. Bulletin of Earthquake Engineering, 21(7), 3357–3398.
Rashvand, P., Hamidia, M. J., & Hassani, N. (2025). Assessment of seismic collapse capacity in special moment-resisting frames designed via equivalent lateral force and response spectrum procedures under ASCE 7-22 and FEMA P-695 frameworks. Interdisciplinary Journal of Civil Engineering, 1(4), 428–445.
Rashvand, P., Hamidia, M., & Hassani, N. (2025). Seismic collapse capacity assessment of steel special moment resisting frames designed based on equivalent lateral force and response spectrum analysis procedures according to ASCE 7–22 standard. Paper presented at the 14th International Congress of Civil Engineering, Tehran, Iran. Civilica. https://civilica.com/doc/2456268
Road, Housing and Urban Development Research Center. (2026). Iranian code of practice for seismic resistant design of buildings (Standard No. 2800, 5th ed.).
Schultz, B. B. (1985). Levene's test for relative variation. Systematic Zoology, 34(4), 449–456.
Shen, Y., Christopoulos, C., Mansour, N., & Tremblay, R. (2011). Seismic design and performance of steel moment-resisting frames with nonlinear replaceable links. Journal of Structural Engineering, 137(10), 1107–1117.
Shirpour, A., & Fanaie, N. (2024). Quantifying the seismic performance factors of half-elliptic-braced steel moment frames. Engineering Structures, 311, 118189.
Spence, R., & Coburn, A. (2006). Earthquake risk and insurance. In Assessing and managing earthquake risk: Geo-scientific and engineering knowledge for earthquake risk mitigation (pp. 385–402). Springer Netherlands.
Spence, R., So, E., Ameri, G., Akinci, A., Cocco, M., Cultrera, G., Pacor, F., Zonno, G., Franceschina, G., Marcucci, S., Milana, G., Di Pasquale, G., Lucantoni, A., Bramerini, F., Pitilakis, K., Kakderi, K., Anastasiadis, A., Reis, S., Aydinoğlu, M., … Carvalho, A. (2007). Earthquake disaster scenario prediction and loss modelling for urban areas (LESSLOSS Report 7). LESSLOSS.
Shirpour, A., Fanaie, N., & Seraji, M. B. (2024). Seismic performance factors of quarter-elliptic-braced steel moment frames using FEMA P695 methodology. Soil Dynamics and Earthquake Engineering, 178, 108453.
St, L., & Wold, S. (1989). Analysis of variance (ANOVA). Chemometrics and Intelligent Laboratory Systems, 6(4), 259–272.
Tong, Y., & Wang, M. (2024). Experimental study on seismic performance of replaceable shear links with low-yield-point steel. Journal of Constructional Steel Research, 222, 108975.
Uriz, P., & Mahin, S. A. (2004, August 1–6). Seismic performance assessment of concentrically braced steel frames. Paper presented at the 13th World Conference on Earthquake Engineering, Vancouver, Canada.
Uriz, P., Mahin, S., Huang, Y., & Chen, C. H. (2006). Bracing for the future: What we know about concentrically braced steel frames. Technical report, Pacific Earthquake Engineering Research Center.
Uriz, P., Filippou, F. C., & Mahin, S. A. (2008). Model for cyclic inelastic buckling of steel braces. Journal of Structural Engineering, 134(4), 619–628.
Uriz, P. (2005). Towards earthquake resistant design of concentrically braced steel structures (Doctoral dissertation, University of California, Berkeley).
Vandepitte, D. (1982). Non-iterative analysis of frames including the P–Δ effect. Journal of Constructional Steel Research, 2(2), 3–10.
Wang, X., Zhang, X. A., Shahzad, M. M., & Shi, X. (2022). Fragility analysis and collapse margin capacity assessment of mega-sub controlled structure system under mainshock-aftershock sequences. Journal of Building Engineering, 49, 104080.
Williamson, E. B. (2003). Evaluation of damage and P–Δ effects for systems under earthquake excitation. Journal of Structural Engineering, 129(8), 1036–1046.
Yao, Z., Wang, W., Fang, C., & Zhang, Z. (2020). An experimental study on eccentrically braced beam-through steel frames with replaceable shear links. Engineering Structures, 206, 110185.
Zamani, P., Azhari, S., Hamidia, M., & Hassani, N. (2024). Crack image-based FEMA P-58-compliant fragility models for automated earthquake-induced loss estimation in non-ductile RC moment frames. Structures, 60, 105873.
Zamani, P., Hamidia, M., & Hassani, N. (2024). Probabilistic post-earthquake loss measurement for RC framed buildings using crack image analysis. Measurement, 238, 115286.
Zahrai, S. M., & Hamidia, M. J. (2010, October 15–16). Studying the rehabilitation of existing structures using compound system of cables and shape memory alloys. In Improving the seismic performance of existing buildings and other structures (pp. 1440–1448). American Society of Civil Engineers.
Zareian, F., Lignos, D. G., & Krawinkler, H. (2010, May 12–15). Evaluation of seismic collapse performance of steel special moment resisting frames using FEMA P695 (ATC-63) methodology. In Structures Congress 2010 (pp. 1275–1286). American Society of Civil Engineers.
Zhang, X., Ma, X., & Zhang, S. (2023). Seismic performance of eccentrically braced precast reinforced concrete columns-steel beams frame with replaceable shear links based on plastic design. Journal of Building Engineering, 76, 107027.
Zhang, H., Su, M., Lian, M., Cheng, Q., Guan, B., & Gong, H. (2020). Experimental and numerical study on the seismic behavior of high-strength steel framed-tube structures with end-plate-connected replaceable shear links. Engineering Structures, 223, 111172.
Zhang, H., Lian, M., & Su, M. (2020). Study on the seismic performance of high-strength steel framed-tube structures with replaceable shear links. Journal of Constructional Steel Research, 171, 106131.
Zinati, M., Hassani, N., & Hamidia, M. (2026). Comparison of peak seismic displacement obtained from simplified analysis for lead rubber bearing (LRB) isolators with nonlinear response history analysis. Interdisciplinary Journal of Civil Engineering, 2(1), 1–15.
Interdisciplinary Journal of Civil Engineering
Volume 2, Issue 1 - Serial Number 5
January 2026
Pages 507-529

Files

Share

How to cite

Statistics