Calibration of resistance factors for seismic design of masonry infilled frames using the random finite element method.

This paper presents a reliability analysis of concrete masonry infill walls with an aim to examine the efficacy of the resistance factor specified in the infill design under seismic loading. A numerical model for masonry infilled reinforced concrete frames was developed and encoded in OpenSees for this study. The model was validated using experimental data. Two features were involved in this reliability study, including 1) that the effect of spatially varying masonry compressive strength f ′ m on the lateral resistance of masonry infills was considered using the Random Finite Element Method, and 2) that seismic load with different return periods was considered to provide a more complete treatment of a reliability analysis. The study selected six Canadian cities with varying levels of seismic intensity for this analysis. By calculating the probability of failure of infill frames subjected to earthquake loading at different locations, the paper showed that the current resistance factor of 0.6 in the infill design equation suggested by the Canadian masonry design standard is conservative. To achieve a reliability index of 3, this factor could be increased to 0.65 for all cities studied. For cities with low seismicity such as Toronto, the results suggest that an even higher resistance factor is justified. • A meso-model encoded in OpenSees to simulate the in-plane behaviour of masonry infilled RC frames. • A reliability-based study on masonry infilled RC frames using the Random Finite Element Method (RFEM). • Considered spatially varied masonry compressive strength and seismic loads with varying return periods. • Calibrate the resistance factor specified in CSA S304-14 for the design of masonry infills. [ABSTRACT FROM AUTHOR]