Abstract
A new formulation on seismic risk assessment for structures with both random and uncertain-but-bounded variables is investigated in this paper. Limit thresholds are regarded as random variables. The median of random variables is described through an improved multidimensional parallelepiped (IMP) convex model, in which the uncertain domain of the dependent bounded variables can be explicitly expressed. The corresponding Engineering Demand Parameters are taken to be dependent and follow a multidimensional lognormal distribution. Through matrix transformation, a given performance function is transformed into the regularized one. An effective method based on active learning Kriging model (ALK) is introduced to approximate the performance function in the region of interest rather than in the overall uncertain space. Based on ALK model, the failure probabilities for different limit states are calculated by using Monte Carlo Simulation (MCS). Further, the failure probabilities for different limit states in 50 years can be obtained through coupling the seismic failure probability with the ground motion hazard curve. A six-story reinforced concrete building subjected to ground motions is investigated to the efficiency and accuracy of the proposed method. The interstory drift and the acceleration as two responses of the case study are, respectively, obtained by utilizing Incremental Dynamic Analysis and nonlinear history analysis.
Highlights
Recent earthquake hazards have caused serious economic and social loss [1, 2]
The failure probabilities for different limit states in 50 years can be obtained through coupling the seismic failure probability with the ground motion hazard curve
The computational cost of the proposed method is much less than that of both mathematical programming method (MPM) and single-loop iterative (SLI). These findings demonstrate that active learning Kriging model (ALK)-MGHAR is suitable to deal with such complicated seismic engineering problems with strongly nonlinear performance functions
Summary
Recent earthquake hazards have caused serious economic and social loss [1, 2]. Currently, a number of academics [3,4,5,6,7] have emphasized the importance of performance-based seismic design (PBSD). An improved unified analysis approach [39] for structural hybrid reliability has been developed based on FORM. Based on the framework of PBSD, the reliability analysis of a given RC structure subjected to ground motions should be discussed with a combination of probability and IMP convex models. This means that a more general hybrid reliability analysis (MGHAR) for complex seismic engineering problems is developed in this paper. The failure probabilities in 50 years can be computed by combining seismic failure probability and the ground motion hazard curve The interstory drift and the acceleration are selected as two-dimensional Engineering Demand Parameters (EDPs), which are, respectively, calculated by Incremental Dynamic Analysis (IDA) and nonlinear history analysis (NHA)
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