![]() ![]() This paper describes the basics of the plasticity framework of the model and provides guidelines to calibrate the input parameters of the model to simulate undrained cyclic loading conditions. ![]() The model parameters are calibrated for typical siliceous Holocene sands with different relative densities and are provided for cases where site-specific experimental data is not available. Despite many input parameters that characterize the complex response of the constitutive model, different sets of input parameters are provided for generic response based on simple data available to designers, i.e. The updated model has been calibrated based on design relationships for a range of relative densities for sand. The model has been implemented in 2D and 3D numerical platforms in OpenSees finite-element, and FLAC and FLAC3D finite-difference frameworks. The model has been improved with new flow rules to better simulate contraction and dilation induced by shear strains in soils, thereby more accurate modeling of liquefaction in sandy soils. ![]() This paper presents new updates to the constitutive model to capture the effects of various parameters on triggering of liquefaction including the effects of the number of loading cycles, the effective overburden stress (Kσ effects), and the initial static shear stress (Kα effects). The pressure-dependent multi-yield surface constitutive model was originally developed to capture cyclic mobility and post-liquefaction accumulation of shear strains. Model responses are examined under different loading conditions for a single element. Different sets of model input parameters are provided for sands with different relative densities. This paper presents the new modified framework of analysis and describes a guideline to calibrate the input parameters of the updated model to capture liquefaction triggering and post-liquefaction cyclic mobility and the accumulation of plastic shear strain. The model has been improved with new flow rules to better capture contraction and dilation in sands and has been implemented as PDMY03 in different computational platforms such as OpenSees finite-element, and FLAC and FLAC3D finite-difference frameworks. A constitutive soil model that was originally developed to model liquefaction and cyclic mobility has been updated to comply with the established guidelines on the dependence of liquefaction triggering to the number of loading cycles, effective overburden stress (Kσ), and static shear stress (Kα). ![]()
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