Abstract
The calibration of discrete element method (DEM) simulations is typically accomplished in a trial-and-error manner. It generally lacks objectivity and is filled with uncertainties. To deal with these issues, the sequential quasi-Monte Carlo (SQMC) filter is employed as a novel approach to calibrating the DEM models of granular materials. Within the sequential Bayesian framework, the posterior probability density functions (PDFs) of micromechanical parameters, conditioned to the experimentally obtained stress–strain behavior of granular soils, are approximated by independent model trajectories. In this work, two different contact laws are employed in DEM simulations and a granular soil specimen is modeled as polydisperse packing using various numbers of spherical grains. Knowing the evolution of physical states of the material, the proposed probabilistic calibration method can recursively update the posterior PDFs in a five-dimensional parameter space based on the Bayes’ rule. Both the identified parameters and posterior PDFs are analyzed to understand the effect of grain configuration and loading conditions. Numerical predictions using parameter sets with the highest posterior probabilities agree well with the experimental results. The advantage of the SQMC filter lies in the estimation of posterior PDFs, from which the robustness of the selected contact laws, the uncertainties of the micromechanical parameters and their interactions are all analyzed. The micro–macro correlations, which are byproducts of the probabilistic calibration, are extracted to provide insights into the multiscale mechanics of dense granular materials.
Highlights
The discrete element method (DEM) captures the collective behavior of a granular material by tracking the kinematics of the constituent grains [9]
A novel probabilistic calibration approach is proposed for the DEM simulations of granular soils
The micromechanical parameters of the contact laws are successfully calibrated against the stress–strain behavior of Toyoura sand in drained triaxial compression conditions at various confining pressures
Summary
The discrete element method (DEM) captures the collective behavior of a granular material by tracking the kinematics of the constituent grains [9]. The aforementioned calibration approaches aim to calibrate micromechanical parameters against the macroscopic material properties (e.g., Young’s modulus, peak- and criticalstate friction angles), rather than the transient behavior of the bulk material This is very likely to hinder the predictive capacity of DEM models. Experimental data obtained step by step during a loading process are assimilated into DEM models to approximate the evolution of posterior PDFs in the corresponding parameter space This “inversemodeling calibration” approach is expedient, because the synergy of the SQMC and SIS algorithms is well-justified for nonlinear and non-Gaussian geomechanical problems, as demonstrated in the applications of these methods to inverse finite element analyses [33,43]. To the authors’ knowledge, this work is the first attempt to develop a sequential data assimilation procedure for calibrating DEM models over the transient behavior of bulk granular materials.
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