Litcius/Paper detail

Bayesian parameter estimation for the inclusion of uncertainty in progressive damage simulation of composites

Johannes Reiner, Nathaniel Linden-Santangeli, Reza Vaziri, Navid Zobeiry, Boris Krämer

2023Composite Structures30 citationsDOIOpen Access PDF

Abstract

Despite gradual progress over the past decades, the simulation of progressive damage in composite laminates remains a challenging task, in part due to inherent uncertainties of material properties. This paper combines three computational methods - finite element analysis (FEA), machine learning and Markov Chain Monte Carlo - to estimate the probability density of FEA input parameters while accounting for the variation of mechanical properties. First, 15,000 FEA simulations of open-hole tension tests are carried out with randomly varying input parameters by applying continuum damage mechanics material models. This synthetically-generated data is then used to train and validate a neural network consisting of five hidden layers and 32 nodes per layer to develop a highly efficient surrogate model. With this surrogate model and the incorporation of statistical test data from experiments, the application of Markov Chain Monte Carlo algorithms enables Bayesian parameter estimation to learn the probability density of input parameters for the simulation of progressive damage evolution in fibre reinforced composites. This methodology is validated against various open-hole tension test geometries enabling the determination of virtual design allowables.

Topics & Concepts

Markov chain Monte CarloMonte Carlo methodFinite element methodSurrogate modelUncertainty quantificationComputer scienceBayesian probabilityBayesian inferenceMarkov chainAlgorithmStructural engineeringMathematicsEngineeringArtificial intelligenceMachine learningStatisticsMechanical Behavior of CompositesProbabilistic and Robust Engineering DesignStructural Health Monitoring Techniques