Add to ORKGInternational audienceA methodology is presented to quantify uncertainties resulting from the analysis of dynamic tests performed on classic split Hopkinson pressure bar system in order to improve material parameter estimation within the framework of Bayesian inference. Since the experimental setup is imperfectly known, the proposed methodology consists in modeling experimental parameters as random variables. Then, cumulative effects of all experimental uncertainties are estimated by a statistical analysis based on one-dimensional wave interpretation. For each test, results consist in stress and strain-rate given as normal random variables. In addition, an experimental campaign is performed on the aluminum alloy AA7075-O, in order to identi...
Motivated by the need to quantify uncertainties in the mechanical behaviour of solid materials, we p...
The accurate prediction of the dynamic behaviour of a complex component or system is often difficult...
One of the main difficulties in the geotechnical design process lies in dealing with uncertainty. Un...
International audienceA methodology is presented to quantify uncertainties resulting from the analys...
Predicting the behaviour of various engineering systems is commonly performed using mathematical mod...
The Bayesian framework for hierarchical modeling is applied to quantify uncertainties, arising mainl...
A stochastic approach is proposed for estimating the variability in structural parameters present in...
Knowledge of the in situ stress state is crucial for a wide range of rock mechanics applications, bu...
Material parameters identified by mechanical tests can vary from one specimen to another. This varia...
peer reviewedThis contribution discusses Bayesian inference (BI) as an approach to identify paramete...
peer reviewedThe aim of this contribution is to explain in a straightforward manner how Bayesian inf...
In the multimodel approach, inference is based on an ensemble of model classes. Uncertainties in th...
Motivated by the need to quantify uncertainties in the mechanical behaviour of solid materials, we p...
The accurate prediction of the dynamic behaviour of a complex component or system is often difficult...
One of the main difficulties in the geotechnical design process lies in dealing with uncertainty. Un...
International audienceA methodology is presented to quantify uncertainties resulting from the analys...
Predicting the behaviour of various engineering systems is commonly performed using mathematical mod...
The Bayesian framework for hierarchical modeling is applied to quantify uncertainties, arising mainl...
A stochastic approach is proposed for estimating the variability in structural parameters present in...
Knowledge of the in situ stress state is crucial for a wide range of rock mechanics applications, bu...
Material parameters identified by mechanical tests can vary from one specimen to another. This varia...
peer reviewedThis contribution discusses Bayesian inference (BI) as an approach to identify paramete...
peer reviewedThe aim of this contribution is to explain in a straightforward manner how Bayesian inf...
In the multimodel approach, inference is based on an ensemble of model classes. Uncertainties in th...
Motivated by the need to quantify uncertainties in the mechanical behaviour of solid materials, we p...
The accurate prediction of the dynamic behaviour of a complex component or system is often difficult...
One of the main difficulties in the geotechnical design process lies in dealing with uncertainty. Un...