ABSTRACT
With mechanistic and mechanistic-empirical modelling of pavement performance there are a considerable number of uncertainties that are inherent in the prediction process. Many of these sources of uncertainty are challenging to quantify, but one that is technically possible to evaluate is the effect of uncertainty in the characterisation and modelling of the mechanical properties of the asphalt concrete. In this study, the Bayesian inference-based Markov Chain Monte Carlo (MCMC) was used to estimate how uncertainties from the simplified viscoelastic continuum damage (S-VECD) model parameters propagate to pavement performance simulation errors in the FlexPAVETM program. Performance predictions were evaluated based on the propagation of three different material parameter uncertainties; (1) modulus, (2) damage characteristic curves, and (3) failure criterion. These factors were systematically varied according to chosen reliability levels and using data from real-world experimental data on different asphalt mixtures. High-performance computing resources were then used to predict pavement performance on the thousands of different combinations of material property uncertainty, and a simplified prediction algorithm was developed to more easily estimate the uncertainty. The results show that the simplified uncertainty prediction model could estimate the reliability of the damage and cracking predictions from FlexPAVETM within 1.2% and 4.8%, respectively.
Acknowledgements
The authors also would like to acknowledge the test data support from Kangjin Caleb Lee, Jaehoon Jeong, Zhe Zeng, Felipe Pivetta, Lei Xue, Mukesh Ravichandran, and Yongchang Wu in North Carolina State University.
Disclosure statement
No potential conflict of interest was reported by the author(s).