ABSTRACT
In situ evaluation of mechanical pavement properties requires fitting measured surface displacements with model displacements. Such inverse analysis is guided by optimisation algorithms that entail re-execution of the underlying model many times over. For layered elasticity, which is the most commonly employed pavement model, this involves calculating computationally demanding semi-infinite integrals in every optimisation step. In this connection, a method was proposed to improve the computational efficiency of surface displacement recalculations in layered elastic systems. It was based on manipulating the original integrals by adding and then subtracting carefully selected auxiliary functions so that they remained mathematically unchanged, yet became faster to compute. The auxiliary functions were derived from an analytic interrogation, rendering the formulation robust and applicable to any layered elastic system without practical restrictions on the model parameters. Overall, the method is deemed consistently more efficient than standard evaluation techniques for achieving a given accuracy level.
Acknowledgements
The authors would like to acknowledge the Innovation Fund Denmark and Dynatest for the project funding. This work is part of a larger effort aimed at developing a new device for measuring pavement surface displacements – provisionally called ‘Raptor’.
Disclosure statement
No potential conflict of interest was reported by the authors.
ORCID
Eyal Levenberg http://orcid.org/0000-0003-1188-8458