This paper aims to provide a novel insight into the influence of uncertainties in system and
pedestrian-induced load parameters on the vibration response of footbridges. The study begins with
sensitivity analysis for the vertical vibration response of a representative footbridge to two loading cases: a
single pedestrian and a crowd. ...
This paper aims to provide a novel insight into the influence of uncertainties in system and
pedestrian-induced load parameters on the vibration response of footbridges. The study begins with
sensitivity analysis for the vertical vibration response of a representative footbridge to two loading cases: a
single pedestrian and a crowd. The two methods are utilised: the Sobol’-based global sensitivity analysis
method and local sensitivity analysis method. Uncertainties in all model parameters (that include bridge
and human body dynamics in walking posture as well as dynamic force generated by humans) are
considered in stochastic response estimation. Parametric analysis is then performed to investigate the
influence of the variation of the mean values of bridge modal mass, damping ratio, and natural frequency
on the results of global and local sensitivity analysis. Systematic comparison of the results of global and
local sensitivity analysis is performed to identify their similarities and differences. It has been found that the
sensitive parameters and their importance ranking strongly depend on bridge modal properties and loading
scenarios (i.e. a single pedestrian or a crowd crossing). The damping ratio and natural frequency of human
body are found to be the only two insensitive parameters. Therefore, they could be treated as deterministic
parameters in stochastic estimation of human-induced vibration. Global sensitivity analysis is
recommended as a choice for the sensitivity analysis of pedestrian-induced vibration of footbridges as it
leads to more reliable results, owing to the advantage of characterising model sensitivity over the entire
input spaces.