Quantifying Networked Resilience via Multi-Scale Feedback Loops in Water Distribution Networks

Water distribution networks (WDNs) are one of the most important man-made infrastructures. Resilience, the ability to respond to disturbances and recover to a desirable state, is of vital importance to our society. There is increasing evidence that the resilience of networked infrastructures with dynamic signals depends on their network topological properties. Whilst existing literature has examined a variety of complex network centrality and spectral properties, very little attention has been given to understand multi-scale flow-based feedback loops and its impact on overall stability. Here, resilience arising from multi-scale feedback loops is inferred using a proxy measure called trophic coherence. This is hypothesised to have a strong impact on both the pressure deficit and the water age. Our results show that trophic coherence is positively correlated with the time to recovery (0.62 to 0.52), while it is negatively correlated with the diffusion of a disruption (-0.66 to -0.52). Finally, we apply random forest analysis to combine resilience measures, showing that the new resilience ensemble provides a more accurate measure for networked resilience.