Applicability of spatial early warning signals to complex network dynamics

Early warning signals (EWSs) for complex dynamical systems aim to anticipate tipping points, or large regime shifts, before they occur. While signals computed from time series data, such as temporal variance and lagged autocorrelation functions, are useful for this task, they are costly to obtain in practice because they need many samples over time to calculate. Spatial EWSs use just a single sample per spatial location and aggregate the samples over space rather than time to try to mitigate this limitation. However, although many complex systems in nature and society form diverse networks, the performance of spatial EWSs is mostly unknown for general networks because the vast majority of studies of spatial EWSs have been on regular lattice networks. Therefore, we have carried out a comprehensive investigation of four major spatial EWSs on various networks. We find that the winning EWS depends on tipping scenarios, while spatial skewness tends to excel when tipping occurs via a saddle-node bifurcation, which is a commonly studied scenario in the literature. We also find that spatial EWSs behave in a drastically different manner between the square lattice and complex networks and tend to be more reliable for the latter than the former according to a standard performance measure. The present results encourage further studies of spatial EWSs on complex networks.