Paper detail

Spatial Scaling of Land Cover Networks

Spatial networks of land cover are well-described by power law rank-size distributions. Continuous field proxies for human settlements, agriculture and forest cover have similar spatial scaling properties spanning 4 to 5 orders of magnitude. Progressive segmentation of these continuous fields yields spatial networks with rank-size distributions having slopes near -1 for a wide range of thresholds. We consider a general explanation for this scaling that does not require different processes for each type of land cover. The same conditions that give rise to scale-free networks in general can produce power law distributions of component sizes for bounded spatial networks confined to a plane or surface. Progressive segmentation of a continuous field naturally results in growth of the network while the increasing perimeters of the growing components result in preferential attachment to the larger components with the longer perimeters. Progressive segmentation of two types of random continuous field results in progressions of growing spatial networks with components that achieve unity power law rank-size distributions immediately before explosive percolation occurs. This suggests that the scaling properties and uniform area distribution implied by a unity power law rank-size distribution may be a general characteristic of bounded spatial networks produced by segmenting some continuous fields. The implication is that different process-specific mechanisms may not be required to explain the rank-size distributions observed for the diversity of land cover products described here.