Resolution of ranking hierarchies in directed networks

An iterative version of a method to identify hierarchies and rankings of nodes in directed networks can partly overcome its resolution limit.

PLoS ONE 13, 2 (2018)

E. Letizia, P. Barucca, F. Lillo

Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"
Image for the paper "Resolution of ranking hierarchies in directed networks"

Identifying hierarchies and rankings of nodes in directed graphs is fundamental in many applications such as social network analysis, biology, economics, and finance. A recently proposed method identifies the hierarchy by finding the ordered partition of nodes which minimises a score function, termed agony. This function penalises the links violating the hierarchy in a way depending on the strength of the violation. To investigate the resolution of ranking hierarchies we introduce an ensemble of random graphs, the Ranked Stochastic Block Model. We find that agony may fail to identify hierarchies when the structure is not strong enough and the size of the classes is small with respect to the whole network. We analytically characterise the resolution threshold and we show that an iterated version of agony can partly overcome this resolution limit.