Explaining the emergence of complex networks through log-normal fitness in a Euclidean node similarity space

Networks of disparate phenomena-be it the global ecology, human social institutions, within the human brain, or in micro-scale protein interactions-exhibit broadly consistent architectural features. To explain this, we propose a new theory where link probability is modelled by a log-normal node fitness (surface) factor and a latent Euclidean space-embedded node similarity (depth) factor. Building on recurring trends in the literature, the theory asserts that links arise due to individualistic as well as dyadic information and that important dyadic information making up the so-called depth factor is obscured by this essentially non-dyadic information making up the surface factor. Modelling based on this theory considerably outperforms popular power-law fitness and hyperbolic geometry explanations across 110 networks. Importantly, the degree distributions of the model resemble power-laws at small densities and log-normal distributions at larger densities, posing a reconciliatory solution to the long-standing debate on the nature and existence of scale-free networks. Validating this theory, a surface factor inversion approach on an economic world city network and an fMRI connectome results in considerably more geometrically aligned nearest neighbour networks, as is hypothesised to be the case for the depth factor. This establishes new foundations from which to understand, analyse, deconstruct and interpret network phenomena.

Automated summary

The theory proposes that link probability in networks is modeled by node fitness and similarity factors, with links emerging due to individualistic and dyadic information. Modeling based on this theory outperforms existing explanations across 110 networks, with degree distributions resembling power-laws at low densities and log-normal distributions at higher densities. Validation through inversion approach on economic and fMRI networks results in geometrically aligned nearest neighbor networks, supporting the theory.