Higher-order shortest paths in hypergraphs
Abstract
One of the defining features of complex networks is the connectivity properties that we observe emerging from local interactions. Recently, hypergraphs have emerged as a versatile tool to model networks with non-dyadic, higher-order interactions. Nevertheless, the connectivity properties of real-world hypergraphs remain largely understudied. In this work we introduce path size as a measure to characterise higher-order connectivity and quantify the relevance of non-dyadic ties for efficient shortest paths in a diverse set of empirical networks with and without temporal information. By comparing our results with simple randomised null models, our analysis presents a nuanced picture, suggesting that non-dyadic ties are often central and are vital for system connectivity, while dyadic edges remain essential to connect more peripheral nodes, an effect which is particularly pronounced for time-varying systems. Our work contributes to a better understanding of the structural organisation of systems with higher-order interactions.
Cite
@article{arxiv.2502.03020,
title = {Higher-order shortest paths in hypergraphs},
author = {Berné L. Nortier and Simon Dobson and Federico Battiston},
journal= {arXiv preprint arXiv:2502.03020},
year = {2025}
}
Comments
Accepted version, 10 pages and 6 figures. Several sections updated, figures changed, supplementary added. For supplementary materials, see https://github.com/joanne-b-nortier/higher-order-shortest-paths