Jeremy Paton scite author profile

The structure of a network is an unlabeled graph, yet graphs in most models of complex networks are labeled by meaningless random integers. Is the associated labeling noise always negligible, or can it overpower the network-structural signal? To address this question, we introduce and consider the sparse unlabeled versions of popular network models, and compare their entropy against the original labeled versions. We show that labeled and unlabeled Erdős-Rényi graphs are entropically equivalent, even though their degree distributions are very different. The labeled and unlabeled versions of the configuration model may have different prefactors in their leading entropy terms, although this remains conjectural. Our main results are upper and lower bounds for the entropy of labeled and unlabeled one-dimensional random geometric graphs. We show that their unlabeled entropy is negligible in comparison with the labeled entropy. These results imply that in sparse networks the entropy of meaningless labeling may dominate the entropy of the network structure, suggesting a need for a thorough reexamination of the statistical foundations of network modeling.

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Entropy of labeled versus unlabeled networks

Paton

Hartle

Stepanyants

et al. 2022

Phys. Rev. E

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Diameter of Compact Riemann Surfaces

Stepanyants¹,

Beardon²,

Paton³

et al. 2023

Preprint

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Diameter is one of the most basic properties of a geometric object, while Riemann surfaces are one of the most basic geometric objects. Surprisingly, the diameter of compact Riemann surfaces is known exactly only for the sphere and the torus. For higher genuses, only very general but loose upper and lower bounds are available. The problem of calculating the diameter exactly has been intractable since there is no simple closed-form expression for the distance between a pair of points on a high-genus surface. Here we prove that the diameter of the maximally symmetric Riemann surface of any genus greater than 1 is equal to the radius of its fundamental polygon.

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Jeremy Paton

Entropy of labeled versus unlabeled networks

Entropy of labeled versus unlabeled networks

Diameter of Compact Riemann Surfaces

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