Guided Graph Generation: Evaluation of Graph Generators in Terms of Network Statistics, and a New Algorithm

We consider the problem of graph generation guided by network statistics, i.e., the generation of graphs which have given values of various numerical measures that characterize networks, such as the clustering coefficient and the number of cycles of given lengths. Algorithms for the generation of sy...

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Bibliographic Details
Published in:arXiv.org 2023-03
Main Authors: Kunegis, Jérôme, Sun, Jun, Yoneki, Eiko
Format: Article
Language:English
Subjects:
Algorithms
Clustering
Coefficients
Evaluation
Generators
Graph theory
Graphs
Growth models
Iterative algorithms
Iterative methods
Mathematical models
Networks
Statistics
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Summary:We consider the problem of graph generation guided by network statistics, i.e., the generation of graphs which have given values of various numerical measures that characterize networks, such as the clustering coefficient and the number of cycles of given lengths. Algorithms for the generation of synthetic graphs are often based on graph growth models, i.e., rules of adding (and sometimes removing) nodes and edges to a graph that mimic the processes present in real-world networks. While such graph generators are desirable from a theoretical point of view, they are often only able to reproduce a narrow set of properties of real-world networks, resulting in graphs with otherwise unrealistic properties. In this article, we instead evaluate common graph generation algorithms at the task of reproducing the numerical statistics of real-world networks, such as the clustering coefficient, the degree assortativity, and the connectivity. We also propose an iterative algorithm, the Guided Graph Generator, based on a greedy-like procedure that recovers realistic values over a large number of commonly used graph statistics, while at the same time allowing an efficient implementation based on incremental updating of only a small number of subgraph counts. We show that the proposed algorithm outperforms previous graph generation algorithms in terms of the error in the reconstructed graphs for a large number of graph statistics such as the clustering coefficient, the assortativity, the mean node distance, and also evaluate the algorithm in terms of precision, speed of convergence and scalability, and compare it to previous graph generators and models. We also show that the proposed algorithm generates graphs with realistic degree distributions, graph spectra, clustering coefficient distributions, and distance distributions.
ISSN:2331-8422