Efficient and Adaptive Estimation of Local Triadic Coefficients

TL;DR

This paper introduces Triad, an adaptive sampling algorithm that efficiently estimates average local triadic coefficients in large graphs, providing insights into network structure without exhaustive enumeration.

Contribution

The paper presents a novel adaptive sampling method with unbiased estimators and sample complexity bounds for estimating local triadic coefficients in large networks.

Findings

Triad achieves high-accuracy estimates efficiently on large graphs.

The method provides meaningful insights into high-order network patterns.

Case study demonstrates practical utility in collaboration networks.

Abstract

Characterizing graph properties is fundamental to the analysis and to our understanding of real-world networked systems. The local clustering coefficient, and the more recently introduced, local closure coefficient, capture powerful properties that are essential in a large number of applications, ranging from graph embeddings to graph partitioning. Such coefficients capture the local density of the neighborhood of each node, considering incident triadic structures and paths of length two. For this reason, we refer to these coefficients collectively as local triadic coefficients. In this work, we consider the novel problem of computing efficiently the average of local triadic coefficients, over a given partition of the nodes of the input graph into a set of disjoint buckets. The average local triadic coefficients of the nodes in each bucket provide a better insight into the interplay of graph structure and the properties of the nodes associated to each bucket. Unfortunately, exact computation, which requires listing all triangles in a graph, is infeasible for large networks. Hence, we focus on obtaining highly-accurate probabilistic estimates. We develop Triad, an adaptive algorithm based on sampling, which can be used to estimate the average local triadic coefficients for a partition of the nodes into buckets. Triad is based on a new class of unbiased estimators, and non-trivial bounds on its sample complexity, enabling the efficient computation of highly accurate estimates. Finally, we show how Triad can be efficiently used in practice on large networks, and we present a case study showing that average local triadic coefficients can capture high-order patterns over collaboration networks.