Statistical inference on errorfully observed graphs

TL;DR

This paper investigates how to perform vertex classification on errorfully observed graphs, balancing the trade-off between the quality and quantity of edge features, using the stochastic blockmodel and real connectome data.

Contribution

It formulates and analyzes a quantity/quality trade-off for edge observation in graph inference, deriving optimal operating points for vertex classification under errorful conditions.

Findings

Optimal quantity/quality trade-off points are surprising.

Methods should be chosen to maximize ultimate inference performance.

Application to C. elegans connectome demonstrates practical relevance.

Abstract

Statistical inference on graphs is a burgeoning field in the applied and theoretical statistics communities, as well as throughout the wider world of science, engineering, business, etc. In many applications, we are faced with the reality of errorfully observed graphs. That is, the existence of an edge between two vertices is based on some imperfect assessment. In this paper, we consider a graph $G = (V,E)$. We wish to perform an inference task -- the inference task considered here is "vertex classification". However, we do not observe $G$; rather, for each potential edge $uv \in {{V}\choose{2}}$ we observe an "edge-feature" which we use to classify $uv$ as edge/not-edge. Thus we errorfully observe $G$ when we observe the graph $\widetilde{G} = (V,\widetilde{E})$ as the edges in $\widetilde{E}$ arise from the classifications of the "edge-features", and are expected to be errorful. Moreover, we face a quantity/quality trade-off regarding the edge-features we observe -- more informative edge-features are more expensive, and hence the number of potential edges that can be assessed decreases with the quality of the edge-features. We studied this problem by formulating a quantity/quality tradeoff for a simple class of random graphs model, namely the stochastic blockmodel. We then consider a simple but optimal vertex classifier for classifying $v$ and we derive the optimal quantity/quality operating point for subsequent graph inference in the face of this trade-off. The optimal operating points for the quantity/quality trade-off are surprising and illustrate the issue that methods for intermediate tasks should be chosen to maximize performance for the ultimate inference task. Finally, we investigate the quantity/quality tradeoff for errorful obesrvations of the {\it C.\ elegans} connectome graph.