Shuffled Graph Classification: Theory and Connectome Applications

Joshua T. Vogelstein; Carey E. Priebe

doi:10.1007/s00357-015-9170-6

Shuffled Graph Classification: Theory and Connectome Applications

Joshua T. Vogelstein, Carey E. Priebe

Whiting School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

We develop a formalism to address statistical pattern recognition of graph valued data. Of particular interest is the case of all graphs having the same number of uniquely labeled vertices. When the vertex labels are latent, such graphs are called shuffled graphs. Our formalism provides insight to trivially answer a number of open statistical questions including: (i) under what conditions does shuffling the vertices degrade classification performance and (ii) do universally consistent graph classifiers exist? The answers to these questions lead to practical heuristic algorithms with state-of-the-art finite sample performance, in agreement with our theoretical asymptotics. Applying these methods to classify sex and autism in two different human connectome classification tasks yields successful classification results in both applications.

Original language	English (US)
Pages (from-to)	3-20
Number of pages	18
Journal	Journal of Classification
Volume	32
Issue number	1
DOIs	https://doi.org/10.1007/s00357-015-9170-6
State	Published - Apr 28 2015

Keywords

Connectomics
Graph matching
Random graphs
Statistical pattern recognition

ASJC Scopus subject areas

Mathematics (miscellaneous)
Psychology (miscellaneous)
Statistics, Probability and Uncertainty
Library and Information Sciences

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10.1007/s00357-015-9170-6

Cite this

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title = "Shuffled Graph Classification: Theory and Connectome Applications",

abstract = "We develop a formalism to address statistical pattern recognition of graph valued data. Of particular interest is the case of all graphs having the same number of uniquely labeled vertices. When the vertex labels are latent, such graphs are called shuffled graphs. Our formalism provides insight to trivially answer a number of open statistical questions including: (i) under what conditions does shuffling the vertices degrade classification performance and (ii) do universally consistent graph classifiers exist? The answers to these questions lead to practical heuristic algorithms with state-of-the-art finite sample performance, in agreement with our theoretical asymptotics. Applying these methods to classify sex and autism in two different human connectome classification tasks yields successful classification results in both applications.",

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AU - Priebe, Carey E.

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Shuffled Graph Classification: Theory and Connectome Applications

Abstract

Keywords

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