Curvature on graphs via equilibrium measures

We introduce a notion of curvature on finite, combinatorial graphs. It can be easily computed by solving a linear system of equations. We show that graphs with curvature bounded below by K>0 $K\gt 0$ have diameter bounded by diam(G)≤2∕K $\text{diam}(G)\le 2\unicode{x02215}K$ (a Bonnet–Myers theor...

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Bibliographic Details
Published inJournal of graph theory Vol. 103; no. 3; pp. 415 - 436
Main Author Steinerberger, Stefan
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.07.2023
Subjects
Bonnet–Myers
Combinatorial analysis
Computation
Curvature
Diameters
graph
Graphs
Lichnerowicz
Minimax technique
minimax theorem
Theorems
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Summary:We introduce a notion of curvature on finite, combinatorial graphs. It can be easily computed by solving a linear system of equations. We show that graphs with curvature bounded below by K>0 $K\gt 0$ have diameter bounded by diam(G)≤2∕K $\text{diam}(G)\le 2\unicode{x02215}K$ (a Bonnet–Myers theorem), that diam(G)=2∕K $\text{diam}(G)=2\unicode{x02215}K$ implies that G $G$ has constant curvature (a Cheng theorem) and that there is a spectral gap λ1≥K∕(2n) ${\lambda }_{1}\ge K\unicode{x02215}(2n)$ (a Lichnerowicz theorem). It is computed for several families of graphs and often coincides with Ollivier curvature or Lin–Lu–Yau curvature. The von Neumann Minimax theorem features prominently in the proofs.
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ISSN:0364-9024
1097-0118
DOI:10.1002/jgt.22925