Spatial Gibbs random graphs

Jean-Christophe Mourrat; Daniel Rodrigues Valesin

doi:10.1214/17-AAP1316

Spatial Gibbs random graphs

Jean-Christophe Mourrat^*, Daniel Rodrigues Valesin

^*Corresponding author for this work

Dynamical Systems, Geometry and Mathematical Physics

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

4 Citations (Scopus)

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Abstract

Many real-world networks of interest are embedded in physical space. We present a new random graph model aiming to reflect the interplay between the geometries of the graph and of the underlying space. The model favors configurations with small average graph distance between vertices, but adding an edge comes at a cost measured according to the geometry of the ambient physical space. In most cases, we identify the order of magnitude of the average graph distance as a function of the parameters of the model. As the proofs reveal, hierarchical structures naturally emerge from our simple modeling assumptions. Moreover, a critical regime exhibits an infinite number of discontinuous phase transitions.

Original language	English
Pages (from-to)	751-789
Number of pages	39
Journal	Annals of applied probability
Volume	28
Issue number	2
DOIs	https://doi.org/10.1214/17-AAP1316
Publication status	Published - Apr-2018

Keywords

Spatial random graph
Gibbs measure
phase transition
LONG-RANGE PERCOLATION
CONNECTIVITY
EMERGENCE
NETWORKS
DIAMETER
NEUROANATOMY
UNIQUENESS
MODEL

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title = "Spatial Gibbs random graphs",

abstract = "Many real-world networks of interest are embedded in physical space. We present a new random graph model aiming to reflect the interplay between the geometries of the graph and of the underlying space. The model favors configurations with small average graph distance between vertices, but adding an edge comes at a cost measured according to the geometry of the ambient physical space. In most cases, we identify the order of magnitude of the average graph distance as a function of the parameters of the model. As the proofs reveal, hierarchical structures naturally emerge from our simple modeling assumptions. Moreover, a critical regime exhibits an infinite number of discontinuous phase transitions.",

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author = "Jean-Christophe Mourrat and {Rodrigues Valesin}, Daniel",

year = "2018",

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doi = "10.1214/17-AAP1316",

language = "English",

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pages = "751--789",

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T1 - Spatial Gibbs random graphs

AU - Mourrat, Jean-Christophe

AU - Rodrigues Valesin, Daniel

PY - 2018/4

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AB - Many real-world networks of interest are embedded in physical space. We present a new random graph model aiming to reflect the interplay between the geometries of the graph and of the underlying space. The model favors configurations with small average graph distance between vertices, but adding an edge comes at a cost measured according to the geometry of the ambient physical space. In most cases, we identify the order of magnitude of the average graph distance as a function of the parameters of the model. As the proofs reveal, hierarchical structures naturally emerge from our simple modeling assumptions. Moreover, a critical regime exhibits an infinite number of discontinuous phase transitions.

KW - Spatial random graph

KW - Gibbs measure

KW - phase transition

KW - LONG-RANGE PERCOLATION

KW - CONNECTIVITY

KW - EMERGENCE

KW - NETWORKS

KW - DIAMETER

KW - NEUROANATOMY

KW - UNIQUENESS

KW - MODEL

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DO - 10.1214/17-AAP1316

M3 - Article

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VL - 28

SP - 751

EP - 789

JO - Annals of applied probability

JF - Annals of applied probability

IS - 2

ER -

Spatial Gibbs random graphs

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Keywords

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