ON THE SPECTRUM OF DENSE RANDOM GEOMETRIC GRAPHS

Kartick Adhikari; Robert J. Adler; Omer Bobrowski; Ron Rosenthal

doi:10.1214/21-AAP1720

ON THE SPECTRUM OF DENSE RANDOM GEOMETRIC GRAPHS

Kartick Adhikari, Robert J. Adler, Omer Bobrowski, Ron Rosenthal

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

Abstract

In this paper we study the spectrum of the random geometric graph G(n, r), in a regime where the graph is dense and highly connected. In the Erdős–Rényi G(n, p) random graph it is well known that upon connectivity the spectrum of the normalized graph Laplacian is concentrated around 1. We show that such concentration does not occur in the G(n, r) case, even when the graph is dense and almost a complete graph. In particular, we show that the limiting spectral gap is strictly smaller than 1. In the special case where the vertices are distributed uniformly in the unit cube and r = 1, we show that for every 0 ≤ k ≤ d there are at least ( ^d_k ) eigenvalues near 1 − 2^−k, and the limiting spectral gap is exactly 1/2. We also show that the corresponding eigenfunctions in this case are tightly related to the geometric configuration of the points.

Original language	English
Pages (from-to)	1734-1773
Number of pages	40
Journal	Annals of Applied Probability
Volume	32
Issue number	3
DOIs	https://doi.org/10.1214/21-AAP1720
State	Published - Jun 2022

Keywords

homological connectivity
Random geometric graphs
spectral measure

ASJC Scopus subject areas

Statistics and Probability
Statistics, Probability and Uncertainty

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10.1214/21-AAP1720

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title = "ON THE SPECTRUM OF DENSE RANDOM GEOMETRIC GRAPHS",

abstract = "In this paper we study the spectrum of the random geometric graph G(n, r), in a regime where the graph is dense and highly connected. In the Erd{\H o}s–R{\'e}nyi G(n, p) random graph it is well known that upon connectivity the spectrum of the normalized graph Laplacian is concentrated around 1. We show that such concentration does not occur in the G(n, r) case, even when the graph is dense and almost a complete graph. In particular, we show that the limiting spectral gap is strictly smaller than 1. In the special case where the vertices are distributed uniformly in the unit cube and r = 1, we show that for every 0 ≤ k ≤ d there are at least ( dk ) eigenvalues near 1 − 2−k, and the limiting spectral gap is exactly 1/2. We also show that the corresponding eigenfunctions in this case are tightly related to the geometric configuration of the points.",

keywords = "homological connectivity, Random geometric graphs, spectral measure",

author = "Kartick Adhikari and Adler, {Robert J.} and Omer Bobrowski and Ron Rosenthal",

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AU - Adhikari, Kartick

AU - Adler, Robert J.

AU - Bobrowski, Omer

AU - Rosenthal, Ron

N1 - Publisher Copyright: © Institute of Mathematical Statistics, 2022

PY - 2022/6

Y1 - 2022/6

N2 - In this paper we study the spectrum of the random geometric graph G(n, r), in a regime where the graph is dense and highly connected. In the Erdős–Rényi G(n, p) random graph it is well known that upon connectivity the spectrum of the normalized graph Laplacian is concentrated around 1. We show that such concentration does not occur in the G(n, r) case, even when the graph is dense and almost a complete graph. In particular, we show that the limiting spectral gap is strictly smaller than 1. In the special case where the vertices are distributed uniformly in the unit cube and r = 1, we show that for every 0 ≤ k ≤ d there are at least ( dk ) eigenvalues near 1 − 2−k, and the limiting spectral gap is exactly 1/2. We also show that the corresponding eigenfunctions in this case are tightly related to the geometric configuration of the points.

AB - In this paper we study the spectrum of the random geometric graph G(n, r), in a regime where the graph is dense and highly connected. In the Erdős–Rényi G(n, p) random graph it is well known that upon connectivity the spectrum of the normalized graph Laplacian is concentrated around 1. We show that such concentration does not occur in the G(n, r) case, even when the graph is dense and almost a complete graph. In particular, we show that the limiting spectral gap is strictly smaller than 1. In the special case where the vertices are distributed uniformly in the unit cube and r = 1, we show that for every 0 ≤ k ≤ d there are at least ( dk ) eigenvalues near 1 − 2−k, and the limiting spectral gap is exactly 1/2. We also show that the corresponding eigenfunctions in this case are tightly related to the geometric configuration of the points.

KW - homological connectivity

KW - Random geometric graphs

KW - spectral measure

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ER -

ON THE SPECTRUM OF DENSE RANDOM GEOMETRIC GRAPHS

Abstract

Keywords

ASJC Scopus subject areas

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