Weighted enumeration of nonbacktracking walks on weighted graphs

Francesca Arrigo; Desmond J. Higham; Vanni  Noferini; Ryan Wood

doi:10.1137/23M155219X

Weighted enumeration of nonbacktracking walks on weighted graphs

Francesca Arrigo, Desmond J. Higham, Vanni Noferini, Ryan Wood^*

^*Corresponding author for this work

Mathematics And Statistics

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

3 Citations (Scopus)

17 Downloads (Pure)

Abstract

We extend the notion of nonbacktracking walks from unweighted graphs to graphs whose edges have a nonnegative weight. Here the weight associated with a walk is taken to be the product over the weights along the individual edges. We give two ways to compute the associated generating function, and corresponding node centrality measures. One method works directly on the original graph and one uses a line graph construction followed by a projection. The first method is more efficient, but the second has the advantage of extending naturally to time-evolving graphs. Based on these generating functions, we define and study corresponding centrality measures. Illustrative computational results are also provided.

Original language	English
Pages (from-to)	397-418
Number of pages	22
Journal	SIAM Journal on Matrix Analysis and Applications
Volume	45
Issue number	1
Early online date	30 Jan 2024
DOIs	https://doi.org/10.1137/23M155219X
Publication status	Published - 31 Mar 2024

Keywords

complex network
matrix function
generating function
line graph
combinatorics
evolving graph
temporal network
centrality measure
Katz centrality

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10.1137/23M155219X

Arrigo-etal-SJMAA-2023-Weighted-enumeration-of-nonbacktracking-walks-on-weighted-graphsAccepted author manuscript, 32.3 MBLicence: CC BY 4.0

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title = "Weighted enumeration of nonbacktracking walks on weighted graphs",

abstract = "We extend the notion of nonbacktracking walks from unweighted graphs to graphs whose edges have a nonnegative weight. Here the weight associated with a walk is taken to be the product over the weights along the individual edges. We give two ways to compute the associated generating function, and corresponding node centrality measures. One method works directly on the original graph and one uses a line graph construction followed by a projection. The first method is more efficient, but the second has the advantage of extending naturally to time-evolving graphs. Based on these generating functions, we define and study corresponding centrality measures. Illustrative computational results are also provided.",

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T1 - Weighted enumeration of nonbacktracking walks on weighted graphs

AU - Arrigo, Francesca

AU - Higham, Desmond J.

AU - Noferini, Vanni

AU - Wood, Ryan

PY - 2024/3/31

Y1 - 2024/3/31

N2 - We extend the notion of nonbacktracking walks from unweighted graphs to graphs whose edges have a nonnegative weight. Here the weight associated with a walk is taken to be the product over the weights along the individual edges. We give two ways to compute the associated generating function, and corresponding node centrality measures. One method works directly on the original graph and one uses a line graph construction followed by a projection. The first method is more efficient, but the second has the advantage of extending naturally to time-evolving graphs. Based on these generating functions, we define and study corresponding centrality measures. Illustrative computational results are also provided.

AB - We extend the notion of nonbacktracking walks from unweighted graphs to graphs whose edges have a nonnegative weight. Here the weight associated with a walk is taken to be the product over the weights along the individual edges. We give two ways to compute the associated generating function, and corresponding node centrality measures. One method works directly on the original graph and one uses a line graph construction followed by a projection. The first method is more efficient, but the second has the advantage of extending naturally to time-evolving graphs. Based on these generating functions, we define and study corresponding centrality measures. Illustrative computational results are also provided.

KW - complex network

KW - matrix function

KW - generating function

KW - line graph

KW - combinatorics

KW - evolving graph

KW - temporal network

KW - centrality measure

KW - Katz centrality

U2 - 10.1137/23M155219X

DO - 10.1137/23M155219X

M3 - Article

SN - 0895-4798

VL - 45

SP - 397

EP - 418

JO - SIAM Journal on Matrix Analysis and Applications

JF - SIAM Journal on Matrix Analysis and Applications

IS - 1

ER -

Weighted enumeration of nonbacktracking walks on weighted graphs

Abstract

Keywords

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