The algebraic connectivity of barbell graphs

Xiaodi Song; Shenggui Zhang; Xinzhuang Chen; Shanshan Gao

doi:10.1016/j.disc.2024.114027

The algebraic connectivity of barbell graphs

Xiaodi Song, Shenggui Zhang, Xinzhuang Chen, Shanshan Gao

School of Mathematics and Statistics

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

Abstract

The algebraic connectivity of a graph is the second smallest eigenvalue of its Laplacian matrix. An eigenvector affording the algebraic connectivity is called a Fiedler vector. The barbell graph B_p,q;l is the graph obtained by joining a vertex in a cycle C_p(p≠2) and a vertex in a cycle C_q(q≠2) by a path P_l with p≥3 or q≥3, and l≥2 if p=1 or q=1. In this paper, we determine the graphs minimizing the algebraic connectivity among all barbell graphs and the graphs containing a barbell graph as a spanning subgraph of given order, respectively. Moreover, we investigate how the algebraic connectivity behaves under some graph perturbations, and compare the algebraic connectivities of barbell graphs, cycles, and θ-graphs.

Original language	English
Article number	114027
Journal	Discrete Mathematics
Volume	347
Issue number	7
DOIs	https://doi.org/10.1016/j.disc.2024.114027
State	Published - Jul 2024

Keywords

Algebraic connectivity
Barbell graph
Fiedler vector
Graph perturbation

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10.1016/j.disc.2024.114027

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abstract = "The algebraic connectivity of a graph is the second smallest eigenvalue of its Laplacian matrix. An eigenvector affording the algebraic connectivity is called a Fiedler vector. The barbell graph Bp,q;l is the graph obtained by joining a vertex in a cycle Cp(p≠2) and a vertex in a cycle Cq(q≠2) by a path Pl with p≥3 or q≥3, and l≥2 if p=1 or q=1. In this paper, we determine the graphs minimizing the algebraic connectivity among all barbell graphs and the graphs containing a barbell graph as a spanning subgraph of given order, respectively. Moreover, we investigate how the algebraic connectivity behaves under some graph perturbations, and compare the algebraic connectivities of barbell graphs, cycles, and θ-graphs.",

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AU - Gao, Shanshan

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N2 - The algebraic connectivity of a graph is the second smallest eigenvalue of its Laplacian matrix. An eigenvector affording the algebraic connectivity is called a Fiedler vector. The barbell graph Bp,q;l is the graph obtained by joining a vertex in a cycle Cp(p≠2) and a vertex in a cycle Cq(q≠2) by a path Pl with p≥3 or q≥3, and l≥2 if p=1 or q=1. In this paper, we determine the graphs minimizing the algebraic connectivity among all barbell graphs and the graphs containing a barbell graph as a spanning subgraph of given order, respectively. Moreover, we investigate how the algebraic connectivity behaves under some graph perturbations, and compare the algebraic connectivities of barbell graphs, cycles, and θ-graphs.

AB - The algebraic connectivity of a graph is the second smallest eigenvalue of its Laplacian matrix. An eigenvector affording the algebraic connectivity is called a Fiedler vector. The barbell graph Bp,q;l is the graph obtained by joining a vertex in a cycle Cp(p≠2) and a vertex in a cycle Cq(q≠2) by a path Pl with p≥3 or q≥3, and l≥2 if p=1 or q=1. In this paper, we determine the graphs minimizing the algebraic connectivity among all barbell graphs and the graphs containing a barbell graph as a spanning subgraph of given order, respectively. Moreover, we investigate how the algebraic connectivity behaves under some graph perturbations, and compare the algebraic connectivities of barbell graphs, cycles, and θ-graphs.

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The algebraic connectivity of barbell graphs

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Keywords

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