An exposition on singular graphs: The cartesian product of two graphs

An exposition on singular graphs: The cartesian product of two graphs

This paper is an exposition of the Singular graphs: The Cartesian Product of Two Graphs, from the study of Severino V. Gervacio. The adjacency matrix of agraph G with vertices V1, V2,...,Vn is the n x n matrix A(G) = [aij], where aij = 1 if Vi and Vj are adjacent, and aij = 0 otherwise. The graph G...

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Main Authors: Calvero, Arianne Faye Marie B., Gernan, Michelle B.
Format: text
Language:English
Published: Animo Repository 2006
Subjects:
Matrices
Matrix inversion
Algebras, Linear
Algebra > Graphic methods
Graph theory
Online Access:https://animorepository.dlsu.edu.ph/etd_bachelors/17433
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Institution: De La Salle University
Language: English
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spelling oai:animorepository.dlsu.edu.ph:etd_bachelors-179462022-02-03T04:01:06Z An exposition on singular graphs: The cartesian product of two graphs Calvero, Arianne Faye Marie B. Gernan, Michelle B. This paper is an exposition of the Singular graphs: The Cartesian Product of Two Graphs, from the study of Severino V. Gervacio. The adjacency matrix of agraph G with vertices V1, V2,...,Vn is the n x n matrix A(G) = [aij], where aij = 1 if Vi and Vj are adjacent, and aij = 0 otherwise. The graph G is said to be singular if A(G) i singular,i.e., det A(G) = 0 otherwise, G is said to be non-singular. The cartesian product of two graphs G and H, denoted by G x H, may be singular or non-singular, independently of the singularity or non-singularity of G and H. We show that det A(Kn0 = (-1) n-1 (n-1) and hence Kn is non-singular only when n-2. If G is any graph, we prove that G x Kn is singular if and only if 1 or (1-n) is an eigenvalue of A(G). In particular, we show that the cartesian product of Cm and Kn, n-4, is singular if and only if m=0 (mod 6). Also, for 1- n-3, we show that Cm x K1 is singular if and only if m = 0 (mod 4) or m = 0 (mod 6), Cm x K2 is singular if and only if m = 0 (mod 30 and Cm x K3 is singular if and only if m = 0 (mod 2). We also prove that det (A(Km x Kn)) = (-2) (m-1)(n-1)(m-2)n-1(n-2)m-1(m+n-2). As a corollary, Km x Kn is singular if and only m = 2 or n = 2. 2006-01-01T08:00:00Z text https://animorepository.dlsu.edu.ph/etd_bachelors/17433 Bachelor's Theses English Animo Repository Matrices Matrix inversion Algebras, Linear Algebra--Graphic methods Graph theory
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
language English
topic Matrices
Matrix inversion
Algebras, Linear
Algebra--Graphic methods
Graph theory
spellingShingle Matrices
Matrix inversion
Algebras, Linear
Algebra--Graphic methods
Graph theory
Calvero, Arianne Faye Marie B.
Gernan, Michelle B.
An exposition on singular graphs: The cartesian product of two graphs
description This paper is an exposition of the Singular graphs: The Cartesian Product of Two Graphs, from the study of Severino V. Gervacio. The adjacency matrix of agraph G with vertices V1, V2,...,Vn is the n x n matrix A(G) = [aij], where aij = 1 if Vi and Vj are adjacent, and aij = 0 otherwise. The graph G is said to be singular if A(G) i singular,i.e., det A(G) = 0 otherwise, G is said to be non-singular. The cartesian product of two graphs G and H, denoted by G x H, may be singular or non-singular, independently of the singularity or non-singularity of G and H. We show that det A(Kn0 = (-1) n-1 (n-1) and hence Kn is non-singular only when n-2. If G is any graph, we prove that G x Kn is singular if and only if 1 or (1-n) is an eigenvalue of A(G). In particular, we show that the cartesian product of Cm and Kn, n-4, is singular if and only if m=0 (mod 6). Also, for 1- n-3, we show that Cm x K1 is singular if and only if m = 0 (mod 4) or m = 0 (mod 6), Cm x K2 is singular if and only if m = 0 (mod 30 and Cm x K3 is singular if and only if m = 0 (mod 2). We also prove that det (A(Km x Kn)) = (-2) (m-1)(n-1)(m-2)n-1(n-2)m-1(m+n-2). As a corollary, Km x Kn is singular if and only m = 2 or n = 2.
format text
author Calvero, Arianne Faye Marie B.
Gernan, Michelle B.
author_facet Calvero, Arianne Faye Marie B.
Gernan, Michelle B.
author_sort Calvero, Arianne Faye Marie B.
title An exposition on singular graphs: The cartesian product of two graphs
title_short An exposition on singular graphs: The cartesian product of two graphs
title_full An exposition on singular graphs: The cartesian product of two graphs
title_fullStr An exposition on singular graphs: The cartesian product of two graphs
title_full_unstemmed An exposition on singular graphs: The cartesian product of two graphs
title_sort exposition on singular graphs: the cartesian product of two graphs
publisher Animo Repository
publishDate 2006
url https://animorepository.dlsu.edu.ph/etd_bachelors/17433
_version_ 1772835280721543168

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