CLASSIFICATION OF TREES EACH OF WHOSE ASSOCIATED ACYCLIC MATRICES WITH DISTINCT DIAGONAL ENTRIES HAS DISTINCT EIGENVALUES

Similar documents
The Singular Acyclic Matrices of Even Order with a P-Set of Maximum Size

Smith Normal Form and Acyclic Matrices

Inverse Eigenvalue Problems for Two Special Acyclic Matrices

On the adjacency matrix of a block graph

An Introduction to Spectral Graph Theory

Minimum rank of a graph over an arbitrary field

The effect on the algebraic connectivity of a tree by grafting or collapsing of edges

Smith Normal Form and acyclic matrices

The minimum rank of matrices and the equivalence class graph

Iowa State University and American Institute of Mathematics

Sparse spectrally arbitrary patterns

Refined Inertia of Matrix Patterns

A Simple Proof of Fiedler's Conjecture Concerning Orthogonal Matrices

RATIONAL REALIZATION OF MAXIMUM EIGENVALUE MULTIPLICITY OF SYMMETRIC TREE SIGN PATTERNS. February 6, 2006

FORBIDDEN MINORS FOR THE CLASS OF GRAPHS G WITH ξ(g) 2. July 25, 2006

Note on deleting a vertex and weak interlacing of the Laplacian spectrum

A lower bound for the Laplacian eigenvalues of a graph proof of a conjecture by Guo

Diagonal Entry Restrictions in Minimum Rank Matrices, and the Inverse Inertia and Eigenvalue Problems for Graphs

INTERLACING PROPERTIES FOR HERMITIAN MATRICES WHOSE GRAPH IS A GIVEN TREE

Spectrally arbitrary star sign patterns

An upper bound for the minimum rank of a graph

Z-Pencils. November 20, Abstract

Some spectral inequalities for triangle-free regular graphs

New feasibility conditions for directed strongly regular graphs

ELA A LOWER BOUND FOR THE SECOND LARGEST LAPLACIAN EIGENVALUE OF WEIGHTED GRAPHS

Bipartite graphs with at most six non-zero eigenvalues

On the inverse of the adjacency matrix of a graph

Average Mixing Matrix of Trees

The least eigenvalue of the signless Laplacian of non-bipartite unicyclic graphs with k pendant vertices

The Adjacency Matrix, Standard Laplacian, and Normalized Laplacian, and Some Eigenvalue Interlacing Results

Energy of Graphs. Sivaram K. Narayan Central Michigan University. Presented at CMU on October 10, 2015

Laplacian Integral Graphs with Maximum Degree 3

The third smallest eigenvalue of the Laplacian matrix

Inverse Perron values and connectivity of a uniform hypergraph

On some matrices related to a tree with attached graphs

Ann. Funct. Anal. 5 (2014), no. 2, A nnals of F unctional A nalysis ISSN: (electronic) URL:

On the Non-Symmetric Spectra of Certain Graphs

A note on a conjecture for the distance Laplacian matrix

Bulletin T.CXXII de l Académie Serbe des Sciences et des Arts Classe des Sciences mathématiques et naturelles Sciences mathématiques, No 26

arxiv: v3 [math.ra] 10 Jun 2016

For a square matrix A, we let q(a) denote the number of distinct eigenvalues of A. For a graph G, we define. q(g) = min{q(a) : A S(G)}.

The Distance Spectrum

Kernels of Directed Graph Laplacians. J. S. Caughman and J.J.P. Veerman

RITZ VALUE BOUNDS THAT EXPLOIT QUASI-SPARSITY

THE SPECTRUM OF THE LAPLACIAN MATRIX OF A BALANCED 2 p -ARY TREE

arxiv:math/ v5 [math.ac] 17 Sep 2009

ON THE WIENER INDEX AND LAPLACIAN COEFFICIENTS OF GRAPHS WITH GIVEN DIAMETER OR RADIUS

Linear Algebra and its Applications

On minors of the compound matrix of a Laplacian

arxiv:quant-ph/ v1 22 Aug 2005

Characteristic polynomials of skew-adjacency matrices of oriented graphs

QUALITATIVE CONTROLLABILITY AND UNCONTROLLABILITY BY A SINGLE ENTRY

b jσ(j), Keywords: Decomposable numerical range, principal character AMS Subject Classification: 15A60

On the second Laplacian eigenvalues of trees of odd order

ZERO FORCING PARAMETERS AND MINIMUM RANK PROBLEMS. March 2, 2010

Sparsity of Matrix Canonical Forms. Xingzhi Zhan East China Normal University

Solving Homogeneous Systems with Sub-matrices

Linear Algebra and its Applications

Maximizing the numerical radii of matrices by permuting their entries

On marker set distance Laplacian eigenvalues in graphs.

On the spectral radii of quasi-tree graphs and quasiunicyclic graphs with k pendent vertices

The Matrix-Tree Theorem

Interlacing Inequalities for Totally Nonnegative Matrices

ON GLOBAL DOMINATING-χ-COLORING OF GRAPHS

On the maximum positive semi-definite nullity and the cycle matroid of graphs

ELA

Sign Patterns that Allow Diagonalizability

Edge-Disjoint Spanning Trees and Eigenvalues of Regular Graphs

The Interlace Polynomial of Graphs at 1

Results on minimum skew rank. of matrices described by a graph. Laura Leigh DeLoss. A thesis submitted to the graduate faculty

New skew Laplacian energy of a simple digraph

On Euclidean distance matrices

Conditioning of the Entries in the Stationary Vector of a Google-Type Matrix. Steve Kirkland University of Regina

On sum of powers of the Laplacian and signless Laplacian eigenvalues of graphs

Normalized rational semiregular graphs

Completions of P-Matrix Patterns

Energies of Graphs and Matrices

Intrinsic products and factorizations of matrices

arxiv: v2 [math.co] 27 Jul 2013

Potentially nilpotent tridiagonal sign patterns of order 4

Graphs determined by their (signless) Laplacian spectra

ELA ON A SCHUR COMPLEMENT INEQUALITY FOR THE HADAMARD PRODUCT OF CERTAIN TOTALLY NONNEGATIVE MATRICES

Minimizing the Laplacian eigenvalues for trees with given domination number

Chapter 2 Spectra of Finite Graphs

Central Groupoids, Central Digraphs, and Zero-One Matrices A Satisfying A 2 = J

Line segments on the boundary of the numerical ranges of some tridiagonal matrices

Graphs and matrices with maximal energy

The Minimum Rank, Inverse Inertia, and Inverse Eigenvalue Problems for Graphs. Mark C. Kempton

Generalizations of the Strong Arnold Property and the Inverse Eigenvalue Problem of a Graph

Sign Patterns with a Nest of Positive Principal Minors

Inverse eigenvalue problems involving multiple spectra

Minimum number of non-zero-entries in a 7 7 stable matrix

On the distance signless Laplacian spectral radius of graphs and digraphs

Inertially arbitrary nonzero patterns of order 4

arxiv: v2 [math.co] 6 Oct 2016

A classification of sharp tridiagonal pairs. Tatsuro Ito, Kazumasa Nomura, Paul Terwilliger

18.312: Algebraic Combinatorics Lionel Levine. Lecture (u, v) is a horizontal edge K u,v = i (u, v) is a vertical edge 0 else

Energy, Laplacian Energy and Zagreb Index of Line Graph, Middle Graph and Total Graph

Eigenvectors Via Graph Theory

ACI-matrices all of whose completions have the same rank

Transcription:

Bull Korean Math Soc 45 (2008), No 1, pp 95 99 CLASSIFICATION OF TREES EACH OF WHOSE ASSOCIATED ACYCLIC MATRICES WITH DISTINCT DIAGONAL ENTRIES HAS DISTINCT EIGENVALUES In-Jae Kim and Bryan L Shader Reprinted from the Bulletin of the Korean Mathematical Society Vol 45, No 1, February 2008 c 2008 The Korean Mathematical Society

Bull Korean Math Soc 45 (2008), No 1, pp 95 99 CLASSIFICATION OF TREES EACH OF WHOSE ASSOCIATED ACYCLIC MATRICES WITH DISTINCT DIAGONAL ENTRIES HAS DISTINCT EIGENVALUES In-Jae Kim and Bryan L Shader Abstract It is known that each eigenvalue of a real symmetric, irreducible, tridiagonal matrix has multiplicity 1 The graph of such a matrix is a path In this paper, we extend the result by classifying those trees for which each of the associated acyclic matrices has distinct eigenvalues whenever the diagonal entries are distinct 1 Introduction Throughout all matrices are real We refer a reader to [2] for basic graph theoretic terminology Let A = [a ij ] be an n by n symmetric matrix If A has k distinct eigenvalues with multiplicities m 1 m 2 m k, then (m 1, m 2,, m k ) is the unordered multiplicity list of the eigenvalues of A If an eigenvalue λ of A has multiplicity 1, then λ is a simple eigenvalue of A The graph of A, denoted by G(A), consists of the vertices 1, 2,, n, and the edges {i, j} for which i j and a ij 0 Note that G(A) does not depend on the diagonal entries of A If G(A) is a tree, then A is an irreducible, acyclic matrix Further, for a given graph G on n vertices, define S(G) to be the set of all n by n symmetric matrices with graph G, ie, S(G) = {A n n A is symmetric and G(A) = G } The spectrum of S(G) is the set of all spectra realized by some matrix in S(G) The unordered multiplicity list of S(G) is the set of all unordered multiplicity lists realized by some matrix in S(G) It is known that for a tree T, some combinatorial properties of T are reflected in the spectrum of S(T ), and hence impose restrictions on the unordered multiplicity list of S(T ) (see [4, 1]) For example, the maximum multiplicity of an eigenvalue of a matrix in S(T ) is the minimum number of disjoint paths in T Received May 25, 2007 2000 Mathematics Subject Classification 15A18, 05C50 Key words and phrases acyclic matrix, Parter-vertex, simple eigenvalue The work of In-Jae Kim was in part supported by a Faculty Research Grant from the Minnesota State University, Mankato 95 c 2008 The Korean Mathematical Society

96 IN-JAE KIM AND BRYAN L SHADER covering all of the vertices of T Thus, for a given tree T, it can be shown that T is a path if and only if the unordered multiplicity list of S(T ) is {(1, 1,, 1)} This implies that if G(A) is a path, then the symmetric, irreducible, tridiagonal matrix A has only simple eigenvalues regardless of the diagonal entries A problem related to this fact is the existence of other trees T for which each associated acyclic matrix with some restrictions on the diagonal entries has the unordered multiplicity list (1, 1,, 1) For a given graph, define SD(G) = {A = [a ij ] S(G) a ss a tt for s t } In this note, we classify the trees T such that every matrix in SD(T ) has only simple eigenvalues 2 Main results We first provide necessary terms and a known result Let T be a tree, and let v be a vertex of T Then T \ {v} is the induced subgraph obtained by deleting vertex v and all incident edges to v Each connected component of T \ {v} is called a branch of T at v Note that each branch of T at v is a tree If the degree of v is k, then there are k branches of T at v Let A S(T ), and B be a branch of T at v Then A(v) denotes the principal submatrix of A whose graph is T \{v}, and A[B] denotes the principal submatrix of A obtained by retaining rows and columns indexed by the vertices of B If B 1, B 2,, B k are the branches of T at v, then A(v) is, up to permutation similarity, equal to A[B 1 ] A[B 2 ] A[B k ] The multiplicity of an eigenvalue λ of A is denoted by m A (λ) If λ = 0, then m A (λ) is the nullity ν(a) of A It is a simple consequence of linear algebra that ν(a) ν(a(v)) 1 Moreover, by the Cauchy Interlacing Theorem (see [3, Theorem 438]), m A (λ) and m A(v) (λ) differ by at most one If m A(v) (λ) = m A (λ) + 1, vertex v is a Parter-vertex of A for λ (see [5]) If G(A) is a tree, then we have the following result Lemma 21 (Parter-Wiener Theorem, [5]) Let A be an irreducible, acyclic matrix, and let λ be an eigenvalue of A with m A (λ) 2 Then there exists a Parter-vertex v of A for λ such that λ is an eigenvalue of at least three of the direct summands of A(v) The following result along with Lemma 24 gives the characterization of the trees T for which each matrix in SD(T ) has distinct eigenvalues Theorem 22 Let T be a tree that is not a path Then each matrix in SD(T ) has distinct eigenvalues if and only if each vertex of degree 3 or more in T has at most one branch which is not a pendant vertex To prove Theorem 22, we first establish the following lemma Lemma 23 Let T be a tree on n vertices for n 2 Then there exists a singular matrix in SD(T ) with all nonzero diagonal entries

TREES WITH DISTINCT EIGENVALUES FOR DISTINCT DIAGONAL ENTRIES 97 Proof Let L = [l ij ] be the Laplacian matrix of T (see [2]) Then L S(T ) Since n 2 and T is connected, L is singular and l ii > 0 for each i = 1,, n Let D = diag(d 1,, d n ) with d j 0 for each j = 1,, n such that d 2 1l 11 > d 2 2l 22 > > d 2 nl nn > 0, and let A = DLD Then A is a singular matrix with nonzero diagonal entries in SD(T ) Proof of Theorem 22 Let T be a tree that is not a path For sufficiency, assume that each of vertices of degree 3 or more in T has at most one branch which is not a pendant vertex, and A SD(T ) Suppose to the contrary that there exists an eigenvalue λ of A with m A (λ) 2 Then, by Lemma 21, there exists a Parter-vertex v of A for λ such that at least three of the direct summands of A(v) have λ as an eigenvalue This implies that at least two diagonal entries of A are λ This contradicts that A has distinct diagonal entries For necessity, suppose to the contrary that there exists a vertex v of degree 3 or more having at least two branches which are not pendant vertices Let k denote the degree of v, and B 1,, B k be the branches of T at v Assume that there are exactly two branches of T at v which are not pendant vertices, say B 1, B 2 Then B 3,, B k are pendant vertices of T By Lemma 23, there is a singular matrix A j without any zero diagonal entries in SD(B j ) for each j = 1, 2 Moreover, by using the construction in Lemma 23, we can construct A 1, A 2 such that the diagonal entries of A 1, A 2 are nonzero, distinct, real numbers We now construct a matrix A = [a ij ] in SD(T ) such that A[B j ] = A j for j = 1, 2, A[B 3 ] = 0, a ss a tt for s t, and the other entries, not yet assigned any value, are 1 Since there are exactly 3 singular summands A[B 1 ], A[B 2 ], and A[B 3 ] of A(v), it follows that ν(a(v)) = 3 Since ν(a) ν(a(v)) 1, it follows that ν(a) 2 Hence, not all of the eigenvalues of A are simple Next assume that there are at least three branches of T at v which are not pendant vertices of T, and B 1, B 2, B 3 are three of them As before, we construct a matrix A in SD(T ) such that A[B j ] s are singular matrices with no zero diagonal entries and A[B j ] SD(B j ) for j = 1, 2, 3, and a ss a tt for s t, and the other entries, not yet assigned any value, are 1 Then, since there are at least 3 singular summands A[B 1 ], A[B 2 ], and A[B 3 ] of A(v), ν(a(v)) 3 Since ν(a) ν(a(v)) 1, it follows that ν(a) 2 Hence, the result follows We now turn our attention to characterize the trees for which each vertex of degree 3 or more has at most one branch which is not a pendant vertex Lemma 24 Let T be a tree If each vertex of degree 3 or more in T has at most one branch which is not a pendant vertex, then there are at most two vertices of degree 3 or more in T Proof Suppose to the contrary that T has at least three vertices of degree 3 or more Let u, v, w be vertices of degree 3 or more in T Since T is a tree, there

98 IN-JAE KIM AND BRYAN L SHADER exists a pair of vertices v 1, v 2 in {u, v, w} such that the path P connecting v 1 and v 2 does not pass through vertex v 3 {u, v, w} \ {v 1, v 2 } Since the branch of T at v 1 (resp v 2 ) containing vertex v 2 (resp vertex v 1 ) is a non-pendant branch, by the assumption, the path connecting v 1 and v 3 shares a vertex y, which is neither v 1 nor v 2, with the path P Thus, deg(y) 3 and there exist at least two branches of T at y that are not pendant vertices This contradicts the assumption The following is a direct consequence of Theorem 22 and Lemma 24 Corollary 25 Let T be a tree Then each matrix in SD(T ) has distinct eigenvalues if and only if T is one of the following trees: (1) No vertex of degree 3 or more (Paths) : (2) One vertex of degree 3 or more: (2a) No branch which is not a pendant vertex (Stars) : (2b) One branch which is not a pendant vertex: (3) Two vertices of degree 3 or more:

TREES WITH DISTINCT EIGENVALUES FOR DISTINCT DIAGONAL ENTRIES 99 Example 26 Consider the following tree T and A SD(T ) : 1 3 4 5 6 7 2 8 A = a 1 0 b 1 0 0 0 0 0 0 a 2 b 2 0 0 0 0 0 b 1 b 2 a 3 b 3 0 0 0 0 0 0 b 3 a 4 b 4 0 0 0 0 0 0 b 4 a 5 b 5 b 6 b 7 0 0 0 0 b 5 a 6 0 0 0 0 0 0 b 6 0 a 7 0 0 0 0 0 b 7 0 0 a 8 where the a i s are distinct real numbers, and each b j is a nonzero real number Then Corollary 25 implies that for any nonzero real numbers b 1,, b 7, each eigenvalue of A is simple References [1] A Leal Duarte and C R Johnson, On the minimum number of distinct eigenvalues for a symmetric matrix whose graph is a given tree, Math Inequal Appl 5 (2002), no 2, 175 180 [2] C Godsil and G Royle, Algebraic graph theory, Graduate Texts in Mathematics, 207 Springer-Verlag, New York, 2001 [3] R Horn and C R Johnson, Matrix analysis, Cambridge University Press, Cambridge, 1985 [4] C R Johnson and A Leal Duarte, The maximum multiplicity of an eigenvalue in a matrix whose graph is a tree, Linear and Multilinear Algebra 46 (1999), no 1-2, 139 144 [5] C R Johnson, A Leal Duarte, and C M Saiago, The Parter-Wiener theorem: refinement and generalization, SIAM J Matrix Anal Appl 25 (2003), no 2, 352 361 In-Jae Kim Department of Mathematics and Statistics Minnesota State University, Mankato Mankato, MN 56001, USA E-mail address: in-jaekim@mnsuedu Bryan L Shader Department of Mathematics University of Wyoming Laramie, WY 82071, USA E-mail address: bshader@uwyoedu,

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback