THE WIENER INDEX AND HOSOYA POLYNOMIAL OF A CLASS OF JAHANGIR GRAPHS

Similar documents
THE GENERALIZED ZAGREB INDEX OF CAPRA-DESIGNED PLANAR BENZENOID SERIES Ca k (C 6 )

Discrete Applied Mathematics archive Volume 156, Issue 10 (May 2008) table of contents Pages Year of Publication: 2008 ISSN: X

About Atom Bond Connectivity and Geometric-Arithmetic Indices of Special Chemical Molecular and Nanotubes

Research Article. Generalized Zagreb index of V-phenylenic nanotubes and nanotori

ON THE GENERALIZED ZAGREB INDEX OF DENDRIMER NANOSTARS

TWO TYPES OF CONNECTIVITY INDICES OF THE LINEAR PARALLELOGRAM BENZENOID

Hexagonal Chains with Segments of Equal Lengths Having Distinct Sizes and the Same Wiener Index

Computing distance moments on graphs with transitive Djoković-Winkler s relation

COMPUTING SANSKRUTI INDEX OF DENDRIMER NANOSTARS. Chengdu University Chengdu, , P.R. CHINA 2 Department of Mathematics

On Trees Having the Same Wiener Index as Their Quadratic Line Graph

Computing Banhatti Indices of Hexagonal, Honeycomb and Derived Networks

Some Topological Indices of L(S(CNC k [n]))

Extremal Graphs with Respect to the Zagreb Coindices

More on Zagreb Coindices of Composite Graphs

Keywords: Szeged index, TUAC 6 [ p, k ] Nanotube

THE (a,b)-zagreb INDEX OF NANOSTAR DENDRIMERS

On the higher randić indices of nanotubes

THE EDGE VERSIONS OF THE WIENER INDEX

ON SOME DEGREE BASED TOPOLOGICAL INDICES OF T io 2 NANOTUBES

Wiener index of generalized 4-stars and of their quadratic line graphs

Second-Order and Third-Order Connectivity Indices of an Infinite Family of Dendrimer Nanostars

Szeged Related Indices of Unilateral Polyomino Chain and Unilateral Hexagonal Chain

The Eccentric Connectivity Index of Dendrimers

M-Polynomial and Degree-Based Topological Indices

The Graovac-Pisanski index of a connected bipartite graph is an integer number

ON THE DISTANCE-BASED TOPOLOGICAL INDICES OF FULLERENE AND FULLERENYL ANIONS HAVING DENDRIMER UNITS

JOURNAL OF MATHEMATICAL NANOSCIENCE. Connective eccentric index of fullerenes

THE ECCENTRIC CONNECTIVITY INDEX OF ARMCHAIR POLYHEX NANOTUBES

On the difference between the revised Szeged index and the Wiener index

Upper Bounds for the Modified Second Multiplicative Zagreb Index of Graph Operations Bommanahal Basavanagoud 1, a *, Shreekant Patil 2, b

A new version of Zagreb indices. Modjtaba Ghorbani, Mohammad A. Hosseinzadeh. Abstract

COMPUTING SANSKRUTI INDEX OF TITANIA NANOTUBES

RELATION BETWEEN WIENER INDEX AND SPECTRAL RADIUS

Wiener Indices and Polynomials of Five Graph Operators

Canadian Journal of Chemistry. On Topological Properties of Dominating David Derived Networks

arxiv: v1 [math.co] 13 Dec 2012

Calculating the hyper Wiener index of benzenoid hydrocarbons

EXACT FORMULAE OF GENERAL SUM-CONNECTIVITY INDEX FOR SOME GRAPH OPERATIONS. Shehnaz Akhter, Rashid Farooq and Shariefuddin Pirzada

VERTEX-WEIGHTED WIENER POLYNOMIALS OF SUBDIVISION-RELATED GRAPHS. Mahdieh Azari, Ali Iranmanesh, and Tomislav Došlić

Applied Mathematics and Nonlinear Sciences

Interpolation method and topological indices: 2-parametric families of graphs

arxiv: v1 [math.co] 14 May 2018

Curriculum vitae Bijan Taeri

On Wiener polarity index of bicyclic networks

HYPER ZAGREB INDEX OF BRIDGE AND CHAIN GRAPHS

Clar number of catacondensed benzenoid hydrocarbons

A Note on Revised Szeged Index of Graph Operations

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

Multiplicative Connectivity Revan Indices of Polycyclic Aromatic Hydrocarbons and Benzenoid Systems

Wiener Index of Graphs and Their Line Graphs

NEW AND MODIFIED ECCENTRIC INDICES OF OCTAGONAL GRID O m n

The eccentric-distance sum of some graphs

Topological indices: the modified Schultz index

HOSOYA POLYNOMIAL OF THORN TREES, RODS, RINGS, AND STARS

WIENER POLARITY INDEX OF QUASI-TREE MOLECULAR STRUCTURES

Redefined Zagreb, Randic, Harmonic and GA Indices of Graphene

The Degree Distance of Armchair Polyhex Nanotubes

On the sextet polynomial of fullerenes

BoundsonVertexZagrebIndicesofGraphs

Canadian Journal of Chemistry. On Molecular Topological Properties of Dendrimers

arxiv: v1 [math.co] 13 Mar 2018

arxiv: v1 [math.co] 15 Sep 2016

M-POLYNOMIALS AND DEGREE-BASED TOPOLOGICAL INDICES OF SOME FAMILIES OF CONVEX POLYTOPES

PAijpam.eu SOME NEW/OLD DEGREE-BASED TOPOLOGICAL INDICES OF NANOSTAR DENDRIMERS

On the Randić Index of Polyomino Chains

Curriculum Vitae. Gholam Hossein Fathtabar Firouzjaei

CALCULATING THE DEGREE DISTANCE OF PARTIAL HAMMING GRAPHS

COUNTING RELATIONS FOR GENERAL ZAGREB INDICES

On ve-degree and ev-degree Zagreb Indices of Titania Nanotubes

Wiener Index of Degree Splitting Graph of some Hydrocarbons

Extremal Topological Indices for Graphs of Given Connectivity

Normal components, Kekulé patterns, and Clar patterns in plane bipartite graphs

It can be easily shown that the above definition is equivalent to

CALCULATING DEGREE BASED TOPOLOGICAL INDICES OF LINE GRAPH OF HAC 5 C 6 C 7 [p, q] NANOTUBE VIA M-POLYNOMIAL

Some Computational Aspects for the Line Graph of Banana Tree Graph

Connectivity indices of some famous dendrimers

M-polynomials and Degree based Topological Indices for the Line Graph of Firecracker Graph

A Method of Calculating the Edge Szeged Index of Hexagonal Chain

THE HOSOYA INDEX AND THE MERRIFIELD-SIMMONS INDEX OF SOME GRAPHS. Communicated by Alireza Ashrafi. 1. Introduction

Some results on the reciprocal sum-degree distance of graphs

(Received: 19 October 2018; Received in revised form: 28 November 2018; Accepted: 29 November 2018; Available Online: 3 January 2019)

The multiplicative Zagreb indices of graph operations

On a Class of Distance Based Molecular Structure Descriptors

THE REVISED EDGE SZEGED INDEX OF BRIDGE GRAPHS

Improved bounds on the difference between the Szeged index and the Wiener index of graphs

(G,x) polynomial and (G) index of Armchair Polyhex Nanotubes TUAC 6 [m,n]

THE AVERAGE ECCENTRICITY AND ECCENTRICITY BASED GEOMETRIC-ARITHMETIC INDEX OF TETRA SHEETS

Counting the average size of Markov graphs

Applications of Isometric Embeddings to Chemical Graphs

M-Polynomial and Degree-Based Topological Indices

Graphs with maximum Wiener complexity

arxiv: v1 [math.co] 17 Apr 2018

The sharp bounds on general sum-connectivity index of four operations on graphs

Complexity of the Szeged Index, Edge Orbits, and Some Nanotubical Fullerenes

A New Multiplicative Arithmetic-Geometric Index

Energy and Laplacian Energy of Graphs. ALI REZA ASHRAFI Department of Mathematics, University of Kashan, Kashan , I. R.

A GAP PROGRAM FOR COMPUTING THE HOSOYA POLYNOMIAL AND WIENER INDEX OF NANO STRUCTURES

THE HARMONIC INDEX OF EDGE-SEMITOTAL GRAPHS, TOTAL GRAPHS AND RELATED SUMS

MULTIPLICATIVE ZAGREB ECCENTRICITY INDICES OF SOME COMPOSITE GRAPHS. Communicated by Ali Reza Ashrafi. 1. Introduction

The Fibonacci numbers for the molecular graphs of linear phenylenes

Transcription:

Fundamental Journal of Mathematics and Mathematical Sciences Vol. 3, Issue, 05, Pages 9-96 This paper is available online at http://www.frdint.com/ Published online July 3, 05 THE WIENER INDEX AND HOSOYA POLYNOMIAL OF A CLASS OF JAHANGIR GRAPHS J 3, m Department of Applied Mathematics Iran University of Science and Technology (IUST) Narmak, Tehran, Iran e-mail: Mr_Farahani@Mathdep.iust.ac.ir MrFarahani88@Gmail.com Abstract { v, u} V In this paper, the Wiener Index W = d( v, u) and Hosoya { v, u} V d ( v, u) polynomial H( G, x) = x of a class of Jahangir graphs J,m 3 with exactly 3 m + vertices and 4 m edges are computed. Keywords and phrases: graphs, Jahangir graphs, Wiener index, topological index, Hosoya polynomial.. Introduction Suppose G is a connected graph and x, y V, where V denotes the set of all vertices in G. The distance d ( x, y) between x and y is defined as the length of a minimal path connecting x and y. The maximum distance between two vertices of G is called the diameter of G, denoted by d. The Wiener index of a connected graph G, W is defined as the summation of all distances between all pairs of vertices of G. The Wiener index is introduced by Harold Wiener [] in 947 and is 00 Mathematics Subject Classification: 53C5, 53C5, 53C. Received April 3, 05; Accepted July 5, 05 05 Fundamental Research and Development International

9 equal to W = d( v, u). v V u V Other properties and applications of Wiener index can be found in [-5]. d The polynomial ( ) ( v, u H G, x = ) x is called the Hosoya v V u V polynomial of G. The name is used in honour of Haruo Hosoya, who discovered a new formula for the Wiener index in terms of graph distance [6]. We refer the interested readers to papers [7-3] for more information on this topic and the Hosoya polynomial.. Main Results In this section, we compute the Wiener index and Hosoya polynomial for Jahangir graphs. Suppose vertices and J 3, m is Jahangir graph m 3, with exactly 3 m + 4 m edges as shown in Figure [4, 5]. m 3, Jahangir graph is a connected graph consisting of a cycle C 3 m with one additional vertex (Center vertex c) such that c is adjacent to m vertices of C 3 m at distance 3 to each other on C 3m. Figure. Some examples of Jahangir graphs J 3, 4 and J 3, 6. Theorem. Let J 3, m be Jahangir graphs m 3. Then: The Wiener index of J 3, m is equal to The Hosoya polynomial of W ( J m ) = 5m 3. 3, m J 3, m is equal to 3 4 H ( J3, m ) = 4mx + m( m + 9) x + m( m ) x + m( m 5) x.

THE WIENER INDEX AND HOSOYA POLYNOMIAL OF A CLASS 93 Proof. Suppose J 3, m denotes Jahangir graph for all positive integer number m 3. From the definition of Jahangir graph J 3, one can see that the size of vertex set V ( J3, m ) is equal to m + m + = 3m + such that there are m vertices of Jahangir graph J 3, m with degree two and m vertices of J 3, m with degree three and Center vertex c has degree m. These imply that the size of edge set E ( J3, m ) be m + 3 m + m E( J3, m ) = = 4m. To compute the Wiener index and Hosoya polynomial of J 3, we first introduce some notions, which are useful to aims in this paper. The number of unordered pairs of vertices x and y of J, m 3 such that distance d ( x, y) = k is denoted by d( J 3, m, k ). Obviously k d( J 3, m ). Thus we redefine the Hosoya polynomial and Wiener index as follows: and d ( J3, m ) k 3, m 3, k = H ( J, x ) = d( J k ) x d( J3, m ) 3 m k. W ( J, ) = d( J3, k ) k = We divide the vertex set V ( J3, m ) of Jahangir graph into several partitions on based d v and denote by V, V 3 and m V such that V = { v V ( J ) d }. Thus k 3, m v = k = { v V ( J ) d = } V, V 3, m v = m = { v V ( J ) d = } V, V3 3, m v 3 = m V m { c V ( J ) d = 3} V. = 3, m c m = From the definition of the Hosoya polynomial, it s easy to see that the first sentence of H ( J3, x ), d( J3, ) is equal to the number of edges of J3, m ( 4m). By definition of Jahangir graph J 3, one can see that m -edges paths start from the vertex c and for every vertex v of V, there are three -edges paths and

94 ( + ( m ) ) -edges paths start from a vertex u of V. So d (, ) = [ m + 3( m) + m( + ( m ) )] = ( m + 9m). 3 J 3, m From Figure, we see that there is not any 3-edges path with c. But there are ( + ( m 3) ) 3-edges paths start from a vertex u of V 3 and also there are ( + ( m ) ) 3-edges paths start from a member of V. Thus d (, 3) = [ 0 + m ( + ( m ) ) + m( + ( m 3) )] = m( m ). From the structure of J 3, m J 3, m in Figure, we see that the diameter of Jahangir graph D ( J 3, m ) is equal to 4 and is between two vertices of V. The format of a 4- edges path of,, J 3, m is denoted by v v3cv v3, where c C, v,, v V and v, 3, v 3 V 3. The number of these 4-edges paths is m ( + ( m 3) ) = m( m 5) ( = d ( J 3, 4)). Thus by these results, the Hosoya polynomial of Jahangir graph H ( J x ) = d( J, i ) x i 3, m, 3, m J 3, m is equal to 3 4 = 4m x + m( m + 9) x + m( m ) x + m( m 5) x. = = m d( J ) 3, m 3, m i 3, 3, It is obvious that for Jahangir graph J, H ( J, ) d( J i ) = 3 m + 3m( 3m + ) =. On the other hand, we have following computations for the Wiener index of Jahangir graph J 3, m as: W ( J ) = d( J, i ) i 3, m 3, m = 4m + m( m + 9) + 3 m( m ) + 4 m( m 5) = 4m + m + 9m + 6m 6m + 8m 0m = 5m 3m. And these complete the proof of Theorem.

THE WIENER INDEX AND HOSOYA POLYNOMIAL OF A CLASS 95 References [] H. Wiener, Structural determination of paraffin boiling points, J. Amer. Chem. Soc. 69 (947), 7 0. [] I. Gutman and O. E. Polansky, Mathematical Concepts in Organic Chemistry, Springer, Berlin, 986. [3] I. Gutman, S. Klavzar and B. Mohar, eds., Fifty years of the Wiener index, MATCH Commun. Math. Comput. Chem. 35 (997), -59. [4] I. Gutman, S. Klavzar and B. Mohar, eds., Fiftieth anniversary of the Wiener index, Discrete Appl. Math. 80 (997), -3. [5] M. B. Ahmadi and M. Seif, Digest J. Nanomaterials and Biostructures 5() (00), 335. [6] H. Wang and H. Hua, Digest J. Nanomaterials and Biostructures 5() (00), 497. [7] H. Yousefi-Azari, A. R. Ashrafi and M. H. Khalifeh, Digest J. Nanomaterials and Biostructures 3(4) (008), 35. [8] M. H. Khalifeh, H. Yousefi-Azari and A. R. Ashrafi, Digest J. Nanomaterials and Biostructures 4() (009), 63. [0] A. A. Dobrynin, R. Entringer and I. Gutman, Wiener index of trees: Theory and applications, Acta Appl. Math. 66 (00), -49. [] M. Knor, P. Potočnik and R. Škrekovski, Wiener index of iterated line graphs of trees homeomorphic to the claw K ;3, Ars Math. Contemp. 6 (03), -9. [] M. R. Farahani, Hosoya polynomial, Wiener and Hyper-Wiener indices of some regular graphs, Informatics Engineering, an International Journal () (03), 9-3. [3] M. R. Farahani and M. P. Vlad, On the Schultz, modified Schultz and Hosoya polynomials and derived indices of Capra-designed planar Benzenoids, Studia UBB Chemia 57(4) (0), 55-63. [4] M. R. Farahani, Hosoya, Schultz, modified Schultz polynomials and their topological indices of Benzene molecules: first members of polycyclic aromatic hydrocarbons (PAHs), Int. J. Theor. Chem. () (03), 9-6. [5] M. R. Farahani, On the Schultz polynomial, modified Schultz polynomial, Hosoya polynomial and Wiener index of circumcoronene series of benzenoid, J. Appl. Math. Info. 3(5-6) (03), 595-608. [6] H. Hosoya, On some counting polynomials in chemistry, Discrete Appl. Math. 9 (988), 39-57. [7] M. V. Diudea, Hosoya polynomial in tori, MATCH Commun. Math. Comput. Chem. 45 (00), 09-.

96 [8] M. Eliasi and B. Taeri, Hosoya polynomial of zigzag polyhex nanotorus, J. Serb. Chem. Soc. 73 (008), 33-39. [9] S. Xu and H. Zhang, Hosoya polynomials of armchair open ended nanotubes, Int. J. Quant. Chem. 07 (007), 586-596. [0] J. Chen, S. Xu and H. Zhang, Hosoya polynomials of TUC 4 C 8 ( R) nanotubes, Int. J. Quant. Chem. 09 (009), 64-649. [] S. Xu and H. Zhang, The Hosoya polynomial decomposition for catacondensed benzenoid graphs, Discr. Appl. Math. 56 (008), 930-938. [] H. Shabani and A. R. Ashrafi, Applications of the matrix package MATLAB in computing the Wiener polynomial of armchair polyhex nanotubes and nanotori, J. Comput. Theor. Nanosci. 7 (00), 43-46. [3] A. R. Ashrafi and H. Shabani, An algorithm for computing Hosoya polynomial of TUC 4 C 8 ( R) nanotubes, Optoelectron. Adv. Mater. Rapid Comm. 3 (009), 356-359. [4] K. Ali, E. T. Baskoro and I. Tomescu, On the Ramzey number of paths and Jahangir graph J 3, 3rd International Conference on st Century Mathematics 007, GC University, Lahore, Pakistan, March 007. [5] D. A. Mojdeh and A. N. Ghameshlou, Domination in Jahangir Graph J, Int. J. Contemp. Math. Sci. (4) (007), 93-99.

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