On the bounds of degree-based topological indices of the Cartesian product of F-sum of connected graphs

AbstractIn 2011, Beeler and Hoilman generalized the game of peg solitaire to arbitrary connected graphs. In the same article, the authors proved some results on the solvability of Cartesian products, given solvable or distance 2-solvable graphs. We extend these results to Cartesian products of certain unsolvable graphs. In particular, we prove that ladders and grid graphs are solvable and, further, even the Cartesian product of two stars, which in a sense are the “most” unsolvable graphs.

Download Full-text

ON MOSTAR INDEX OF GRAPHS

Advances in Mathematics: Scientific Journal ◽

10.37418/amsj.10.4.26 ◽

2021 ◽

Vol 10 (4) ◽

pp. 2115-2129

Author(s):

P. Kandan ◽

S. Subramanian

Keyword(s):

Connected Graph ◽

Cartesian Product ◽

Bipartite Graphs ◽

Topological Indices ◽

Great Success ◽

Complete Graphs ◽

Molecular Graphs ◽

Graphs And Networks ◽

Complete Bipartite Graphs ◽

Simple Connected Graph

On the great success of bond-additive topological indices like Szeged, Padmakar-Ivan, Zagreb, and irregularity measures, yet another index, the Mostar index, has been introduced recently as a peripherality measure in molecular graphs and networks. For a connected graph G, the Mostar index is defined as $$M_{o}(G)=\displaystyle{\sum\limits_{e=gh\epsilon E(G)}}C(gh),$$ where $C(gh) \,=\,\left|n_{g}(e)-n_{h}(e)\right|$ be the contribution of edge $uv$ and $n_{g}(e)$ denotes the number of vertices of $G$ lying closer to vertex $g$ than to vertex $h$ ($n_{h}(e)$ define similarly). In this paper, we prove a general form of the results obtained by $Do\check{s}li\acute{c}$ et al.\cite{18} for compute the Mostar index to the Cartesian product of two simple connected graph. Using this result, we have derived the Cartesian product of paths, cycles, complete bipartite graphs, complete graphs and to some molecular graphs.

Download Full-text

Component factors of the Cartesian product of graphs

Asian-European Journal of Mathematics ◽

10.1142/s1793557116500418 ◽

2016 ◽

Vol 09 (02) ◽

pp. 1650041

Author(s):

M. R. Chithra ◽

A. Vijayakumar

Keyword(s):

Connected Graph ◽

Maximum Degree ◽

Cartesian Product ◽

Induced Subgraph ◽

Connected Graphs ◽

Cartesian Product Of Graphs ◽

Spanning Subgraph ◽

Component Factor ◽

Product Of Graphs

Let [Formula: see text] be a family of connected graphs. A spanning subgraph [Formula: see text] of [Formula: see text] is called an [Formula: see text]-factor (component factor) of [Formula: see text] if each component of [Formula: see text] is in [Formula: see text]. In this paper, we study the component factors of the Cartesian product of graphs. Here, we take [Formula: see text] and show that every connected graph [Formula: see text] has a [Formula: see text]-factor where [Formula: see text] and [Formula: see text] is the maximum degree of an induced subgraph [Formula: see text] in [Formula: see text] or [Formula: see text]. Also, we characterize graphs [Formula: see text] having a [Formula: see text]-factor.

Download Full-text

Bandwidth of the cartesian product of two connected graphs

Discrete Mathematics ◽

10.1016/s0012-365x(01)00455-1 ◽

2002 ◽

Vol 252 (1-3) ◽

pp. 227-235 ◽

Cited By ~ 5

Author(s):

Toru Kojima ◽

Kiyoshi Ando

Keyword(s):

Cartesian Product ◽

Connected Graphs

Download Full-text

BILANGAN KROMATIK LOKASI DARI GRAF P m P n ; K m P n ; DAN K , m K n

Jurnal Matematika UNAND ◽

10.25077/jmu.2.1.14-22.2013 ◽

2013 ◽

Vol 2 (1) ◽

pp. 14

Author(s):

Mariza Wenni

Keyword(s):

Natural Number ◽

Chromatic Number ◽

Cartesian Product ◽

Complete Graphs ◽

Chromatic Numbers ◽

Color Code ◽

Connected Graphs ◽

Vertex Set ◽

Distinct Color

Let G and H be two connected graphs. Let c be a vertex k-coloring of aconnected graph G and let = fCg be a partition of V (G) into the resultingcolor classes. For each v 2 V (G), the color code of v is dened to be k-vector: c1; C2; :::; Ck(v) =(d(v; C1); d(v; C2); :::; d(v; Ck)), where d(v; Ci) = minfd(v; x) j x 2 Cg, 1 i k. Ifdistinct vertices have distinct color codes with respect to , then c is called a locatingcoloring of G. The locating chromatic number of G is the smallest natural number ksuch that there are locating coloring with k colors in G. The Cartesian product of graphG and H is a graph with vertex set V (G) V (H), where two vertices (a; b) and (a)are adjacent whenever a = a0and bb02 E(H), or aa0i2 E(G) and b = b, denotedby GH. In this paper, we will study about the locating chromatic numbers of thecartesian product of two paths, the cartesian product of paths and complete graphs, andthe cartesian product of two complete graphs.

Download Full-text

ON THE WIENER INDEX OF F_H SUMS OF GRAPHS

Journal of Computer Science and Applied Mathematics ◽

10.37418/jcsam.3.2.1 ◽

2021 ◽

Vol 3 (2) ◽

pp. 37-57

Author(s):

L. Alex ◽

Indulal G

Keyword(s):

Complete Graph ◽

Cartesian Product ◽

Chemical Properties ◽

Wiener Index ◽

Topological Indices ◽

Single Vertex ◽

Molecular Graphs ◽

New Class ◽

And Chemical Properties

Wiener index is the first among the long list of topological indices which was used to correlate structural and chemical properties of molecular graphs. In \cite{Eli} M. Eliasi, B. Taeri defined four new sums of graphs based on the subdivision of edges with regard to the cartesian product and computed their Wiener index. In this paper, we define a new class of sums called $F_H$ sums and compute the Wiener index of the resulting graph in terms of the Wiener indices of the component graphs so that the results in \cite{Eli} becomes a particular case of the Wiener index of $F_H$ sums for $H = K_1$, the complete graph on a single vertex.

Download Full-text

ON FRACTIONAL METRIC DIMENSION OF GRAPHS

Discrete Mathematics Algorithms and Applications ◽

10.1142/s1793830913500377 ◽

2013 ◽

Vol 05 (04) ◽

pp. 1350037 ◽

Cited By ~ 5

Author(s):

S. ARUMUGAM ◽

VARUGHESE MATHEW ◽

JIAN SHEN

Keyword(s):

Connected Graph ◽

Cartesian Product ◽

Metric Dimension ◽

Connected Graphs

A vertex x in a connected graph G = (V, E) is said to resolve a pair {u, v} of vertices of G if the distance from u to x is not equal to the distance from v to x. The resolving neighborhood for the pair {u, v} is defined as R{u, v} = {x ∈ V : d(u, x) ≠ d(v, x)}. A real valued function f : V → [0, 1] is a resolving function (RF) of G if f(R{u, v}) ≥ 1 for any two distinct vertices u, v ∈ V. The weight of f is defined by |f| = f(V) = ∑u∈Vf(v). The fractional metric dimension dim f(G) is defined by dim f(G) = min {|f| : f is a resolving function of G}. In this paper, we characterize graphs G for which [Formula: see text]. We also present several results on fractional metric dimension of Cartesian product of two connected graphs.

Download Full-text

On S Degrees of Vertices and S Indices of Graphs

10.20944/preprints201707.0068.v1 ◽

2017 ◽

Author(s):

Süleyman Ediz

Keyword(s):

Connected Graph ◽

Chemical Properties ◽

Topological Indices ◽

Complete Graphs ◽

Structure Property ◽

Connected Graphs ◽

Structure Activity ◽

Structure Property Relationship ◽

Simple Connected Graph ◽

And Chemical Properties

Topological indices have been used to modeling biological and chemical properties of molecules in quantitive structure property relationship studies and quantitive structure activity studies. All the degree based topological indices have been defined via classical degree concept. In this paper we define a novel degree concept for a vertex of a simple connected graph: S degree. And also we define S indices of a simple connected graph by using the S degree concept. We compute the S indices for well-known simple connected graphs such as paths, stars, complete graphs and cycles.

Download Full-text

Separation of Cartesian products of graphs into several connected components by the removal of edges

Applicable Analysis and Discrete Mathematics ◽

10.2298/aadm160719018s ◽

2021 ◽

pp. 18-18

Author(s):

Simon Spacapan

Keyword(s):

Cartesian Product ◽

Connected Components ◽

Edge Connectivity ◽

Cartesian Products ◽

Minimum Cardinality ◽

Connected Graphs ◽

Cartesian Products Of Graphs

Let G = (V (G),E(G)) be a graph. A set S ? E(G) is an edge k-cut in G if the graph G-S = (V (G), E(G) \ S) has at least k connected components. The generalized k-edge connectivity of a graph G, denoted as ?k(G), is the minimum cardinality of an edge k-cut in G. In this article we determine generalized 3-edge connectivity of Cartesian product of connected graphs G and H and describe the structure of any minimum edge 3-cut in G2H. The generalized 3-edge connectivity ?3(G2H) is given in terms of ?3(G) and ?3(H) and in terms of other invariants of factors G and H.

Download Full-text

The generalized 3-connectivity of Cartesian product graphs

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.572 ◽

2012 ◽

Vol Vol. 14 no. 1 (Graph Theory) ◽

Author(s):

Hengzhe Li ◽

Xueliang Li ◽

Yuefang Sun

Keyword(s):

Graph Theory ◽

Positive Integer ◽

Cartesian Product ◽

Vertex Connectivity ◽

Connected Graphs ◽

Generalized Connectivity ◽

Product Graphs ◽

International Audience ◽

Cartesian Product Graphs ◽

Internally Disjoint Trees

Graph Theory International audience The generalized connectivity of a graph, which was introduced by Chartrand et al. in 1984, is a generalization of the concept of vertex connectivity. Let S be a nonempty set of vertices of G, a collection \T-1, T (2), ... , T-r\ of trees in G is said to be internally disjoint trees connecting S if E(T-i) boolean AND E(T-j) - empty set and V (T-i) boolean AND V(T-j) = S for any pair of distinct integers i, j, where 1 <= i, j <= r. For an integer k with 2 <= k <= n, the k-connectivity kappa(k) (G) of G is the greatest positive integer r for which G contains at least r internally disjoint trees connecting S for any set S of k vertices of G. Obviously, kappa(2)(G) = kappa(G) is the connectivity of G. Sabidussi's Theorem showed that kappa(G square H) >= kappa(G) + kappa(H) for any two connected graphs G and H. In this paper, we prove that for any two connected graphs G and H with kappa(3) (G) >= kappa(3) (H), if kappa(G) > kappa(3) (G), then kappa(3) (G square H) >= kappa(3) (G) + kappa(3) (H); if kappa(G) = kappa(3)(G), then kappa(3)(G square H) >= kappa(3)(G) + kappa(3) (H) - 1. Our result could be seen as an extension of Sabidussi's Theorem. Moreover, all the bounds are sharp.

Download Full-text