On the differences between Szeged and Wiener indices of graphs

Let G be a connected graph and η(G)=Sz(G)−W(G), where W(G) and Sz(G) are the Wiener and Szeged indices of G, respectively. A well-known result of Klav?ar, Rajapakse, and Gutman states that η(G)≥0, and by a result of Dobrynin and Gutman η(G)=0 if and only if each block of G is complete. In this paper, a path-edge matrix for the graph G is presented by which it is possible to classify the graphs in which η(G)=2. It is also proved that there is no graph G with the property that η(G)=1 or η(G)=3. Finally, it is proved that, for a given positive integer k,k≠1,3, there exists a graph G with η(G)=k.     

Calculating the edge Wiener and edge Szeged indices of graphs

The edge Szeged and edge Wiener indices of graphs are new topological indices presented very recently. It is not difficult to apply a modification of the well-known cut method to compute the edge Szeged and edge Wiener indices of hexagonal systems. The aim of this paper is to propose a method for computing these indices for general graphs under some additional assumptions.     

Four new sums of graphs and their Wiener indices

The Wiener index is the sum of distances between all vertex pairs in a connected graph. This notion was motivated by various mathematical properties and chemical applications. In this paper we introduce four new operations on graphs and study the Wiener indices of the resulting graphs.     

单圈图的hyper-Wiener指标

令u（n）表示具有n个顶点的单圈图.在一个圈C3的一个顶点上悬挂n-3个悬挂边的n个顶点的单圈图记为U~＊（n-3,0,0）.本文证明了在u（n）中具有最小hyper-Wiener指数的单圈图是U~＊（n-3,0,0）.     

On well-dominated direct,Cartesian and strong product graphs

If each minimal dominating set in a graph is a minimum dominating set, then the graph is called well-dominated. Since the seminal paper on well-dominated graphs appeared in 1988, the structure of well-dominated graphs from several restricted classes has been studied. In this paper we give a complete characterization of nontrivial direct products that are well-dominated. We prove that if a strong product is well-dominated, then both of its factors are well-dominated. When one of the factors of a strong product is a complete graph, the other factor being well-dominated is also a sufficient condition for the product to be well-dominated. Our main result gives a complete characterization of well-dominated Cartesian products in which at least one of the factors is a complete graph. In addition, we conjecture that this result is actually a complete characterization of the class of nontrivial, well-dominated Cartesian products.     

Connectivity of Cartesian product graphs

Use v_i,κ_i,λ_i,δ_i to denote order, connectivity, edge-connectivity and minimum degree of a graph G_i for i=1,2, respectively. For the connectivity and the edge-connectivity of the Cartesian product graph, up to now, the best results are κ(G₁×G₂)?κ₁+κ₂ and λ(G₁×G₂)?λ₁+λ₂. This paper improves these results by proving that κ(G₁×G₂)?min{κ₁+δ₂,κ₂+δ₁} and λ(G₁×G₂)=min{δ₁+δ₂,λ₁v₂,λ₂v₁} if G₁ and G₂ are connected undirected graphs; κ(G₁×G₂)?min{κ₁+δ₂,κ₂+δ₁,2κ₁+κ₂,2κ₂+κ₁} if G₁ and G₂ are strongly connected digraphs. These results are also generalized to the Cartesian products of connected graphs and n strongly connected digraphs, respectively.     

Proof of a conjecture on connectivity of Kronecker product of graphs

For a graph G, κ(G) denotes its connectivity. The Kronecker product G₁×G₂ of graphs G₁ and G₂ is the graph with the vertex set V(G₁)×V(G₂), two vertices (u₁,v₁) and (u₂,v₂) being adjacent in G₁×G₂ if and only if u₁u₂∈E(G₁) and v₁v₂∈E(G₂). Guji and Vumar [R. Guji, E. Vumar, A note on the connectivity of Kronecker products of graphs, Appl. Math. Lett. 22 (2009) 1360–1363] conjectured that for any nontrivial graph G, κ(G×K_n)=min{nκ(G),(n−1)δ(G)} when n≥3. In this note, we confirm this conjecture to be true.     

几类积图的团染色数

设G=（VE）为简单图,V和E分别表示图的点集和边集．图G的一个k-团染色是指点集V到色集{1,2,…,k）的一个映射,使得G的每个至少含两个点的极大团都至少有两种颜色．分别给出了任意两个图的团色数与它们通过笛卡尔积、Kronecker积、强直积或字典积运算后得到的积图的团色数之间的关系．     

On optimizing edge connectivity of product graphs

This work studies the super edge connectivity and super restricted edge connectivity of direct product graphs, Cartesian product graphs, strong product graphs and lexicographic product graphs. As a result, sufficient conditions for optimizing the edge connectivity and restricted edge connectivity of these graphs are presented.     

Circular chromatic index of Cartesian products of graphs

The circular chromatic index of a graph G, written , is the minimum r permitting a function such that whenever e and are incident. Let □ , where □ denotes Cartesian product and H is an ‐regular graph of odd order, with (thus, G is s‐regular). We prove that , where is the minimum, over all bases of the cycle space of H, of the maximum length of a cycle in the basis. When and m is large, the lower bound is sharp. In particular, if , then □ , independent of m. © 2007 Wiley Periodicals, Inc. J Graph Theory 57: 7–18, 2008     

Cartesian products of directed graphs with loops

We show that every nontrivial finite or infinite connected directed graph with loops and at least one vertex without a loop is uniquely representable as a Cartesian or weak Cartesian product of prime graphs. For finite graphs the factorization can be computed in linear time and space.     

Zagreb indices of graphs

The first Zagreb index M₁(G) is equal to the sum of squares of the degrees of the vertices, and the second Zagreb index M₂(G) is equal to the sum of the products of the degrees of pairs of adjacent vertices of the underlying molecular graph G. In this paper, we obtain lower and upper bounds on the first Zagreb index M₁(G) of G in terms of the number of vertices (n), number of edges (m), maximum vertex degree (Δ), and minimum vertex degree (δ). Using this result, we find lower and upper bounds on M₂(G). Also, we present lower and upper bounds on M₂(G) +M₂(G) in terms of n, m, Δ, and δ, where G denotes the complement of G. Moreover, we determine the bounds on first Zagreb coindex M₁(G) and second Zagreb coindex M₂(G). Finally, we give a relation between the first Zagreb index and the second Zagreb index of graph G.     

欧拉图的hyper-Wiener指标

ε_n表示n个顶点欧拉图的集合.通过对欧拉图hyper-Wiener指标性质的研究,刻画了ε_n中具有最小和最大hyper-Wiener指标的极图.     

Prime graphs and exponential composition of species

In this paper, we enumerate prime graphs with respect to the Cartesian multiplication of graphs. We use the unique factorization of a connected graph into the product of prime graphs given by Sabidussi to find explicit formulas for labeled and unlabeled prime graphs. In the case of species, we construct the exponential composition of species based on the arithmetic product of species of Maia and Méndez, and express the species of connected graphs as the exponential composition of the species of prime graphs.     

两种四角系统的Wiener数和Hyper-Wiener数(英文)

我们推导出两类四角系统的Wiener数和Hyper-Wiener数的计算公式.     

星形图乘积的pebbling数

图 G的 pebbling数 f(G)是最小的整数 n,使得不论 n个 pebble如何放置在 G的顶点上 ,总可以通过一系列的 pebbling移动把一个 pebble移到任意一个顶点上 ,其中的 pebbling移动是从一个顶点上移走两个 pebble而把其中的一个移到与其相邻的一个顶点上 .设 K1,n为 n+1个顶点的星形图 .本文证明了 (n+2 )(m+2 )≥ f K1,n× K1,m)≥ (n+1) (m+1) +7,n>1,m>1.     

关于笛卡尔乘积图的优美性

研究了笛卡尔乘积图Pm×Pn×P1的优美标号算法,并且给出了他们都是优美图的证明,同时推广了笛卡尔乘积图Pm×Pn是优美图的结论.     

Hamiltonicity and pancyclicity of cartesian products of graphs

The cartesian product of a graph G with K₂ is called a prism over G. We extend known conditions for hamiltonicity and pancyclicity of the prism over a graph G to the cartesian product of G with paths, cycles, cliques and general graphs. In particular we give results involving cubic graphs and almost claw-free graphs.We also prove the following: Let G and H be two connected graphs. Let both G and H have a 2-factor. If Δ(G)≤g^′(H) and Δ(H)≤g^′(G) (we denote by g^′(F) the length of a shortest cycle in a 2-factor of a graph F taken over all 2-factorization of F), then G□H is hamiltonian.