一个关于余直径的度条件

本文研究关于余直径的度条件,主要结果是,若G是3-连通图,其顶点集为V(G)={v1,v2,…,vn),其度序列为: d(v1)≤d(v2)≤…≤d(vn)则对G的任意一条边e都存在特征点对va,vb,使G中过e的最长圈至少为d(va)+d(vb)-1.在相同的条件下我们有d*(G)≥ m-2,     

导出子图和周长的局部定理

设G是n阶2-连通图，3≤c≤n.本文绘出对于图G的每一个同构于K1.3或Z1的导出子图L，若d（u）且如果dL（u，v）=2有（v）=min{，|M3（u）|/2}这里M3（u）={v|dc（u,v）≤3}，则G包含长至少为c的圈．     

两类图的L(2.1)-标号数

图G的一个L(2.1)-标号是从顶点集V(G)到非负整数的一个函数f,使得若d(u,v)=1时,有|f(u)-f(v)|≥2;若d(u,v)=2时,有|f(u)-f(v)|≥1.图G的L(2.1)-标号数λ(G)是G的所有L(2.1)-标号下的跨度max{f(v):v∈V(G)}的最小数.图Fn+1*为扇图的路上每个顶点增加一个悬挂边得到的图.图Hn为轮图的圈上每个顶点增加一个悬挂边得到的图.本文确定了图Fn+1*与Hn的L(2.1)-标号数.     

一类三圈图的Wiener指数

图G的Wiener指数是指图G中所有顶点对间的距离之和,即W（G）=∑dc（u,u）,{u,u}CG其中de（u,u）表示G中顶点u,u之间的距离.三圈图是指边数与顶点数之差等于2的连通图,任意两个圈至多只有一个公共点的三圈图记为T_n~3.研究了三圈图T_n~3的Wiener指数,给出了其具有最小、次小Wiener指数的图结构.     

Ore度和条件下赋权triangle-free图中的重圈(英文)

设G是一个2-连通赋权图,且G中每一对不相邻顶点u和v都满足d~w(u)+d~w(v)≥2d.Bondy等人证明了G或者包含一个哈密尔顿圈,或者包含一个权至少为2d的圈.如果G不是哈密尔顿图,这个结论意味着G中包含一个权至少为2d的圈.但是当G是哈密尔顿图时,我们不能判断G是否包含一个权至少为2d的圈.这篇文章中,在Fujisawa的一篇文章的启发下,我们证明了当G是triangle-free图并且|V(G)|是奇数时,G中一定包含一个权至少为2d的圈,即使G是哈密尔顿图.     

Two-tree的调和指标

图G的调和指标是指图G中所有边uv所对应的2/d(u)+d(v)权和,其中d(u),d(v)分别表示顶点u,v的度数.本文的主要目标是计算出所有的n个顶点的two-tree图中的最小与第二小的调和指标.     

长圈的邻域交条件的推广

证明了若G为一个k(k≥2)连通简单图,独立数为α,V(G)=n≥3,X1,X2,…,Xk是顶点集合V的子集,X=X1∪X2∪…∪Xk,且对于Xi(i=1,2,…,k)中任意两个不相邻点u,v,|N(u)∩N(v)|≥α,则X在G中可圈,并给出几个相关推论.     

关于蕴含Ar,s—可图序列的注记

设G＝（V（G）,E（G）是n阶简单图,其顶点集V（G）＝{v1,…,vr,vr 1,…,vr s,…,vn},n={d1,…,dr 1,…,dr s,…,dn}是G的度序列,且vi的度为dio称G具有性质Ar,s,如果{v1,…,vr,vr 1,…,vr x}的导出子图是完全二部图Kr,s,且{v1,…,vr}和{vr 1,…,vr s}是Kr,s顶点集的二部划分,序列π={d1,…,dr,dr 1,…,dr s,…,dn}称为是蕴含Ar,s－可图的序列判别准则。     

无爪图泛圈性的邻域并条件

证明了,若G是一个p-阶3-连通无爪图,p≠10,11,15,并对G中任意两个不相邻的点u和v,满足|N(u)∪N(v)|≥(p-1)/2,则G是泛圈图.     

一类多重联图的邻点可区别E-全染色

设G（V,E）是一个简单图,k是一个正整数,f是一个V（G）∪E（G）到{1,2,…,k]．的映射．如果Au,v∈E（G）,则f（u）≠f（v）,f（u）≠f（uv）,f（v）≠f（uv）,C（u）≠C（v）,其中C（u）={f（u））U{f（uv）｜uv∈E（G））．称f是图G的邻点可区别E-全染色,称最小的数k为图G的邻点可区别B全色数．本文给出了星、路、圈间的多重联图的邻点可区别E-全色数．     

Forbidden induced subgraph characterizations of subclasses and variations of perfect graphs: A survey

A graph is perfect if the chromatic number is equal to the clique number for every induced subgraph of the graph. Perfect graphs were defined by Berge in the sixties. In this survey we present known results about partial characterizations by forbidden induced subgraphs of different graph classes related to perfect graphs. We analyze a variation of perfect graphs, clique-perfect graphs, and two subclasses of perfect graphs, coordinated graphs and balanced graphs.     

On the Zagreb indices of the line graphs of the subdivision graphs

The aim of this paper is to investigate the Zagreb indices of the line graphs of the tadpole graphs, wheel graphs and ladder graphs using the subdivision concepts.     

Partial characterizations of clique-perfect graphs I: Subclasses of claw-free graphs

A clique-transversal of a graph G is a subset of vertices that meets all the cliques of G. A clique-independent set is a collection of pairwise vertex-disjoint cliques. The clique-transversal number and clique-independence number of G are the sizes of a minimum clique-transversal and a maximum clique-independent set of G, respectively. A graph G is clique-perfect if these two numbers are equal for every induced subgraph of G. The list of minimal forbidden induced subgraphs for the class of clique-perfect graphs is not known. In this paper, we present a partial result in this direction; that is, we characterize clique-perfect graphs by a restricted list of forbidden induced subgraphs when the graph belongs to two different subclasses of claw-free graphs.     

On minimal forbidden subgraph characterizations of balanced graphs

A graph is balanced if its clique-matrix contains no edge–vertex incidence matrix of an odd chordless cycle as a submatrix. While a forbidden induced subgraph characterization of balanced graphs is known, there is no such characterization by minimal forbidden induced subgraphs. In this work, we provide minimal forbidden induced subgraph characterizations of balanced graphs restricted to graphs that belong to one of the following graph classes: complements of bipartite graphs, line graphs of multigraphs, and complements of line graphs of multigraphs. These characterizations lead to linear-time recognition algorithms for balanced graphs within the same three graph classes.     

Line-graphs of cubic graphs are normal

A graph is called normal if its vertex set can be covered by cliques Q₁,Q₂,…,Q_k and also by stable sets S₁,S₂,…,S_l, such that S_i∩Q_j≠∅ for every i,j. This notion is due to Körner, who introduced the class of normal graphs as an extension of the class of perfect graphs. Normality has also relevance in information theory. Here we prove, that the line graphs of cubic graphs are normal.     

Partial characterizations of clique-perfect graphs II: Diamond-free and Helly circular-arc graphs

A clique-transversal of a graph G is a subset of vertices that meets all the cliques of G. A clique-independent set is a collection of pairwise vertex-disjoint cliques. A graph G is clique-perfect if the sizes of a minimum clique-transversal and a maximum clique-independent set are equal for every induced subgraph of G. The list of minimal forbidden induced subgraphs for the class of clique-perfect graphs is not known. Another open question concerning clique-perfect graphs is the complexity of the recognition problem. Recently we were able to characterize clique-perfect graphs by a restricted list of forbidden induced subgraphs when the graph belongs to two different subclasses of claw-free graphs. These characterizations lead to polynomial time recognition of clique-perfect graphs in these classes of graphs. In this paper we solve the characterization problem in two new classes of graphs: diamond-free and Helly circular-arc () graphs. This last characterization leads to a polynomial time recognition algorithm for clique-perfect graphs.     

Transitive,Locally Finite Median Graphs with Finite Blocks

The subject of this paper are infinite, locally finite, vertex-transitive median graphs. It is shown that the finiteness of the Θ-classes of such graphs does not guarantee finite blocks. Blocks become finite if, in addition, no finite sequence of Θ-contractions produces new cut-vertices. It is proved that there are only finitely many vertex-transitive median graphs of given finite degree with finite blocks. An infinite family of vertex-transitive median graphs with finite intransitive blocks is also constructed and the list of vertex-transitive median graphs of degree four is presented. Sandi Klavžar: Supported by the Ministry of Science of Slovenia under the grant P1-0297. The author is also with the Faculty of Mathematics and Natural Sciences, University of Maribor, Slovenia and the Institute of Mathematics, Physics and Mechanics, Ljubljana.     

On conservative and supermagic graphs

A graph is called supermagic if it admits a labelling of the edges by pairwise different consecutive positive integers such that the sum of the labels of the edges incident with a vertex is independent of the particular vertex. A graph G is called conservative if it admits an orientation and a labelling of the edges by integers {1,…,|E(G)|} such that at each vertex the sum of the labels on the incoming edges is equal to the sum of the labels on the outgoing edges. In this paper we deal with conservative graphs and their connection with the supermagic graphs. We introduce a new method to construct supermagic graphs using conservative graphs. Inter alia we show that the union of some circulant graphs and regular complete multipartite graphs are supermagic.     

Collapsible biclaw-free graphs

A graph is called biclaw-free if it has no biclaw as an induced subgraph. In this note, we prove that if G is a connected bipartite biclaw-free graph with δ(G)?5, then G is collapsible, and of course supereulerian. This bound is best possible.