梯子细分图Ln＊的排斥（下整）和数

（下整）和标号与排斥（下整）和标号是图的一种压缩表示．一个图G称为下整和图,若它同构于某个S Q＋的下整和图．图Pn×K2称为梯子．本文给出了梯子细分图Ln＊的定义,并确定了梯子细分图Ln＊的排斥（下整）和数．     

梯子图P_n□P_2的整和数

Nicholas等人证明梯子图L_n(=P_n□P_2,n≥2)的和数与整和数都是3,并且L_n都是排斥图.结果证明了这个结论是错误的.我们证明了n≥3时,L_n的整和数是0,这就说明n≥3时,所有的L_n的和数与整和数并不相等.还证明当n=3,4,5时,Ln的和数是2,从而它们也不是排斥图.     

一类整和图

证明了双星S(m，n)是一个整和图，进而阐明在同构的意义下双星的整和标号是唯一的．     

Q整图新类

对于一个简单图G, 方阵Q(G)=D(G)+A(G)称为G的无符号拉普拉斯矩阵,其中D(G)和A(G)分别为G的度对角矩阵和邻接矩阵. 一个图是Q整图是指该图的无符号拉普拉斯矩阵的特征值全部为整数.首先通过Stanic 得到的六个顶点数目较小的Q整图,构造出了六类具有无穷多个的非正则的Q整图. 进而,通过图的笛卡尔积运算得到了很多的Q整图类. 最后, 得到了一些正则的Q整图.     

(a,b,n)-临界图的几个充分条件

设G是一个图 .设g和f是两个定义在V(G)上的整值函数使得对V(G)所有顶点x有g(x) ≤f(x) .图G被称为 (g ,f,n) 临界图 ,如果删去G的任意n个顶点后的子图都含有G的 (g ,f) 因子 .本文给出了图是 (a ,b ,n) 临界图几个充分条件 ,即度和邻域条件 .进一步指出这些条件是最佳的 .     

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.     

关于图的L(3,2,1)-标号问题

图 G的 L (2 ,1) -标号是一个从顶点集 V(G)到非负整数集的函数 f (x) ,使得若 d(x,y) =1,则 | f (x)- f (y) |≥ 2 :若 d(x ,y) =2 ,则 | f (x) - f (y) |≥ 1.图 G的 L (2 ,1) -标号数λ(G)是使得 G有 max{ f (v) :v∈ V(G) } =k的 L(2 ,1) -标号中的最小数 k.本文将 L(2 ,1) -标号问题推广到更一般的情形即 L(3,2 ,1) -标号问题 ,并得出了细分图、Descartes图的 λ3 (G)的上界 .     

几类特殊图的(2,1)-全标号

研究了与频道分配有关的一种染色-(p,1)-全标号.通过在一个顶点粘结不同的简单图构造了几类有趣图,根据所构造图的特征,利用穷染法,给出了一种标号方法,得到了平凡和非平凡叶子图Gm,4、风车图K3t和图Dm,n的(2,1)-全标号数.(p,1)-全标号是对图的全染色的一种推广.     

不含5-圈和6-圈的平面图的(2,1)-全标号

图G的(2,1)-全标号是对图G的顶点和边的一个标号分配,使得:(1)任意两个相邻顶点标号不同;(2)任意两条相邻边标号不同;(3)任意顶点与其相关联的边标号至少相差2.两个标号的最大差值称为跨度,图G的所有(2,1)-全标号的最小跨度称为(2,1)-全标号数,记为λ_2~T(G).本文证明了如果G是一个?=p+5的平面图,且G不包含5-圈和6-圈,那么λ_2~T(G)=2?-p,p=1,2,3.     

n-double图的连通性

设Gl=(V1,E1),G2=(V2,E2)是两个连通图,直积(direct product)(也称为Kronecker product,tensor product和cross product) G1(×)G2的点集为V(G1(×)G2)=V(G1)(×)V(G2),边集为E(G1(×)G2)={(u1,v1)(u2,v2)∶ulu2∈E(G1),vlv2∈E(G2)}.简单图G的n-double图Dn[G]=G(×)Tn,其中n个点的全关系图Tn是完全图Kn在每个点加上一个自环得到的图.在本文中,我们研究了Dn[G]的(边)连通性,超(边)连通性.     

和图、整和图及模和图的几个结果

Let N denote the set of positive integers.The sum graph G (S) of a finite subset S (C) N is the graph (S,E) with uv ∈ E if and only if u v ∈ S.A graph G is said to be a sum graph if it is isomorphic to the sum graph of some S С N.By using the set Z of all integers instead of N,we obtain the definition of the integral sum graph.A graph G=(V,E) is a mod sum graph if there exists a positive integer z and a labelling,λ,of the vertices of G with distinct elements from {0,1,2,...,z-1} so that uv ∈ E if and only if the sum,modulo z,of the labels assigned to u and v is the label of a vertex of G.In this paper,we prove that flower tree is integral sum graph.We prove that Dutch m-wind-mill (Dm) is integral sum graph and mod sum graph,and give the sum number of Dm.     

和图、整和图与模和图的几个结果

Let N denote the set of positive integers. The sum graph G^＋（S） of a finite subset S belong to N is the graph （S, E） with uv ∈ E if and only if u ＋ v ∈ S. A graph G is said to be a sum graph if it is isomorphic to the sum graph of some S belong to N. By using the set Z of all integers instead of N, we obtain the definition of the integral sum graph. A graph G = （V, E） is a mod sum graph if there exists a positive integer z and a labelling, λ, of the vertices of G with distinct elements from {0, 1, 2,..., z - 1} so that uv ∈ E if and only if the sum, modulo z, of the labels assigned to u and v is the label of a vertex of G. In this paper, we prove that flower tree is integral sum graph. We prove that Dutch m-wind-mill （Dm） is integral sum graph and mod sum graph, and give the sum number of Dm.     

On integral sum graphs

A graph G is said to be an integral sum graph if its nodes can be given a labeling f with distinct integers, so that for any two distinct nodes u and v of G, uv is an edge of G if and only if f(u)+f(v)=f(w) for some node w in G. A node of G is called a saturated node if it is adjacent to every other node of G. We show that any integral sum graph which is not K₃ has at most two saturated nodes. We determine the structure for all integral sum graphs with exactly two saturated nodes, and give an upper bound for the number of edges of a connected integral sum graph with no saturated nodes. We introduce a method of identification on constructing new connected integral sum graphs from given integral sum graphs with a saturated node. Moreover, we show that every graph is an induced subgraph of a connected integral sum graph. Miscellaneous related results are also presented.     

图G_n的优美表示

将给出三个结果:(i)如果图G是SZ(|S|=n≥2)上的整数和图,那么0∈S当且仅当图G至少有一个(n-1)度顶点;(ii)图G(G≠K2)是至少有两个零点的整数和图当且仅当G■K2·Gn;(iii)设图G(G≠K2)是SZ上的整数和图,|S|=n+2,n∈N+.若图G至少有两个零点,则S={mx|m=-1,0,1,2,…,n;x∈Z且x≠0}.     

Some results on integral sum graphs

Let Z denote the set of all integers. The integral sum graph of a finite subset S of Z is the graph (S,E) with vertex set S and edge set E such that for u,vS, uvE if and only if u+vS. A graph G is called an integral sum graph if it is isomorphic to the integral sum graph of some finite subset S of Z. The integral sum number of a given graph G, denoted by ζ(G), is the smallest number of isolated vertices which when added to G result in an integral sum graph. Let x denote the least integer not less than the real x. In this paper, we (i) determine the value of ζ(K_n−E(K_r)) for r2n/3−1, (ii) obtain a lower bound for ζ(K_n−E(K_r)) when 2r<2n/3−1 and n5, showing by construction that the bound is sharp when r=2, and (iii) determine the value of ζ(K_r,r) for r2. These results provide partial solutions to two problems posed by Harary (Discrete Math. 124 (1994) 101–108). Finally, we furnish a counterexample to a result on the sum number of K_r,s given by Hartsfiedl and Smyth (Graphs and Matrices, R. Rees (Ed.), Marcel, Dekker, New York, 1992, pp. 205–211).     

图Gn的优美表示

将给出三个结果：（i）如果图G是SZ（｜S｜=n≥2）上的整数和图,那么0∈S当且仅当图G至少有一个（n-1）度顶点;（ii）图G（G≠K2）是至少有两个零点的整数和图当且仅当G■K2·Gn;（iii）设图G（G≠K2）是SZ上的整数和图,｜S｜=n＋2,n∈N＋.若图G至少有两个零点,则S={mx｜m=-1,0,1,2,…,n;x∈Z且x≠0}.     

Subdivided trees are integral sum graphs

A graph G=(V,E) is an integral sum graph (ISG) if there exists a labeling S(G)⊂Z such that V=S(G) and for every pair of distinct vertices u,v∈V, uv is an edge if and only if u+v∈V. A vertex in a graph is called a fork if its degree is not 2. In 1998, Chen proved that every tree whose forks are at distance at least 4 from each other is an ISG. In 2004, He et al. reduced the distance to 3. In this paper we reduce the distance further to 2, i.e. we prove that every tree whose forks are at least distance 2 apart is an ISG.     

图的循环带宽和

Abstract. Let G be a simple graph. The cyclic bandwidth sum problem is to determine a labeling of graph G in a cycle such that the total length of edges is as small as possible. In this paper, some upper and lower bounds on cyclic bandwidth sum of graphs are studied.