关于两个有向图n·_3之并的优美性

证实了 ,两个无交有向图 n.C 3之两个相邻 2度点处反方向粘合的优美性 .由于在设计优美标号时 ,缺乏规律性 .从而采用了对顶点数 n,分段设计标号的方法 .     

关于两个有向图n·(→C3)之并的优美性

证实了,两个无交有向图n·C→3之两个相邻2度点处反方向粘合的优美性.由于在设计优美标号时,缺乏规律性.从而采用了对顶点数n,分段设计标号的方法.     

加边与删边运算下图的亏格分布

设(G,u,v)是以u和u为根的双根连通图,用边e连接点u和v,所得之图记为G+E.Gross对根u和v的度均为2的情形,给出了G+e的亏格分布与(G,u,v)的部分亏格分布之间的一个关系.本文推广到有一个根的度可以任意大的情形,并由(G,u,v)的部分亏格分布导出了G+e的亏格分布.     

伴随多项式的根与色等价图的刻画

文[2]给出了不含三角形图伴随多项式根的内插性质,本文研究了含三角形图的伴随多项式根的性质,在此基础上完整地刻画了■的色等价图,且给出这类图色唯一的充要条件.Cti表示有ti个顶点的圈;Dn表示Pn-2的一个1度点粘接下来K3的一个点得到的图.     

一个不可定向曲面的极小禁用子图的构造

曲面S的一个极小禁用子图是这样的一个图,它的任何一个顶点的度都不小于3,它不能嵌入在S上,但是删去任何一条边后得到的图能嵌入在S上.本文给出了四种构造一个不可定向曲面的极小禁用子图的方式,即粘合一个顶点,一个图的边被其它的图替换,粘合两个顶点,将一个图放在另一个图的一个曲面嵌入的面内.     

紧度量空间上的连续在上映射是粘合映射

本文讨论了有关粘合映射的一个问题 ,证明了 ,如果X是紧致度量空间 ,Y是度量空间 ,则由X到Y的连续在上映射是粘合映射 .并给出了一个反例 ,说明 :如果去掉紧致性条件 ,则定理的结论不再成立 .     

两点连图的Tutte多项式及应用

设G和H为两个连通图,将G中的两个顶点与H中的两个顶点分别粘合,得到的酲就是G与H的二点连图G:H.本文主要研究了两点连图的Tutte多项式,给出了T(G:H;x,y)的一个分拆方程.并利用得到的结果,研究了两类复杂网络模型的生成树数目和广义书图的Tutt多项式,均计算出了具体的表达式.最后,我们还考虑了正多边形链,得到了其Tutte多项式的一个递归表达式.     

判别式的几何应用

在一元二次方程ax2+bx+c=0(a≠0)中,称式子b2-4ac为一元二次方程根的判别式.利用一元二次方程根的判别式,不仅能判定几何图形中符合某条件的"点"的个数,而且还能求与图形有关的代数式的最值.现举例说明:     

一个平面几何问题的探究

<正>2020年4月22日,黄利兵老师在微信群"我们爱几何"贴出一个问题:题1如图1,已知△ABC,M为BC的中点,⊙L过点B、M且与AB相切,过L作LN丄AC,N为垂足,证明:∠BMA=∠CNM.分析1点N是题目中的特殊点,注意到∠BMA=∠CNM与△AMN∽△ACM、AM²=AN·AC可互相推出,先从根轴的角度处理点N.     

关于双奇异平面地图的计数

本文讨论了带根双奇异平面地图的计数问题,提供了以根面次、度和内面数为参数及以根面次、奇异边数和自环数为参数的计数函数所满足的计数方程,并且导出了所有的计数显式.     

Dirichlet–Neumann inverse spectral problem for a star graph of Stieltjes strings

We solve two inverse spectral problems for star graphs of Stieltjes strings with Dirichlet and Neumann boundary conditions, respectively, at a selected vertex called root. The root is either the central vertex or, in the more challenging problem, a pendant vertex of the star graph. At all other pendant vertices Dirichlet conditions are imposed; at the central vertex, at which a mass may be placed, continuity and Kirchhoff conditions are assumed. We derive conditions on two sets of real numbers to be the spectra of the above Dirichlet and Neumann problems. Our solution for the inverse problems is constructive: we establish algorithms to recover the mass distribution on the star graph (i.e. the point masses and lengths of subintervals between them) from these two spectra and from the lengths of the separate strings. If the root is a pendant vertex, the two spectra uniquely determine the parameters on the main string (i.e. the string incident to the root) if the length of the main string is known. The mass distribution on the other edges need not be unique; the reason for this is the non-uniqueness caused by the non-strict interlacing of the given data in the case when the root is the central vertex. Finally, we relate of our results to tree-patterned matrix inverse problems.     

Connections between generalized graph entropies and graph energy

Dehmer and Mowshowitz introduced a class of generalized graph entropies using known information‐theoretic measures. These measures rely on assigning a probability distribution to a graph. In this article, we prove some extremal properties of such generalized graph entropies by using the graph energy and the spectral moments. Moreover, we study the relationships between the generalized graph entropies and compute the values of the generalized graph entropies for special graph classes. © 2014 Wiley Periodicals, Inc. Complexity 21: 35–41, 2015     

A new closure concept preserving graph Hamiltonicity and based on neighborhood equivalence

A graph is Hamiltonian if it contains a cycle which goes through all vertices exactly once. Determining if a graph is Hamiltonian is known as an NP-complete problem, and no satisfactory characterization for these graphs has been found.In 1976, Bondy and Chvàtal introduced a way to get round the Hamiltonicity problem complexity by using a closure of the graph. This closure is a supergraph of G which is Hamiltonian iff G is. In particular, if the closure is the complete graph, then G is Hamiltonian. Since this seminal work, several closure concepts preserving Hamiltonicity have been introduced. In particular, in 1997, Ryjá?ek defined a closure concept for claw-free graphs based on local completion.Following a different approach, in 1974, Goodman and Hedetniemi gave a sufficient condition for Hamiltonicity based on the existence of a clique covering of the graph. This condition was recently generalized using the notion of Eulerian clique covering. In this context, closure concepts based on local completion are interesting since the closure of a graph contains more simplicial vertices than the graph itself, making the search for a clique covering easier.In this article, we introduce a new closure concept based on local completion which preserves the Hamiltonicity for every graph. Note that, moreover, the closure may be claw free even when the graph is not.     

Multicyclic treelike reflexive graphs

A simple graph is reflexive if its second largest eigenvalue does not exceed 2. A graph is treelike (sometimes also called a cactus) if all its cycles (circuits) are mutually edge-disjoint. In a lot of cases one can establish whether a given graph is reflexive by identifying and removing a single cut-vertex (Theorem 1). In this paper we prove that, if this theorem cannot be applied to a connected treelike reflexive graph G and if all its cycles do not have a common vertex (do not form a bundle), such a graph has at most five cycles (Theorem 2). On the same conditions, in Theorem 3 we find all maximal treelike reflexive graphs with four and five cycles.     

Extensions of barrier sets to nonzero roots of the matching polynomial

In matching theory, barrier sets (also known as Tutte sets) have been studied extensively due to their connection to maximum matchings in a graph. For a root θ of the matching polynomial, we define θ-barrier and θ-extreme sets. We prove a generalized Berge-Tutte formula and give a characterization for the set of all θ-special vertices in a graph.     

List Ramsey numbers

We introduce a list‐coloring extension of classical Ramsey numbers. We investigate when the two Ramsey numbers are equal, and in general, how far apart they can be from each other. We find graph sequences where the two are equal and where they are far apart. For $?$‐uniform cliques we prove that the list Ramsey number is bounded by an exponential function, while it is well known that the Ramsey number is superexponential for uniformity at least 3. This is in great contrast to the graph case where we cannot even decide the question of equality for cliques.     

Vertex disjoint equivalent subgraphs of order 3

Let k be a fixed integer at least 3. It is proved that every graph of order (2k ? 1 ? 1/k)n + O(1) contains n vertex disjoint induced subgraphs of order k such that these subgraphs are equivalent to each other and they are equivalent to one of four graphs: a clique, an independent set, a star, or the complement of a star. In particular, by substituting 3 for k, it is proved that every graph of order 14n/3 + O(1) contains n vertex disjoint induced subgraphs of order 3 such that they are equivalent to each other. © 2007 Wiley Periodicals, Inc. J Graph Theory 56: 159–166, 2007     

Ehrhart Series for Connected Simple Graphs

The Ehrhart ring of the edge polytope ${\mathcal{P}_G}$ for a connected simple graph G is known to coincide with the edge ring of the same graph if G satisfies the odd cycle condition. This paper gives for a graph which does not satisfy the condition, a generating set of the defining ideal of the Ehrhart ring of the edge polytope, described by combinatorial information of the graph. From this result, two factoring properties of the Ehrhart series are obtained; the first one factors out bipartite biconnected components, and the second one factors out a even cycle which shares only one edge with other part of the graph. As an application of the factoring properties, the root distribution of Ehrhart polynomials for bipartite polygon trees is determined.     

Some remarks about leaf roots

Nishimura et al. [On graph powers for leaf-labeled trees, J. Algorithms 42 (2002) 69-108] define a k-leaf root of a graph G=(V_G,E_G) as a tree T=(V_T,E_T) such that the vertices of G are exactly the leaves of T and two vertices in V_G are adjacent in G if and only if their distance in T is at most k. Solving a problem posed by Niedermeier [Personal communication, May 2004] we give a structural characterization of the graphs that have a 4-leaf root. Furthermore, we show that the graphs that have a 3-leaf root are essentially the trees, which simplifies a characterization due to Dom et al. [Error compensation in leaf power problems, Algorithmica 44 (2006) 363-381. (A preliminary version appeared under the title “Error compensation in leaf root problems”, in: Proceedings of the 15th Annual International Symposium on Algorithms and Computation (ISAAC 2004), Lecture Notes in Computer Science, vol. 3341, pp. 389-401)] and also a related recognition algorithm due to Nishimura et al. [On graph powers for leaf-labeled trees, J. Algorithms 42 (2002) 69-108].     

A Contribution to a Conjecture of A. Saito

 A. Saito conjectured that every finite 3-connected line graph of diameter at most 3 is hamiltonian unless it is the line graph of a graph obtained from the Petersen graph by adding at least one pendant edge to each of its vertices. Here we shall see that a line graph of connectivity 3 and diameter at most 3 has a hamiltonian path. Received: May 31, 2000 Final version received: August 17, 2001 RID="*" ID="*" This work has partially been supported by DIMATIA, Grant 201/99/0242, Grant Agency of the Czech Republic AMS subject classification: 05C45, 05C40