联图Fn∨Pm的邻点可区别全染色

设G(V,E)是阶数至少为2的简单连通图,k是正整数,V∪E到{1,2,3,…k}的映射f满足:对任意uv,uw∈E(G),u≠w,有f(uv)≠f(vw);对任意uv∈E(G),有f(u)≠f(v), f(u)≠f(uv),f(v)≠f(uv);那么称f为G的k-正常全染色,若f还满足对任意uv∈E(G),有G(u)≠C(v),其中C(u)={f(u)}∪{f(uv)|uv∈E(G),v∈V(G)}那么称f为G的k-邻点可区别的全染色(简记为k-AVDTC),称min{k|G有k-邻点可区别的全染色}为G的邻点可区别的全色数,记作Xat(G)．本文得到了联图Fn∨Pm的全色数．     

若干Mycielski图的邻点可区别E-全染色

设G(V,E)是简单连通图,k是正整数,若V∪到{1,2,3,…,k}的映射f满足对任意uv∈E(G),有f(U)≠f(v),f(u)≠f(uv)f(v)≠f(uv),且C(u)≠C(v),其中C(u):{f(u)}∪{f(uv)|uv∈E(G)}.那么称f为G的k-邻点可区别的E-全染色(简记为k-AVDETC),并称X_(at)~e(G)=min{k|G有k-邻点可区别的E-全染色}为G的邻点可区别的E-全色数.本文讨论了路、圈、扇、星、轮及完全图的Mycielski图的邻点可区别E-全染色,得到了该类图的邻点可区别的E-全色数.     

若干联图的邻点可区别-点边全染色

设G(V,E)是简单图,k是正整数.从V(G)∪E(G)到{1,2,…,k}的映射f被称作G的邻点可区别-点边全染色,当且仅当:■uv∈E(G),f(u)≠f(uv),f(v)≠f(uv),■uv∈E(G),C(u)≠C(v),且称最小的数k为G的邻点可区别-点边全色数.其中C(u)={f(u)}∪{f(uv)|uv∈E(G)},研究了一些联图的邻点可区别-点边全染色法,得到了它们的色数.     

图K_(2n)\E(F_4)(n≥12)的点可区别边染色

对简单图G(V,E),设f是从E(G)到{1,2,…,k}的映射,k为自然数,如果.f满足:1)对任意的uv,uw∈E(G),v≠w,有.f(uv)≠f(uw);2)对任意的u,v∈V(G),u≠v,有C(u)≠C(v).则称f为图G的k-点可区别边染色法,而最小的k被称为点可区别边色数(其中C(u)={f(uv)|uv∈E(G)}.研究了图K_(2n)\E(F_4)(n≥12)的点可区别边色数.     

轮与路的多重联图的邻点可区别E-全染色

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(V)u,v∈V(G),则f(u)≠f(v),f(u)≠f(uv),f(v)≠f(uv),C(u)≠C(v),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E-全色数.给出了轮与路间的多重联图的邻点可区别E-全色数,其中C(u)={f(u)}∪ {f(uv)|uv∈E(G)}.     

S_n+W_n的邻点强可区别全色数

设G(V,E)是阶数不小于3的简单连通图,k是自然数,f是从V(G)∪E(G)到1,2,…,k的映射,满足:对任意的uv∈E(G),f(u)≠f(v),f(u)≠f(uv)≠f(v);对任意的uv,uw∈E(G)(v≠w),f(uv)≠f(uw);对任意的uv∈E(G),C(u)≠C(v),其中C(u)={f(u)}∪{f(v)uv∈E(G)}∪{f(uv)uv∈E(G)},则称f是图G的一个邻点强可区别的全染色法,简记作k-AVSDTC,且称χast(G)=min{k G的所有k-AVSDTC}为G的邻点强可区别的全色数.得到了星与轮联图的邻点强可区别的全色数.     

图的邻点全和可区别全染色

设f:V(G)∪E(G)→{1,2,…,k}是图G的一个正常k-全染色。令■其中N(x)={y∈V(G)|xy∈E(G)}。对任意的边uv∈E(C),若有Φ(u)≠Φ(v)成立,则称f是图G的一个邻点全和可区别k-全染色。图G的邻点全和可区别全染色中最小的颜色数k叫做G的邻点全和可区别全色数,记为f tndi∑(G)。本文确定了路、圈、星、轮、完全二部图、完全图以及树的邻点全和可区别全色数,同时猜想:简单图G(≠K2)的邻点全和可区别全色数不超过△(G)+2。     

轮与星的多重联图的邻点可区别E-全染色

G(V,E)是一个简单图,k是一个正整数,f是一个V(G)UE(G)到{1,2,…,k}的映射.如果■u,v∈V(G),则f(u)≠f(v),f(u)≠f(uv),f(v)≠f(uv),C(u)≠C(v),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E-全色数.给出了轮与星的多重联图的邻点可区别E-全色数.     

一类3-正则图的邻强边染色

对简单图G(V,E),f是从V(G)∪E(G)到{1,2,…,k}的映射,k是自然数,若f满足(1)uv,uw∈E(G),u≠w,f(uv)≠f(uw);(2)uv∈E(G),C(u)≠C(v).则称f是G的一个邻强边染色,最小的k称为邻强边色数,其中C(u)={f(uv)|uv∈E(G)}.给出了一类3-正则重圈图的邻强边色数.     

Pm×Kn的邻点可区别全色数

设G是简单图．设f是一个从V(G)∪E(G)到{1,2,…,k}的映射．对每个v∈V(G),令C_f(v)={f(v)}∪{f(vw)|w∈V(G),vw∈E(G)}．如果f是k-正常全染色,且对任意u,v∈V(G),uv∈E(G),有C_f(u)≠C_f(v),那么称f为图G的邻点可区别全染色(简称为k-AVDTC)．数x_(at)(G)=min{k|G有k-AVDTC}称为图G的邻点可区别全色数．本文给出路P_m和完全图K_n的Cartesion积的邻点可区别全色数．     

Edge Coloring of Split Graphs

A split graph is a graph whose vertex set admits a partition into a stable set and a clique. The chromatic indexes for some subsets of split graphs, such as split graphs with odd maximum degree and split-indifference graphs, are known. However, for the general class, the problem remains unsolved. This paper presents new results about the classification problem for split graphs as a contribution in the direction of solving the entire problem for this class.     

Acyclic List Edge Coloring of Graphs

A proper edge coloring of a graph is said to be acyclic if any cycle is colored with at least three colors. An edge-list L of a graph G is a mapping that assigns a finite set of positive integers to each edge of G. An acyclic edge coloring ? of G such that for any is called an acyclic L-edge coloring of G. A graph G is said to be acyclically k-edge choosable if it has an acyclic L‐edge coloring for any edge‐list L that satisfies for each edge e. The acyclic list chromatic index is the least integer k such that G is acyclically k‐edge choosable. We develop techniques to obtain bounds for the acyclic list chromatic indices of outerplanar graphs, subcubic graphs, and subdivisions of Halin graphs.     

Acyclic Edge Coloring of IC-planar Graphs

Acta Mathematicae Applicatae Sinica, English Series - A proper edge coloring of a graph G is acyclic if there is no 2-colored cycle in G. The acyclic chromatic index of G is the least number of...     

图的点可区别的分数边染色数

讨论了图的点可区别的边染色数在分数图论的拓展,采用分数图论中超图的a:b-染色方法,证明了邻点可区别的分数边染色数与分数边染色数的等价性,同时进一步推导出经典图论中几类点可区别的边染色数概念如κ-D(β)-点可区别的边染色数、点可区别的边染色数和边染色数也在分数图论的拓展下具有等价性.     

Star Edge Coloring of Some Classes of Graphs

A star edge coloring of a graph is a proper edge coloring without bichromatic paths and cycles of length four. In this article, we establish tight upper bounds for trees and subcubic outerplanar graphs, and derive an upper bound for outerplanar graphs.     

关于图的点可区别边染色的一个猜想

图G的一个k-正常边染色f被称为点可区别的是指任意两个不同点的点及其关联边所染色集合不同,所用最少染色数被称为G的点可区别边色数,张忠辅教授提出一猜想即对每一个正整数k≥3,总存在一个最大度为△(G)=k≥3的图G,,满足图G一定有一个子图H,且母图的点可区别的边色数小于子图的.本文证明了对于最大度小于9时,此猜想正确.     

List Edge Coloring of Outer-1-planar Graphs

Acta Mathematicae Applicatae Sinica, English Series - A graph is outer-1-planar if it can be drawn in the plane so that all vertices are on the outer face and each edge is crossed at most once. It...     

关于图的一般邻点可区别边染色

给出了轮图W_n、扇图F_n、风车图K_2~t、图D_(m,4)、图D_(m,n)、齿轮图W_n的一般邻点可区别色指标.     

线性超图的边染色

超图$H$的一个$k$-边染色是用$k$种颜色的边染色, 使得相交的边染不同的颜色. Erd\H{o}s-Faber-Lov\''asz猜想认为任一$n$个顶点的无环线性超图都有一个$n$-边染色. 2021年, Kang, Kelly, K\"uhn, Methuku和Osthus对充分大的$n$确认了该猜想成立. 在本文中, 我们证明该猜想对弱冲突的超图是成立的. 这严格拓展了Bretto, Faisant 和Hennecart在2020年的两个相关结果.     

Edge Coloring of Embedded Graphs with Large Girth

Let G be a simple graph embedded in the surface of Euler characteristic ()0. Denote _e(G), and g the edge chromatic number, the maximum degree and the girth of the graph G, respectively. The paper shows that _e(G)= if 5 and g4, or 4 and g5, or 3 and g9. In addition, if ()>0, then _e(G)= if 3 and g8. Acknowledgments.The authors would like to thank Dr. C.Q. Zhang for carefully reading several versions of this paper during its preparation and for suggesting several stylistic changes that have improved the overall presentation.