Global ETD Search

11	On Saturation Numbers of Ramsey-minimal Graphs Davenport, Hunter M 01 January 2018 (has links) Dating back to the 1930's, Ramsey theory still intrigues many who study combinatorics. Roughly put, it makes the profound assertion that complete disorder is impossible. One view of this problem is in edge-colorings of complete graphs. For forbidden graphs H1,...,Hk and a graph G, we write G "arrows" (H1,...,Hk) if every k-edge-coloring of G contains a monochromatic copy of Hi in color i for some i=1,2,...,k. If c is a (red, blue)-edge-coloring of G, we say c is a bad coloring if G contains no red K3or blue K1,t under c. A graph G is (H1,...,Hk)-Ramsey-minimal if G arrows (H1,...,Hk) but no proper subgraph of G has this property. Given a family F of graphs, we say that a graph G is F-saturated if no member of F is a subgraph of G, but for any edge xy not in E(G), G + xy contains a member of F as a subgraph. Letting Rmin(K3, K1,t) be the family of (K3,K1,t)-Ramsey minimal graphs, we study the saturation number, denoted sat(n,Rmin(K3,K1,t)), which is the minimum number of edges among all Rmin(K3,K1,t)-saturated graphs on n vertices. We believe the methods and constructions developed in this thesis will be useful in studying the saturation numbers of (K4,K1,t)-saturated graphs. edge-coloring saturated graphs ramsey theory ramsey-minimal Discrete Mathematics and Combinatorics
12	Edge colorings of graphs and multigraphs McClain, Christopher 24 June 2008 (has links) No description available. Mathematics edge coloring multigraph Goldberg chromatic index cluster clique line graph
13	On The Coloring of Graphs Kurt, Oguz January 2009 (has links) No description available. Mathematics Graphs, Coloring Edge Coloring Edge Cover Coloring Chromatc index Cover Index
14	Colorations de graphes sous contraintes / Graph coloring under constraints Hocquard, Hervé 05 December 2011 (has links) Dans cette thèse, nous nous intéressons à différentes notions de colorations sous contraintes. Nous nous intéressons plus spécialement à la coloration acyclique, à la coloration forte d'arêtes et à la coloration d'arêtes sommets adjacents distinguants.Dans le Chapitre 2, nous avons étudié la coloration acyclique. Tout d'abord nous avons cherché à borner le nombre chromatique acyclique pour la classe des graphes de degré maximum borné. Ensuite nous nous sommes attardés sur la coloration acyclique par listes. La notion de coloration acyclique par liste des graphes planaires a été introduite par Borodin, Fon-Der Flaass, Kostochka, Raspaud et Sopena. Ils ont conjecturé que tout graphe planaire est acycliquement 5-liste coloriable. De notre côté, nous avons proposé des conditions suffisantes de 3-liste coloration acyclique des graphes planaires. Dans le Chapitre 3, nous avons étudié la coloration forte d'arêtes des graphes subcubiques en majorant l'indice chromatique fort en fonction du degré moyen maximum. Nous nous sommes également intéressés à la coloration forte d'arêtes des graphes subcubiques sans cycles de longueurs données et nous avons également obtenu une majoration optimale de l'indice chromatique fort pour la famille des graphes planaires extérieurs. Nous avons aussi présenté différents résultats de complexité pour la classe des graphes planaires subcubiques. Enfin, au Chapitre 4, nous avons abordé la coloration d'arêtes sommets adjacents distinguants en déterminant les majorations de l'indice avd-chromatique en fonction du degré moyen maximum. Notre travail s'inscrit dans la continuité de celui effectué par Wang et Wang en 2010. Plus précisément, nous nous sommes focalisés sur la famille des graphes de degré maximum au moins 5. / In this thesis, we are interested in various coloring of graphs under constraints. We study acyclic coloring, strong edge coloring and adjacent vertex-distinguishing edge coloring.In Chapter 2, we consider acyclic coloring and we bound the acyclic chromatic number by a function of the maximum degree of the graph. We also study acyclic list coloring. The notion of acyclic list coloring of planar graphs was introduced by Borodin, Fon-Der Flaass, Kostochka, Raspaud, and Sopena. They conjectured that every planar graph is acyclically 5-choosable. We obtain some sufficient conditions for planar graphs to be acyclically 3-choosable.In Chapter 3, we study strong edge coloring of graphs. We prove some upper bounds of the strong chromatic index of subcubic graphs as a function of the maximum average degree. We also obtain a tight upper bound for the minimum number of colors in a strong edge coloring of outerplanar graphs as a function of the maximum degree. We also prove that the strong edge k-colouring problem, when k=4,5,6, is NP-complete for subcubic planar bipartite graphs with some girth condition. Finally, in Chapter 4, we focus on adjacent vertex-distinguishing edge coloring, or avd-coloring, of graphs. We bound the avd-chromatic number of graphs by a function of the maximum average degree. This work completes a result of Wang and Wang in 2010. Graphe planaire Coloration acyclique Coloration forte d'arêtes Degré maximum Degré moyen maximum Cycle Planar graph Acyclic coloring Strong edge coloring Maximum degree Maximum average degree Cycle
15	Upper bounds for the star chromatic index of multipartite graphs Sparrman, Gabriel January 2022 (has links) A star edge coloring is any edge coloring which is both proper and contains no cycles or path of length four which are bicolored, and the star chromatic index of a graph is the smallest number of colors for which that graph can be star edge colored. Star edge coloring is a relatively new field in graph theory, and very little is known regarding upper bounds of the star chromatic index of most graph types, one of these families being multipartite graphs. We investigate a method for obtaining upper bounds on the star chromatic index of complete multipartite graphs. The basic idea is to decompose such graphs into smaller complete bipartite graphs and applying known upper bounds for such graphs.This method has also been implemented and we present a hypothesis based on simulations. Graph Graph theory Multipartite Graph Graph Coloring Star edge coloring Star chromatic index Discrete Mathematics Diskret matematik
16	Coloration d’arêtes ℓ-distance et clustering : études et algorithmes auto-stabilisants / L-distance-edge-coloring and clustering : studies and self-stabilizing algorithms Drira, Kaouther 14 December 2010 (has links) La coloration de graphes est un problème central de l’optimisation combinatoire. C’est un domaine très attractif par ses nombreuses applications. Différentes variantes et généralisations du problème de la coloration de graphes ont été proposées et étudiées. La coloration d’arêtes d’un graphe consiste à attribuer une couleur à chaque arête du graphe de sorte que deux arêtes ayant un sommet commun n’ont jamais la même couleur, le tout en utilisant le moins de couleurs possibles. Dans la première partie de cette thèse, nous étudions le problème de la coloration d’arêtes ℓ-distance, qui est une généralisation de la coloration d’arêtes classique. Nous menons une étude combinatoire et algorithmique du paramètre. L’étude porte sur les classes de graphes suivantes : les chaines, les grilles, les hypercubes, les arbres et des graphes puissances. Le paramètre de la coloration d’arêtes ℓ-distance permet de modéliser des problèmes dans des réseaux assez grands. Cependant, avec la multiplication du nombre de nœuds, les réseaux sont de plus en plus vulnérables aux défaillances (ou pannes). Dans la deuxième partie, nous nous intéressons aux algorithmes tolérants aux pannes et en particulier les algorithmes auto-stabilisants. Nous proposons un algorithme auto-stabilisant pour la coloration propre d’arêtes. Notre solution se base sur le résultat de vizing pour utiliser un minimum de couleurs possibles. Par la suite, nous proposons un algorithme auto-stabilisant de clustering destine a des applications dans le domaine de la sécurité dans les réseaux mobiles Ad hoc. La solution que nous proposons est un partitionnement en clusters base sur les relations de confiance qui existent entre nœuds. Nous proposons aussi un algorithme de gestion de clés de groupe dans les réseaux mobiles ad hoc qui s’appuie sur la topologie de clusters préalablement construite. La sécurité de notre protocole est renforcée par son critère de clustering qui surveille en permanence les relations de confiance et expulse les nœuds malveillants de la session de diffusion. / Graph coloring is a famous combinatorial optimization problem and is very attractive for its numerous applications. Many variants and generalizations of the graph-coloring problem have been introduced and studied. An edge-coloring assigns a color to each edge so that no two adjacent edges share the same color. In the first part of this thesis, we study the problem of the ℓ-distance-edge-coloring, which is a generalization of the classical edge-coloring. The study focuses on the following classes of graphs : paths, grids, hypercubes, trees and some power graphs. We are conducting a combinatorial and algorithmic study of the parameter. We give a sequential coloring algorithm for each class of graph. The ℓ-distance-edge-coloring is especially considered in large-scale networks. However, with the increasing number of nodes, networks are increasingly vulnerable to faults. In the second part, we focus on fault-tolerant algorithms and in particular self-stabilizing algorithms. We propose a self-stabilizing algorithm for proper edge-coloring. Our solution is based on Vizing’s result to minimize number of colors. Subsequently, we propose a selfstabilizing clustering algorithm for applications in the field of security in mobile ad hoc networks. Our solution is a partitioning into clusters based on trust relationships between nodes. We also propose a group key-management algorithm in mobile ad hoc networks based on the topology of clusters previously built. The security of our protocol is strengthened by its clustering criterion which constantly monitors trust relationships and expels malicious nodes out of the multicast session. Coloration d’arêtes Algorithmes Auto-stabilisation Clustering Réseaux mobiles ad hoc Gestion de clés Edge-coloring Algorithms Self-stabilization Clustering Mobiles ad hoc networks Key-management 004
17	Coloring, packing and embedding of graphs Tahraoui, Mohammed Amin 04 December 2012 (has links) (PDF) In this thesis, we investigate some problems in graph theory, namelythe graph coloring problem, the graph packing problem and tree pattern matchingfor XML query processing. The common point between these problems is that theyuse labeled graphs.In the first part, we study a new coloring parameter of graphs called the gapvertex-distinguishing edge coloring. It consists in an edge-coloring of a graph G whichinduces a vertex distinguishing labeling of G such that the label of each vertex isgiven by the difference between the highest and the lowest colors of its adjacentedges. The minimum number of colors required for a gap vertex-distinguishing edgecoloring of G is called the gap chromatic number of G and is denoted by gap(G).We will compute this parameter for a large set of graphs G of order n and we evenprove that gap(G) 2 fn E 1; n; n + 1g.In the second part, we focus on graph packing problems, which is an area ofgraph theory that has grown significantly over the past several years. However, themajority of existing works focuses on unlabeled graphs. In this thesis, we introducefor the first time the packing problem for a vertex labeled graph. Roughly speaking,it consists of graph packing which preserves the labels of the vertices. We studythe corresponding optimization parameter on several classes of graphs, as well asfinding general bounds and characterizations.The last part deal with the query processing of a core subset of XML query languages:XML twig queries. An XML twig query, represented as a small query tree,is essentially a complex selection on the structure of an XML document. Matching atwig query means finding all the occurrences of the query tree embedded in the XMLdata tree. Many holistic twig join algorithms have been proposed to match XMLtwig pattern. Most of these algorithms find twig pattern matching in two steps. Inthe first one, a query tree is decomposed into smaller pieces, and solutions againstthese pieces are found. In the second step, all of these partial solutions are joinedtogether to generate the final solutions. In this part, we propose a novel holistictwig join algorithm, called TwigStack++, which features two main improvementsin the decomposition and matching phase. The proposed solutions are shown to beefficient and scalable, and should be helpful for the future research on efficient queryprocessing in a large XML database. [INFO:INFO_OH] Computer Science/Other [INFO:INFO_OH] Informatique/Autre Graph theory Labeled graph Vertex-distinguishing edge coloring Labeled packing of graphs XML tree pattern matching
18	On some graph coloring problems Casselgren, Carl Johan January 2011 (has links) No description available. List coloring interval edge coloring coloring graphs from random lists biregular graph avoiding arrays Latin square scheduling Discrete mathematics Diskret matematik
19	Coloração de Arestas em Grafos Split-Comparabilidade / Edge coloring in split-comparability graphs Cruz, Jadder Bismarck de Sousa 02 May 2017 (has links) Submitted by Milena Rubi (milenarubi@ufscar.br) on 2017-10-09T16:26:41Z No. of bitstreams: 1 CRUZ_Jadder_2017.pdf: 1326879 bytes, checksum: 61ee3c40e293d26085a939c0a0290716 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2017-10-09T16:26:55Z (GMT) No. of bitstreams: 1 CRUZ_Jadder_2017.pdf: 1326879 bytes, checksum: 61ee3c40e293d26085a939c0a0290716 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2017-10-09T16:27:03Z (GMT) No. of bitstreams: 1 CRUZ_Jadder_2017.pdf: 1326879 bytes, checksum: 61ee3c40e293d26085a939c0a0290716 (MD5) / Made available in DSpace on 2017-10-09T16:27:11Z (GMT). No. of bitstreams: 1 CRUZ_Jadder_2017.pdf: 1326879 bytes, checksum: 61ee3c40e293d26085a939c0a0290716 (MD5) Previous issue date: 2017-05-02 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Let G = (V, E) be a simple and undirected graph. An edge-coloring is an assignment of colors to the edges of the graph such that any two adjacent edges receive different colors. The chromatic index of a graph G is the smallest number of colors such that G has an edge-coloring. Clearly, a lower bound for the chromatic index is the degree of the vertex of higher degree, denoted by ?(G). In 1964, Vizing proved that chromatic index is ?(G) or ?(G) + 1. The Classification Problem is to determine if the chromatic index is ?(G) (Class 1 ) or if it is ?(G) + 1 (Class 2 ). Let n be number of vertices of a graph G and let m be its number of edges. We say G is overfull if m > (n-1) 2 ?(G). Every overfull graph is Class 2. A graph is subgraph-overfull if it has a subgraph with same maximum degree and it is overfull. It is well-known that every overfull and subgraph-overfull graph is Class 2. The Overfull Conjecture asserts that every graph with ?(G) > n 3 is Class 2 if and only if it is subgraph-overfull. In this work we prove the Overfull Conjecture to a particular class of graphs, known as split-comparability graphs. The Overfull Conjecture was open to this class. / Dado um grafo simples e não direcionado G = (V, E), uma coloração de arestas é uma função que atribui cores às arestas do grafo tal que todas as arestas que incidem em um mesmo vértice têm cores distintas. O índice cromático é o número mínimo de cores para obter uma coloração própria das arestas de um grafo. Um limite inferior para o índice cromático é, claramente, o grau do vértice de maior grau, denotado por ?(G). Em 1964, Vizing provou que o índice cromático ou é ?(G) ou ?(G) + 1, surgindo assim o Problema da Classificação, que consiste em determinar se o índice cromático é ?(G) (Classe 1 ) ou ?(G) + 1 (Classe 2 ). Seja n o número de vértices de um grafo G e m seu número de arestas. Dizemos que um grafo é sobrecarregado se m > (n-1) 2 ?(G). Um grafo é subgrafo-sobrecarregado se tem um subgrafo de mesmo grau máximo que é sobrecarregado. É sabido que se um grafo é sobrecarregado ou subgrafo-sobrecarregado ele é necessariamente Classe 2. A Conjectura Overfull é uma famosa conjectura de coloração de arestas e diz que um grafo com ?(G) > n 3 é Classe 2 se e somente se é subgrafo-sobrecarregado. Neste trabalho provamos a Conjectura Overfull para uma classe de grafos, a classe dos grafos split-comparabilidade. Até este momento a Conjectura Overfull estava aberta para esta classe. Teoria dos grafos Coloração de arestas Problema da Classificação Grafos comparabilidade Classification Problem Graph theory Grafos split Edge coloring Chromatic index Split graphs Comparability graphs
20	Steinerovská barvení kubických grafů / Steiner coloring of cubic graphs Tlustá, Stanislava January 2017 (has links) This thesis is dedicated to the coloring of cubic graphs. It summarizes the knowledge we have about so called Steiner coloring, which is an edge-coloring such that the colors incident with one vertex form a triple of some partial Steiner system. The main objects of interest are the projective and affine systems. Afterwards the sufficient condition for universality of the system is stated and it is observed, that all other transitive Steiner triple systems satisfy it. This thesis also contains methods of construction of the coloring for the Fano plane, for the affine system Z3 3 and for the universal system created as a product of the Fano plane and the trivial system (F7 S⊠ 3). Finally an algorithm usable for the rest of the systems and graphs with bounded treewidth is presented.

Search results