Spelling suggestions: "subject:"perfect graphs"" "subject:"nerfect graphs""
11 |
Perfect Graphs Involving Semitotal and Semipaired DominationHaynes, Teresa W., Henning, Michael A. 01 August 2018 (has links)
Let G be a graph with vertex set V and no isolated vertices, and let S be a dominating set of V. The set S is a semitotal dominating set of G if every vertex in S is within distance 2 of another vertex of S. And, S is a semipaired dominating set of G if S can be partitioned into 2-element subsets such that the vertices in each 2-set are at most distance two apart. The semitotal domination number γt 2(G) is the minimum cardinality of a semitotal dominating set of G, and the semipaired domination number γpr 2(G) is the minimum cardinality of a semipaired dominating set of G. For a graph without isolated vertices, the domination number γ(G) , the total domination γt(G) , and the paired domination number γpr(G) are related to the semitotal and semipaired domination numbers by the following inequalities: γ(G) ≤ γt 2(G) ≤ γt(G) ≤ γpr(G) and γ(G) ≤ γt 2(G) ≤ γpr 2(G) ≤ γpr(G) ≤ 2 γ(G). Given two graph parameters μ and ψ related by a simple inequality μ(G) ≤ ψ(G) for every graph G having no isolated vertices, a graph is (μ, ψ) -perfect if every induced subgraph H with no isolated vertices satisfies μ(H) = ψ(H). Alvarado et al. (Discrete Math 338:1424–1431, 2015) consider classes of (μ, ψ) -perfect graphs, where μ and ψ are domination parameters including γ, γt and γpr. We study classes of perfect graphs for the possible combinations of parameters in the inequalities when γt 2 and γpr 2 are included in the mix. Our results are characterizations of several such classes in terms of their minimal forbidden induced subgraphs.
|
12 |
Entropy and GraphsChangiz Rezaei, Seyed Saeed January 2014 (has links)
The entropy of a graph is a functional depending both on the graph itself and on a probability distribution on its vertex set. This graph functional originated from the problem of source coding in information theory and was introduced by J. K\"{o}rner in 1973. Although the notion of graph entropy has its roots in information theory, it was proved to be closely related to some classical and frequently studied graph theoretic concepts. For example, it provides an equivalent definition for a graph to be perfect and it can also be applied to obtain lower bounds in graph covering problems.
In this thesis, we review and investigate three equivalent definitions of graph entropy and its basic properties. Minimum entropy colouring of a graph was proposed by N. Alon in 1996. We study minimum entropy colouring and its relation to graph entropy. We also discuss the relationship between the entropy and the fractional chromatic number of a graph which was already established in the literature.
A graph $G$ is called \emph{symmetric with respect to a functional $F_G(P)$} defined on the set of all the probability distributions on its vertex set if the distribution $P^*$ maximizing $F_G(P)$ is uniform on $V(G)$. Using the combinatorial definition of the entropy of a graph in terms of its vertex packing polytope and the relationship between the graph entropy and fractional chromatic number, we prove that vertex transitive graphs are symmetric with respect to graph entropy. Furthermore, we show that a bipartite graph is symmetric with respect to graph entropy if and only if it has a perfect matching. As a generalization of this result, we characterize some classes of symmetric perfect graphs with respect to graph entropy. Finally, we prove that the line graph of every bridgeless cubic graph is symmetric with respect to graph entropy.
|
13 |
Problemas em grafos com poucos P4's em grafos indiferença / Problems on graphs with few P4's and indifference graphsPedrotti, Vagner, 1980- 19 August 2018 (has links)
Orientador: Célia Picinin de Mello / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Computação / Made available in DSpace on 2018-08-19T10:47:23Z (GMT). No. of bitstreams: 1
Pedrotti_Vagner_D.pdf: 2015411 bytes, checksum: 4a6917f5811bde65dedbf0f7ab2577c5 (MD5)
Previous issue date: 2011 / Resumo: Nesta tese de doutoramento sáo considerados três problemas em grafos, para os quais sáo obtidos resultados quando a entrada é restrita a algumas classes. Todos os problemas sáo problemas de otimização combinatória sobre grafos simples e apresentam diferentes classificações de complexidade. Em dois casos, o estudo focou classes de grafos com "poucos iYs" e ° uso da decomposição modular. No último caso, considerou-se uma subclasse dos grafos de intervalos e a aplicação de uma técnica conhecida como pullback. O primeiro problema estudado é o Problema dos Separadores Minimais, para o qual são conhecidos algoritmos polinomiais em toda classe de grafos que possuir um número polinomial de separadores minimais. Serão dados, como contribuição deste trabalho, um algoritmo linear para listar os separadores minimais de grafos P4-carregados estendidos e limitantes justos no número e tamanho dos separadores minimais destes grafos, bem como de algumas de suas subclasses, P4-carregada, P4-arrumada e P4-íeve. Estes resultados estendem um algoritmo anterior para grafos P4-esparsos, ao mesmo tempo que incluem estas classes de grafos entre as que possuem um número de separadores minimais limitado por um função linear no número de vértices do grafo. Em seguida, será tratado o Problema de Empacotamento de Cliques, uma extensão do problema de emparelhamento máximo. Para a maioria das classes de grafos mais importantes, o problema é NP-Difícil. A contribuição apresentada resolve este problema em tempo polinomial (para qualquer tamanho fixo de clique) em grafos P4-arrumados, através de uma técnica similar a utilizada para os cografos. Infelizmente, para as superclasses mais estudadas da classe P4-arrumada, este problema é NP-Difícil, o que é um indício de que a técnica utilizada foi totalmente aproveitada em relação ás classes com poucos _P4's. Por fim, será estudado o Problema da Coloração Total Forte, uma variação do problema clássico da coloração total, que foi introduzido há pouco tempo e ainda tem sua complexidade computacional desconhecida. Como esperado, existem algoritmos polinomiais apenas para classes bastante simples de grafos. Além da complexidade, outro importante ponto em aberto para o problema é a conjectura de que o número de cores necessárias na solução do problema para um grafo G seria limitado por A(G) + 3. A técnica do pullback, já utilizada para os Problemas de Coloração de Arestas e Coloração Total em grafos dualmente cordais será estendida, resultando em um algoritmo linear para grafos indiferença (também conhecido como grafos de intervalos próprios). Este algoritmo produz uma solução que valida a conjectura nesta classe de grafos. Estas contribuições confirmam a importância da decomposição modular em algoritmos para classes de grafos com "poucos iYs" e ampliam o uso da técnica do pullback para variações dos problemas clássicos de coloração / Abstract: In this doctoral thesis, three problems on graphs are considered and results are given for them when the input is resctricted to some graph classes. All the problems are combinatorial optimization problems on simple graphs and have distinct classihcations of complexity. In two of them, the research focused on graph classes known as graphs with "few iVs" and on the use of modular decomposition on such graphs. In the last problem, a subclass of interval graphs was studied with respect to the application of the technique known as pullback. The first problem studied is the Minimal Separator Problem. For this problem, there exists polynomial time algorithms for every class of graphs which has a polynomial number of minimal separators. A linear-time algorithm, that lists all minimal separators of extended iVladen graphs, is presented. Moreover, tight bounds on the number and on the total size of minimal separators are given for extended iVladen graphs and for some of their subclasses: the iVladen, iVtidy, and iVlite graphs. This result extends a previous algorithm for iVspai'se graphs and gives, for the above classes, better bounds on the number of minimal separators that were already known to be polynomial. Then, the Clique Packing Problem is analyzed. The problem is an extension of the classical Maximum Matching Problem and is NP-Hard for almost all graph classes. The contribution presented solves the problem in polynomial time (for any fixed clique size) in iVtidy graphs through a technique similar to that used for cographs. However, the most well-known superclasses of iVtidy graphs contains split graphs, for which this problem is NP-Hard. This is an evidence that the technique was fully explored with respect of graph classes with few iVs. At last, the Strong Total Coloring Problem is considered. It is a recently introduced variation of the classical Total Coloring Problem and its complexity is still unknown. As expected, there are quite few graph classes for which the problem has a polynomial time algorithm. Besides its complexity, another important open question for this problem is a conjecture which states that A(G) + 3 colors are sufficient for coloring any graph G. A known technique, called pullback, used for edge and total coloring of dually chordal graphs is extended to derive a linear time algorithm for indifference graphs (also known as proper interval graphs). This algorithm produces solutions that validate the conjecture for this graph class. These contributions assert the importance of modular decomposition in algorithms for graph classes with "few P4's" and broaden the pullback technique to variations of classical coloring problems / Doutorado / Ciência da Computação / Doutor em Ciência da Computação
|
14 |
Coloração de arestas em grafos split / Edge-coloring of split graphsAlmeida, Sheila Morais de, 1979- 20 August 2018 (has links)
Orientador: Célia Picinin de Mello / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Computação / Made available in DSpace on 2018-08-20T03:13:25Z (GMT). No. of bitstreams: 1
Almeida_SheilaMoraisde_D.pdf: 958566 bytes, checksum: ac97bf74cca2e690531df0f6d05c8a00 (MD5)
Previous issue date: 2012 / Resumo: Por apresentar basicamente fórmulas, o resumo, na íntegra, poderá ser visualizado no texto completo da tese digital / Abstract: Not informed / Doutorado / Ciência da Computação / Doutor em Ciência da Computação
|
15 |
Two level polytopes :geometry and optimizationMacchia, Marco 07 September 2018 (has links)
A (convex) polytope P is said to be 2-level if every hyperplane H that is facet-defining for P has a parallel hyperplane H' that contains all the vertices of P which are not contained in H.Two level polytopes appear in different areas of mathematics, in particular in contexts related to discrete geometry and optimization. We study the problem of enumerating all combinatorial types of 2-level polytopes of a fixed dimension d. We describe the first algorithm to achieve this. We ran it to produce the complete database for d <= 8. Our results show that the number of combinatorial types of 2-level d-polytopes is surprisingly small for low dimensions d.We provide an upper bound for the number of combinatorially inequivalent 2-level d-polytopes. We phrase this counting problem in terms of counting some objects called 2-level configurations, that capture the class of "maximal" rank d 0/1-matrices, including (maximal) slack matrices of 2-level cones and 2-level polytopes. We provide a proof that the number of d-dimensional 2-level configurations coming from cones and polytopes, up to linear equivalence, is at most 2^{O(d^2 log d)}.Finally, we prove that the extension complexity of every stable set polytope of a bipartite graph with n nodes is O(n^2 log n) and that there exists an infinite class of bipartite graphs such that, for every n-node graph in this class, its stable set polytope has extension complexity equal to Omega(n log n). / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
|
16 |
Trigraphes de Berge apprivoisés / Tame Berge trigraphesTrunck, Théophile 17 September 2014 (has links)
L'objectif de cette thèse est de réussir à utiliser des décompositions de graphes afin de résoudre des problèmes algorithmiques sur les graphes. Notre objet d'étude principal est la classe des graphes de Berge apprivoisés. Les graphes de Berge sont les graphes ne possédant ni cycle de longueur impaire supérieur à 4 ni complémentaire de cycle de longueur impaire supérieure à 4. Dans les années 60, Claude Berge a conjecturé que les graphes de Berge étaient des graphes parfaits. C'est-à-dire que la taille de la plus grande clique est exactement le nombre minimum de couleurs nécessaire à une coloration propre et ce pour tout sous-graphe. En 2002, Chudnovsky, Robertson, Seymour et Thomas ont démontré cette conjecture en utilisant un théorème de structure: les graphes de Berge sont basiques ou admettent une décomposition. Ce résultat est très utile pour faire des preuves par induction. Cependant, une des décompositions du théorème, la skew-partition équilibrée, est très difficile à utiliser algorithmiquement. Nous nous focalisons donc sur les graphes de Berge apprivoisés, c'est-à-dire les graphes de Berge sans skew-partition équilibrée. Pour pouvoir faire des inductions, nous devons adapter le théorème destructure de Chudnovsky et al à notre classe. Nous prouvons un résultat plus fort: les graphes de Berge apprivoisés sont basiques ou admettent une décomposition telle qu'un côté de la décomposition soit toujours basique. Nous avons de plus un algorithme calculant cette décomposition. Nous utilisons ensuite notre théorème pour montrer que les graphes de Berge apprivoisés admettent la propriété du grand biparti, de la clique-stable séparation et qu'il existe un algorithme polynomial permettant de calculer le stable maximum. / The goal of this these is to use graph's decompositions to solve algorithmic problems on graphs. We will study the class of Berge tame graphs. A Berge graph is a graph without cycle of odd length at least 4 nor complement of cycle of odd length at least 4.In the 60's, Claude Berge conjectured that Berge graphs are perfect graphs. The size of the biggest clique is exactly the number of colors required to color the graph. In 2002, Chudnovsky, Robertson, Seymour et Thomas proved this conjecture using a theorem of decomposition: Berge graphs are either basic or have a decomposition. This is a useful result to do proof by induction. Unfortunately, one of the decomposition, the skew-partition, is really hard to use. We arefocusing here on Berge tame graphs, i.e~Berge graph without balanced skew-partition. To be able to do induction, we must first adapt the Chudnovsky et al's theorem of structure to our class. We prove a stronger result: Berge tame graphs are basic or have a decomposition such that one side is always basic. We also have an algorithm to compute this decomposition. We then use our theorem to prouve that Berge tame graphs have the big-bipartite property, the clique-stable set separation property and there exists a polytime algorithm to compute the maximum stable set.
|
17 |
Propriétés géométriques du nombre chromatique : polyèdres, structures et algorithmes / Geometric properties of the chromatic number : polyhedra, structure and algorithmsBenchetrit, Yohann 12 May 2015 (has links)
Le calcul du nombre chromatique et la détermination d'une colo- ration optimale des sommets d'un graphe sont des problèmes NP- difficiles en général. Ils peuvent cependant être résolus en temps po- lynomial dans les graphes parfaits. Par ailleurs, la perfection d'un graphe peut être décidée efficacement. Les graphes parfaits sont caractérisés par la structure de leur poly- tope des stables : les facettes non-triviales sont définies exclusivement par des inégalités de cliques. Réciproquement, une structure similaire des facettes du polytope des stables détermine-t-elle des propriétés combinatoires et algorithmiques intéressantes? Un graphe est h-parfait si les facettes non-triviales de son polytope des stables sont définies par des inégalités de cliques et de circuits impairs. On ne connaît que peu de résultats analogues au cas des graphes parfaits pour la h-perfection, et on ne sait pas si les problèmes sont NP-difficiles. Par exemple, les complexités algorithmiques de la re- connaissance des graphes h-parfaits et du calcul de leur nombre chro- matique sont toujours ouvertes. Par ailleurs, on ne dispose pas de borne sur la différence entre le nombre chromatique et la taille maxi- mum d'une clique d'un graphe h-parfait. Dans cette thèse, nous montrons tout d'abord que les opérations de t-mineurs conservent la h-perfection (ce qui fournit une extension non triviale d'un résultat de Gerards et Shepherd pour la t-perfection). De plus, nous prouvons qu'elles préservent la propriété de décompo- sition entière du polytope des stables. Nous utilisons ce résultat pour répondre négativement à une question de Shepherd sur les graphes h-parfaits 3-colorables. L'étude des graphes minimalement h-imparfaits (relativement aux t-mineurs) est liée à la recherche d'une caractérisation co-NP com- binatoire de la h-perfection. Nous faisons l'inventaire des exemples connus de tels graphes, donnons une description de leur polytope des stables et énonçons plusieurs conjectures à leur propos. D'autre part, nous montrons que le nombre chromatique (pondéré) de certains graphes h-parfaits peut être obtenu efficacement en ar- rondissant sa relaxation fractionnaire à l'entier supérieur. Ce résultat implique notamment un nouveau cas d'une conjecture de Goldberg et Seymour sur la coloration d'arêtes. Enfin, nous présentons un nouveau paramètre de graphe associé aux facettes du polytope des couplages et l'utilisons pour donner un algorithme simple et efficace de reconnaissance des graphes h- parfaits dans la classe des graphes adjoints. / Computing the chromatic number and finding an optimal coloring of a perfect graph can be done efficiently, whereas it is an NP-hard problem in general. Furthermore, testing perfection can be carried- out in polynomial-time. Perfect graphs are characterized by a minimal structure of their sta- ble set polytope: the non-trivial facets are defined by clique-inequalities only. Conversely, does a similar facet-structure for the stable set polytope imply nice combinatorial and algorithmic properties of the graph ? A graph is h-perfect if its stable set polytope is completely de- scribed by non-negativity, clique and odd-circuit inequalities. Statements analogous to the results on perfection are far from being understood for h-perfection, and negative results are missing. For ex- ample, testing h-perfection and determining the chromatic number of an h-perfect graph are unsolved. Besides, no upper bound is known on the gap between the chromatic and clique numbers of an h-perfect graph. Our first main result states that the operations of t-minors keep h- perfection (this is a non-trivial extension of a result of Gerards and Shepherd on t-perfect graphs). We show that it also keeps the Integer Decomposition Property of the stable set polytope, and use this to answer a question of Shepherd on 3-colorable h-perfect graphs in the negative. The study of minimally h-imperfect graphs with respect to t-minors may yield a combinatorial co-NP characterization of h-perfection. We review the currently known examples of such graphs, study their stable set polytope and state several conjectures on their structure. On the other hand, we show that the (weighted) chromatic number of certain h-perfect graphs can be obtained efficiently by rounding-up its fractional relaxation. This is related to conjectures of Goldberg and Seymour on edge-colorings. Finally, we introduce a new parameter on the complexity of the matching polytope and use it to give an efficient and elementary al- gorithm for testing h-perfection in line-graphs.
|
18 |
Problèmes de placement, de coloration et d’identification / On packing, colouring and identification problemsValicov, Petru 09 July 2012 (has links)
Dans cette thèse, nous nous intéressons à trois problèmes issus de l'informatique théorique, à savoir le placement de formes rectangulaires dans un conteneur (OPP), la coloration dite "forte" d'arêtes des graphes et les codes identifiants dans les graphes. L'OPP consiste à décider si un ensemble d'items rectangulaires peut être placé sans chevauchement dans un conteneur rectangulaire et sans dépassement des bords de celui-ci. Une contrainte supplémentaire est prise en compte, à savoir l'interdiction de rotation des items. Le problème est NP-difficile même dans le cas où le conteneur et les formes sont des carrés. Nous présentons un algorithme de résolution efficace basé sur une caractérisation du problème par des graphes d'intervalles, proposée par Fekete et Schepers. L'algorithme est exact et utilise les MPQ-arbres - structures de données qui encodent ces graphes de manière compacte tout en capturant leurs propriétés remarquables. Nous montrons les résultats expérimentaux de notre approche en les comparant aux performances d'autres algorithmes existants. L'étude de la coloration forte d'arêtes et des codes identifiants porte sur les aspects structurels et de calculabilité de ces deux problèmes. Dans le cas de la coloration forte d'arêtes nous nous intéressons plus particulièrement aux familles des graphes planaires et des graphes subcubiques. Nous montrons des bornes optimales pour l'indice chromatique fort des graphes subcubiques en fonction du degré moyen maximum et montrons que tout graphe planaire subcubique sans cycles induits de longueur 4 et 5 est coloriable avec neuf couleurs. Enfin nous confirmons la difficulté du problème de décision associé, en prouvant qu'il est NP-complet dans des sous-classes restreintes des graphes planaires subcubiques.La troisième partie de la thèse est consacrée aux codes identifiants. Nous proposons une caractérisation des graphes identifiables dont la cardinalité du code identifiant minimum ID est n-1, où n est l'ordre du graphe. Nous étudions la classe des graphes adjoints et nous prouvons des bornes inférieures et supérieures serrées pour le paramètre ID dans cette classe. Finalement, nous montrons qu'il existe un algorithme linéaire de calcul de ID dans la classe des graphes adjoints L(G) où G a une largeur arborescente bornée par une constante. En revanche nous nous apercevons que le problème est NP-complet dans des sous-classes très restreintes des graphes parfaits. / In this thesis we study three theoretical computer science problems, namely the orthogonal packing problem (OPP for short), strong edge-colouring and identifying codes.OPP consists in testing whether a set of rectangular items can be packed in a rectangular container without overlapping and without exceeding the borders of this container. An additional constraint is that the rotation of the items is not allowed. The problem is NP-hard even when the problem is reduced to packing squares in a square. We propose an exact algorithm for solving OPP efficiently using the characterization of the problem by interval graphs proposed by Fekete and Schepers. For this purpose we use some compact representation of interval graphs - MPQ-trees. We show experimental results of our approach by comparing them to the results of other algorithms known in the literature. we observe promising gains.The study of strong edge-colouring and identifying codes is focused on the structural and computational aspects of these combinatorial problems. In the case of strong edge-colouring we are interested in the families of planar graphs and subcubic graphs. We show optimal upper bounds for the strong chromatic index of subcubic graphs as a function of the maximum average degree. We also show that every planar subcubic graph without induced cycles of length 4 and 5 can be strong edge-coloured with at most nine colours. Finally, we confirm the difficulty of the problem by showing that it remains NP-complete even in some restricted classes of planar subcubic graphs.For the subject of identifying codes we propose a characterization of non-trivial graphs having maximum identifying code number ID, that is n-1, where n is the number of vertices. We study the case of line graphs and prove lower and upper bounds for ID parameter in this class. At last we investigate the complexity of the corresponding decision problem and show the existence of a linear algorithm for computing ID of the line graph L(G) where G has the size of the tree-width bounded by a constant. On the other hand, we show that the identifying code problem is NP-complete in various subclasses of planar graphs.
|
Page generated in 0.0609 seconds