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Interactions entre les Cliques et les Stables dans un Graphe / Interactions between Cliques and Stable Sets in a GraphLagoutte, Aurélie 23 September 2015 (has links)
Cette thèse s'intéresse à différents types d'interactions entre les cliques et les stables, deux objets très importants en théorie des graphes, ainsi qu'aux relations entre ces différentes interactions. En premier lieu, nous nous intéressons au problème classique de coloration de graphes, qui peut s'exprimer comme une partition des sommets du graphe en stables. Nous présentons un résultat de coloration pour les graphes sans triangles ni cycles pairs de longueur au moins 6. Dans un deuxième temps, nous prouvons la propriété d'Erdös-Hajnal, qui affirme que la taille maximale d'une clique ou d'un stable devient polynomiale (contre logarithmique dans les graphes aléatoires) dans le cas des graphes sans chemin induit à k sommets ni son complémentaire, quel que soit k.Enfin, un problème moins connu est la Clique-Stable séparation, où l'on cherche un ensemble de coupes permettant de séparer toute clique de tout stable. Cette notion a été introduite par Yannakakis lors de l’étude des formulations étendues du polytope des stables dans un graphe parfait. Il prouve qu’il existe toujours un séparateur Clique-Stable de taille quasi-polynomiale, et se demande si l'on peut se limiter à une taille polynomiale. Göös a récemment fourni une réponse négative, mais la question se pose encore pour des classes de graphes restreintes, en particulier pour les graphes parfaits. Nous prouvons une borne polynomiale pour la Clique-Stable séparation dans les graphes aléatoires et dans plusieurs classes héréditaires, en utilisant notamment des outils communs à l'étude de la conjecture d'Erdös-Hajnal. Nous décrivons également une équivalence entre la Clique-Stable séparation et deux autres problèmes : la conjecture d'Alon-Saks-Seymour généralisée et le Problème Têtu, un problème de Satisfaction de Contraintes. / This thesis is concerned with different types of interactions between cliques and stable sets, two very important objects in graph theory, as well as with the connections between these interactions. At first, we study the classical problem of graph coloring, which can be stated in terms of partioning the vertices of the graph into stable sets. We present a coloring result for graphs with no triangle and no induced cycle of even length at least six. Secondly, we study the Erdös-Hajnal property, which asserts that the maximum size of a clique or a stable set is polynomial (instead of logarithmic in random graphs). We prove that the property holds for graphs with no induced path on k vertices and its complement.Then, we study the Clique-Stable Set Separation, which is a less known problem. The question is about the order of magnitude of the number of cuts needed to separate all the cliques from all the stable sets. This notion was introduced by Yannakakis when he studied extended formulations of the stable set polytope in perfect graphs. He proved that a quasi-polynomial number of cuts is always enough, and he asked if a polynomial number of cuts could suffice. Göös has just given a negative answer, but the question is open for restricted classes of graphs, in particular for perfect graphs. We prove that a polynomial number of cuts is enough for random graphs, and in several hereditary classes. To this end, some tools developed in the study of the Erdös-Hajnal property appear to be very helpful. We also establish the equivalence between the Clique-Stable set Separation problem and two other statements: the generalized Alon-Saks-Seymour conjecture and the Stubborn Problem, a Constraint Satisfaction Problem.
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Experimentos Computacionais com ImplementaÃÃes de Conjunto por EndereÃamento Direto e o Problema de Conjunto Independente MÃximo / Computational Experiments with Set Implementations by Direct Addressing and the Maximum Independent Set ProblemMarcio Costa Santos 13 September 2013 (has links)
CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / A utilizaÃÃo de vetores de bits à prÃtica corrente na representaÃÃo
de conjuntos por endereÃamento direto com o intuito de reduzir o espaÃo de memÃria necessÃrio e melhorar o desempenho de aplicaÃÃes com uso de tÃcnicas de paralelismo em bits.
Nesta dissertaÃÃo, examinamos implementaÃÃes para
representaÃÃo de conjuntos por endereÃamento direto.
A estrutura bÃsica nessas implementaÃÃes à o vetor de bits.
No entanto, alÃm dessa estrutura bÃsica, implementamos tambÃm duas
variaÃÃes. A primeira delas consiste em uma estratificaÃÃo de
vetores de bits, enquanto a segunda emprega uma tabela de
dispersÃo.
As operaÃÃes associadas Ãs estruturas implementadas sÃo a
inclusÃo ou remoÃÃo de um elemento do conjunto e a uniÃo ou
interseÃÃo de dois conjuntos. Especial atenÃÃo à dada ao uso
de paralelismo em bits nessas operaÃÃes. As implementaÃÃes das
diferentes estruturas nesta dissertaÃÃo utilizam uma interface e uma
implementaÃÃo abstrata comuns, nas quais as operaÃÃes sÃo
especificadas e o paralelismo em bits à explorado. A diferenÃa entre
as implementaÃÃes està apenas na estrutura utilizada. Uma comparaÃÃo
experimental à realizada entre as diferentes estruturas utilizando
algoritmos enumerativos para
o problema de conjunto independente mÃximo.
Duas abordagens sÃo utilizadas na implementaÃÃo de algoritmos
enumerativos para o problema de conjunto independente mÃximo,
ambas explorando o potencial de paralelismo em bits na
representaÃÃo do grafo e na operaÃÃo sobre subconjuntos de vÃrtices.
A primeira delas à um algoritmo do tipo {em branch-and-boound}
proposto na literatura e a segunda emprega o mÃtodo das bonecas russas. Em ambos os casos, o uso de paralelismo em bits proporciona ganhos de eficiÃncia quando empregado no cÃlculo de limites inferiores baseados em cobertura por cliques. Resultados de experimentos computacionais sÃo apresentados como forma de comparaÃÃo entre os dois algoritmos e como forma de avaliaÃÃo das estruturas implementadas. Esses resultados permitem concluir que o algoritmo baseado no mÃtodo das bonecas russas à mais eficiente quanto ao tempo de execuÃÃo e quanto ao consumo
de memÃria. AlÃm disso, os resultados experimentais mostram tambÃm que o uso de estratificaÃÃo e tabelas de dispersÃo permitem ainda maior eficiÃncia no caso de grafos com muito vÃrtices e poucas arestas. / The use of bit vectors is a usual practice for represent sets by
direct addressing with the aim of reduce memory consumed and improve
efficiency of applications with the use of bit parallel techniques.
In this text, we study implementations for represent sets by
direct addressed. The basic structure in this implementations is
the bit vector. Besides that basic implementation, we implement two
variations also. The first one is a stratification of the bit vector, while
the second uses a hash table.
The operations linked to the implemented structure are include and
remove an element and the union and intersection of two sets. Especial
attention is given to the use of bit parallel in this condition. The
implementation of the different structures in this work use an
base interface and a base abstract class, where the operations
are defined and the bit parallel is used. An experimental comparative
between this structures is carry out using enumerative algorithms for
the maximum stable set problem.
Two approaches are used in the implementation of the enumerative
algorithms for the maximum stable set problem, both using the bit parallel in the representation of the graph and on the operations
with subsets of vertices. The first one is a known branch-and-bound algorithm
and the second uses the Russian dolls method. In both cases, the use of
bit parallel improve efficiency when the lower bounds are calculated
based in a clique cover of the vertices. The results of computational experiments are presented as
comparison between the two algorithms and as an assessment of the structures
implemented. These results show that the algorithm based on the method
Russian Dolls is more efficient regarding runtime and the memory consumed.
Furthermore, the experimental results also show that the use
stratification and hash tables also allow
more efficiency in the case of sparse graphs.
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Propriedades genéricas das classes homoclínicasHancco, Hugo Rolando Jacho 18 July 2016 (has links)
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Previous issue date: 2016-07-18 / Consideramos os campos vetoriais C1 sobre uma variedade riemanniana compacta, sem bordo, de dimensão finita n, com n ≥3. Uma classe homoclínica de um campo vetorial é o fecho de conjunto de pontos homoclínicos transversais associados com uma órbita periódica hiperbólica. Neste trabalho, provamos que as classes homoclínicas para um conjunto residual de campos vetoriais C1 são conjuntos neutrais, mais ainda, a classe homoclínica é a intersecção dos fechos do conjunto estável e o conjunto instável. Como consequencia das propriedades do conjuntos neutrais, provamos as propriedades genéricas das classes homoclínicas.
Assim, provamos que as classes homoclínicas de campos vetoriais C1-genérico X são conjuntos transitivos maximais, saturados e que dependem continuamente da órbita periódica. Também provamos que uma classe homoclínica de X não apresentam ciclos de X formados por classes homoclínicas de X. Além disso, uma classe homoclínica de X é isolado se, e somente se, é Ω-isolado. Mais ainda, é isolado, se a classe homoclínica é hiperbólica. Todas estas propriedades são bem conhecidos para campos vetoriais estruturalmente estáveis e Axioma A. / We consider the vector fields C1 on a compact Riemannian manifold, boundaryless of finite dimension n, with n ≥3. A homoclinic class of a vector field is the closure of the set transverse homoclinic point associated with a hyperbolic periodic orbit. In this work, we prove that the homoclinic classes for a residual set of vector fields C1, are neutral sets, moreover, the homoclinic class is the intersection of the closure the stable set and unstable set. As a consequence of the properties of the neutral sets, we prove the generic properties of homoclinic classes.
Thus, we proved that in the homoclinic classes of generic C1 vector fields X are maximal transitive sets, saturated and depend continuously on the periodic orbit. We also proved that a homoclinic class X, does not exhibit cycles of X formed by homoclinic class of X. Furthermore, homoclinic class X is isolated if it only if it is Ω-isolated. But still, it is isolated, the homoclinic class is hyperbolic. All these properties are well known to structurally stable vector fields and Axiom A.
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Choice deferral, status quo bias, and matchingButurak, Gökhan January 2011 (has links)
This thesis consists of three independent papers. They are put in reverse chronological order according to when they were initiated. The first paper, which is a joint work with Özgür Evren, extends the standard rational choice framework with the option to postpone the act of selecting an alternative. In that paper, we propose an axiomatic model of choice over risky prospects that restricts the classical rationality axioms solely to those instances in which the decision maker does not defer. The cardinal approach we follow allows us to identify the preference relation of the decision maker over lotteries, even if the choice data is very scarce due to deferral. Moreover, we also derive the value of deferring choice from a given set of options, which turns out to be an affine utility function over choice sets. At each choice situation, the decision maker compares the utility of each available alternative with that of deferral so as to decide on opting for an alternative immediately. The second paper is a model of status quo bias with choice avoidance. It describes the choice behavior of an otherwise standard decision maker whose choices are affected by the presence of a status quo alternative. The status quo emerges as a temporary choice, which may be reversed upon arrival of new (introspective or objective) information, or upon finding new alternatives. The third paper considers the network formation problem from a matching perspective. In that paper, agents want to link with each other and each has preferences over the subsets of others. We consider various solution concepts regarding the stability of a matching between the agents, establish relations between these concepts under several preference restrictions, and provide sufficient conditions for these solutions to be nonempty. / Diss. Stockholm : Handelshögskolan i Stockholm, 2011
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Algorithms for the Maximum Independent Set ProblemLê, Ngoc C. 13 July 2015 (has links) (PDF)
This thesis focuses mainly on the Maximum Independent Set (MIS) problem. Some related graph theoretical combinatorial problems are also considered. As these problems are generally NP-hard, we study their complexity in hereditary graph classes, i.e. graph classes defined by a set F of forbidden induced subgraphs.
We revise the literature about the issue, for example complexity results, applications, and techniques tackling the problem. Through considering some general approach, we exhibit several cases where the problem admits a polynomial-time solution. More specifically, we present polynomial-time algorithms for the MIS problem in:
+ some subclasses of $S_{2;j;k}$-free graphs (thus generalizing the classical result for $S_{1;2;k}$-free graphs);
+ some subclasses of $tree_{k}$-free graphs (thus generalizing the classical results for subclasses of P5-free graphs);
+ some subclasses of $P_{7}$-free graphs and $S_{2;2;2}$-free graphs; and various subclasses of graphs of bounded maximum degree, for example subcubic graphs.
Our algorithms are based on various approaches. In particular, we characterize augmenting graphs in a subclass of $S_{2;k;k}$-free graphs and a subclass of $S_{2;2;5}$-free graphs. These characterizations are partly based on extensions of the concept of redundant set [125]. We also propose methods finding augmenting chains, an extension of the method in [99], and finding augmenting trees, an extension of the methods in [125]. We apply the augmenting vertex technique, originally used for $P_{5}$-free graphs or banner-free graphs, for some more general graph classes.
We consider a general graph theoretical combinatorial problem, the so-called Maximum -Set problem. Two special cases of this problem, the so-called Maximum F-(Strongly) Independent Subgraph and Maximum F-Induced Subgraph, where F is a connected graph set, are considered. The complexity of the Maximum F-(Strongly) Independent Subgraph problem is revised and the NP-hardness of the Maximum F-Induced Subgraph problem is proved. We also extend the augmenting approach to apply it for the general Maximum Π -Set problem.
We revise on classical graph transformations and give two unified views based on pseudo-boolean functions and αff-redundant vertex. We also make extensive uses of α-redundant vertices, originally mainly used for $P_{5}$-free graphs, to give polynomial solutions for some subclasses of $S_{2;2;2}$-free graphs and $tree_{k}$-free graphs.
We consider some classical sequential greedy heuristic methods. We also combine classical algorithms with αff-redundant vertices to have new strategies of choosing the next vertex in greedy methods. Some aspects of the algorithms, for example forbidden induced subgraph sets and worst case results, are also considered.
Finally, we restrict our attention on graphs of bounded maximum degree and subcubic graphs. Then by using some techniques, for example ff-redundant vertex, clique separator, and arguments based on distance, we general these results for some subclasses of $S_{i;j;k}$-free subcubic graphs.
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Algorithms for the Maximum Independent Set ProblemLê, Ngoc C. 18 February 2015 (has links)
This thesis focuses mainly on the Maximum Independent Set (MIS) problem. Some related graph theoretical combinatorial problems are also considered. As these problems are generally NP-hard, we study their complexity in hereditary graph classes, i.e. graph classes defined by a set F of forbidden induced subgraphs.
We revise the literature about the issue, for example complexity results, applications, and techniques tackling the problem. Through considering some general approach, we exhibit several cases where the problem admits a polynomial-time solution. More specifically, we present polynomial-time algorithms for the MIS problem in:
+ some subclasses of $S_{2;j;k}$-free graphs (thus generalizing the classical result for $S_{1;2;k}$-free graphs);
+ some subclasses of $tree_{k}$-free graphs (thus generalizing the classical results for subclasses of P5-free graphs);
+ some subclasses of $P_{7}$-free graphs and $S_{2;2;2}$-free graphs; and various subclasses of graphs of bounded maximum degree, for example subcubic graphs.
Our algorithms are based on various approaches. In particular, we characterize augmenting graphs in a subclass of $S_{2;k;k}$-free graphs and a subclass of $S_{2;2;5}$-free graphs. These characterizations are partly based on extensions of the concept of redundant set [125]. We also propose methods finding augmenting chains, an extension of the method in [99], and finding augmenting trees, an extension of the methods in [125]. We apply the augmenting vertex technique, originally used for $P_{5}$-free graphs or banner-free graphs, for some more general graph classes.
We consider a general graph theoretical combinatorial problem, the so-called Maximum -Set problem. Two special cases of this problem, the so-called Maximum F-(Strongly) Independent Subgraph and Maximum F-Induced Subgraph, where F is a connected graph set, are considered. The complexity of the Maximum F-(Strongly) Independent Subgraph problem is revised and the NP-hardness of the Maximum F-Induced Subgraph problem is proved. We also extend the augmenting approach to apply it for the general Maximum Π -Set problem.
We revise on classical graph transformations and give two unified views based on pseudo-boolean functions and αff-redundant vertex. We also make extensive uses of α-redundant vertices, originally mainly used for $P_{5}$-free graphs, to give polynomial solutions for some subclasses of $S_{2;2;2}$-free graphs and $tree_{k}$-free graphs.
We consider some classical sequential greedy heuristic methods. We also combine classical algorithms with αff-redundant vertices to have new strategies of choosing the next vertex in greedy methods. Some aspects of the algorithms, for example forbidden induced subgraph sets and worst case results, are also considered.
Finally, we restrict our attention on graphs of bounded maximum degree and subcubic graphs. Then by using some techniques, for example ff-redundant vertex, clique separator, and arguments based on distance, we general these results for some subclasses of $S_{i;j;k}$-free subcubic graphs.
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