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Fundamentos da geometria complexa: aspectos geométricos, topológicos e analiticos. / Foundations of Complex Geometry: geometric, topological and analytic aspects.Sacchetto, Lucas Kaufmann 03 May 2012 (has links)
Este trabalho tem como objetivo apresentar um estudo detalhado dos fundamentos da Geometria Complexa, ressaltando seus aspectos geométricos, topológicos e analíticos. Começando com materiais preliminares, como resultados básicos sobre funções holomorfas de uma ou mais variáveis e a definição e primeiros exemplos de variedades complexas, passamos a uma introdução à teoria de feixes e sua cohomologia, ferramenta indispensável para o restante do trabalho. Após um estudo sobre fibrados de linha e divisores damos atenção à Geometria de Kähler e alguns de seus resultados centrais, como por exemplo o Teorema da Decomposição de Hodge, o Teorema ``Difícil\'\' e o Teorema das $(1,1)$-classes de Lefschetz. Em seguida, nos dedicamos ao estudo dos fibrados vetoriais complexos e sua geometria, abordando os conceitos de conexões, curvatura e Classes de Chern. Terminamos o trabalho descrevendo alguns aspectos da topologia de variedades complexas, como o Teorema dos Hiperplanos de Lefschetz e algumas de suas consequências. / The main goal of this work is to present a detailed study of the foundations of Complex Geometry, highlighting its geometric, topological and analytical aspects. Beginning with a preliminary material, such as the basic results on holomorphic functions in one or more variables and the definition and first examples of a complex manifold, we move on to an introduction to sheaf theory and its cohomology, an essential tool to the rest of the work. After a discussion on divisors and line bundles we turn attention to Kähler Geometry and its central results, such as the Hodge Decomposition Theorem, the Hard Lefschetz Theorem and the Lefschetz Theorem on $(1,1)$-classes. After that, we study complex vector bundles and its geometry, focusing on the concepts of connections, curvature and Chern classes. Finally, we finish by describing some aspects of the topology of complex manifolds, such as the Lefschetz Hyperplane Theorem and some of its consequences.
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Fundamentos da geometria complexa: aspectos geométricos, topológicos e analiticos. / Foundations of Complex Geometry: geometric, topological and analytic aspects.Lucas Kaufmann Sacchetto 03 May 2012 (has links)
Este trabalho tem como objetivo apresentar um estudo detalhado dos fundamentos da Geometria Complexa, ressaltando seus aspectos geométricos, topológicos e analíticos. Começando com materiais preliminares, como resultados básicos sobre funções holomorfas de uma ou mais variáveis e a definição e primeiros exemplos de variedades complexas, passamos a uma introdução à teoria de feixes e sua cohomologia, ferramenta indispensável para o restante do trabalho. Após um estudo sobre fibrados de linha e divisores damos atenção à Geometria de Kähler e alguns de seus resultados centrais, como por exemplo o Teorema da Decomposição de Hodge, o Teorema ``Difícil\'\' e o Teorema das $(1,1)$-classes de Lefschetz. Em seguida, nos dedicamos ao estudo dos fibrados vetoriais complexos e sua geometria, abordando os conceitos de conexões, curvatura e Classes de Chern. Terminamos o trabalho descrevendo alguns aspectos da topologia de variedades complexas, como o Teorema dos Hiperplanos de Lefschetz e algumas de suas consequências. / The main goal of this work is to present a detailed study of the foundations of Complex Geometry, highlighting its geometric, topological and analytical aspects. Beginning with a preliminary material, such as the basic results on holomorphic functions in one or more variables and the definition and first examples of a complex manifold, we move on to an introduction to sheaf theory and its cohomology, an essential tool to the rest of the work. After a discussion on divisors and line bundles we turn attention to Kähler Geometry and its central results, such as the Hodge Decomposition Theorem, the Hard Lefschetz Theorem and the Lefschetz Theorem on $(1,1)$-classes. After that, we study complex vector bundles and its geometry, focusing on the concepts of connections, curvature and Chern classes. Finally, we finish by describing some aspects of the topology of complex manifolds, such as the Lefschetz Hyperplane Theorem and some of its consequences.
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Méthode SPH implicite d’ordre 2 appliquée à des fluides incompressibles munis d’une frontière libreRioux-Lavoie, Damien 05 1900 (has links)
L’objectif de ce mémoire est d’introduire une nouvelle méthode smoothed particle hydrodynamics
(SPH) implicite purement lagrangienne, pour la résolution des équations de Navier-
Stokes incompressibles bidimensionnelles en présence d’une surface libre. Notre schéma de
discrétisation est basé sur celui de Kéou Noutcheuwa et Owens [19]. Nous avons traité la
surface libre en combinant la méthode multiple boundary tangent (MBT) de Yildiz et al. [43]
et les conditions aux limites sur les champs auxiliaires de Yang et Prosperetti [42]. Ce faisant,
nous obtenons un schéma de discrétisation d’ordre $\mathcal{O}(\Delta t ^2)$ et $\mathcal{O}(\Delta x ^2)$, selon certaines
contraintes sur la longueur de lissage $h$. Dans un premier temps, nous avons testé notre
schéma avec un écoulement de Poiseuille bidimensionnel à l’aide duquel nous analysons l’erreur
de discrétisation de la méthode SPH. Ensuite, nous avons tenté de simuler un problème
d’extrusion newtonien bidimensionnel. Malheureusement, bien que le comportement de la
surface libre soit satisfaisant, nous avons rencontré des problèmes numériques sur la singularité
à la sortie du moule. / The objective of this thesis is to introduce a new implicit purely lagrangian smoothed particle
hydrodynamics (SPH) method, for the resolution of the two-dimensional incompressible
Navier-Stokes equations in the presence of a free surface. Our discretization scheme is based
on that of Kéou Noutcheuwa et Owens [19]. We have treated the free surface by combining
Yildiz et al. [43] multiple boundary tangent (MBT) method and boundary conditions on the
auxiliary fields of Yang et Prosperetti [42]. In this way, we obtain a discretization scheme of
order $\mathcal{O}(\Delta t ^2)$ and $\mathcal{O}(\Delta x ^2)$, according to certain constraints on the smoothing length $h$. First,
we tested our scheme with a two-dimensional Poiseuille flow by means of which we analyze
the discretization error of the SPH method. Then, we tried to simulate a two-dimensional
Newtonian extrusion problem. Unfortunately, although the behavior of the free surface is
satisfactory, we have encountered numerical problems on the singularity at the output of the
die.
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