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1. On the continuity of the map square root of nonnegative isomorphisms in Hilbert spaces

Author

Jeovanny de Jesus Muentes Acevedo

Subjects
Nonnegative operators, functions of operators, Hilbert spaces, spectral theory, Operadores no negativos, funciones de operadores, espacios de Hilbert, teoría espectral, Mathematics, QA1-939
Abstract

Let H be a real (or complex) Hilbert space. Every nonnegative operator L ∈ L(H) admits a unique nonnegative square root R ∈ L(H), i.e., a nonnegative operator R ∈ L(H) such that R2 = L. Let GL+ S (H) be the set of nonnegative isomorphisms in L(H). First we will show that GL+ S (H) is a convex (real) Banach manifold. Denoting by L1/2 the nonnegative square root of L. In [3], Richard Bouldin proves that L1/2 depends continuously on L (this proof is non-trivial). This result has several applications. For example, it is used to find the polar decomposition of a bounded operator. This polar decomposition allows us to determine the positive and negative spectral subespaces of any self-adjoint operator, and moreover, allows us to define the Maslov index. The autor of the paper under review provides an alternative proof (and a little more simplified) that L1/2 depends continuously on L, and moreover, he shows that the map is a homeomorphism. Resumen. Sea H un espacio de Hilbert real (o complejo). Todo operador no negativo L ∈ L(H) admite una única raíz cuadrada no negativa R ∈ L(H), esto es, un operador no negativo R ∈ L(H) tal que R2 = L. Sea GL+ S (H) el conjunto de los isomorfismos no negativos en L(H). Primero probaremos que GL+ S (H) es una variedad de Banach (real). Denotando como L1/2 la raíz cuadrada no negativa de L, en [3] Richard Bouldin prueba que L1/2 depende continuamente de L (esta prueba es no trivial). Este resultado tiene varias aplicaciones. Por ejemplo, es usado para encontrar la descomposición polar de un operador limitado. Esta descomposición polar nos lleva a determinar los subespacios espectrales positivos y negativos de cualquier operador autoadjunto, y además, lleva a definir el índice de Máslov. El autor de este artículo da una prueba alternativa (y un poco más simplificada) de que L1/2 depende continuamente de L, y además, prueba que la aplicación es un homeomorfismo

Published
2015

2. Sobre la continuidad de la aplicación raíz cuadrada de isomorfismos no negativos en espacios de Hilbert

Author

Jeovanny de Jesus Muentes Acevedo

Subjects
Operadores no negativos, funciones de operadores, espacios de Hilbert, teoría espectral, Mathematics, QA1-939
Abstract

Sea H un espacio de Hilbert real (o complejo). Todo operador no negativo L ∈ L(H) admite una única raíz cuadrada no negativa R ∈ L(H), esto es, un operador no negativo R ∈ L(H) tal que R2 = L. Sea GL+S (H) el conjunto de los isomorfismos no negativos en L(H). Primero probaremos que GL+S (H) es una variedad de Banach (real). Denotando como L1/2 la raíz cuadrada no negativa de L, en [3] Richard Bouldin prueba que L1/2 depende continuamente de L (esta prueba es no trivial). Este resultado tiene varias aplicaciones. Por ejemplo, es usado para encontrar la descomposición polar de un operador limitado. Esta descomposición polar nos lleva a determinar los subespacios espectrales positivos y negativos de cualquier operador autoadjunto, y además, lleva a definir el índice de Máslov. El autor de este artículo da una prueba alternativa (y un poco más simplificada) de que L1/2 depende continuamente de L, y además, prueba que la aplicación R : GL+S (H) → GL+S (H) L → L1/2 es un homeomorfismo. Para citar este artículo: J.J. Muentes Acevedo, On the continuity of the map square root of nonnegative isomorphisms in Hilbert spaces, Rev. Integr. Temas Mat. 33 (2015), no. 1, 11-26.

Published
2015

3. Density of the level sets of the metric mean dimension for homeomorphisms

Author

Jeovanny de Jesus Muentes Acevedo, Sergio Augusto Romaña Ibarra, and Raibel de Jesus Arias Cantillo

Abstract

Let N be an n-dimensional compact riemannian manifold, with n ≥ 2. In this paper, we prove that for any α ϵ 2 [0, n], the set consisting of homeomorphisms on N with lower and upper metric mean dimensions equal to α is dense in Hom(N). More generally, given α, β ϵ [0; n], with α ≤ β , we show the set consisting of homeomorphisms on N with lower metric mean dimension equal to α and upper metric mean dimension equal to β is dense in Hom(N). Furthermore, we also give a proof that the set of homeomorphisms with upper metric mean dimension equal to n is residual in Hom(N).

Published
2023
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18. On the Continuity of the Topological Entropy of Non-autonomous Dynamical Systems

Author

Jeovanny de Jesus Muentes Acevedo

Subjects
Physics, Dynamical systems theory, Continuous map, General Mathematics, 010102 general mathematics, Dynamical Systems (math.DS), 37A35, 37B40, 37B55, 0102 computer and information sciences, Topological entropy, Riemannian manifold, 01 natural sciences, Combinatorics, 010201 computation theory & mathematics, FOS: Mathematics, Entropy (information theory), Mathematics - Dynamical Systems, 0101 mathematics
Abstract

Let M be a compact Riemannian manifold. The set $$\text {F}^{r}(M)$$ consisting of sequences $$(f_{i})_{i\in {\mathbb {Z}}}$$ of $$C^{r}$$ -diffeomorphisms on M can be endowed with the compact topology or with the strong topology. A notion of topological entropy is given for these sequences. I will prove this entropy is discontinuous at each sequence if we consider the compact topology on $$\text {F}^{r}(M)$$ . On the other hand, if $$ r\ge 1$$ and we consider the strong topology on $$\text {F}^{r}(M)$$ , this entropy is a continuous map.

Published
2017
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19. Mean dimension and metric mean dimension for non-autonomous dynamical systems

Author

Jeovanny de Jesus Muentes Acevedo and Fagner B. Rodrigues

Subjects
0209 industrial biotechnology, Numerical Analysis, Pure mathematics, Control and Optimization, Algebra and Number Theory, Topological entropy, Dynamical systems theory, Mean dimension, 010102 general mathematics, 02 engineering and technology, Extension (predicate logic), Dynamical Systems (math.DS), 01 natural sciences, 020901 industrial engineering & automation, Dimension (vector space), Control and Systems Engineering, Non-autonomous dynamical systems, Metric (mathematics), FOS: Mathematics, 0101 mathematics, Mathematics - Dynamical Systems, Metric mean dimension, Mathematics
Abstract

In this paper we extend the definitions of mean dimension and metric mean di-mension for non-autonomous dynamical systems. We show some properties of this extension and furthermore some applications to the mean dimension and metric mean dimension of single continuous maps.

Published
2019
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21. Anosov families: structural stability, Invariant manifolds and entropy for non-stationary dynamical sytems

Author

Jeovanny de Jesus Muentes Acevedo, Albert Meads Fisher, Sylvain Philippe Pierre Bonnot, Daniel Smania Brandão, Sergio Augusto Romana Ibarra, and Pedro Antonio Santoro Salomão

Abstract

As famílias Anosov foram introduzidas por P. Arnoux e A. Fisher, motivados por generalizar a noção de difeomorfismo de Anosov. A grosso modo, as famílias Anosov são sequências de difeomorfismos (fi)i&#8712Z definidos em uma sequencia de variedades Riemannianas compactas (Mi)i&#8712Z, em que fi: Mi ->Mi+1 para todo i &#8712 Z, tal que a composição fi+no· · ·ofi, para n >=1, tem comportamento assintoticamente hiperbólico. Esta noção é conhecida como um sistema dinâmico não-estacionário ou um sistema dinâmico não-autônomo. Sejam M a união disjunta de cada Mi, para i &#8712 Z, e Fm(M) o conjunto consistente das famílias de difeomorfismos (fi)i&#8712Z de classe Cm definidos na sequência (Mi)i&#8712Z. O propósito principal deste trabalho é mostrar algumas propriedades das famílias Anosov. Em particular, mostraremos que o conjunto destas famílias é aberto em Fm(M), em que Fm(M) é munido da topologia forte (ou topologia Whitney); a estabilidade estrutural de certa classe de famílias Anosov, considerando conjugações topológicas uniformes; e várias versões para os Teoremas de variedades estáveis e instáveis. Os resultados que serão apresentados aqui generalizam alguns outros resultados obtidos em Sistemas Dinâmicos Aleatórios, os quais serão mencionados ao longo do trabalho. Além do anterior, será introduzida a entropia topológica para elementos em Fm(M) e mostraremos algumas das suas propriedades. Provaremos que esta entropia é contínua em Fm(M) munido da topologia forte. Porém, ela é descontínua em cada elemento de Fm(M) munido da topologia produto. Também apresentaremos um resultado que pode ser uma ferramenta de muita utilidade no estudo da continuidade da entropia topológica de difeomorfismos definidos em variedades compactas. Finalizaremos o trabalho dando uma lista de problemas que surgiram ao longo desta pesquisa e que serão analisados em um trabalho futuro. Anosov families were introduced by P. Arnoux and A. Fisher, motivated by generalizing the notion of Anosov dieomorphisms. Roughly, Anosov families are sequences of dieomorphisms (fi)i&#8712Z dened on a sequence of compact Riemannian manifolds (Mi)i&#8712Z, where fi: Mi -> Mi+1 for all i &#8712 Z, such that the composition fi+n o · · · o fi, for n >=1, has asymptotically hyperbolic behavior. This notion is known as a non-stationary dynamical system or a non-autonomous dynamical system. Let M be the disjoint union of each Mi, for each i &#8712 Z, and Fm(M) the set consisting of families of Cm-dieomorphisms (fi)i&#8712Z dened on the sequence (Mi)i&#8712Z. The main goal of this work is to explore some properties of Anosov families. In particular, we will show that the set consisting of these families is open in Fm(M), where Fm(M) is endowed with the strong topology (or Whitney topology); the structural stability of a certain class of Anosov families, considering uniform topological conjugacies; and some versions of stable and unstable manifold theorems. The results that will be presented here generalize some results obtained in Random Dynamical Systems, which will be mentioned throughout the work. In addition to the above mentioned theorems, the topological entropy for elements in Fm(M) will be introduced, and we will show some of its properties. We will prove that this entropy is continuous on Fm(M) endowed with strong topology. However, it is discontinuous at each element of Fm(M) endowed with the product topology. We will also present a result that can be a very useful tool in the study of the continuity of the topological entropy of dieomorphisms dened on compact manifolds. We will nish the work by giving a list of problems that have arisen throughout this research and that will be analyzed in a future work.

Published
2017

22. Local Stable and Unstable Manifolds for Anosov Families

Author

Jeovanny de Jesus Muentes Acevedo

Subjects
invariant manifolds, 37D10, Pure mathematics, Mathematics::Dynamical Systems, Dynamical systems theory, 37B55, General Mathematics, Dynamical Systems (math.DS), FOS: Mathematics, Anosov diffeomorphism, Mathematics - Dynamical Systems, random hyperbolic dynamical systems, Mathematics::Symplectic Geometry, Mathematics, Expanding Maps, Hadamard-Perron Theorem, LEMB, 37D20, Dynamical System, SRB Measure, Riemannian manifold, Mathematics::Geometric Topology, non-stationary dynamical systems, Anosov families, Mathematics::Differential Geometry, non-autonomous dynamical systems, 37D10, 37D20, 37B55
Abstract

Anosov families were introduced by A. Fisher and P. Arnoux motivated by generalizing the notion of Anosov diffeomorphism defined on a compact Riemannian manifold. They are time-dependent dynamical systems with hyperbolic behavior. In addition to presenting several properties and examples of Anosov families, in this paper we build local stable and local manifolds for such families. © Hokkaido University.

Published
2017
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23. Spectral flow of a path of selfadjoint Fredholm operators in Hilbert spaces

Author

Jeovanny de Jesus Muentes Acevedo, Pierluigi Benevieri, Christina Brech, and Márcia Cristina Anderson Braz Federson

Abstract

O objetivo principal desta dissertação é apresentar o fluxo espectral de um caminho de operadores de Fredholm auto-adjuntos em um espaço de Hilbert e suas propriedades. Pelos resultados clássicos de teoria espectral, sabemos que se H é um espaço de Hilbert e L : H &#8594 H é um operador linear, limitado e auto-adjunto, H pode ser escrito como soma direta ortogonal H+(L)&#8853 H-(L)&#8853 Ker L, onde H+(L) e H-(L) são os subespaços espectrais positivo e negativo de L, respectivamente. No trabalho damos uma definição de fluxo espectral baseada na decomposição acima, aprofundando as conexões deste conceito com a teoria espectral dos operadores de Fredholm em espaços de Hilbert. Entre as propriedades do fluxo espectral, será analisada a invariância homotópica que se apresenta em várias formas. Veremos o conceito de índice de Morse relativo, que estende o clássico índice de Morse, e sua relação com o fluxo espectral. A construção do fluxo espectral dada neste trabalho segue a abordagem de P. M. Fitzpatrick, J. Pejsachowicz e L. Recht em [9]. The main purpose of this dissertation is to present the spectral flow of a path of selfadjoint Fredholm operators in a Hilbert space and its properties. By classical results in spectral theory, we know that, if H is a Hilbert space and L : H &#8594 H is a bounded self-adjoint linear operator, H may be written as the following orthogonal direct sum H = H+(L)&#8853 H-(L)&#8853 Ker L, where H+(L) and H-(L) are the positive and negative spectral subspaces of L, respectively. In this work we give a definition of spectral flow which is based on the above splitting, examining in depth the connection between this concept and the spectral theory of Fredholm operators in Hilbert spaces. Among the properties of the spectral flow we will analyze the homotopic invariance, which appears on different ways. We will see the concept of relative Morse index, which generalize the classical Morse index, and its relation with the spectral flow. The construction of the spectral flow given in this work follows the approach of P. M. Fitzpatrick, J. Pejsachowicz and L. Recht in [9].

Published
2013

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