Showing total 4 results

1. The Semicontinuity of Attractors for Closed Relations on Compact Hausdorff Spaces

Author

Negaard-Paper, Shannon

Subjects

Mathematics - Dynamical Systems

Abstract

We show that attractors are semicontinuous for closed relations on compact Hausdorff spaces. Semicontinuity is what guarantees that small changes to a system do not result in massive growth of certain features, notably attractors. That is, there is a certain preservation of structure. When it comes to flows, semiflows, and maps, it is well established that attractors are semicontinuous. In [2], relations were established as a way to generalize maps, and a formal definition of attractors was established. Relations (in the dynamical systems sense) represent discrete time systems, which may lack uniqueness (or existence) in forward time., Comment: 8 pages, 3 figures (one with two parts)

Published

2019

2. Attractors and Attracting Neighborhoods for Multiflows

Author

Negaard-Paper, Shannon

Subjects

Mathematics - Dynamical Systems

Abstract

We already know a great deal about dynamical systems with uniqueness in forward time. Indeed, flows, semiflows, and maps (both invertible and not) have been studied at length. A view that has proven particularly fruitful is topological: consider invariant sets (attractors, repellers, periodic orbits, etc.) as topological objects, and the connecting sets between them form gradient like flows. In the case of systems with uniqueness in forward time, an attractor in one system is related to nearby attractors in a family of other, "close enough" systems. One way of seeing that connection is through the Conley decomposition (and the Conley index) [2], [13]. This approach requires focusing on isolated invariant sets - that is, invariant sets with isolating neighborhoods. If there is an invariant set $I$, which has an isolating neighborhood $N$ $\ldots$. This approach was expanded to discrete time systems which lack uniqueness in forward time, using relations, in [7] and [11]. Relations do not rely on uniqueness in forward time, but the graph of any map is a relation; thus they serve to generalize maps. Some of this is reviewed in the next few sections. In addition, I expanded on work done in [7] to show that in compact metric spaces, attractors for closed relations continue (see Section 6). On the continuous time side, more work needs to be done. This paper is a step toward a more systematic approach for continuous time systems which lack uniqueness in forward time. This work applies to Filippov systems [4] and in control theory [12]. In the following pages, we establish a tool (multiflows) for discussing the continuous time case and develop a framework for understanding attractors (and therefore stability) in these systems. A crucial part of this work was establishing attractor / attracting neighborhood pairs, which happens in Section 5.5., Comment: 52 pages, 20 figures; author's dissertation

Published

2019

3. Extreme Value Laws for non stationary processes generated by sequential and random dynamical systems

Author

Ana C. Freitas, Sandro Vaienti, Jorge Milhazes Freitas, Centro de Matemática - Universidade do Porto (CMUP), Universidade do Porto = University of Porto, Centre de Physique Théorique - UMR 7332 (CPT), Aix Marseille Université (AMU)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), CPT - Ex E7 Systèmes dynamiques et théorie ergodique, Aix Marseille Université (AMU)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), ACMF was partially supported by FCT (Portugal) grant SFRH/BPD/66174/2009. JMF was partially supported by FCT grant SFRH/BPD/66040/2009. All these grants are financially supported by the program POPH/FSE. ACMF and JMF were partially supported by FCT project FAPESP/19805/2014 and by CMUP (UID/MAT/00144/2013), which is funded by FCT with national (MEC) and European structural funds through the programs ,FEDER, under the partnership agreement PT2020. SV was supported by the ANRProject Perturbations and by the project Atracción de Capital Humano Avanzado del Extranjero MEC 80130047, CONICYT, at the CIMFAV, University of Valparaiso. All authors were partially supported by FCT project PTDC/MAT/12034 /2010, which is funded by national and European structural funds through the programs FEDER and COMPETE. SV is grateful to N. Haydn, M. Nicol and A. Török for several and fruitful discussions on sequential systems, especially in the framework of indifferent maps. JMF is grateful to M. Todd for fruitful discussions and careful reading of a preliminary version of this paper. All authors acknowledge the Isaac Newton Institute for Mathematical Sciences, where this work was initiated during the program Mathematics for the Fluid Earth., ANR-10-BLAN-0106,PERTURBATIONS,Perturbations aléatoires de systèmes dynamiques: applications non-uniformément dilatantes, isométries, billards et systèmes de fonctions itérées. Grandes déviations et valeurs extrêmes.(2010), Faculdade de Economia, Faculdade de Ciências, and Universidade do Porto

Subjects

Hitting Times, Statistics and Probability, Pure mathematics, Random dynamical systems, 60G70, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], FOS: Physical sciences, Dynamical Systems (math.DS), 01 natural sciences, 010104 statistics & probability, Sequential dynamical systems, FOS: Mathematics, 37A50, Mathematics - Dynamical Systems, 0101 mathematics, Extreme value theory, Mathematical Physics, Mathematics, 37A25, 37B20, Non-stationarity, Probability (math.PR), 010102 general mathematics, Mathematical Physics (math-ph), Non stationarity, Statistics, Probability and Uncertainty, Mathematics - Probability

Abstract

International audience; We develop and generalize the theory of extreme value for non-stationary stochastic processes, mostly by weakening the uniform mixing condition that was previously used in this setting. We apply our results to non-autonomous dynamical systems, in particular to sequential dynamical systems, both given by uniformly expanding maps and by maps with a neutral fixed point, and to a few classes of random dynamical systems. Some examples are presented and worked out in detail.

Published

2017

4. Hausdorff dimension of particularly non-normal numbers in dynamical systems fulfilling the specification property

Author

Madritsch, Manfred G., Petrykiewicz, Izabela, Madritsch, Manfred, Institut Élie Cartan de Lorraine (IECL), Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), Max Planck Institute for Mathematics (MPIM), Max-Planck-Gesellschaft, and For the realization of the present paper the first author received support from the Conseil Régional de Lorraine.

Subjects

FOS: Mathematics, Dynamical Systems (math.DS), Mathematics - Dynamical Systems, [MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT], 11K16 (11A63, 28A80 37B10, 37C45, 54H20), [MATH.MATH-NT] Mathematics [math]/Number Theory [math.NT]

Abstract

In this paper, we consider non-normal numbers occurring in dynamical systems fulfilling the specification property. It has been shown that in this case the set of non-normal numbers has measure zero. In the present papers we show that a smaller set, namely the set of particularly non-normal numbers, has full Hausdorff dimension. A particularly non-normal number is a number $x$ such that there exist two digits, one whose limiting frequency in $x$ exists and another one whose limiting frequency in $x$ does not exist., 11 pages

Published

2015