Linear dynamical systems on Hilbert spaces: ...
Document type :
Autre communication scientifique (congrès sans actes - poster - séminaire...)
DOI :
Title :
Linear dynamical systems on Hilbert spaces: typical properties and explicit examples
Author(s) :
Grivaux, Sophie [Auteur]
Laboratoire Paul Painlevé - UMR 8524 [LPP]
Matheron, Etienne [Auteur]
Laboratoire de Mathématiques de Lens [LML]
Menet, Quentin [Auteur]
Laboratoire de Mathématiques de Lens [LML]
Laboratoire Paul Painlevé - UMR 8524 [LPP]
Matheron, Etienne [Auteur]
Laboratoire de Mathématiques de Lens [LML]
Menet, Quentin [Auteur]
Laboratoire de Mathématiques de Lens [LML]
Publisher :
AMS
Publication date :
2021
HAL domain(s) :
Mathématiques [math]
Mathématiques [math]/Systèmes dynamiques [math.DS]
Mathématiques [math]/Analyse fonctionnelle [math.FA]
Mathématiques [math]/Systèmes dynamiques [math.DS]
Mathématiques [math]/Analyse fonctionnelle [math.FA]
English abstract : [en]
We solve a number of questions pertaining to the dynamics of linear operators on Hilbert spaces, sometimes by using Baire category arguments and sometimes by constructing explicit examples. In particular, we prove the ...
Show more >We solve a number of questions pertaining to the dynamics of linear operators on Hilbert spaces, sometimes by using Baire category arguments and sometimes by constructing explicit examples. In particular, we prove the following results.(i) A typical hypercyclic operator is not topologically mixing, has no eigenvalues and admits no non-trivial invariant measure, but is denselydistributionally chaotic.(ii) A typical {upper-triangular} operator with coefficients of modulus $1$ on the diagonal is ergodic in the Gaussian sense, whereas a typical operator of the form ``diagonal with coefficients of modulus $1$ on the diagonal plus backward unilateral weighted shift" is ergodic but has only countably many unimodular eigenvalues; in particular, it is ergodic but {not} ergodic in the Gaussian sense.(iii) There exist Hilbert space operators which are chaotic and $\mathcal U$-frequently hypercyclic but not frequently hypercyclic, Hilbert space operators which are {chaotic and} frequently hypercyclic but not ergodic, and Hilbert space operators which are chaotic and topologically mixing but not $\mathcal U$-frequently hypercyclic.We complement our results by investigating the descriptive complexity of some natural classes of operators defined by dynamical properties.Show less >
Show more >We solve a number of questions pertaining to the dynamics of linear operators on Hilbert spaces, sometimes by using Baire category arguments and sometimes by constructing explicit examples. In particular, we prove the following results.(i) A typical hypercyclic operator is not topologically mixing, has no eigenvalues and admits no non-trivial invariant measure, but is denselydistributionally chaotic.(ii) A typical {upper-triangular} operator with coefficients of modulus $1$ on the diagonal is ergodic in the Gaussian sense, whereas a typical operator of the form ``diagonal with coefficients of modulus $1$ on the diagonal plus backward unilateral weighted shift" is ergodic but has only countably many unimodular eigenvalues; in particular, it is ergodic but {not} ergodic in the Gaussian sense.(iii) There exist Hilbert space operators which are chaotic and $\mathcal U$-frequently hypercyclic but not frequently hypercyclic, Hilbert space operators which are {chaotic and} frequently hypercyclic but not ergodic, and Hilbert space operators which are chaotic and topologically mixing but not $\mathcal U$-frequently hypercyclic.We complement our results by investigating the descriptive complexity of some natural classes of operators defined by dynamical properties.Show less >
Language :
Anglais
Audience :
Internationale
Popular science :
Non
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