22 research outputs found

    On Polish Groups of Finite Type

    Get PDF
    Sorin Popa initiated the study of Polish groups which are embeddable into the unitary group of a separable finite von Neumann algebra. Such groups are called of finite type. We give necessary and sufficient conditions for Polish groups to be of finite type, and construct exmaples of such groups from semifinite von Neumann algebras. We also discuss permanence properties of finite type groups under various algebraic operations. Finally we close the paper with some questions concerning Polish groups of finite type.Comment: 20 page

    On Borel equivalence relations related to self-adjoint operators

    Full text link
    In a recent work, the authors studied various Borel equivalence relations defined on the Polish space SA(H){\rm{SA}}(H) of all (not necessarily bounded) self-adjoint operators on a separable infinite-dimensional Hilbert space HH. In this paper we study the domain equivalence relation EdomSA(H)E_{\rm{dom}}^{{\rm{SA}}(H)} given by AEdomSA(H)BdomA=domBAE_{\rm{dom}}^{{\rm{SA}}(H)}B\Leftrightarrow {\rm{dom}}{A}={\rm{dom}}{B} and determine its exact Borel complexity: EdomSA(H)E_{\rm{dom}}^{{\rm{SA}}(H)} is an FσF_{\sigma} (but not KσK_{\sigma}) equivalence relation which is continuously bireducible with the orbit equivalence relation ERNE_{\ell^{\infty}}^{\mathbb{R}^{\mathbb{N}}} of the standard Borel group =(N,R)\ell^{\infty}=\ell^{\infty}(\mathbb{N},\mathbb{R}) on RN\mathbb{R}^{\mathbb{N}}. This, by Rosendal's Theorem, shows that EdomSA(H)E_{\rm{dom}}^{{\rm{SA}}(H)} is universal for KσK_{\sigma} equivalence relations. Moreover, we show that generic self-adjoint operators have purely singular continuous spectrum equal to R\mathbb{R}.Comment: 10 pages, added more detail of the proof of Proposition 3.8 after the referee's suggestio

    Weyl-von Neumann Theorem and Borel Complexity of Unitary Equivalence Modulo Compacts of Self-Adjoint Operators

    Get PDF
    Weyl-von Neumann Theorem asserts that two bounded self-adjoint operators A,BA,B on a Hilbert space HH are unitarily equivalent modulo compacts, i.e., uAu+K=BuAu^*+K=B for some unitary uU(H)u\in \mathcal{U}(H) and compact self-adjoint operator KK, if and only if AA and BB have the same essential spectra: σess(A)=σess(B)\sigma_{\rm{ess}}(A)=\sigma_{\rm{ess}}(B). In this paper we consider to what extent the above Weyl-von Neumann's result can(not) be extended to unbounded operators using descriptive set theory. We show that if HH is separable infinite-dimensional, this equivalence relation for bounded self-adjoin operators is smooth, while the same equivalence relation for general self-adjoint operators contains a dense GδG_{\delta}-orbit but does not admit classification by countable structures. On the other hand, apparently related equivalence relation $A\sim B\Leftrightarrow \exists u\in \mathcal{U}(H)\ [u(A-i)^{-1}u^*-(B-i)^{-1}$ is compact], is shown to be smooth. Various Borel or co-analytic equivalence relations related to self-adjoint operators are also presented.Comment: 36 page

    Non-commutative hypergroup of order five

    Get PDF
    We prove that all hypergroups of order four are commutative and that there exists a non-comutative hypergroup of order five. These facts imply that the minimum order of non-commutative hypergroups is five even though the minimum order of non-commutative groups is six

    Non-commutative hypergroup of order five

    Get PDF
    We prove that all hypergroups of order four are commutative and that there exists a non-comutative hypergroup of order five. These facts imply that the minimum order of non-commutative hypergroups is five, even though the minimum order of non-commutative groups is six.ArticleJournal of Algebra and Its Applications.16(7):1750127(2016)journal articl
    corecore