Curvature Calculations Of The Operators In Cowen-Douglas Class

In a foundational paper “Operators Possesing an Open Set of Eigenvalues” written several decades ago, Cowen and Douglas showed that an operator T on a Hilbert space ‘H possessing an open set Ω C of eigenvalues determines a holomorphic Hermitian vector bundle ET . One of the basic theorems they pro...

Full description

Bibliographic Details
Main Author: Deb, Prahllad
Other Authors: Misra, Gadadhar
Language:en_US
Published: 2014
Subjects:
Online Access:http://etd.iisc.ernet.in/handle/2005/2284
http://etd.ncsi.iisc.ernet.in/abstracts/2939/G25236-Abs.pdf
id ndltd-IISc-oai-etd.ncsi.iisc.ernet.in-2005-2284
record_format oai_dc
spelling ndltd-IISc-oai-etd.ncsi.iisc.ernet.in-2005-22842018-01-10T03:36:31ZCurvature Calculations Of The Operators In Cowen-Douglas ClassDeb, PrahlladEigenvaluesCurvature CalculationsMathematical AlgebraOperator AlgebrasCowen-Douglas Operator ClassOperator TheoryAlgebraIn a foundational paper “Operators Possesing an Open Set of Eigenvalues” written several decades ago, Cowen and Douglas showed that an operator T on a Hilbert space ‘H possessing an open set Ω C of eigenvalues determines a holomorphic Hermitian vector bundle ET . One of the basic theorems they prove states that the unitary equivalence class of the operator T and the equivalence class of the holomorphic Hermitian vector bundle ET are in one to one correspondence. This correspondence appears somewhat mysterious until one detects the invariants for the vector bundle ET in the operator T and vice-versa. Fortunately, this is possible in some cases. Thus they point out that if the operator T possesses the additional property that the dimension of the eigenspace at ω is 1 for all ω Ω then the map ω ker(T - ω) admits a non-zero holomorphic section, say γ, and therefore defines a line bundle on Ω. As is well known, the curvature defined by the formula is a complete invariant for the line bundle . On the other hand, define and note that NT (ω)2 = 0. It follows that if T is unitarily equivalent to T˜, then the corresponding operators NT (ω) and NT˜(ω) are unitarily equivalent for all ω Ω. However, Cowen and Douglas prove the non-trivial converse, namely that if NT (ω) and NT˜(ω) are unitarily equivalent for all ω Ω then T and T˜ are unitarily equivalent. What does this have to do with the line bundles and .To answer this question, we must ask what is a complete invariant for the unitary equivalence class of the operator NT (ω). To find such a complete invariant we represent NT (ω) with respect to the orthonormal basis obtained from the two linearly independent vectors γ(ω),∂γ(ω) by Gram-Schmidt orthonormalization process. Then an easy computation shows that It then follows that is a complete invariant for NT (ω), ω Ω. This explains the relationship between the line bundle and the operator T in an explicit manner. Subsequently, in the paper ”Operators Possesing an Open Set of Eigenvalues”, Cowen and Douglas define a class of commuting operators possessing an open set of eigenvalues and attempt to provide similar computations as above. However, they give the details only for a pair of commuting operators. While the results of that paper remain true in the case of an arbitrary n tuple of commuting operators, it requires additional effort which we explain in this thesis.Misra, Gadadhar2014-03-03T09:38:06Z2014-03-03T09:38:06Z2014-03-032012-09Thesishttp://etd.iisc.ernet.in/handle/2005/2284http://etd.ncsi.iisc.ernet.in/abstracts/2939/G25236-Abs.pdfen_USG25236
collection NDLTD
language en_US
sources NDLTD
topic Eigenvalues
Curvature Calculations
Mathematical Algebra
Operator Algebras
Cowen-Douglas Operator Class
Operator Theory
Algebra
spellingShingle Eigenvalues
Curvature Calculations
Mathematical Algebra
Operator Algebras
Cowen-Douglas Operator Class
Operator Theory
Algebra
Deb, Prahllad
Curvature Calculations Of The Operators In Cowen-Douglas Class
description In a foundational paper “Operators Possesing an Open Set of Eigenvalues” written several decades ago, Cowen and Douglas showed that an operator T on a Hilbert space ‘H possessing an open set Ω C of eigenvalues determines a holomorphic Hermitian vector bundle ET . One of the basic theorems they prove states that the unitary equivalence class of the operator T and the equivalence class of the holomorphic Hermitian vector bundle ET are in one to one correspondence. This correspondence appears somewhat mysterious until one detects the invariants for the vector bundle ET in the operator T and vice-versa. Fortunately, this is possible in some cases. Thus they point out that if the operator T possesses the additional property that the dimension of the eigenspace at ω is 1 for all ω Ω then the map ω ker(T - ω) admits a non-zero holomorphic section, say γ, and therefore defines a line bundle on Ω. As is well known, the curvature defined by the formula is a complete invariant for the line bundle . On the other hand, define and note that NT (ω)2 = 0. It follows that if T is unitarily equivalent to T˜, then the corresponding operators NT (ω) and NT˜(ω) are unitarily equivalent for all ω Ω. However, Cowen and Douglas prove the non-trivial converse, namely that if NT (ω) and NT˜(ω) are unitarily equivalent for all ω Ω then T and T˜ are unitarily equivalent. What does this have to do with the line bundles and .To answer this question, we must ask what is a complete invariant for the unitary equivalence class of the operator NT (ω). To find such a complete invariant we represent NT (ω) with respect to the orthonormal basis obtained from the two linearly independent vectors γ(ω),∂γ(ω) by Gram-Schmidt orthonormalization process. Then an easy computation shows that It then follows that is a complete invariant for NT (ω), ω Ω. This explains the relationship between the line bundle and the operator T in an explicit manner. Subsequently, in the paper ”Operators Possesing an Open Set of Eigenvalues”, Cowen and Douglas define a class of commuting operators possessing an open set of eigenvalues and attempt to provide similar computations as above. However, they give the details only for a pair of commuting operators. While the results of that paper remain true in the case of an arbitrary n tuple of commuting operators, it requires additional effort which we explain in this thesis.
author2 Misra, Gadadhar
author_facet Misra, Gadadhar
Deb, Prahllad
author Deb, Prahllad
author_sort Deb, Prahllad
title Curvature Calculations Of The Operators In Cowen-Douglas Class
title_short Curvature Calculations Of The Operators In Cowen-Douglas Class
title_full Curvature Calculations Of The Operators In Cowen-Douglas Class
title_fullStr Curvature Calculations Of The Operators In Cowen-Douglas Class
title_full_unstemmed Curvature Calculations Of The Operators In Cowen-Douglas Class
title_sort curvature calculations of the operators in cowen-douglas class
publishDate 2014
url http://etd.iisc.ernet.in/handle/2005/2284
http://etd.ncsi.iisc.ernet.in/abstracts/2939/G25236-Abs.pdf
work_keys_str_mv AT debprahllad curvaturecalculationsoftheoperatorsincowendouglasclass
_version_ 1718603721023160320