the unilateral shift as a hilbert module over the disc algebra
TRANSCRIPT
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The unilateral shift as a Hilbert module over the disc algebra
Raphael Clouatre
Indiana University
COSy 2013, Fields InstituteMay 31, 2013
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 1 / 18
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Hilbert modules over function algebras
In 1989, Douglas and Paulsen reformulated several interesting operator theoretic problemsusing the language of module theory.
This suggested the use of cohomological methodssuch as extension groups to further the study of problems such as commutant lifting.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 2 / 18
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Hilbert modules over function algebras
In 1989, Douglas and Paulsen reformulated several interesting operator theoretic problemsusing the language of module theory.This suggested the use of cohomological methodssuch as extension groups to further the study of problems such as commutant lifting.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 2 / 18
![Page 4: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/4.jpg)
Hilbert modules over function algebras
A bounded linear operator T : H → H is said to be polynomially bounded if there existsa constant C > 0 such that for every polynomial ϕ, we have
‖ϕ(T )‖ ≤ C‖ϕ‖∞
where‖ϕ‖∞ = sup
|z|<1
|ϕ(z)|.
The mapA(D)×H → H
(ϕ, h) 7→ ϕ(T )h
gives rise to a structure of an A(D)-module on H, and we say that (H,T ) is a Hilbertmodule.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 3 / 18
![Page 5: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/5.jpg)
Hilbert modules over function algebras
A bounded linear operator T : H → H is said to be polynomially bounded if there existsa constant C > 0 such that for every polynomial ϕ, we have
‖ϕ(T )‖ ≤ C‖ϕ‖∞
where‖ϕ‖∞ = sup
|z|<1
|ϕ(z)|.
The mapA(D)×H → H
(ϕ, h) 7→ ϕ(T )h
gives rise to a structure of an A(D)-module on H, and we say that (H,T ) is a Hilbertmodule.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 3 / 18
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Extension groups
Given two Hilbert modules (H1,T1) and (H2,T2), we can consider the extension groupExt1A(D)(T2,T1), which consists of equivalence classes of exact sequences
0→ H1 → K → H2 → 0
where K is another Hilbert module and each map is a module morphism.
Rather than formally defining the equivalence relation and the group operation, wesimply use the following characterization.
Theorem (Carlson-Clark 1995)
Let (H1,T1) and (H2,T2) be Hilbert modules. Then, the group
Ext1A(D)(T2,T1)
is isomorphic to A /J , where A is the space of operators X : H2 → H1 for which theoperator (
T1 X0 T2
)is polynomially bounded, and J is the space of operators of the form T1L− LT2 for somebounded operator L : H2 → H1.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 4 / 18
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Extension groups
Given two Hilbert modules (H1,T1) and (H2,T2), we can consider the extension groupExt1A(D)(T2,T1), which consists of equivalence classes of exact sequences
0→ H1 → K → H2 → 0
where K is another Hilbert module and each map is a module morphism.Rather than formally defining the equivalence relation and the group operation, wesimply use the following characterization.
Theorem (Carlson-Clark 1995)
Let (H1,T1) and (H2,T2) be Hilbert modules. Then, the group
Ext1A(D)(T2,T1)
is isomorphic to A /J , where A is the space of operators X : H2 → H1 for which theoperator (
T1 X0 T2
)is polynomially bounded, and J is the space of operators of the form T1L− LT2 for somebounded operator L : H2 → H1.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 4 / 18
![Page 8: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/8.jpg)
Extension groups
Given two Hilbert modules (H1,T1) and (H2,T2), we can consider the extension groupExt1A(D)(T2,T1), which consists of equivalence classes of exact sequences
0→ H1 → K → H2 → 0
where K is another Hilbert module and each map is a module morphism.Rather than formally defining the equivalence relation and the group operation, wesimply use the following characterization.
Theorem (Carlson-Clark 1995)
Let (H1,T1) and (H2,T2) be Hilbert modules. Then, the group
Ext1A(D)(T2,T1)
is isomorphic to A /J , where A is the space of operators X : H2 → H1 for which theoperator (
T1 X0 T2
)is polynomially bounded, and J is the space of operators of the form T1L− LT2 for somebounded operator L : H2 → H1.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 4 / 18
![Page 9: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/9.jpg)
Projective Hilbert modules
An important question in the study of extension groups is that of determining whichHilbert modules (H2,T2) have the property that
Ext1A(D)(T2,T1) = 0
for every Hilbert module (H1,T1).
Such Hilbert modules are said to be projective.Note that T2 is projective if and only if
Ext1A(D)(T1,T ∗2 ) = 0
for every Hilbert module (H1,T1).A characterization of projective Hilbert modules has long been sought.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 5 / 18
![Page 10: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/10.jpg)
Projective Hilbert modules
An important question in the study of extension groups is that of determining whichHilbert modules (H2,T2) have the property that
Ext1A(D)(T2,T1) = 0
for every Hilbert module (H1,T1).Such Hilbert modules are said to be projective.
Note that T2 is projective if and only if
Ext1A(D)(T1,T ∗2 ) = 0
for every Hilbert module (H1,T1).A characterization of projective Hilbert modules has long been sought.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 5 / 18
![Page 11: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/11.jpg)
Projective Hilbert modules
An important question in the study of extension groups is that of determining whichHilbert modules (H2,T2) have the property that
Ext1A(D)(T2,T1) = 0
for every Hilbert module (H1,T1).Such Hilbert modules are said to be projective.Note that T2 is projective if and only if
Ext1A(D)(T1,T ∗2 ) = 0
for every Hilbert module (H1,T1).
A characterization of projective Hilbert modules has long been sought.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 5 / 18
![Page 12: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/12.jpg)
Projective Hilbert modules
An important question in the study of extension groups is that of determining whichHilbert modules (H2,T2) have the property that
Ext1A(D)(T2,T1) = 0
for every Hilbert module (H1,T1).Such Hilbert modules are said to be projective.Note that T2 is projective if and only if
Ext1A(D)(T1,T ∗2 ) = 0
for every Hilbert module (H1,T1).A characterization of projective Hilbert modules has long been sought.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 5 / 18
![Page 13: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/13.jpg)
Results of Carlson and Clark
The unilateral shift operatorSE : H2(E)→ H2(E)
is defined as(SE f )(z) = zf (z)
for every f ∈ H2(E).
Theorem (Carlson-Clark 1995)
Let (H,T ) be a Hilbert module. Then, an operator X : H → E gives rise to an element[X ] ∈ Ext1A(D)(T , SE) if and only if there exists a constant c > 0 such that
∞∑n=0
‖XT nh‖2 ≤ c‖h‖2
for every h ∈ H. Moreover, for every [X ] ∈ Ext1A(D)(T , SE) there exists an operatorY : H → E with the property that [X ] = [Y ].
We bring the reader’s attention to the fact that the group Ext1A(D)(T , SE) is really of a
“scalar” nature: it consists of elements [X ] where the operator X : H → H2(E) has rangecontained in the constant functions E .
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 6 / 18
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Results of Carlson and Clark
The unilateral shift operatorSE : H2(E)→ H2(E)
is defined as(SE f )(z) = zf (z)
for every f ∈ H2(E).
Theorem (Carlson-Clark 1995)
Let (H,T ) be a Hilbert module. Then, an operator X : H → E gives rise to an element[X ] ∈ Ext1A(D)(T , SE) if and only if there exists a constant c > 0 such that
∞∑n=0
‖XT nh‖2 ≤ c‖h‖2
for every h ∈ H.
Moreover, for every [X ] ∈ Ext1A(D)(T , SE) there exists an operatorY : H → E with the property that [X ] = [Y ].
We bring the reader’s attention to the fact that the group Ext1A(D)(T , SE) is really of a
“scalar” nature: it consists of elements [X ] where the operator X : H → H2(E) has rangecontained in the constant functions E .
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 6 / 18
![Page 15: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/15.jpg)
Results of Carlson and Clark
The unilateral shift operatorSE : H2(E)→ H2(E)
is defined as(SE f )(z) = zf (z)
for every f ∈ H2(E).
Theorem (Carlson-Clark 1995)
Let (H,T ) be a Hilbert module. Then, an operator X : H → E gives rise to an element[X ] ∈ Ext1A(D)(T , SE) if and only if there exists a constant c > 0 such that
∞∑n=0
‖XT nh‖2 ≤ c‖h‖2
for every h ∈ H. Moreover, for every [X ] ∈ Ext1A(D)(T , SE) there exists an operatorY : H → E with the property that [X ] = [Y ].
We bring the reader’s attention to the fact that the group Ext1A(D)(T , SE) is really of a
“scalar” nature: it consists of elements [X ] where the operator X : H → H2(E) has rangecontained in the constant functions E .
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 6 / 18
![Page 16: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/16.jpg)
Results of Carlson and Clark
The unilateral shift operatorSE : H2(E)→ H2(E)
is defined as(SE f )(z) = zf (z)
for every f ∈ H2(E).
Theorem (Carlson-Clark 1995)
Let (H,T ) be a Hilbert module. Then, an operator X : H → E gives rise to an element[X ] ∈ Ext1A(D)(T , SE) if and only if there exists a constant c > 0 such that
∞∑n=0
‖XT nh‖2 ≤ c‖h‖2
for every h ∈ H. Moreover, for every [X ] ∈ Ext1A(D)(T , SE) there exists an operatorY : H → E with the property that [X ] = [Y ].
We bring the reader’s attention to the fact that the group Ext1A(D)(T , SE) is really of a
“scalar” nature: it consists of elements [X ] where the operator X : H → H2(E) has rangecontained in the constant functions E .
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 6 / 18
![Page 17: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/17.jpg)
Projective modules in a smaller category
Theorem (Ferguson 1997)
Let T ∈ B(H) be similar to a contraction. The following statements are equivalent:
(i) Ext1A(D)(T , SE) = 0 for some separable Hilbert space E(ii) the Hilbert module (H,T ) is projective in the category of Hilbert modules similar to
a contractive one
(iii) the operator T is similar to an isometry.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 7 / 18
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Projective modules in a smaller category
Theorem (Ferguson 1997)
Let T ∈ B(H) be similar to a contraction. The following statements are equivalent:
(i) Ext1A(D)(T , SE) = 0 for some separable Hilbert space E
(ii) the Hilbert module (H,T ) is projective in the category of Hilbert modules similar toa contractive one
(iii) the operator T is similar to an isometry.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 7 / 18
![Page 19: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/19.jpg)
Projective modules in a smaller category
Theorem (Ferguson 1997)
Let T ∈ B(H) be similar to a contraction. The following statements are equivalent:
(i) Ext1A(D)(T , SE) = 0 for some separable Hilbert space E(ii) the Hilbert module (H,T ) is projective in the category of Hilbert modules similar to
a contractive one
(iii) the operator T is similar to an isometry.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 7 / 18
![Page 20: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/20.jpg)
Projective modules in a smaller category
Theorem (Ferguson 1997)
Let T ∈ B(H) be similar to a contraction. The following statements are equivalent:
(i) Ext1A(D)(T , SE) = 0 for some separable Hilbert space E(ii) the Hilbert module (H,T ) is projective in the category of Hilbert modules similar to
a contractive one
(iii) the operator T is similar to an isometry.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 7 / 18
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Only known example
Theorem (Carlson-Clark-Foias-Williams 1994)
If T ∈ B(H) is similar to a unitary operator, then the Hilbert module (H,T ) is projective.
Projective Hilbert modules over A(D) are still quite mysterious. In fact, as things standcurrently, unitary modules are the only known instance of such objects.On the other hand, by the result of Ferguson, all projective modules which are similar toa contractive one must in fact be similar to an isometric module.In view of the classical Wold-von Neumann decomposition of an isometry, we see that thequest to identify the contractive projective Hilbert modules over the disc algebra isreduced to the following question:
Question Are unilateral shifts projective?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 8 / 18
![Page 22: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/22.jpg)
Only known example
Theorem (Carlson-Clark-Foias-Williams 1994)
If T ∈ B(H) is similar to a unitary operator, then the Hilbert module (H,T ) is projective.
Projective Hilbert modules over A(D) are still quite mysterious. In fact, as things standcurrently, unitary modules are the only known instance of such objects.
On the other hand, by the result of Ferguson, all projective modules which are similar toa contractive one must in fact be similar to an isometric module.In view of the classical Wold-von Neumann decomposition of an isometry, we see that thequest to identify the contractive projective Hilbert modules over the disc algebra isreduced to the following question:
Question Are unilateral shifts projective?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 8 / 18
![Page 23: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/23.jpg)
Only known example
Theorem (Carlson-Clark-Foias-Williams 1994)
If T ∈ B(H) is similar to a unitary operator, then the Hilbert module (H,T ) is projective.
Projective Hilbert modules over A(D) are still quite mysterious. In fact, as things standcurrently, unitary modules are the only known instance of such objects.On the other hand, by the result of Ferguson, all projective modules which are similar toa contractive one must in fact be similar to an isometric module.
In view of the classical Wold-von Neumann decomposition of an isometry, we see that thequest to identify the contractive projective Hilbert modules over the disc algebra isreduced to the following question:
Question Are unilateral shifts projective?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 8 / 18
![Page 24: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/24.jpg)
Only known example
Theorem (Carlson-Clark-Foias-Williams 1994)
If T ∈ B(H) is similar to a unitary operator, then the Hilbert module (H,T ) is projective.
Projective Hilbert modules over A(D) are still quite mysterious. In fact, as things standcurrently, unitary modules are the only known instance of such objects.On the other hand, by the result of Ferguson, all projective modules which are similar toa contractive one must in fact be similar to an isometric module.In view of the classical Wold-von Neumann decomposition of an isometry, we see that thequest to identify the contractive projective Hilbert modules over the disc algebra isreduced to the following question:
Question Are unilateral shifts projective?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 8 / 18
![Page 25: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/25.jpg)
Only known example
Theorem (Carlson-Clark-Foias-Williams 1994)
If T ∈ B(H) is similar to a unitary operator, then the Hilbert module (H,T ) is projective.
Projective Hilbert modules over A(D) are still quite mysterious. In fact, as things standcurrently, unitary modules are the only known instance of such objects.On the other hand, by the result of Ferguson, all projective modules which are similar toa contractive one must in fact be similar to an isometric module.In view of the classical Wold-von Neumann decomposition of an isometry, we see that thequest to identify the contractive projective Hilbert modules over the disc algebra isreduced to the following question:
Question Are unilateral shifts projective?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 8 / 18
![Page 26: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/26.jpg)
Pisier says no!
A consequence of Pisier’s famous counter-example to the Halmos conjecture is that theanswer is negative in the case of infinite multiplicity.
Indeed, recall that he constructed an operator-valued Hankel matrix X : H2(E)→ H2(E)with the property that
R(X ) =
(S∗E X0 SE
)is polynomially bounded but not similar to a contraction (here E is infinite dimensional).In particular, R(X ) is not similar to S∗E ⊕ SE and [X ] is a non-trivial element ofExt1A(D)(SE , S∗E ).Whether or not things are different for finite multiplicities is still an open problem, and isthe driving force behind our results.The difficulty in attacking the main question is two-fold: first we need to exhibit anelement [X ] ∈ Ext1A(D)(T ,S∗E ), and then we need to check whether it is trivial or not.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 9 / 18
![Page 27: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/27.jpg)
Pisier says no!
A consequence of Pisier’s famous counter-example to the Halmos conjecture is that theanswer is negative in the case of infinite multiplicity.Indeed, recall that he constructed an operator-valued Hankel matrix X : H2(E)→ H2(E)with the property that
R(X ) =
(S∗E X0 SE
)is polynomially bounded but not similar to a contraction (here E is infinite dimensional).
In particular, R(X ) is not similar to S∗E ⊕ SE and [X ] is a non-trivial element ofExt1A(D)(SE , S∗E ).Whether or not things are different for finite multiplicities is still an open problem, and isthe driving force behind our results.The difficulty in attacking the main question is two-fold: first we need to exhibit anelement [X ] ∈ Ext1A(D)(T ,S∗E ), and then we need to check whether it is trivial or not.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 9 / 18
![Page 28: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/28.jpg)
Pisier says no!
A consequence of Pisier’s famous counter-example to the Halmos conjecture is that theanswer is negative in the case of infinite multiplicity.Indeed, recall that he constructed an operator-valued Hankel matrix X : H2(E)→ H2(E)with the property that
R(X ) =
(S∗E X0 SE
)is polynomially bounded but not similar to a contraction (here E is infinite dimensional).In particular, R(X ) is not similar to S∗E ⊕ SE and [X ] is a non-trivial element ofExt1A(D)(SE , S∗E ).
Whether or not things are different for finite multiplicities is still an open problem, and isthe driving force behind our results.The difficulty in attacking the main question is two-fold: first we need to exhibit anelement [X ] ∈ Ext1A(D)(T ,S∗E ), and then we need to check whether it is trivial or not.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 9 / 18
![Page 29: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/29.jpg)
Pisier says no!
A consequence of Pisier’s famous counter-example to the Halmos conjecture is that theanswer is negative in the case of infinite multiplicity.Indeed, recall that he constructed an operator-valued Hankel matrix X : H2(E)→ H2(E)with the property that
R(X ) =
(S∗E X0 SE
)is polynomially bounded but not similar to a contraction (here E is infinite dimensional).In particular, R(X ) is not similar to S∗E ⊕ SE and [X ] is a non-trivial element ofExt1A(D)(SE , S∗E ).Whether or not things are different for finite multiplicities is still an open problem, and isthe driving force behind our results.
The difficulty in attacking the main question is two-fold: first we need to exhibit anelement [X ] ∈ Ext1A(D)(T ,S∗E ), and then we need to check whether it is trivial or not.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 9 / 18
![Page 30: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/30.jpg)
Pisier says no!
A consequence of Pisier’s famous counter-example to the Halmos conjecture is that theanswer is negative in the case of infinite multiplicity.Indeed, recall that he constructed an operator-valued Hankel matrix X : H2(E)→ H2(E)with the property that
R(X ) =
(S∗E X0 SE
)is polynomially bounded but not similar to a contraction (here E is infinite dimensional).In particular, R(X ) is not similar to S∗E ⊕ SE and [X ] is a non-trivial element ofExt1A(D)(SE , S∗E ).Whether or not things are different for finite multiplicities is still an open problem, and isthe driving force behind our results.The difficulty in attacking the main question is two-fold: first we need to exhibit anelement [X ] ∈ Ext1A(D)(T ,S∗E ), and then we need to check whether it is trivial or not.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 9 / 18
![Page 31: The unilateral shift as a Hilbert module over the disc algebra](https://reader031.vdocuments.mx/reader031/viewer/2022012508/618556ee855c130cf303d9a7/html5/thumbnails/31.jpg)
How to find elements of the extension group
We introduce a special class of operators X : H2 → H1 on which we will focus.
Lemma
Let (H1,T1) and (H2,T2) be Hilbert modules. Let X : H2 → H1 be a bounded operatorsuch that TN
1 XTN2 = 0 for some integer N ≥ 0. Then, the operator
R : H1⊕H2 → H1⊕H2 defined as
R =
(T1 X0 T2
)is polynomially bounded.
Note that if T1 = S∗E , then the condition S∗NE X = 0 really says that the range of theoperator X : H → H2(E) is contained in the polynomials of degree at most N − 1.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 10 / 18
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How to find elements of the extension group
We introduce a special class of operators X : H2 → H1 on which we will focus.
Lemma
Let (H1,T1) and (H2,T2) be Hilbert modules. Let X : H2 → H1 be a bounded operatorsuch that TN
1 XTN2 = 0 for some integer N ≥ 0. Then, the operator
R : H1⊕H2 → H1⊕H2 defined as
R =
(T1 X0 T2
)is polynomially bounded.
Note that if T1 = S∗E , then the condition S∗NE X = 0 really says that the range of theoperator X : H → H2(E) is contained in the polynomials of degree at most N − 1.
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How to find elements of the extension group
We introduce a special class of operators X : H2 → H1 on which we will focus.
Lemma
Let (H1,T1) and (H2,T2) be Hilbert modules. Let X : H2 → H1 be a bounded operatorsuch that TN
1 XTN2 = 0 for some integer N ≥ 0. Then, the operator
R : H1⊕H2 → H1⊕H2 defined as
R =
(T1 X0 T2
)is polynomially bounded.
Note that if T1 = S∗E , then the condition S∗NE X = 0 really says that the range of theoperator X : H → H2(E) is contained in the polynomials of degree at most N − 1.
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Definition of the polynomial subgroup
We can now define the object appearing in our main result.
Definition
Let E be a separable Hilbert space. Given two Hilbert modules (H2(E),T1) and (H,T2),we define the polynomial subgroup Ext1poly(T2,T1) of Ext1A(D)(T2,T1) to be the subgroup
of elements [X ] such that S∗NE XTN2 = 0 for some integer N ≥ 0.
We are primarily interested in the case of T1 = SE or T1 = S∗E .Now, how can we tell when such operators satisfy [X ] = 0 in Ext1A(D)(T ,S∗E )?
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Definition of the polynomial subgroup
We can now define the object appearing in our main result.
Definition
Let E be a separable Hilbert space. Given two Hilbert modules (H2(E),T1) and (H,T2),we define the polynomial subgroup Ext1poly(T2,T1) of Ext1A(D)(T2,T1) to be the subgroup
of elements [X ] such that S∗NE XTN2 = 0 for some integer N ≥ 0.
We are primarily interested in the case of T1 = SE or T1 = S∗E .
Now, how can we tell when such operators satisfy [X ] = 0 in Ext1A(D)(T ,S∗E )?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 11 / 18
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Definition of the polynomial subgroup
We can now define the object appearing in our main result.
Definition
Let E be a separable Hilbert space. Given two Hilbert modules (H2(E),T1) and (H,T2),we define the polynomial subgroup Ext1poly(T2,T1) of Ext1A(D)(T2,T1) to be the subgroup
of elements [X ] such that S∗NE XTN2 = 0 for some integer N ≥ 0.
We are primarily interested in the case of T1 = SE or T1 = S∗E .Now, how can we tell when such operators satisfy [X ] = 0 in Ext1A(D)(T ,S∗E )?
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 11 / 18
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Characterization
Definition
Let (H,T ) be a Hilbert module and let E be a separable Hilbert space. We denote byZE(T ) the subspace of B(H, E) consisting of the operators X ∈ B(H, E) with theproperty that there exists a constant cX > 0 such that
∞∑n=0
‖XT nh‖2 ≤ cX‖h‖2
for every h ∈ H.
By the results of Carlson and Clark, we see that the set ZE(T ) consists exactly of thoseoperators X : H → E which give rise to an element [X ] ∈ Ext1A(D)(T , SE).
Theorem (C., 2013)
Let SE : H2(E)→ H2(E) be the unilateral shift and let (H,T ) be a Hilbert module. Then
B(H, E)T + ZE(T ) = B(H, E)
if and only ifExt1poly(T ,S∗E ) = 0.
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Characterization
Definition
Let (H,T ) be a Hilbert module and let E be a separable Hilbert space. We denote byZE(T ) the subspace of B(H, E) consisting of the operators X ∈ B(H, E) with theproperty that there exists a constant cX > 0 such that
∞∑n=0
‖XT nh‖2 ≤ cX‖h‖2
for every h ∈ H.
By the results of Carlson and Clark, we see that the set ZE(T ) consists exactly of thoseoperators X : H → E which give rise to an element [X ] ∈ Ext1A(D)(T , SE).
Theorem (C., 2013)
Let SE : H2(E)→ H2(E) be the unilateral shift and let (H,T ) be a Hilbert module. Then
B(H, E)T + ZE(T ) = B(H, E)
if and only ifExt1poly(T ,S∗E ) = 0.
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Characterization
Definition
Let (H,T ) be a Hilbert module and let E be a separable Hilbert space. We denote byZE(T ) the subspace of B(H, E) consisting of the operators X ∈ B(H, E) with theproperty that there exists a constant cX > 0 such that
∞∑n=0
‖XT nh‖2 ≤ cX‖h‖2
for every h ∈ H.
By the results of Carlson and Clark, we see that the set ZE(T ) consists exactly of thoseoperators X : H → E which give rise to an element [X ] ∈ Ext1A(D)(T , SE).
Theorem (C., 2013)
Let SE : H2(E)→ H2(E) be the unilateral shift and let (H,T ) be a Hilbert module. Then
B(H, E)T + ZE(T ) = B(H, E)
if and only ifExt1poly(T ,S∗E ) = 0.
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Functional model
The goal now is to show that Ext1poly(T , S∗E ) = 0 whenever T is a contraction.
Theorem (Sz.-Nagy–Foias)
Let T ∈ B(H) be a completely non-unitary contraction. Then, there exists a contractiveholomorphic function Θ ∈ H∞(B(E , E∗)) with the property that T is unitarily equivalentto S(Θ).
The ability to work on a function space allows us to obtain the following crucial fact.
Theorem (C., 2013)
Let F ,F∗, E be separable Hilbert spaces. Let Θ ∈ H∞(B(F ,F∗)) be a contractiveholomorphic function. Then,
B(H(Θ), E) = B(H(Θ), E)S(Θ)∗ + ZE(S(Θ)∗).
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Functional model
The goal now is to show that Ext1poly(T , S∗E ) = 0 whenever T is a contraction.
Theorem (Sz.-Nagy–Foias)
Let T ∈ B(H) be a completely non-unitary contraction. Then, there exists a contractiveholomorphic function Θ ∈ H∞(B(E , E∗)) with the property that T is unitarily equivalentto S(Θ).
The ability to work on a function space allows us to obtain the following crucial fact.
Theorem (C., 2013)
Let F ,F∗, E be separable Hilbert spaces. Let Θ ∈ H∞(B(F ,F∗)) be a contractiveholomorphic function. Then,
B(H(Θ), E) = B(H(Θ), E)S(Θ)∗ + ZE(S(Θ)∗).
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Functional model
The goal now is to show that Ext1poly(T , S∗E ) = 0 whenever T is a contraction.
Theorem (Sz.-Nagy–Foias)
Let T ∈ B(H) be a completely non-unitary contraction. Then, there exists a contractiveholomorphic function Θ ∈ H∞(B(E , E∗)) with the property that T is unitarily equivalentto S(Θ).
The ability to work on a function space allows us to obtain the following crucial fact.
Theorem (C., 2013)
Let F ,F∗, E be separable Hilbert spaces. Let Θ ∈ H∞(B(F ,F∗)) be a contractiveholomorphic function. Then,
B(H(Θ), E) = B(H(Θ), E)S(Θ)∗ + ZE(S(Θ)∗).
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Idea behind the proof
Focusing on the simple case where E = C and S(Θ) = SC, we need to establish
H2 = zH2 + H∞.
This is elementary: for every f ∈ H2 we have
f (z) = z
(f − f (0)
z
)+ f (0).
The general case is based on this idea.
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Idea behind the proof
Focusing on the simple case where E = C and S(Θ) = SC, we need to establish
H2 = zH2 + H∞.
This is elementary: for every f ∈ H2 we have
f (z) = z
(f − f (0)
z
)+ f (0).
The general case is based on this idea.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 14 / 18
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Idea behind the proof
Focusing on the simple case where E = C and S(Θ) = SC, we need to establish
H2 = zH2 + H∞.
This is elementary: for every f ∈ H2 we have
f (z) = z
(f − f (0)
z
)+ f (0).
The general case is based on this idea.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 14 / 18
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Main result
Theorem (C., 2013)
Let E be a separable Hilbert space and let SE : H2(E)→ H2(E) be the unilateral shift.Then, Ext1poly(T , S∗E ) = 0 for every operator T which is similar to a contraction.
This result might be seen as supporting the idea that the shift is projective.However, notice that it holds regardless of multiplicity.
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Main result
Theorem (C., 2013)
Let E be a separable Hilbert space and let SE : H2(E)→ H2(E) be the unilateral shift.Then, Ext1poly(T , S∗E ) = 0 for every operator T which is similar to a contraction.
This result might be seen as supporting the idea that the shift is projective.
However, notice that it holds regardless of multiplicity.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 15 / 18
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Main result
Theorem (C., 2013)
Let E be a separable Hilbert space and let SE : H2(E)→ H2(E) be the unilateral shift.Then, Ext1poly(T , S∗E ) = 0 for every operator T which is similar to a contraction.
This result might be seen as supporting the idea that the shift is projective.However, notice that it holds regardless of multiplicity.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 15 / 18
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Remarks on the main result
The theorem illustrates a clear difference between SE and S∗E on the level of extensiongroups:
Ext1poly(T , S∗E ) = 0 for every contraction T while Ext1A(D)(T , SE) = 0 only whenthe contraction T is similar to an isometry.Note here that
Ext1A(D)(·, SE) = Ext1poly(·,SE).
This is not the case if SE is replaced by S∗E , since
0 = Ext1poly(SE ,S∗E ) 6= Ext1A(D)(SE , S∗E ).
We do not know whether equality holds if we require that the shift be of finite multiplicity.
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Remarks on the main result
The theorem illustrates a clear difference between SE and S∗E on the level of extensiongroups: Ext1poly(T , S∗E ) = 0 for every contraction T while Ext1A(D)(T , SE) = 0 only whenthe contraction T is similar to an isometry.
Note here thatExt1A(D)(·, SE) = Ext1poly(·,SE).
This is not the case if SE is replaced by S∗E , since
0 = Ext1poly(SE ,S∗E ) 6= Ext1A(D)(SE , S∗E ).
We do not know whether equality holds if we require that the shift be of finite multiplicity.
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Remarks on the main result
The theorem illustrates a clear difference between SE and S∗E on the level of extensiongroups: Ext1poly(T , S∗E ) = 0 for every contraction T while Ext1A(D)(T , SE) = 0 only whenthe contraction T is similar to an isometry.Note here that
Ext1A(D)(·, SE) = Ext1poly(·,SE).
This is not the case if SE is replaced by S∗E , since
0 = Ext1poly(SE ,S∗E ) 6= Ext1A(D)(SE ,S∗E ).
We do not know whether equality holds if we require that the shift be of finite multiplicity.
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Remarks on the main result
The theorem illustrates a clear difference between SE and S∗E on the level of extensiongroups: Ext1poly(T , S∗E ) = 0 for every contraction T while Ext1A(D)(T , SE) = 0 only whenthe contraction T is similar to an isometry.Note here that
Ext1A(D)(·, SE) = Ext1poly(·,SE).
This is not the case if SE is replaced by S∗E , since
0 = Ext1poly(SE ,S∗E ) 6= Ext1A(D)(SE , S∗E ).
We do not know whether equality holds if we require that the shift be of finite multiplicity.
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 16 / 18
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Remarks on the main result
The theorem illustrates a clear difference between SE and S∗E on the level of extensiongroups: Ext1poly(T , S∗E ) = 0 for every contraction T while Ext1A(D)(T , SE) = 0 only whenthe contraction T is similar to an isometry.Note here that
Ext1A(D)(·, SE) = Ext1poly(·,SE).
This is not the case if SE is replaced by S∗E , since
0 = Ext1poly(SE ,S∗E ) 6= Ext1A(D)(SE , S∗E ).
We do not know whether equality holds if we require that the shift be of finite multiplicity.
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Concluding remarks
The question of whether or not
Ext1poly(R(X ), S∗C)
vanishes (in the case where R(X ) is not similar to a contraction, of course) remains open.
This is a meaningful question and we hope that our approach may help settle it in thefuture.
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Concluding remarks
The question of whether or not
Ext1poly(R(X ), S∗C)
vanishes (in the case where R(X ) is not similar to a contraction, of course) remains open.This is a meaningful question and we hope that our approach may help settle it in thefuture.
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Thank you!
R. Clouatre (Indiana University) The unilateral shift as a Hilbert module COSy 2013 18 / 18