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∗-K-Operator Frame for Hom∗A(X)

Mohamed Rossafi1,∗, Roumaissae El Jazzar2 and Ali Kacha2
1LaSMA Laboratory Department of Mathematics, Faculty of Sciences Dhar El Mahraz,

University Sidi Mohamed Ben Abdellah, B. P. 1796 Fes Atlas, Morocco
mohamed.rossafi@usmba.ac.ma

2Laboratory of Partial Differential Equations, Spectral Algebra and Geometry Department of Mathematics,
Faculty of Sciences, University Ibn Tofail, Kenitra, Morocco

roumaissae.eljazzar@uit.ac.ma, ali.kacha@yahoo.fr
∗Correspondence: rossafimohamed@gmail.com

Abstract. In this work, we introduce the concept of ∗-K-operator frames in Hilbert pro-C∗-modules,which is a generalization of K-operator frame. We present the analysis operator, the synthesisoperator and the frame operator. We also give some properties and we study the tensor product of
∗-K-operator frame for Hilbert pro-C∗-modules.

1. Introduction
Duffin and Schaeffer introduced the notion of frame in nonharmonic Fourier analysis in 1952 [3].In 1986 the work of Duffin and Schaeffer were reintroduced and developed by Grossman andMeyer [7]. The concept of frame on Hilbert space has already been successfully extended to pro-

C∗-algebras and Hilbert modules. Many properties of frames in Hilbert C∗-modules are valid forframes of multipliers in Hilbert modules over pro-C∗-algebras [9].Operator frames for B(H) is a new notion of frames that Li and Cio introduced in [11] andgeneralized by Rossafi in [16]. In this work we introduce the notion of ∗-K-operator frame for thespace Hom∗A(X) of all adjointable operators on a Hilbert pro-C∗-module for X .This paper is divided into three sections. In section 2 we recall some fundamental definitionsand notations of Hilbert pro-C∗-modules. In section 3 we introduce the ∗-K-operator Frame andwe give some of its properties. Lastly we investigate tensor product of Hilbert pro-C∗-modules, weshow that tensor product of ∗-K-operator frames for Hilbert pro-C∗-modules X and Y, present an
∗-K-operator frames for X ⊗Y, and tensor product of their frame operators is the frame operatorof their tensor product of ∗-K-operator frames.

Received: 18 Nov 2021.
Key words and phrases. frame; ∗-K-operator frame; K-operator frame pro-C∗-algebra; Hilbert pro-C∗-modules; tensorproduct. 1

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 2
2. Preliminaries

The basic information about pro-C∗-algebras can be found in the works [4–6, 8, 12, 14, 15].
C∗-algebra whose topology is induced by a family of continuous C∗-seminorms instead of a

C∗-norm is called pro-C∗-algebra. Hilbert pro-C∗-modules are generalizations of Hilbert spacesby allowing the inner product to take values in a pro-C∗-algebra rather than in the field of complexnumbers.Pro-C∗-algebra is defined as a complete Hausdorff complex topological ∗-algebra A whosetopology is determined by its continuous C∗-seminorms in the sens that a net {aα} converges to 0if and only if p(aα) converges to 0 for all continuous C∗-seminorm p on A [8, 10, 15], and we have:1) p(ab) ≤ p(a)p(b)2) p(a∗a) = p(a)2
for all a,b ∈AIf the topology of pro-C∗-algebra is determined by only countably many C∗-seminorms, then it iscalled a σ-C∗-algebra.We denote by sp(a) the spectrum of a such that: sp(a) = {λ ∈C : λ1A −a is not invertible } forall a ∈A. Where A is unital pro-C∗-algebra with unite 1A.The set of all continuous C∗-seminorms on A is denoted by S(A). If A+ denotes the set of allpositive elements of A, then A+ is a closed convex C∗-seminorms on A.
Example 2.1. Every C∗-algebra is a pro-C∗-algebra.
Proposition 2.2. [8] Let A be a unital pro-C∗-algebra with an identity 1A. Then for any p ∈ S(A),
we have:

(1) p(a) = p(a∗) for all a ∈ A(2) p (1A) = 1(3) If a,b ∈A+ and a ≤ b, then p(a) ≤ p(b)(4) If 1A ≤ b, then b is invertible and b−1 ≤ 1A(5) If a,b ∈A+ are invertible and 0 ≤ a ≤ b, then 0 ≤ b−1 ≤ a−1(6) If a,b,c ∈A and a ≤ b then c∗ac ≤ c∗bc(7) If a,b ∈A+ and a2 ≤ b2, then 0 ≤ a ≤ b
Definition 2.3. [15] A pre-Hilbert module over pro-C∗-algebra A, is a complex vector space Ewhich is also a left A-module compatible with the complex algebra structure, equipped with an
A-valued inner product 〈., .〉 E×E →A which is C-and A-linear in its first variable and satisfiesthe following conditions:

1) 〈ξ,η〉∗ = 〈η,ξ〉 for every ξ,η ∈ E2) 〈ξ,ξ〉≥ 0 for every ξ ∈ E

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 3
3) 〈ξ,ξ〉 = 0 if and only if ξ = 0

for every ξ,η ∈ E. We say E is a Hilbert A-module (or Hilbert pro-C∗-module over A ). If E iscomplete with respect to the topology determined by the family of seminorms
p̄E(ξ) =

√
p(〈ξ,ξ〉) ξ ∈ E,p ∈ S(A)

Let A be a pro-C∗-algebra and let X and Y be Hilbert A-modules and assume that I and J becountable index sets. A bounded A-module map from X to Y is called an operators from X to Y.We denote the set of all operator from X to Y by HomA(X ,Y).
Definition 2.4. [1] An A-module map T : X −→Y is adjointable if there is a map T∗ : Y −→Xsuch that 〈Tξ,η〉 = 〈ξ,T∗η〉 for all ξ ∈X ,η ∈Y, and is called bounded if for all p ∈ S(A), thereis Mp > 0 such that p̄Y(Tξ) ≤ Mpp̄X (ξ) for all ξ ∈X .We denote by Hom∗A(X ,Y), the set of all adjointable operator from X to Y and Hom∗A(X) =
Hom∗A(X ,X)

Definition 2.5. [1] Let A be a pro-C∗-algebra and X ,Y be two Hilbert A-modules. The operator
T : X →Y is called uniformly bounded below, if there exists C > 0 such that for each p ∈ S(A),

p̄Y(Tξ) 6 Cp̄X (ξ), for all ξ ∈X
and is called uniformly bounded above if there exists C′ > 0 such that for each p ∈ S(A),

p̄Y(Tξ) > C
′p̄X (ξ), for all ξ ∈X

‖T‖∞ = inf{M : M is an upper bound for T}
p̂Y(T ) = sup{p̄Y(T (x)) : ξ ∈X , p̄X (ξ) 6 1}

It’s clear to see that, p̂(T ) 6 ‖T‖∞ for all p ∈ S(A).
Proposition 2.6. [2]. Let X be a Hilbert module over pro-C∗-algebra A and T be an invertible
element in Hom∗A(X) such that both are uniformly bounded. Then for each ξ ∈X ,∥∥T−1∥∥−2∞ 〈ξ,ξ〉≤ 〈Tξ,Tξ〉≤ ‖T‖2∞〈ξ,ξ〉.

3. ∗-K-operator frame for Hom∗A(X)
We begin this section with the definition of a K-operator frame.

Definition 3.1. Let {Ti}i∈I be a family of adjointable operators on a Hilbert A-module X over aunital pro-C∗-algebra, and let K ∈ Hom∗A(X). {Ti}i∈I is called a K-operator frame for Hom∗A(X),if there exist two positive constants A,B > 0 such that
A〈K∗ξ,K∗ξ〉≤

∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉,∀ξ ∈X . (3.1)

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 4
The numbers A and B are called lower and upper bound of the K-operator frame, respectively. If

A〈K∗ξ,K∗ξ〉 =
∑
i∈I
〈Tiξ,Tiξ〉,

the K-operator frame is an A-tight. If A = 1, it is called a normalized tight K-operator frame or aParseval K-operator frame.
We will now move to define the ∗-K-operator frame for Hom∗A(X).

Definition 3.2. Let {Ti}i∈I be a family of adjointable operators on a Hilbert A-module X overa unital pro-C∗-algebra, and let K ∈ Hom∗A(X). {Ti}i∈I is called a ∗-K-operator frame for
Hom∗A(H), if there exists two nonzero elements A and B in A such that

A〈K∗ξ,K∗ξ〉A∗ ≤
∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉B∗,∀ξ ∈X . (3.2)

The elements A and B are called lower and upper bounds of the ∗-K-operator frame, respectively.If
A〈K∗ξ,K∗ξ〉∗ =

∑
i∈I
〈Tiξ,Tiξ〉,

the ∗-K-operator frame is an A-tight. If A = 1, it is called a normalized tight ∗-K-operator frameor a Parseval ∗-K-operator frame.
Example 3.3. Let l∞ be the set of all bounded complex-valued sequences. For any u = {uj}j∈N,v =
{vj}j∈N ∈ l∞, we define

uv = {ujvj}j∈N,u∗ = {ūj}j∈N,‖u‖ = sup
j∈N
|uj|.

Then A = {l∞,‖.‖} is a C∗-algebra. Then A is pro-C∗-algebra.Let X = C0 be the set of all null sequences. For any u,v ∈X we define
〈u,v〉 = uv∗ = {ujūj}j∈N.

Therefore X is a Hilbert A-module.Define fj = {f ji }i∈N∗ by f ji = 12 + 1i if i = j and f ji = 0 if i 6= j ∀j ∈N∗.Now define the adjointable operator Tj : X →X , Tj{(ξi )i} = (ξif ji )i .Then for every x ∈X we have∑
j∈N
〈Tjξ,Tjξ〉 = {

1

2
+

1

i
}i∈N∗〈ξ,ξ〉{

1

2
+

1

i
}i∈N∗.

So {Tj}j is a {12 + 1i }i∈N∗-tight ∗-operator frame.Let K : H→H defined by Kξ = {ξi
i
}i∈N∗.Then for every ξ ∈X we have

〈K∗ξ,K∗ξ〉≤
∑
j∈N
〈Tjξ,Tjξ〉 = {

1

2
+

1

i
}i∈N∗〈ξ,ξ〉{

1

2
+

1

i
}i∈N∗.

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 5
This shows that {Tj}j∈N is an ∗-K-operator frame with bounds 1,{12 + 1i }i∈N∗.
Remark 3.4. (1) Every ∗-operator frame for Hom∗A(X) is an ∗-K-operator frame, for any K ∈

Hom∗A(X): K 6= 0.(2) If K ∈ Hom∗A(X) is a surjective operator, then every ∗-K-operator frame for Hom∗A(X) isan ∗-operator frame.
Example 3.5. Let X be a finitely or countably generated Hilbert A-module. Hom∗A(X). Let
K ∈ Hom∗A(X) an invertible element such that both are uniformly bounded and K 6= 0. Let
{Ti}i∈I be an ∗-operator frame for X with bounds A and B, respectively. We have

A〈ξ,ξ〉A∗ ≤
∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉B∗,∀ξ ∈X .

Or
〈K∗ξ,K∗ξ〉≤ ‖K‖2∞〈ξ,ξ〉,∀ξ ∈X .Then

‖K‖−1∞ A〈K
∗ξ,K∗ξ〉(‖K‖−1∞ A)

∗ ≤
∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉B∗,∀ξ ∈X .

So {Ti}i∈I is ∗-K-operator frame for X with bounds ‖K‖−1∞ A and B, respectively.
In what follows, we introduce the analysis, the synthesis and the frame operator. We alsoestablish some properties.Let {Ti}i∈I be an ∗-K-operator frame for Hom∗A(X). Define an operator R : X → l2(X) by

Rξ = {Tiξ}i∈I,∀ξ ∈X , then R is called the analysis operator. The adjoint of the analysis operator
R, R∗ : l2(X) →X is given by R∗({ξi}i ) = ∑i∈I T∗i ξi,∀{ξi}i ∈ l2(X). The operator R∗ is calledthe synthesis operator. By composing R and R∗, the frame operator S : X → X is given by
Sξ = R∗Rξ =

∑
i∈I T

∗
i Tiξ.Note that S need not be invertible in general. But under some condition S will be invertible.

Theorem 3.6. Let K be a surjective operators in Hom∗A(X). If {Ti}i∈I is an ∗-K-operator frame
for Hom∗A(X), then the frame operator S is positive, invertible and adjointable. In addition we
have the reconstruction formula, ξ =

∑
i∈I T

∗
i TiS

−1ξ, ∀ξ ∈X .

Proof. We start by showing that, S is a self-adjoint operator. By definition we have ∀ξ,η ∈H
〈Sξ,η〉 =

〈∑
i∈I

T∗i Tiξ,η

〉
=
∑
i∈I
〈T∗i Tiξ,η〉

=
∑
i∈I
〈ξ,T∗i Tiη〉

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 6
=

〈
ξ,
∑
i∈I

T∗i Tiη

〉
= 〈ξ,Sη〉.

Then S is a selfadjoint.The operator S is clearly positive.By (2) in Remark 3.4 {Ti}i∈I is an ∗-operator frame for Hom∗A(X).The definition of an ∗-operator gives
A1〈ξ,ξ〉A∗1 ≤

∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉B∗.

Thus by the definition of norm in l2(X)
p̄X (Rξ)

2 = p̄X (
∑
i∈I
〈Tiξ,Tiξ〉) ≤ p̄X (B)2p(〈ξ,ξ〉),∀ξ ∈X . (3.3)

Therefore R is well defined and p̄X (R) ≤ p̄X (B). It’s clear that R is a linear A-module map. Wewill then show that the range of R is closed. Let {Rξn}n∈N be a sequence in the range of R suchthat limn→∞Rξn = η. For n,m ∈N, we have
p(A〈ξn −ξm,ξn −ξm〉A∗) ≤ p(〈R(ξn −ξm),R(ξn −ξm)〉) = p̄X (R(ξn −ξm))2.

Seeing that {Rξn}n∈N is Cauchy sequence in X , then
p(A〈ξn −ξm,ξn −ξm〉A∗) → 0, as n,m →∞.Note that for n,m ∈N,

p(〈ξn −ξm,ξn −ξm〉) = p(A−1A〈ξn −ξm,ξn −ξm〉A∗(A∗)−1)

≤ p(A−1)2p(A〈ξn −ξm,ξn −ξm〉A∗).

Thus the sequence {ξn}n∈N is Cauchy and hence there exists ξ ∈X such that ξn → ξ as n →∞.Again by (3.3), we have
p̄X (R(ξn −ξm))2 ≤ p̄X (B)2p(〈ξn −ξ,ξn −ξ〉).

Thus p(Rξn − Rξ) → 0 as n → ∞ implies that Rξ = η. It is therefore concluded that therange of R is closed. We now show that R is injective. Let ξ ∈ X and Rξ = 0. Note that
A〈ξ,ξ〉A∗ ≤〈Rξ,Rξ〉 then 〈ξ,ξ〉 = 0 so ξ = 0 i.e. R is injective.For ξ ∈X and {ξi}i∈I ∈ l2(X) we have

〈Rξ,{ξi}i∈I〉 = 〈{Tiξ}i∈I,{ξi}i∈I〉 =
∑
i∈I
〈Tiξ,ξi〉 =

∑
i∈I
〈ξ,T∗i ξi〉 = 〈ξ,

∑
i∈I

T∗i ξi〉.

Then R∗({ξi}i∈I) = ∑i∈I T∗i ξi . Since R is injective, then the operator R∗ has closed range and
X = range(R∗), therefore S = R∗R is invertible

�

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 7
Let K ∈ Hom∗A(X), in the following theorem we constructed an ∗-K-operator frame by using an

∗-operator frame.
Theorem 3.7. Let {Ti}i∈I be an ∗-K-operator frame in X with bounds A, B and K ∈ Hom∗A(X) be
an invertible element such that both are uniformly bounded. Then {TiK}i∈I is an ∗-K∗-operator
frame in X with bounds A, ‖K‖∞B. The frame operator of {TiK}i∈I is S

′
= K∗SK, where S is

the frame operator of {Ti}i∈I.

Proof. From
A〈ξ,ξ〉A∗ ≤

∑
i∈I
〈Tiξ,Tiξ〉≤ B〈ξ,ξ〉B∗,∀ξ ∈X .

We get for all ξ ∈X ,
A〈Kξ,Kξ〉A∗ ≤

∑
i∈I
〈TiKξ,TiKξ〉≤ B〈Kξ,Kξ〉B∗ ≤‖K‖∞B〈ξ,ξ〉(‖K‖∞B)∗.

Then {TiK}i∈I is an ∗-K∗-operator frame in X with bounds A, ‖K‖∞B.By definition of S,we have SKξ = ∑i∈I T∗i TiKξ. Then
K∗SK = K∗

∑
i∈I

T∗i TiKξ =
∑
i∈I

K∗T∗i TiKξ.

Hence S′ = K∗SK. �
Corollary 3.8. Let K ∈ Hom∗A(X) and {Ti}i∈I be an ∗-operator frame. Then {TiS

−1K}i∈I is an
∗-K∗-operator frame, where S is the frame operator of {Ti}i∈I.

Proof. Result of the Theorem 3.7 for the ∗-operator frame {TiS−1}i∈I. �
4. Tensor Product

We denote by A⊗B, the minimal or injective tensor product of the pro-C∗-algebras A and B, itis the completion of the algebraic tensor product A⊗alg B with respect to the topology determinedby a family of C∗-seminorms. Suppose that X is a Hilbert module over a pro-C∗-algebra A and
Y is a Hilbert module over a pro-C∗-algebra B. The algebraic tensor product X ⊗alg Y of X and
Y is a pre-Hilbert A⊗B-module with the action of A⊗B on X ⊗alg Y defined by

(ξ⊗η)(a⊗b) = ξa⊗ηb for all ξ ∈X ,η ∈Y,a ∈A and b ∈B
and the inner product

〈·, ·〉 :
(
X ⊗alg Y)×(X ⊗alg Y) →A⊗alg B. defined by
〈ξ1 ⊗η1,ξ2 ⊗η2〉 = 〈ξ1,ξ2〉⊗〈η1,η2〉

And we know that for z = ∑ni=1ξi⊗ηi in X⊗algY we have 〈z,z〉A⊗B = ∑i,j〈ξi,ξj〉A⊗〈ηi,ηj〉B ≥ 0and 〈z,z〉A⊗B = 0 iff z = 0.

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 8
The external tensor product of X and Y is the Hilbert module X ⊗Y over A⊗B obtained by thecompletion of the pre-Hilbert A⊗B-module X ⊗alg Y.If P ∈ M(X) and Q ∈ M(Y) then there is a unique adjointable module morphism P ⊗ Q :
A⊗B →X ⊗Y such that (P ⊗Q)(a⊗b) = P (a) ⊗Q(b) and (P ⊗Q)∗(a⊗b) = P∗(a) ⊗Q∗(b)for all a ∈ A and for all b ∈ B (see, for example, cite The minimal or injective tensor product ofthe pro-C∗-algebras A and B, denoted by A⊗B, is the completion of the algebraic tensor product
A⊗alg B with respect to the topology determined by a family of C∗-seminorms. Suppose that Xis a Hilbert module over a pro-C∗-algebra A and Y is a Hilbert module over a pro-C∗-algebra B.The algebraic tensor product X ⊗alg Y of X and Y is a pre-Hilbert A⊗B-module with the actionof A⊗B on X ⊗alg Y defined by

(ξ⊗η)(a⊗b) = ξa⊗ηb for all ξ ∈X ,η ∈Y,a ∈A and b ∈B
and the inner product

〈·, ·〉 :
(
X ⊗alg Y)×(X ⊗alg Y) →A⊗alg B. defined by
〈ξ1 ⊗η1,ξ2 ⊗η2〉 = 〈ξ1,ξ2〉⊗〈η1,η2〉

We also know that for z = ∑ni=1ξi⊗ηi in X⊗algY we have 〈z,z〉A⊗B = ∑i,j〈ξi,ξj〉A⊗〈ηi,ηj〉B ≥ 0and 〈z,z〉A⊗B = 0 iff z = 0.The external tensor product of X and Y is the Hilbert module X ⊗Y over A⊗B obtained by thecompletion of the pre-Hilbert A⊗B-module X ⊗alg Y.If P ∈ M(X) and Q ∈ M(Y) then there is a unique adjointable module morphism P ⊗ Q :
A⊗B →X ⊗Y such that (P ⊗Q)(a⊗b) = P (a) ⊗Q(b) and (P ⊗Q)∗(a⊗b) = P∗(a) ⊗Q∗(b)for all a ∈ A and for all b ∈ B (see, for example, [9])Let I and J be countable index sets.
Theorem 4.1. Let X and Y be two Hilbert pro-C∗-modules over unitary pro-C∗-algebras A and
B, respectively. Let {Ti}i∈I ⊂ Hom∗A(X) be an ∗-K-operator frame for X with bounds A and B
and frame operators ST and {Pj}j∈J ⊂ Hom∗B(Y) be an ∗-L-operator frame for K with bounds
C and D and frame operators SL. Then {Ti ⊗ Lj}i∈I,j∈J is an ∗-K⊗L-operator frame for Hibert
A⊗B-module X ⊗Y with frame operator ST ⊗SP and bounds A⊗C and B ⊗D.

Proof. The defintion of ∗-K-operator frame {Ti}i∈I and ∗-L-operator frame {Pj}j∈J gives
A〈K∗ξ,K∗ξ〉AA∗ ≤

∑
i∈I
〈Tiξ,Tiξ〉A ≤ B〈ξ,ξ〉AB∗,∀ξ ∈X .

C〈L∗η,L∗η〉BC∗ ≤
∑
j∈J
〈Pjη,Pjη〉B ≤ D〈η,η〉BD∗,∀η ∈Y.

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Eur. J. Math. Anal. 10.28924/ada/ma.2.4 9
Therefore

(A〈K∗ξ,K∗ξ〉AA∗) ⊗ (C〈L∗η,L∗η〉BC∗)

≤
∑
i∈I
〈Tiξ,Tiξ〉A ⊗

∑
j∈J
〈Pjη,Pjη〉B

≤ (B〈ξ,ξ〉AB∗) ⊗ (D〈η,η〉BD∗),∀ξ ∈X ,∀η ∈Y.Then
(A⊗C)(〈K∗ξ,K∗ξ〉A ⊗〈L∗η,L∗η〉B)(A∗ ⊗C∗)

≤
∑
i∈I,j∈J

〈Tiξ,Tiξ〉A ⊗〈Pjη,Pjη〉B

≤ (B ⊗D)(〈ξ,ξ〉A ⊗〈η,η〉B)(B∗ ⊗D∗),∀ξ ∈X ,∀η ∈Y.Consequently we have
(A⊗C)〈K∗ξ⊗L∗η,K∗ξ⊗L∗η〉A⊗B(A⊗C)∗

≤
∑
i∈I,j∈J

〈Tiξ⊗Pjη,Tiξ⊗Pjη〉A⊗B

≤ (B ⊗D)〈ξ⊗η,ξ⊗η〉A⊗B(B ⊗D)∗,∀ξ ∈X ,∀η ∈Y.

Then for all ξ⊗η in X ⊗Y we have
(A⊗C)〈(K ⊗L)∗(ξ⊗η), (K ⊗L)∗(ξ⊗η)〉A⊗B(A⊗C)∗

≤
∑
i∈I,j∈J

〈(Ti ⊗Pj)(ξ⊗η), (Ti ⊗Pj)(ξ⊗η)〉A⊗B

≤ (B ⊗D)〈ξ⊗η,ξ⊗η〉A⊗B(B ⊗D)∗.

The last inequality is true for every finite sum of elements in X ⊗alg Y and then it’s true for all
z ∈X ⊗K. It shows that {Ti ⊗Pj}i∈I,j∈J is an ∗-K ⊗L-operator frame for Hilbert A⊗B-module
X ⊗Y with lower and upper bounds A⊗C and B ⊗D, respectively.By the definition of frame operator ST and SP we have

STξ =
∑
i∈I

T∗i Tiξ,∀ξ ∈X .

SPη =
∑
j∈J

P∗j Pjη,∀η ∈Y.

Therefore
(ST ⊗SP )(ξ⊗η) = STξ⊗SPη

=
∑
i∈I

T∗i Tiξ⊗
∑
j∈J

P∗j Pjη

=
∑
i∈I,j∈J

T∗i Tiξ⊗P
∗
j Pjη

=
∑
i∈I,j∈J

(T∗i ⊗P
∗
j )(Tiξ⊗Pjη)

https://doi.org/10.28924/ada/ma.2.4


Eur. J. Math. Anal. 10.28924/ada/ma.2.4 10
=

∑
i∈I,j∈J

(T∗i ⊗P
∗
j )(Ti ⊗Pj)(ξ⊗η)

=
∑
i∈I,j∈J

(Ti ⊗Pj)∗(Ti ⊗Pj)(ξ⊗η).

Then by the uniqueness of frame operator, the last expression is equal to ST⊗P (ξ⊗η). Consequentlywe have (ST ⊗SP )(ξ⊗η) = ST⊗P (ξ⊗η). The last equality is true for every finite sum of elementsin X ⊗alg Y and then it’s true for all z ∈ X ⊗Y. It follows that (ST ⊗SP )(z) = ST⊗P (z). Thus
ST⊗P = ST ⊗SP . �

References
[1] N. Haddadzadeh, G-frames in Hilbert modules over pro-C*-algebras, Int. J. Ind. Math. 9(4) (2017) 259-267.[2] M. Azhini and N. Haddadzadeh, Fusion frames in Hilbert modules over pro-C∗-algebras, Int. J. Ind. Math. 5(2)(2013) Article ID IJIM-00211.[3] R. J. Duffin and A. C. Schaeffer, A class of nonharmonic fourier series, Trans. Amer. Math. Soc. 72 (1952) 341-366.[4] M. Fragoulopoulou, An introduction to the representation theory of topological ∗-algebras, Schriftenreihe, Univ.Münster, 48 (1988) 1-81.[5] M. Fragoulopoulou, Tensor products of enveloping locally C∗-algebras, Schriftenreihe, Univ. Münster (1997) 1-81.[6] M. Fragoulopoulou, Topological algebras with involution, North Holland, Amsterdam, 2005.[7] A. Grossman, and Y. Meyer, Painless nonorthogonal expansions, J. Math. Phys. 27 (1986) 1271-1283.[8] A. Inoue, Locally C∗-algebra, Mem. Fac. Sci. Kyushu Univ. Ser. A, Math. 25(2) (1972) 197-235.[9] M. Joita, On frames in Hilbert modules over pro-C∗-algebras, Topol. Appl. 156 (2008) 83-92.[10] E. C. Lance, Hilbert C∗-modules, A toolkit for operator algebraists, London Math. Soc. Lecture Note Series 210.Cambridge Univ. Press, Cambridge, 1995.[11] C. Y. Li and H. X. Cao, Operator Frames for B(H), Wavelet Analysis and Applications. Birkhäuser Basel, 2006.67-82.[12] A. Mallios, Topological algebras: Selected Topics, North Holland, Amsterdam, 1986.[13] M. Naroei and A. Nazari, Some properties of –frames in Hilbert modules over pro-C∗-algebras, Sahand Commun.Math. Anal. 16 (2019) 105–117.[14] N. C. Phillips, Inverse limits of C*-algebras, J. Oper. Theory. 19 (1988) 159-195.[15] N. C. Phillips, Representable K-theory for σ -C∗-algebras, K-Theory, 3 (1989) 441-478.[16] M. Rossafi and S. Kabbaj, Operator frame for End∗A(H), J. Linear Topol. Algebra. 8 (2019) 85-95.

https://doi.org/10.28924/ada/ma.2.4

	1. Introduction
	2. Preliminaries
	3. -K-operator frame for HomA(X)
	4. Tensor Product
	References

