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Article

Lp-Mapping Properties of a Class of Spherical Integral Operators

1
School of Basic Sciences and Humanities, German Jordanian University, Amman 11180, Jordan
2
Department of Mathematics, Faculty of Science, Zarqa University, Zarga 13110, Jordan
3
Department of Mathematics, Al Zaytoonah University, Amman 11733, Jordan
4
Nonlinear Dynamics Research Center (NDRC), Ajman University, Ajman 346, United Arab Emirates
*
Author to whom correspondence should be addressed.
Axioms 2023, 12(9), 802; https://doi.org/10.3390/axioms12090802
Submission received: 25 June 2023 / Revised: 12 July 2023 / Accepted: 17 July 2023 / Published: 22 August 2023
(This article belongs to the Special Issue Recent Advances in Functional Analysis and Operator Theory)

Abstract

:
In this paper, we study a class of spherical integral operators I Ω f . We prove an inequality that relates this class of operators with some well-known Marcinkiewicz integral operators by using the classical Hardy inequality. We also attain the boundedness of the operator I Ω f for some 1 < p < 2 whenever Ω belongs to a certain class of Lebesgue spaces. In addition, we introduce a new proof of the optimality condition on Ω in order to obtain the L 2 -boundedness of I Ω . Generally, the purpose of this work is to set up new proofs and extend several known results connected with a class of spherical integral operators.

1. Introduction

For d 2 , let R d be the d-dimensional Euclidean space and let S d 1 denote the unit sphere in R d equipped with the normalized surface measure d σ . Let Ω L 1 ( S d 1 ) be a homogeneous function of degree 0 on R d which satisfies the cancellation property:
S d 1 Ω ( y ) d σ ( y ) = 0 .
For f L p ( R d ) and r > 0 , we define the spherical averages:
A r Ω f ( x ) = S d 1 f ( x r y ) Ω ( y ) d σ ( y ) ,
and the corresponding maximal operator by:
A Ω f ( x ) = sup r > 0 A r Ω f ( x ) .
An application of Minkowski’s inequality for integrals shows that the linear operators A r are bounded on L p ( R d ) with norms less than or equal to | | Ω | | L 1 ( S d 1 ) ; hence, A r f ( x ) is well-defined for almost every x R d whenever f L p ( R d ) .
Observe that when Ω 1 , A r 1 f ( x ) is a constant multiple of the average value of f on the sphere S ( x , r ) . Spherical means are used to reformulate PDE’s in the form of integral equations whose kernels are generalized functions [1]. Moreover, the spherical averages A r 1 play a crucial rule in solving certain types of partial differential equations that have several methods to solve, see [2,3]. For instance, in R 3 , the function:
u ( x , t ) = 1 4 π S 2 f ( x t y ) d σ ( y )
is a solution of the Darboux equation:
Δ x ( u ) ( x , t ) = 2 u t 2 ( x , t ) + 2 t u t ( x , t ) , u ( x , 0 ) = f ( x ) , u t ( x , 0 ) = 0 .
The corresponding maximal function is given by:
A 1 f ( x ) = sup r > 0 A r 1 f ( x ) .
Many authors studied the boundedness issue of the maximal operator A 1 in order to attain the point-wise convergence of the spherical averages. For instance, Stein [4] proved that, for d 3 , the maximal spherical operator is bounded on L p ( R d ) if and only if p > d d 1 . After several years, the two-dimensional case was established independently by Bourgain [5]. We mention here that different techniques were applied to conclude the theorems of Stein and Bourgain and others [6]. For the former, we refer the reader to [7,8], and different proofs for the latter result can be found in [9,10,11].
Chen and Lin [12] introduced the maximal operator:
M Ω ( f ) ( x ) = sup h K | T Ω , h f ( x ) | ,
where K is the closed unit ball of the space L 2 ( R + , d r / r ) and:
T Ω , h f ( x ) = lim ϵ 0 + | y | ϵ f ( x y ) Ω ( y ) | y | d h ( | y | ) d y .
The authors of [12] proved the boundedness of the maximal operator M Ω f for p > 2 d / 2 d 1 , whenever Ω is a continuous function on the unit sphere of R d . Motivated by the observation that:
| T Ω , h f ( x ) | | | h | | L 2 ( R + , d r / r ) I Ω f ( x ) ,
we study operators of the form:
I Ω f ( x ) = 0 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r 1 2 : = 0 A r Ω f ( x ) 2 d r r 1 2 ,
In particular, an inequality connecting this class of operators with some well-known Marcinkiewicz integral operators is proved by using the classical Hardy inequality. Then, the boundedness of the operator I Ω f is determined for some 1 < p < 2 whenever Ω belongs to a certain class of Lebesgue spaces. In addition, for the purpose of outlining the L 2 -boundedness of I Ω , a novel proof of the optimality condition is proposed on Ω .
In view of the previous results, it is natural to ask whether we can obtain the boundedness of the operator I Ω f for some 1 < p < 2 whenever Ω L ( S d 1 ) , the space of bounded complex-valued measurable functions on S d 1 . It is our goal in Section 2 to attain a partial answer to this inquiry by establishing several initial results including the boundedness of the operator I Ω f some 3 2 < p < 2 . In addition, by establishing the boundedness of I Ω f , Al-Salman [13] improved the result of Chen and Lin and obtained the boundededness of M Ω f for p 2 whenever Ω belongs to certain Zygmund classes. The relations among Zygmund classes and other Lebesgue space are clearly stated in Section 3. In addition, Al-Salman [13] proved that the condition Ω L ( log L ) 1 / 2 ( S d 1 ) is optimal in order to obtain the L 2 -boundedness of the operator I Ω f . More precisely, he proved that there exists a function Ω that lies in L ( log L ) 1 2 ϵ ( S d 1 ) for all ϵ > 0 such that I Ω f in not bounded on L 2 ( R d ) . However, in Section 3, we use the classical Hardy inequality to deduce the same result by proposing a new simple proof that uses the previously known results.

2. A First Look at L p Mapping Properties of I Ω

For a dense subspace in L p ( R d ) , we first prove that:
I Ω f ( x ) <
for every x R d . More precisely, we have the following result.
Theorem 1. 
The operator I Ω maps S ( R d ) into the space of locally integrable functions on R d .
Proof. 
It is enough to show that for f S ( R d ) there exists constants α , β such that I Ω f ( x ) α + β | x | for all x R d . Firstly, by the cancellation property (1), we have:
0 1 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r 1 2 0 1 S d 1 | f ( x r y ) f ( x ) | | Ω ( y ) | d σ ( y ) 2 d r r 1 2 .
By the mean value theorem and since f is a Schwartz function, there exists a constant θ ( 0 , 1 ) such that:
0 1 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r 1 2 0 1 S d 1 | f ( x θ r y ) · r y | | Ω ( y ) | d σ ( y ) 2 d r r 1 2 C | | Ω | | L 1 ( S d 1 ) .
On the other hand, the estimate:
( 1 + | x r y | ) 1 ( 1 + | x | ) ( 1 + r ) 1
gives:
1 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r 1 2 C ( 1 + | x | ) | | Ω | | L 1 ( S d 1 ) 1 1 ( 1 + r ) 2 d r r 1 2 C | | Ω | | L 1 ( S d 1 ) ( 1 + | x | ) .
Finally, by Equations (2) and (3) and the simple inequality a + b a + b such that a , b 0 , we obtain the required result. □
Remark 1. 
We notice that in case of Theorem 1, we have:
A r Ω f ( x ) L 2 ( 0 , ) , d r r
where f is a Schwartz function and x R d . So, by the properties of L p -norms, we have:
A Ω f ( x ) = lim q 0 A r Ω f ( x ) q d r r 1 q .
Next, we wish to investigate for what finite values of 1 < p < 2 the inequality:
| | I Ω f | | L p ( R d ) C p | | f | | L p ( R d )
holds for all f L p ( R d ) . In order to do this, we split the operator I Ω into dyadic sub-operators as follows. Let a m = 2 m + 1 for m 0 . Pick a radial smooth function φ 0 such that φ 0 ( ξ ) = 1 if | ξ | 1 and φ 0 ( ξ ) = 0 if | ξ | a m . Now, for k 1 , define:
φ m , k = φ 0 ( a m k ξ ) φ 0 ( a m 1 k ξ ) .
It can be readily seen that φ 0 , k is supported in the annulus 2 k 1 | ξ | 2 k + 1 and:
k = 0 φ 0 , k ( ξ ) = 1
for all ξ R d with the convention φ 0 , 0 = φ 0 . Let Ψ ( k ) ( x ) = ( φ 0 , k ˇ d λ ) ( x ) = ( Φ 2 k f ) ( x ) for a suitable Schwartz function Φ , where:
d λ ( y ) = Ω ( y ) 1 S d 1 ( y ) d σ ( y ) .
For k 0 , define:
I Ω k f ( x ) = 0 ( Ψ ( k ) ) r f ( x ) 2 d r r 1 2 ,
where:
( Ψ ( k ) ) r ( · ) = r d Ψ ( k ) · r .
We shall need the following lemmas which can be found in [2] and references therein.
Lemma 1. 
Let Ψ L 1 ( R d ) that satisfies:
R d Ψ ( x ) d x = 0 ,
| Ψ ( x ) | B ( 1 + | x | ) d ϵ 1 ,
R d | Ψ ( x y ) Ψ ( x ) | d x B | y | ϵ 2 ,
for some positive constants B , ϵ 1 , ϵ 2 and for all y 0 . Then:
0 Ψ r f ( x ) 2 d r r 1 2 L p ( R d ) C d B max ( p , ( p 1 ) 1 ) | | f | | L p ( R d )
for 1 < p < and all f L p ( R d ) . Moreover, we have:
0 Ψ r f ( x ) 2 d r r 1 2 L 1 , ( R d ) C d B | | f | | L 1 ( R d ) ,
for all f L 1 ( R d ) .
Lemma 2. 
Let N > M > d . Then, the following inequality holds:
S d 1 2 k d ( 1 + 2 k | x y | ) N d σ ( y ) C M , d 2 k ( 1 + | x | ) M .
As a consequence of the previous results, we have the following lemma.
Lemma 3. 
Suppose that Ω L ( S d 1 ) and satisfies the mean value zero condition (1). Then, I Ω ( k ) satisfies the conclusions (7) and (8) in Lemma 1.
Proof. 
It is clear that we need only to verify the assumptions of Lemma 1 for k 1 to get the required result. The case k = 0 can be treated in a similar manner. Obviously, Ψ ( k ) ( x ) is integrable on R d . To prove (4), notice that:
R d Ψ ( k ) ( x ) d x = R d ( Φ 2 k d λ ) ( x ) d x = R d S d 1 Φ 2 k ( x y ) Ω ( y ) d σ ( y ) d x = S d 1 Ω ( y ) R d Φ 2 k ( x y ) d x d σ ( y ) = S d 1 Ω ( y ) R d Φ 2 k ( x ) d x d σ ( y ) = 0 .
Since Φ is a Schwartz function, an application of Lemma 2 gives (5). More precisely, for N > d + 1 , we have:
| Ψ ( k ) ( x ) | S d 1 | Φ 2 k ( x y ) | | Ω ( y ) | d σ ( y ) C N S d 1 2 k d ( 1 + 2 k | x y | ) N | Ω ( y ) | d σ ( y ) C d | | Ω | | L ( S d 1 ) 2 k ( 1 + | x | ) d + 1 .
Finally, by using the mean value theorem we get:
R d | Ψ ( k ) ( x y ) Ψ ( k ) ( x ) | d x = R d S d 1 ( Φ 2 k ( x y z ) Φ 2 k ( x z ) ) Ω ( z ) d σ ( z ) d x 2 k | y | S d 1 | Ω ( z ) | R d 2 k d | Φ ( 2 k ( x z θ y ) ) | d x d σ ( z ) = | | Ω | | L 1 ( S d 1 ) | | Φ | | L 1 ( R d ) 2 k | y | ,
and thus we have (6) from which the result follows. □
Lemma 4. 
Let Ω be as in Lemma 3. Then:
| | I Ω ( k ) f | | L 2 ( R d ) C 2 α k | | f | | L 2 ( R d )
for some 0 < α < 1 2 and all f L 2 ( R d ) .
Proof. 
Firstly, by using Plancherel and Fubini theorems, we have:
| | I Ω ( k ) f | | L 2 ( R d ) 2 = R d 0 ( ( Ψ ( k ) ) r f ) ( x ) 2 d r r d x = 0 R d ( ( Ψ ( k ) ) r f ) ( x ) 2 d x d r r = 0 R d | φ k ( r ξ ) | 2 | λ ^ ( r ξ ) | 2 | f ^ ( ξ ) | 2 d ξ d r r = R d | f ^ ( ξ ) | 2 2 k 1 / | ξ | 2 k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ ( r ξ ) | 2 d r r d ξ
Now, an application of Van der Corput’s Lemma gives:
2 k 1 / | ξ | 2 k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ ( r ξ ) | 2 d r r C S d 1 S d 1 | Ω ( y ) | | Ω ( z ) ¯ | 2 k 1 / | ξ | 2 k + 1 / | ξ | e i r < y z , ξ > d r r d σ ( y ) d σ ( z ) C 2 α ˜ k S d 1 × S d 1 | Ω m ( y ) | | Ω m ( z ) ¯ | < y z , ξ α ˜ d σ ( y z ) C 2 α ˜ k
for some 0 < α ˜ < 1 . Finally, by combining (9) and (10) we deduce our result. □
Now, we are ready to conclude the main result of this section. More precisely, in [13] it was shown that the operator I Ω f is bounded for p 2 . In the following Theorem, we attain the boundedness for 3 2 < p < 2 .
Theorem 2. 
Let Ω be as in Lemma 3. Then:
| | I Ω f | | L p ( R d ) C p | | f | | L p ( R d )
for 3 2 < p < 2 .
Proof. 
Notice that:
I Ω f ( x ) = 0 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r 1 2 = 0 ( f ^ ( ξ ) λ ^ ( r ξ ) ) ˇ ( x ) 2 d r r 1 2 = 0 k = 0 f ^ ( ξ ) φ k ( r ξ ) λ ^ ( r ξ ) ˇ ( x ) 2 d r r 1 2 I Ω ( 0 ) f ( x ) + k = 1 I Ω ( k ) ) f ( x ) .
Lemma 3 guarantees the boundedness of I Ω ( 0 ) for all 1 < p < . So, we need only to take care of the sum on most right-hand side in (11). Interpolating between the L 2 L 2 and L 1 L 1 , estimates in Lemmas 3 and 4 yields:
| | I Ω ( k ) ) f | | L p ( R d ) C d 2 ( 2 + 2 α p 2 α 1 ) k | | f | | L p ( R d )
for k 1 and 1 < p < 2 . Finally, combining the fact that g ( α ) = 2 α + 2 2 α + 1 is decreasing on ( 0 , 1 / 2 ) with (11) and (12) ends the proof. □

3. L 2 -Boundedness of I Ω

In this section, we introduce a new proof of the L 2 -boundedness of I Ω . The main feature of our proof is inequality (24) which reveals the relationship between the spherical operators and the well-known parametric Marcinkiewicz integral operators which we derive by using the classical Hardy inequality. We start this section by deriving a multiplier formula for I Ω and as a consequence of this derivation, we find a necessary and sufficient condition on Ω which guarantee the L 2 -boundedness of I Ω f . We emphasis here that the proof of the next result follows the same lines of the one in [13] but in great detail.
Theorem 3. 
Suppose that Ω L 1 ( S d 1 ) satisfies (1). Then, the operator I Ω is bounded on L 2 ( R d ) iff:
sup ξ S d 1 S d 1 S d 1 log 1 | < y z , ξ > | Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) < .
Proof. 
In this proof, we follow the same lines as the one in [14]. By Plancherel and Fubini theorems, we have:
| | I Ω f | | 2 2 = R d 0 S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d r r d x = 0 R d S d 1 f ( x r y ) Ω ( y ) d σ ( y ) 2 d x d r r = 0 R d f ^ ( ξ ) S d 1 e i r y · ξ Ω ( y ) d σ ( y ) 2 d ξ d r r = R d | f ^ ( ξ ) | 2 0 S d 1 e i r y · ξ Ω ( y ) d σ ( y ) 2 d r r d ξ : = R d | f ^ ( ξ ) | 2 M ( ξ ) d ξ .
On the other hand, consider:
S d 1 e i r y · ξ Ω ( y ) d σ ( y ) 2 = S d 1 e i r y · ξ Ω ( y ) d σ ( y ) S d 1 e i r z · ξ Ω ( z ) d σ ( z ) ¯ = S d 1 e i r y · ξ Ω ( y ) d σ ( y ) S d 1 e i r z · ξ Ω ( z ) ¯ d σ ( z ) = S d 1 S d 1 e i r < y z , ξ > Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) .
By combining (14) and (15) and applying Lebesgue dominated convergence theorem, we obtain:
M ( ξ ) = lim η 0 + , N η N S d 1 e i r y · ξ Ω ( y ) d σ ( y ) 2 d r r = lim η 0 + , N η N S d 1 S d 1 e i r < y z , ξ > Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) d r r = lim η 0 + , N S d 1 S d 1 η N e i r < y z , ξ > d r r Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) = lim η 0 + , N S d 1 S d 1 η N e i r < y z , ξ > cos ( r | ξ | ) d r r Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) = lim η 0 + , N S d 1 S d 1 η | ξ | N | ξ | e i r < y z , ξ > cos ( r ) d r r Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) = S d 1 S d 1 log 1 | < y z , ξ > | i π 2 sgn ( < y z , ξ > ) Ω ( y ) Ω ( z ) ¯ d σ ( y ) d σ ( z ) .
The sufficiency of (13) is obvious. Assume that I Ω is bounded on L 2 ( R d ) and notice that:
R d | f ^ ( ξ ) | 2 ( | | I Ω | | 2 M ( ξ ) ) d ξ 0 .
The fact that Fourier transform is an isometry on L 2 ( R d ) enables us to find a function f L 2 ( R d ) such that f ^ ( ξ ) = ( 2 r ) d / 2 Π k = 1 d 1 [ r , r ] ( ξ k ) and so an application of Lebesgue differentiation theorem proves the necessity of (13). □
Remark 2. 
The following inclusions among Zygmund classes and Lebesgue spaces hold and are proper. For q > 1 and 0 < α < β , we have:
L q ( S d 1 ) L ( log L ) ( S d 1 ) L 1 ( S d 1 ) , L ( log L ) β ( S d 1 ) L ( log L ) α ( S d 1 ) .
The following lemma can be found in [15].
Lemma 5. 
Let Ω L ( log L ) ( S d 1 ) be satisfy (1). Then:
sup ξ S d 1 0 S d 1 e i r y · ξ Ω ( y ) d σ ( y ) 2 d r r < .
Remark 3. 
Equation (14) and Lemma 5 show that I Ω is bounded on L 2 ( R d ) whenever Ω L ( log L ) ( S d 1 ) . Therefore, by the relations among Zygmund classes it is natural to ask what is the optimal α such that I Ω is bounded on L 2 ( R d ) whenever Ω L ( log L ) α ( S d 1 ) .
As a first step in answering the inquiry in Remark 3, we need to recall the L ( log L ) α ( S n 1 ) decomposition.
Lemma 6. 
Suppose that for some α > 0 , Ω L ( log L ) α ( S n 1 ) and satisfies the mean value zero condition. Then there exists a subset D of N , a sequence { λ m : m N { 0 } } of nonnegative real numbers, and a sequence of functions { Ω m : m D { 0 } } in L 1 ( S n 1 ) such that:
(i) 
S n 1 Ω m ( y ) d σ ( y ) = 0 for m D { 0 } ,
(ii) 
sup m { 0 } D | | Ω | | L 1 ( S d 1 ) < ,
(iii) 
| | Ω m | | 2 C a m 2 for m D { 0 } ,
(iv) 
m D { 0 } ( m + 1 ) α λ m < ,
(v) 
Ω = m D { 0 } λ m Ω m .
Theorem 4. 
Let Ω L ( log L ) 1 / 2 ( S d 1 ) be satisfy (1). Then I Ω is bounded on L 2 ( R d ) . Moreover, the condition Ω L ( log L ) 1 / 2 ( S d 1 ) is optimal for I Ω to be L 2 -bounded.
Proof. 
We follow the same proof of Theorem 2 with a slight modification. By Lemma 6, we have:
I Ω f ( x ) λ 0 I Ω 0 f ( x ) + m D λ m I Ω m f ( x ) λ 0 I Ω 0 f ( x ) + m D λ m ( I Ω m ( 0 ) f ( x ) + k = 1 I Ω m ( k ) f ( x ) ) .
Let:
I Ω m ( k ) f ( x ) = 0 ( ( Ψ m ( k ) ) r f ) ( x ) 2 d r r 1 2 ,
where:
Ψ m ( k ) = ( φ m , k ) ˇ d λ m = Φ a m k d λ m ,
and:
( Ψ m ( k ) ) r ( · ) = r d Ψ m ( k ) · r .
In view of Lemma 3 and Remarks 3 and 6, we need only to show that:
m D λ m k = 1 I Ω m ( k ) f L 2 ( R d ) C | | f | | L 2 ( R d ) .
It is clear that:
| | I Ω m ( k ) f | | L 2 ( R d ) 2 = R d 0 ( ( Ψ m ( k ) ) r f ) ( x ) 2 d r r d x = R d | f ^ ( ξ ) | 2 a m k 1 / | ξ | a m k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ m ( r ξ ) | 2 d r r d ξ
Now, interpolating between the simple estimates:
a m k 1 / | ξ | a m k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ m ( r ξ ) | 2 d r r C ( m + 1 )
and:
a m k 1 / | ξ | a m k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ m ( r ξ ) | 2 d r r C a m k 1 / | ξ | a m k + 1 / | ξ | | λ ^ m ( r ξ ) | 2 d r r C S d 1 S d 1 | Ω m ( y ) | | Ω m ( z ) ¯ | a m k 1 / | ξ | a m k + 1 / | ξ | e i r < y z , ξ > d r r d σ ( y ) d σ ( z ) C a m α ( 1 k ) ( m + 1 ) S d 1 × S d 1 | Ω m ( y ) | | Ω m ( z ) ¯ | < y z , ξ α d σ ( y z ) C a m α ( 1 k ) + 4 ( m + 1 ) ,
yields:
a m k 1 / | ξ | a m k + 1 / | ξ | | φ k ( r ξ ) | 2 | λ ^ m ( r ξ ) | 2 d r r C 2 α k ( m + 1 ) ,
and:
| | I Ω m ( k ) f | | L 2 ( R d ) C 2 α k / 2 ( m + 1 ) 1 / 2 | | f | | L 2 ( R d ) .
Therefore, (18) and (23) complete the first part of the proof. To prove the optimality of the condition Ω L ( log L ) 1 / 2 ( S d 1 ) , assume that Ω is a homogeneous function of degree 0 and recall that the parametric Marcinkiewicz integral operator [16] is given by:
M Ω ρ f ( x ) = 0 t ρ | y | t f ( x y ) Ω ( y ) | y | d ρ d y 2 d t t 1 / 2 ,
for ρ > 0 . It can be easily seen that:
M Ω ρ f ( x ) 1 ρ I Ω f ( x )
for almost every x R d . To see this, we need the following version of Hardy inequality [17]:
0 1 x 0 x | F ( t ) | d t p x η d x 1 p p p 1 η 0 | F ( t ) | p t η d t 1 p ,
where F is a measurable function, 1 < p < and η < p 1 . Switching to polar coordinates gives:
M Ω ρ f ( x ) = 0 t ρ | y | t f ( x y ) Ω ( y ) | y | d ρ d y 2 d t t 1 / 2 0 1 t 0 t S d 1 f ( x r y ) Ω ( y ) r 1 ρ d σ ( y ) d r 2 t 1 2 ρ d t 1 2 .
Thus, we get (24) by applying (25) with:
F ( x , r ) = S d 1 f ( x r y ) Ω ( y ) r 1 ρ d σ ( y ) , η = 1 2 ρ .
Finally, Al-Salman [18] proved that there exists Ω ϵ > 0 L ( log L ) 1 / 2 ϵ ( S d 1 ) such that M Ω ρ could not be bounded on L 2 ( R d ) . Therefore, this fact and (24) complete the proof. □

4. Conclusions

In conclusion, it is important to declare that we have successfully reproved and extended several known results connected with a class of spherical integral operators. More precisely, an inequality has been properly proposed to describe the relation between such class of operators with some well-known Marcinkiewicz integral operators. As a consequence of this inequality, we have obtained the optimality of the condition on Ω for the L 2 -boundedness of I Ω f differently from the one proposed in [13]. The boundedness of the operator I Ω f has been proved for 3 2 < p < 2 whenever Ω L ( S d 1 ) . In future work, we aim to answer the question whether this range of values of p is optimal or can be improved by using different techniques.

Author Contributions

Conceptualization, L.H., A.Q., R.S., A.Z. and I.M.B.; Methodology, L.H., A.Q., R.S., A.Z. and I.M.B.; Software, L.H., A.Q., R.S., A.Z. and I.M.B.; Validation, L.H., A.Q., R.S., A.Z. and I.M.B.; Formal analysis, L.H., A.Q., R.S., A.Z. and I.M.B.; Investigation, L.H., A.Q., R.S., A.Z. and I.M.B.; Data curation, L.H., A.Q., R.S., A.Z. and I.M.B.; Supervision, L.H., A.Q., R.S., A.Z. and I.M.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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MDPI and ACS Style

Hawawsheh, L.; Qazza, A.; Saadeh, R.; Zraiqat, A.; Batiha, I.M. Lp-Mapping Properties of a Class of Spherical Integral Operators. Axioms 2023, 12, 802. https://doi.org/10.3390/axioms12090802

AMA Style

Hawawsheh L, Qazza A, Saadeh R, Zraiqat A, Batiha IM. Lp-Mapping Properties of a Class of Spherical Integral Operators. Axioms. 2023; 12(9):802. https://doi.org/10.3390/axioms12090802

Chicago/Turabian Style

Hawawsheh, Laith, Ahmad Qazza, Rania Saadeh, Amjed Zraiqat, and Iqbal M. Batiha. 2023. "Lp-Mapping Properties of a Class of Spherical Integral Operators" Axioms 12, no. 9: 802. https://doi.org/10.3390/axioms12090802

APA Style

Hawawsheh, L., Qazza, A., Saadeh, R., Zraiqat, A., & Batiha, I. M. (2023). Lp-Mapping Properties of a Class of Spherical Integral Operators. Axioms, 12(9), 802. https://doi.org/10.3390/axioms12090802

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