Generalized Marcinkiewicz Integral Operators Along Certain Surfaces

Mohammed Ali

doi:10.20944/preprints202605.0437.v1

Submitted:

07 May 2026

Posted:

08 May 2026

You are already at the latest version

Abstract

In this article, a class of rough generalized Marcinkiewicz operators is considered. Under the condition that the singular kernel belongs to the space Lq(Bs−1), the boundedness of these operators are confirmed from the space of homogeneous Triebel–Lizorkin functions to the Lp(Rd+1) space. Moreover, appropriate Lp bounds are obtained which allow us to utilize Yano’s extrapolation procedure to prove the boundedness of the aforementioned operators under weaker assumptions on the kernels. In this work, several known past results are generalized, extended, and improved.

Keywords:

generalized Marcinkiewicz

;

Triebel–Lizorkin space

;

singular integrals

;

extrapolation

;

bounds

Subject:

Computer Science and Mathematics - Analysis

MSC: 42B35; 42B25; 42B20

1. Introduction

Throughout this paper, we assume that

R^{s}

is the

2 \leq s

-dimensional Euclidean space and

B^{s - 1}

is the unit sphere in

R^{s}

equipped with the normalized Lebesgue surface measure

d σ_{s} (\cdot)

. Also, we assume that

y = v / | v |

for

v \in R^{s} ∖ {0}

.

Let

ζ

be a measurable function on

R_{+}

and

Φ \in L_{1} (B^{s - 1})

be a homogeneous function of degree zero on

R^{s}

that satisfies the condition

\int_{B^{s - 1}} Φ (y) d σ_{s} (y) = 0 .

(1)

For suitable mappings

P : R^{s} \to R^{d}

and

Ψ : R_{+} \to R

, we define the generalized Marcinkiewicz integral

G_{Φ, P, Ψ, ζ}^{α}

, initially for

V \in C_{0}^{\infty} (R^{d + 1})

, by

G_{Φ, P, Ψ, ζ}^{α} (V) (\dot{x}) = {(\int_{R_{+}} {|\frac{1}{t^{a}} \int_{| v | \leq t} V (x - P (v), x_{d + 1} - Ψ (| v |)) \frac{Φ (v) ζ (|v|)}{{|v|}^{s - a}} d v|}^{α} \frac{d t}{t})}^{1 / α},

where

\dot{x} = (x, x_{d + 1}) \in R^{d + 1}

,

α > 1

, and

a = a_{1} + i a_{2}

with

a_{1} > 0

and

a_{2} \in R

.

When

α = 2

,

s = d

,

P (v) = I (v) = v

,

Ψ \equiv 0

, and

ζ \equiv 1

, we denote

G_{Φ, P, Ψ, ζ}^{α}

by

M_{Φ, a}

; and when

a = 1

, we denote

M_{Φ, a}

by

M_{Φ}

which is the traditional Marcinkiewicz operator that Stein initiated in [1]. The boundedness of

M_{Φ}

has been considered by many authors for a long time. Historically, Stein [1] proved that

M_{Φ}

is bounded on

L_{p} (R^{s})

for

1 < p < 2

provided that

Φ \in L i p_{ϵ} (B^{s - 1})

with

ϵ \in (0, 1]

. Then, the authors of [2] improved this result; they confirmed the

L_{p}

boundedness of

M_{Φ}

for all

p \in (1, \infty)

whenever

Φ \in C^{1} (B^{s - 1})

. Later, Walsh [3] obtained only

L^{2} (R^{s})

boundedness of

M_{Φ}

if

Φ \in L {(l o g L)}^{1 / 2} (B^{s - 1})

, and also he found that the condition

Φ \in L {(log L)}^{1 / 2} (B^{s - 1})

is optimal in the sense that if

Φ \in L {(l o g L)}^{β} (B^{s - 1})

for any

β \in (0, 1 / 2)

, then

M_{Φ}

will forfeit the

L_{2}

boundedness. Thereafter, the above results were extended and improved for all

p \in (1, \infty)

whenever

Φ \in L {(log L)}^{1 / 2} (B^{s - 1})

, see [4]; and also whenever

Φ \in B_{q}^{(0, - 1 / 2)} (B^{s - 1})

for some

q > 1

, see [5]. Here

B_{q}^{(0, ε)} (B^{s - 1})

indicates to the special class of block space that was introduced in [6].

It is worth mentioning that the investigation of

L_{p}

boundedness of parametric Marcinkiewicz operator

M_{Φ, a}

was begun by Hörmander [7] and then continued by many researchers. Let us present some past results related to our findings. For instance, the operator

G_{Φ, P, Ψ, ζ}^{2}

was studied in [8] for the special case

Ψ \equiv 0

,

Φ \in L {(log L)}^{1 / 2} (B^{s - 1}) \cup B_{q}^{(0, - 1 / 2)} (B^{s - 1})

,

ζ \in Θ_{η} (R_{+})

for some

η > 1

, and

P (v) = (P_{1} (v), P_{2} (v), \dots, P_{d} (v))

is a polynomial mapping, where each

P_{j}

is a real valued polynomial on

R^{s}

. In fact, it was proved the

L_{p}

boundedness of

G_{Φ, P, Ψ, ζ}^{2}

for all

|1 / p - 1 / 2| < min {1 / η^{'}, 1 / 2}

. Here,

Θ_{η} (R_{+})

(with

η > 1

) denotes the collection of all mappings

ζ

satisfying

{∥ζ∥}_{Θ_{η} (R_{+})} = sup_{m \in Z} {(\int_{2^{m}}^{2^{m + 1}} {|ζ (t)|}^{η} \frac{d t}{t})}^{1 / η} < \infty .

The authors of [9] got the same results in [8] with replacing the conditions

P

and

Ψ

by

P = I

and

Ψ \in C^{2} (R_{+})

is convex and increasing function with

Ψ (0) = 0

; respectively. Very recently, the authors of [10] generalized the results in [8,9] by obtaining

L_{p}

boundedness of the operator

G_{Φ, P, Ψ, ζ}^{2}

for all

|1 / p - 1 / 2| < min {1 / η^{'}, 1 / 2}

provided that

P (v) = (P_{1} (v), P_{2} (v), \dots, P_{d} (v))

is a polynomial mapping,

Φ \in L {(log L)}^{1 / 2} (B^{s - 1}) \cup B_{q}^{(0, - 1 / 2)} (B^{s - 1})

,

ζ \in Θ_{η} (R_{+})

for some

η > 1

, and

Ψ

is a function satisfying

Ψ (t) = ψ_{1} (t) + ψ_{2} (t),

where

ψ_{1}

is a polynomial,

ψ_{2}^{(n)} (0) = 0

for all

1 \leq n \leq K

,

ψ_{2}^{(n)}

is positive non-decreasing on

R_{+}

for all

1 \leq n \leq K + 1

, and

K = max {d e g (ψ_{1}), d e g (P)}

. Afterwards, the

L_{p}

boundedness of

G_{Φ, P, Ψ, ζ}^{2}

was investigated by many authors under various conditions on

Φ

,

P

,

Ψ

, and

ζ

. For a sample of past discussions relevant to our current study, we refer the readers to consult [11,12,13,14,15], and for developments and recent advances, see [16,17,18,19,20].

On the other side, the discussion of generalized Marcinkiewicz operator

G_{Φ, P, Ψ, ζ}^{α}

was started in [21] where the authors established the

L_{p}

(

1 < p < \infty

) boundedness of

G_{Φ, P, 0, 1}^{α}

whenever

Φ \in L^{q} (B^{s - 1})

,

P (v) \equiv I (v) = v

and

α \in (1, \infty)

. Later on, Le [22] improved this result by proving the boundedness of

G_{Φ, I, 0, ζ}^{α}

under weaker conditions that

ζ \in Θ_{max {η^{'}, 2}} (R_{+})

and

Φ \in L (log L) (B^{s - 1})

. The authors of [23] improved and extended the above results. Precisely, they employed Yano’s extrapolation argument to obtain the boundedness of

G_{Φ, I, 0, ζ}^{α}

for all

p \in (1, α)

with

α^{'} \geq η

and also for all

p \in (η^{'}, \infty)

with

α > η^{'}

if

ζ \in Θ_{η} (R_{+})

with

η > 2

and

Φ \in L {(log L)}^{1 / α} (B^{s - 1}) \cup B_{q}^{(0, \frac{1}{α} - 1)} (B^{s - 1})

. Thereafter, the operator

G_{Φ, P, Ψ, ζ}^{α}

was studied under specific conditions on

α, Φ, P, Ψ

, and

ζ

(see [24,25,26,27,28], and the references therein.)

For

u \in (- \infty, \infty)

and

α, p \in (1, \infty)

, the space of homogeneous Triebel-Lizorkin functions

{\dot{F}}_{p}^{u, α} (R^{s})

is the collection of all tempered distribution mappings

V

on

R^{s}

such that

{∥V∥}_{{\dot{F}}_{p}^{u, α} (R^{s})} = {∥{(\sum_{j \in Z} 2^{j u α} {|ϝ_{j} * V|}^{α})}^{1 / α}∥}_{L_{p} (R^{s})} < \infty,

where

\hat{ϝ_{j}} (v) = λ (v / 2^{j})

and

λ \in C_{0}^{\infty} (R^{s})

is a radial mapping satisfying:

(1)

0 \leq λ \leq 1

,

(b) There exists

C > 0

such that, for all v with

\frac{3}{5} \leq |v| \leq \frac{5}{3}]

, we have

λ (v) \geq C

,

(c)

S \supset s u p p (λ)

, where

S = \{v : |v| \in [1 / 2, 2]\}

,

(d)

\sum_{j \in Z} λ (v / 2^{j}) = 1

for all non-zero

v \in R^{s}

.

We point out that the authors of [25] proved the following:

(i) The Schwartz space

S (R^{s})

is dense in

{\dot{F}}_{p}^{u, α} (R^{s})

,

(ii) When

α = 2

and

u = 0

, we have

{\dot{F}}_{p}^{0, 2} (R^{s}) = L_{p} (R^{s})

for all

p \in (1, \infty)

,

(iii) If

α_{2} \geq α_{1}

, we have

{\dot{F}}_{p}^{u, α_{2}} (R^{s}) \supseteq {\dot{F}}_{p}^{u, α_{1}} (R^{s})

.

Motivated by the results obtained in [10] concerning the boundedness of

G_{Φ, P, Ψ, ζ}^{2}

on

L_{p} (R^{d + 1})

, it is natural discuss the

L_{p}

boundedness of

G_{Φ, P, Ψ, ζ}^{α}

under the same conditions in [10] with replacing

α = 2

by

α > 1

. The prime findings of this paper are described as follows:

Theorem 1.

Let

ζ \in Θ_{η} (R_{+})

with

η \in (1, 2]

and

Φ \in L_{q} (B^{s - 1})

be a homogeneous function of degree zero satisfying (1) with

q \in (1, 2]

. Suppose that

P (v) = (P_{1} (v), P_{2} (v), \dots, P_{d} (v))

is a polynomial mapping and Ψ is a function satisfying

Ψ (t) = ψ_{1} (t) + ψ_{2} (t),

where

ψ_{1}

is a polynomial,

ψ_{2}^{(n)} (0) = 0

for all

1 \leq n \leq K

,

ψ_{2}^{(n)}

is positive non-decreasing on

R_{+}

for all

1 \leq n \leq K + 1

, and

K = max {d e g (ψ_{1}), d e g (P)}

. Then, there exists

C_{p, Φ, ζ}

such that

{∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{- 1 / α} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} for p \in [α, \frac{η α^{'}}{α^{'} - η}];

{∥G_{Φ, P, Ψ, ζ}^{α} (V∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{\frac{α - η α - η}{η α}} {∥V)∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} for p \in (\frac{η α}{η α - α + η}, α);

and

{∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{\frac{α - η α + 1}{η α}} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} for p \in (\frac{η α^{'}}{α^{'} - η}, α),

where

C_{p, Φ, ζ} = C_{p} C_{Φ, ζ}

,

C_{Φ, ζ} = C {∥Φ∥}_{L_{q} (B^{s - 1})} {∥ζ∥}_{Θ_{η} (R_{+})}

, and

C_{p}

is a positive number independent of

Φ, P, Ψ, ζ

, and α.

Theorem 2.

Assume that

Φ, P

, and Ψ are given as in the Theorem 1 and that

ζ \in Θ_{η} (R_{+})

with

η \in (2, \infty)

.

(a): If $α > η^{'}$ , then for $p \in (η^{'}, \infty)$ , we have

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[q - 1]}^{- 1 / η^{'}} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})};$
(b): If $α \leq η^{'}$ , then for $p \in (1, α)$ , we have

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[q - 1]}^{- 1} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} .$

Theorems 1-2 along with Yano’s extrapolation technique ([29,30]) lead to the following results.

Theorem 3.

Let

P

, Ψ, and ζ be given as in the Theorem 1.

(i): If $Φ \in L {(log L)}^{1 / α} (B^{s - 1})$ , then for $p \in [α, \frac{η α^{'}}{α^{'} - η}]$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{L {(log L)}^{1 / α} (B^{s - 1})}) .$
(ii): If $Φ \in L {(log L)}^{\frac{η α - α + η}{η α}} (B^{s - 1})$ , then for $p \in (\frac{η α}{η α - α + η}, α)$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{L {(log L)}^{\frac{η α - α + η}{η α}} (B^{s - 1})}) .$
(iii): If $Φ \in L {(log L)}^{\frac{α - η α + 1}{η α}} (B^{s - 1})$ , then for $p \in (\frac{η α^{'}}{α^{'} - η}, α)$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{L {(log L)}^{\frac{α - η α + 1}{η α}} (B^{s - 1})}) .$
(iv): If $Φ \in B_{q}^{(0, - 1 / α^{'})} (B^{s - 1})$ with $q > 1$ , then for $p \in [α, \frac{η α^{'}}{α^{'} - η}]$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{q^{(0, - 1 / α^{'})} (B^{s - 1})}) .$
(v): If $Φ \in B_{q}^{(0, \frac{η - α}{η α})} (B^{s - 1})$ with $q > 1$ , then for $p \in (\frac{η α}{η α - α + η}, α)$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{B_{q}^{(0, \frac{η - α}{η α})} (B^{s - 1})}) .$
(vi): If $Φ \in B_{q}^{(0, \frac{1 + α - 2 η α}{η α})} (B^{s - 1})$ with $q > 1$ , then for $p \in (\frac{η α^{'}}{α^{'} - η}, α)$ ,

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{B_{q}^{(0, \frac{1 + α - 2 η α}{η α})} (B^{s - 1})}) .$

Theorem 4.

Let

P

, Ψ, and ζ be given as in the Theorem 2.

(i): If $Φ \in L {(log L)}^{1 / η^{'}} (B^{s - 1})$ and $α > η^{'}$ , then the estimate

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{L {(log L)}^{1 / η^{'}} (B^{s - 1})})$

holds for $p \in (η^{'}, \infty)$ .
(ii): If $Φ \in L (log L) (B^{s - 1})$ and $α \leq η^{'}$ , then the inequality

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{L (log L) (B^{s - 1})})$

holds for $p \in (1, α)$ .
(iii): If $Φ \in B_{q}^{(0, - 1 / η^{'})} (B^{s - 1})$ and $η^{'} < α$ , then we have

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{q^{(0, - 1 / η^{'})} (B^{s - 1})})$

for $p \in (η^{'}, \infty)$ .
(iv): If $Φ \in B_{q}^{(0, 0)} (B^{s - 1})$ and $α \leq η^{'}$ , then we have

${∥G_{Φ, P, Ψ, ζ}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p} {∥ζ∥}_{Θ_{η} (R_{+})} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} (1 + {∥Φ∥}_{q^{(0, 0)} (B^{s - 1})})$

for all $p \in (1, α)$ .

Remarks

(i): For the case $α = 2$ , $s = d$ , $P \equiv I$ , $Ψ \equiv 0$ , $ζ \equiv 1$ , and $a = 1$ , Theorem 4 gives the $L^{p}$ boundedness of $G_{Φ, P, Ψ, ζ}^{α}$ for all $p \in (1, \infty)$ under the condition $Φ \in L (log L) (B^{s - 1}) \cup B_{q}^{(0, - 1)} (B^{s - 1}) \supset L i p_{ϵ} (B^{s - 1}) \supset C^{1} (B^{s - 1})$ . Therefore, our results improve and extend the findings in [1,2].
(ii): When $α = 2$ , $s = d$ , $P \equiv I$ , $Ψ \equiv 0$ , $a = 1$ , $ζ \in Θ_{η} (R_{+})$ , and $Φ \in L (log L) (B^{s - 1})$ , the authors of [12] obtained only $L^{2}$ boundedness of $G_{Φ, P, Ψ, ζ}^{α}$ . Thus, our findings generalize and improve the findings in [12].
(iii): The operator $G_{Φ, P, Ψ, ζ}^{α}$ was discussed in [21] whenever $P \equiv I$ , $Ψ \equiv 0$ , and $ζ \in Θ_{η} (R_{+})$ under the rough assumptions $Φ \in L^{q} (B^{s - 1})$ which is stronger than the conditions on $Φ$ in this paper.
(iv): This work was studied in [10] only for the case $α = 2$ . Moreover, the conditions $Φ \in L {(log L)}^{1 / 2} (B^{s - 1})$ and $Φ \in B_{q}^{(0, - 1 / 2)} (B^{s - 1})$ in Theorem 3 (i) and (iv) are the weakest conditions among their respective spaces, see [3,5].
(v): When $ζ \equiv 1$ , we get the full range for p which is $p \in (1, \infty)$ .
(vi): In Theorem 3, the space $L {(log L)}^{\frac{α - η α + 1}{η α}}$ is the best space among the spaces $(i)$ - $(i i i)$ , and the space $B_{q}^{(0, \frac{α - 2 α η + 1}{η α})} (B^{s - 1})$ is the best space among the spaces in $(i v)$ - $(v i)$ . However, the range of $p \in (\frac{η α}{η α - α + η}, α)$ is better than the range of $p \in (\frac{η α^{'}}{α^{'} - η}, α)$ .
(vii): As $L {(log L)}^{1 / η^{'}} (B^{s - 1}) \supset L (log L) (B^{s - 1})$ and $B_{q}^{(0, - 1 / η^{'})} (B^{s - 1}) \supset B_{q}^{(0, 0)} (B^{s - 1})$ , then in Theorem 4, the classes in $(i)$ and $(i i i)$ are larger than the classes in $(i i)$ and $(i v)$ .
(viii): A model example about the surfaces considered in this work is $S_{P, Ψ} (v) = (v_{1}^{2}, v_{2}^{2}, \dots, v_{d}^{2}, {|v|}^{4})$ .

2. Principle Lemmas

In this part, we stablish some subsidiary lemmas that are needed to prove our main results. Let

τ \geq 2

. For compatible mappings

Φ : B^{s} \to R

,

P : R^{s} \to R^{d}

,

Ψ : R_{+} \to R

, and

ζ : R_{+} \to C

, we consider the set of measures

{℧_{Φ, P, Ψ, ζ, t} : = ℧_{ζ, t} : t \in R_{+}}

and its maximal operators

M_{τ}

and

℧_{ζ}^{*}

on

R^{d + 1}

by

\begin{matrix} \int_{R^{d + 1}} V d ℧_{ζ, t} & = & \frac{1}{t^{a}} \int_{t / 2 \leq | v | \leq t} V (P (v), Ψ (| v |)) \frac{Φ (v^{'}) ζ (|v|)}{{|v|}^{s - a}} d v, \end{matrix}

\begin{matrix} M_{τ} (V) & = & sup_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} | | ℧_{ζ, t} | * V | \frac{d t}{t}, \end{matrix}

and

\begin{matrix} ℧_{ζ}^{*} (V) & = & sup_{t \in R_{+}} | | ℧_{ζ, t} | * V | . \end{matrix}

Here, we define

| ℧_{ζ, t} |

similarly as the definition of

℧_{ζ, t}

with substituting

Φ ζ

by

| Φ ζ |

.

Let us present the following lemma which is due to the authors of [10].

Lemma 1.

Let

Φ, P

, and Ψ be given as in Theorems 1 and 2. Assume that

ζ \in Θ_{η} (R_{+})

for some

η > 1

. Then, the following estimates

∥ M_{τ} {(V) ∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} (ln τ) {∥ V ∥}_{L_{p} (R^{d + 1})}

(2)

and

∥ ℧_{ζ}^{*} {(V) ∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥ V ∥}_{L_{p} (R^{d + 1})}

(3)

hold for all

p > η^{'}

.

To prove our main results, we need to establish the following lemmas.

Lemma 2.

Let

Φ, P

, and Ψ be given as in Theorems 1 and 2. Assume that

τ \geq 2

,

α > 1

, and

ζ \in Θ_{η} (R_{+})

for some

η \in (2, \infty)

. Then for arbitrary set of functions

{H_{j}, j \in Z}

on

R^{d + 1}

, we have the following:

(a): If $α > η^{'}$ , then for all $p \in (η^{'}, \infty)$ ,

$\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}$
(b): If $α \leq η^{'}$ , then for all $p \in (1, α)$ ,

$\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} (ln τ) {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}$

Proof.

By (3), it is easy to see that

\begin{matrix} {∥sup_{j \in Z} sup_{t \in [τ^{j}, τ^{j + 1}]} |℧_{ζ, t} * H_{j}|∥}_{L_{p} (R^{d + 1})} & \leq & {∥℧_{ζ}^{*} (sup_{j \in Z} |H_{j}|)∥}_{L_{p} (R^{d + 1})} \\ \leq & C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥sup_{j \in Z} |H_{j}|∥}_{L_{p} (R^{d + 1})} \end{matrix}

for all

p \in (η^{'}, \infty)

. This leads to

\begin{matrix} {∥{∥∥ ℧_{ζ, τ^{j} t} * H_{j} ∥_{L^{\infty} ([1, τ], \frac{d t}{t})}∥}_{L_{\infty} (Z)}∥}_{L_{p} (R^{d + 1})} & \leq & C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥{∥H_{j}∥}_{L_{\infty} (Z)}∥}_{L_{p} (R^{d + 1})} . \end{matrix}

(4)

As

p > η^{'}

, then by duality, there is

f \in L_{{(p / η^{'})}^{'}} (R^{d + 1})

such that

{∥f∥}_{L_{{(p / η^{'})}^{'}} (R^{d + 1})} \leq 1

and

\begin{matrix} {∥{(\sum_{j \in Z} \int_{1}^{τ} {|℧_{ζ, τ^{j} t} * H_{j}|}^{η^{'}} \frac{d t}{t})}^{\frac{1}{η^{'}}}∥}_{L_{p} (R^{d + 1})}^{η^{'}} = \int_{R^{d + 1}} \sum_{j \in Z} \int_{1}^{τ} {|℧_{ζ, τ^{j} t} * H_{j} (\dot{x})|}^{η^{'}} \frac{d t}{t} f (\dot{x}) d \dot{x} \\ \leq C {∥Φ∥}_{L_{1} (B^{s - 1})}^{(η^{'} / η)} {∥ζ∥}_{Θ_{η} (R_{+})}^{η^{'}} \int_{R^{d + 1}} \sum_{j \in Z} {|H_{j} (\dot{x})|}^{η^{'}} ℧_{ζ}^{*} \tilde{f} (- \dot{x}) d \dot{x} \\ \leq C {∥Φ∥}_{L_{1} (B^{s - 1})}^{(η^{'} / η)} {∥ζ∥}_{Θ_{η} (R_{+})}^{η^{'}} {∥\sum_{j \in Z} {|H_{j}|}^{η^{'}}∥}_{L_{(\frac{p}{η^{'}})} (R^{d + 1})} {∥℧_{ζ}^{*} (\tilde{f})∥}_{L_{{(\frac{p}{η^{'}})}^{'}} (R^{d + 1})} \\ \leq C_{p} (ln τ) {∥Φ∥}_{L_{q} (B^{s - 1})}^{(η^{'} / η) + 1} {∥ζ∥}_{Θ_{η} (R^{+})}^{η^{'}} {∥{(\sum_{j \in Z} {|H_{j}|}^{η^{'}})}^{\frac{1}{η^{'}}}∥}_{L_{p} (R^{d + 1})}^{η^{'}}, \end{matrix}

(5)

where

\tilde{f} (\dot{x}) = f (- \dot{x})

. Therefore,

\begin{matrix} {∥{(\sum_{j \in Z} \int_{1}^{τ} {|℧_{ζ, τ^{j} t} * H_{j}|}^{η^{'}} \frac{d t}{t})}^{\frac{1}{η^{'}}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥{(\sum_{j \in Z} {|H_{j}|}^{η^{'}})}^{\frac{1}{η^{'}}}∥}_{L_{p} (R^{d + 1})} . \end{matrix}

(6)

Define the linear operator

T

on

H_{j}

by

T (H_{j}) = ℧_{ζ, τ^{j} t} * H_{j}

, and then interpolate (4) with (6), so we conclude for

α > η^{'}

,

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq {∥{(\sum_{j \in Z} \int_{1}^{τ} {|℧_{ζ, τ^{j} t} * H_{j}|}^{α} \frac{d t}{t})}^{1 / α}∥}_{L_{p} (R^{d + 1})} \\ \leq C_{p, Φ, ζ} {(ln τ)}^{1 / η^{'}} {∥{(\sum_{j \in Z} {|H_{j}|}^{α^{'}})}^{\frac{1}{α^{'}}}∥}_{L_{p} (R^{d + 1})} \end{matrix}

(7)

for all

p \in (η^{'}, \infty)

, which proves part (a).

Let us now prove part (b). By invoking the duality, there is a mapping

g_{j} (\dot{x}, t)

on

R^{d + 1} \times R_{+}

such that

{∥{∥∥ g_{j} ∥_{L_{α^{'}} ([τ^{j}, τ^{j + 1}], \frac{d t}{t})}∥}_{l_{α^{'}}}∥}_{L_{p^{'}} (R^{d + 1})} \leq 1

and

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{1 / α}∥}_{L_{p} (R^{s + 1})} = & \int_{R^{d + 1}} \sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} (℧_{ζ, t} * H_{j}) g_{j} (\dot{x}, t) \frac{d t}{t} d \dot{x} \end{matrix}

\begin{matrix} \leq & C_{p} {(ln τ)}^{1 / α} {∥{(F (g_{j}))}^{1 / α^{'}}∥}_{L_{p^{'}} (R^{d + 1})} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})}, \end{matrix}

(8)

where

F (g_{j}) (\dot{x}) = \sum_{j \in Z} \int_{τ^{j}}^{τ^{j}} {|℧_{ζ, t} * g_{j} (\dot{x}, t)|}^{α^{'}} \frac{d t}{t} .

Thanks to Hölder’s inequality, we deduce that

\begin{matrix} {|℧_{ζ, t} * g_{j} (\dot{x}, t)|}^{α^{'}} & \leq & C {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α^{'} / α)} {∥ζ∥}_{Θ_{η} (R_{+})}^{α^{'}} \int_{τ^{j}}^{τ^{j + 1}} \int_{B^{s - 1}} |Φ (y)| \\ \times & {|g_{j} (x - P (r y), x_{d + 1} - Ψ (r), t)|}^{α^{'}} d σ_{s} (y) \frac{d r}{r} . \end{matrix}

(9)

By using duality, we have a function

h \in L_{{(p^{'} / α^{'})}^{'}} (R^{d + 1})

such that

\begin{matrix} {∥{(F (g_{j}))}^{1 / α^{'}}∥}_{L_{p^{'}} (R^{d + 1})}^{α^{'}} = \sum_{j \in Z} \int_{R^{d + 1}} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * g_{j} (\dot{x}, t)|}^{α^{'}} \frac{d t}{t} h (\dot{x}) d \dot{x} . \end{matrix}

Therefore, by Hölder’s inequality together with (3) and (9), we obtain

\begin{matrix} {∥{(F (g_{j}))}^{1 / α^{'}}∥}_{L_{p^{'}} (R^{d + 1})}^{α^{'}} & \leq & C {∥ζ∥}_{Θ_{η} (R_{+})}^{α^{'}} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α^{'} / α)} {∥{℧^{*}}_{|ζ|} (h)∥}_{L_{{(\frac{p^{'}}{α^{'}})}^{'}} (R^{d + 1})} \\ \times & {∥(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|g_{j} (\dot{v}, t)|}^{α^{'}} \frac{d t}{t})∥}_{L_{{(\frac{p^{'}}{α^{'}})}^{'}} (R^{d + 1})} \\ \leq & C_{p} (ln τ) {∥Φ∥}_{L_{q} (B^{s - 1})}^{(α^{'} / α) + 1} {∥ζ∥}_{Θ_{η} (R_{+})}^{α^{'}} {∥h∥}_{L_{{(\frac{p^{'}}{α^{'}})}^{'}} (R^{d + 1})} . \end{matrix}

(10)

Consequently, by the estimates (8) and (10), we complete the proof of part (b). □

Lemma 3.

Let τ, α,

Φ, P

, Ψ, and

H_{j}

be given as in Lemma 2. Assume that

ζ \in Θ_{η} (R_{+})

for some

η \in (1, 2]

. Then, we have the following:

(i): For all $p \in [α, \frac{η α^{'}}{α^{'} - η}]$ ,

$\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{1 / α} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}$
(ii): For all $p \in (\frac{η α}{η α - α + η}, α)$ ,

$\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{\frac{η α - α + η}{η α}} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R_{d + 1})} . \end{matrix}$
(iii): For all $p \in (\frac{η α^{'}}{α^{'} - η}, α)$ ,

$\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{\frac{η α - α - 1}{η α}} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}$

Proof.

To prove part

(i)

, we need to consider two cases:

Case 1.

p \in (α, \frac{η α^{'}}{α^{'} - η}]

. By duality, there is a function

ϑ

which is non-negative and belonging to

L_{{(p / α)}^{'}} (R^{d + 1})

with norm less than or equal one such that

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})}^{α} = \int_{R^{d + 1}} \sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j} (\dot{x})|}^{α} \frac{d t}{t} ϑ (\dot{x}) d \dot{x} . \end{matrix}

(11)

It is easy to get, by using Hölder’s inequality, that

\begin{matrix} {|℧_{ζ, t} * H_{j} (\dot{v})|}^{α} & \leq & C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'})} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α / α^{'})} \int_{t / 2}^{t} \int_{B^{s - 1}} {|H_{j} (x - P (r y), x_{d + 1} - Ψ (r))|}^{α} \\ \times & |Φ (y)| {|ζ (r)|}^{α - \frac{α η}{α^{'}}} d σ_{s} (y) \frac{d r}{r} . \end{matrix}

(12)

Hence, Lemma 1 and Hölder’s inequality along with (11)-(12) give

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{1 / α}∥}_{L_{p} (R^{d + 1})}^{α} \\ \leq & C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'})} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α / α^{'})} \int_{R^{d + 1}} (\sum_{j \in Z} {|H_{j} (\dot{v})|}^{α}) M_{{|ζ|}^{α - \frac{α η}{α^{'}}}} \tilde{ϑ} (- \dot{x}) d \dot{x} \\ \leq & C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'})} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α / α^{'})} {∥\sum_{j \in Z} {|H_{j}|}^{α}∥}_{L_{(p / α)} (R^{d + 1})} {∥M_{{|ζ|}^{\frac{α (α^{'} - η)}{α^{'}}}} (\tilde{ϑ})∥}_{L_{{(p / α)}^{'}} (R^{d + 1})} \\ \leq & C (ln τ) C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'}) + 1} {∥Φ∥}_{L_{q} (B^{s - 1})}^{(α / α^{'}) + 1} {∥\sum_{j \in Z} {|H_{j}|}^{α}∥}_{L_{(p / α)} (R^{d + 1})} {∥\tilde{ϑ}∥}_{L_{{(p / α)}^{'}} (R^{d + 1})}, \end{matrix}

where

\tilde{ϑ} (\dot{x}) = ϑ (- \dot{x})

. Consequently, by taking the

α^{t h}

root, we finish the prove of (i) for the case

p \in (α, \frac{η α^{'}}{α^{'} - η}]

.

Case 2.

p = α

. By Hölder’s inequality, (12), and then (2), we get

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})}^{α} \leq C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'})} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α / α^{'})} \\ \times & \sum_{j \in Z} \int_{R^{d + 1}} \int_{τ^{j}}^{τ^{j + 1}} \int_{t / 2}^{t} \int_{B^{s - 1}} {|H_{j} (x - P (r y), x_{d + 1} - Ψ (r))|}^{α} |Φ (y)| {|ζ (r)|}^{α - \frac{α η}{α^{'}}} d σ_{s} (y) \frac{d r}{r} \frac{d t}{t} d \dot{x} \\ \leq & C (ln τ) {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'}) + 1} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α / α^{'}) + 1} \int_{R^{d + 1}} {(\sum_{j \in Z} {|H_{j} (\dot{x})|}^{α} d \dot{x})}^{p / α} \\ \leq & C (ln τ) {∥ζ∥}_{Θ_{η} (R_{+})}^{(α / α^{'}) + 1} {∥Φ∥}_{L_{q} (B^{s - 1})}^{(α / α^{'}) + 1} {∥\sum_{j \in Z} {|H_{j}|}^{α}∥}_{L_{1} (R^{d + 1})} . \end{matrix}

Therefore,

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{1 / α} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}

(13)

To prove part

(ii)

, we use duality. So we have a set of mappings

{ρ_{j} (\dot{v}, t)}

on

R^{d + 1} \times R_{+}

such that

{∥{∥∥ ρ_{j} ∥_{L_{α^{'}} ([τ^{j}, τ^{j + 1}], \frac{d t}{t})}∥}_{l_{α^{'}}}∥}_{L_{p^{'}} (R^{d + 1})} \leq 1

and

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{1 / α}∥}_{L_{p} (R^{d + 1})} = \int_{R^{d + 1}} \sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} (℧_{ζ, t} * H_{j}) ρ_{j} (\dot{x}, t) \frac{d t}{t} d \dot{x} . \end{matrix}

(14)

Let

A (ρ_{j}) (\dot{x}) = \sum_{j \in Z} \int_{τ^{j}}^{τ^{j}} {|℧_{ζ, t} * ρ_{j} (\dot{x}, t)|}^{α^{'}} \frac{d t}{t} .

Then again by invoking the duality, there is function

Y \in L_{{(p^{'} / α^{'})}^{'}} (R^{d + 1})

with norm 1 and

\begin{matrix} {∥{(A (ρ_{j}))}^{1 / α^{'}}∥}_{L_{p^{'}} (R^{d + 1})}^{α^{'}} = \sum_{j \in Z} \int_{R^{d + 1}} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * ρ_{j} (\dot{x}, t)|}^{α^{'}} Y (\dot{x}) \frac{d t}{t} d \dot{x} \\ \leq & C {∥ζ∥}_{Θ_{η} (R_{+})}^{(α^{'} / α)} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α^{'} / α)} {∥{℧^{*}}_{{|ζ|}^{\frac{α^{'} (α - η)}{α}}} (Y)∥}_{L_{{(p^{'} / α^{'})}^{'}} (R^{d + 1})} {∥(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|ρ_{j} (\dot{x}, t)|}^{α^{'}} \frac{d t}{t})∥}_{L_{(p^{'} / α^{'})} (R^{d + 1})} \\ \leq & C_{p} {(ln τ)}^{1 / {(\frac{α η}{α - η})}^{'}} {∥ζ∥}_{Θ_{η} (R_{+})}^{(α^{'} / α) + 1} {∥Φ∥}_{L_{1} (B^{s - 1})}^{(α^{'} / α) + 1} {∥Y∥}_{L_{{(p^{'} / α^{'})}^{'}} (R^{d + 1})} \end{matrix}

(15)

for all

p \in (\frac{η α}{η α - α + η}, α)

. Therefore, by Hölder’s inequality together with (14)-(15), we reach that

\begin{matrix} {∥{(\sum_{j \in Z} \int_{τ^{j}}^{τ^{j + 1}} {|℧_{ζ, t} * H_{j}|}^{α} \frac{d t}{t})}^{\frac{1}{α}}∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {(ln τ)}^{\frac{η α - α + η}{η α}} {∥{(\sum_{j \in Z} {|H_{j}|}^{α})}^{1 / α}∥}_{L_{p} (R^{d + 1})} . \end{matrix}

(16)

We prove part

(iii)

as follows: let

T

be the linear operator

T

defined on

H_{j}

by

T (H_{j}) = ℧_{ζ, τ^{j} t} * H_{j}

. Then

T

satisfies

\begin{matrix} {∥{∥{∥T (H_{j})∥}_{L_{1} (1, τ), \frac{d t}{t}}∥}_{l_{1} (Z)}∥}_{L_{1} (R^{d + 1})} \leq C ln (τ) {∥(\sum_{j \in Z} |H_{j}|)∥}_{L_{1} (R^{d + 1})} . \end{matrix}

(17)

Consequently, by interpolating between (4) and (17), the statement

(iii)

holds. □

3. Proof of the Main Results

Let

d_{1}, d_{2}, \dots, d_{K}

be non-negative integers with

d_{ℓ} < d_{ℓ + 1}

for all

ℓ \in {1, 2, \dots, K - 1}

. Then, any polynomial

P

can be written in the form

P (v) = \sum_{m = 1}^{K} P^{(m)} (v) + R^{(m)} (| v |),

where

v \in R^{s}

,

P^{(m)} (v) = (P_{1, m} (v), P_{2, m} (v), \dots, P_{d, m} (v))

,

{P_{i, m} (v) : 1 \leq i \leq d, 1 \leq m \leq K}

are real-valued homogeneous polynomials of degree

d_{m}

with

{| v |}^{d_{m}} \notin s p a n {P_{1, m}, \dots, P_{d, m}}

,

R^{(m)} (t) = (R_{1}^{(m)} (t), R_{2}^{(m)} (t), \dots, R_{d}^{(m)} (t))

, and

{R_{i}^{(m)} (t) : 1 \leq i \leq d, 1 \leq m \leq K}

be polynomials on

R

of degree less than

d_{m}

. Let

γ_{m}

indicate to the number of elements of

{α = (α_{1}, α_{2} \dots, α_{s}) \in {(N \cup {0})}^{s} : | α | = d_{m}} = {α (1), α (2), \dots, α (γ_{m})}

. Then

P_{i, m}

can be written in the form

P_{i, m} (v) = \sum_{n = 1}^{γ_{m}} c_{n, i} v^{α (n)}

. Define the linearfunction

L_{m} : R^{d} \to R^{γ_{m}}

by

L_{m} (ζ) = (\sum_{i = 1}^{d} c_{1, i}^{m} ζ_{i}, \dots, \sum_{i = 1}^{d} c_{γ_{m}, i}^{m} ζ_{i}),

and set

P_{m} (v) = \sum_{i = 1}^{m} P^{(i)} (v) + W (| v |)

and

P_{0} (v) = W (| v |)

. This leads to

P_{K} (v) = P (v)

. For

1 \leq m \leq K

, we let

℧_{ζ, t}^{(m)} = ℧_{Φ, P_{m}, Ψ, ζ, t}

and

℧_{ζ}^{(m) *} (V) = sup_{t \in R_{+}} | | ℧_{ζ, t}^{(m)} | * V |

.

Now, we are ready to prove our main results.

Proof of Theorem 1. Let $Φ, P, Ψ$ , and $ζ$ be given as in Theorem 1. Set $τ = 2^{η^{'} q^{'}}$ . By Minkowski’s inequality, we reach

$\begin{matrix} G_{Φ, P, Ψ, ζ}^{α} (V) (\dot{x}) \\ \leq & \sum_{j = 0}^{\infty} {(\int_{R_{+}} {|\frac{1}{t^{a}} \int_{2^{- j - 1} l < | v | \leq 2^{- j} l} V (x - P (v), x_{d + 1} - Ψ (| v |)) \frac{Φ (v) ζ (|v|)}{{|v|}^{s - a}} d v|}^{α} \frac{d t}{t})}^{1 / α} \\ \leq & C {(\int_{R_{+}} {|℧_{ζ, t}^{(K)} * V (\dot{x})|}^{α} \frac{d t}{t})}^{1 / α} . \end{matrix}$

(18)

Let

{\{φ_{j}\}}_{j \in Z}

be a set of functions satisfying

\begin{matrix} φ_{j} \in C^{\infty} (0, \infty), φ_{j} \in [0, 1], \sum_{j} φ_{j} (t) = 1, \\ supp φ_{j} & \subseteq & [τ^{- 1 - j}, τ^{1 - j}], a n d |\frac{d^{k} φ_{j} (t)}{d t^{k}}| \leq \frac{C_{k}}{t^{k}} . \end{matrix}

Define the multiplier operator

\hat{Λ_{j} V} (\dot{ξ}) = φ_{j} (|ξ|) \hat{V} (\dot{ξ})

. Thus, by (18), we get that

G_{Φ, P, Ψ, ζ}^{α} (V) \leq C K {(\int_{R_{+}} {|℧_{ζ, t}^{(K)} * V (\dot{x})|}^{α} \frac{d t}{t})}^{1 / α} \leq C \sum_{j \in Z} B_{Φ, P, Ψ, ζ, j}^{α} (V),

(19)

where

B_{Φ, P, Ψ, ζ, j}^{α} (V) (\dot{x}) = {(\int_{R_{+}} {|Γ_{Φ, P, Ψ, ζ, j} (\dot{x}, t)|}^{α} \frac{d t}{t})}^{1 / α}

and

Γ_{Φ, P, Ψ, ζ, j} (\dot{x}, t) = \sum_{k \in Z} (Λ_{k + j} * ℧_{ζ, t}^{(M)} * V) (\dot{x}) χ_{[τ^{k}, τ^{k + 1})} (t) .

Thus, to finish the proof of Theorem 1, it is enough to find a positive number

δ < 1

such that

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq 2^{- δ |j|} C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{- 1 / α} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})}; \end{matrix}

(20)

for

p \in [α, \frac{η α^{'}}{α^{'} - η}]

,

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq 2^{- δ |j|} C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{\frac{α - η α - η}{η α}} {∥V)∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} \end{matrix}

(21)

for

p \in (\frac{η α}{η α - α + η}, α);

and

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq 2^{- δ |j|} C_{p, Φ, ζ} {[(η - 1) (q - 1)]}^{\frac{α - η α + 1}{η α}} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} \end{matrix}

(22)

for

p \in (\frac{η α^{'}}{α^{'} - η}, α)

.

Let us first consider the case

p = α = 2

. Thanks to Plancherel’s theorem and the estimates of Lemma 2 in [10] we get

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{2} (R^{d + 1})}^{2} \\ \leq & \sum_{μ \in Z} \int_{Δ_{τ, j + μ}} (\int_{τ^{μ}}^{τ^{μ + 1}} {|{\hat{℧}}_{ζ, t}^{(K)} (\dot{ξ})|}^{2} \frac{d t}{t}) {|\hat{V} (\dot{ξ})|}^{2} d \dot{ξ} \\ \leq & (ln τ) C_{2, Φ, ζ}^{2} \sum_{μ \in Z} \int_{Δ_{τ, j + μ}} (min \{{|τ^{j d_{K}} ξ|}^{- \frac{δ}{ln τ}}, {|τ^{j d_{K}} ξ|}^{\frac{δ}{ln τ}}\}) {|\hat{V} (\dot{ξ})|}^{2} d \dot{ξ} \\ \leq & (ln τ) C_{2, Φ, ζ}^{2} 2^{- δ |j|} \sum_{μ \in Z} \int_{Δ_{τ, j + μ}} {|\hat{V} (\dot{ξ})|}^{2} d \dot{ξ} \\ \leq & (ln τ) C_{2, Φ, ζ}^{2} 2^{- δ |j|} {∥V∥}_{L^{2} (R^{d + 1})}^{2} = (ln τ) C_{2, Φ, ζ}^{2} 2^{- δ |j|} {∥V∥}_{{\dot{F}}_{2}^{0, 2} (R^{d + 1})}^{2}, \end{matrix}

where

Δ_{τ, μ} = \{\dot{ξ} \in R^{d + 1} : |\dot{ξ}| \in [τ^{- 1 - j}, τ^{1 - j}]\}

and

0 < δ < 1

. So,

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{2} (R^{d + 1})} \leq {[(η - 1) (q - 1)]}^{- 1 / 2} C_{2, Φ, ζ} 2^{- δ |j| / 2} {∥V∥}_{{\dot{F}}_{2}^{0, 2} (R^{d + 1})} . \end{matrix}

(23)

By invoking Lemma 3, we get

(i) For all

p \in [α, \frac{η α^{'}}{α^{'} - η}]

,

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(q - 1) (η - 1)]}^{- 1 / α} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} . \end{matrix}

(24)

(ii) For all

p \in (\frac{η α}{η α - α + η}, α)

,

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(q - 1) (η - 1)]}^{\frac{α - η α - η}{η α}} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} . \end{matrix}

(25)

(iii) For all

p \in (\frac{η α^{'}}{α^{'} - η}, α)

\begin{matrix} {∥B_{Φ, P, Ψ, ζ, j}^{α} (V)∥}_{L_{p} (R^{d + 1})} \leq C_{p, Φ, ζ} {[(q - 1) (η - 1)]}^{\frac{α - η α + 1}{η α}} {∥V∥}_{{\dot{F}}_{p}^{0, α} (R^{d + 1})} . \end{matrix}

(26)

Therefore, by interpolating between (23) and (24)-(26), we obtain (20)-(22), which gives by (18)-(19) that the conclusions of Theorem 1 hold.

Proof of Theorem 2. In fact, we can prove this theorem by employing the above arguments with employing Lemma 2 instead of Lemma 3 and replacing $τ = 2^{η^{'} q^{'}}$ by $τ = 2^{q^{'}}$ .

4. Conclusions

This research paper investigated the boundedness of

G_{Φ, P, Ψ, ζ}^{α}

from the space

{\dot{F}}_{p}^{0, α} (R^{d + 1})

to the space

L_{p} (R^{d + 1})

. For a polynomial mapping

P : R^{s} \to R^{d}

and a function

Ψ : R_{+} \to R

, where

Ψ (t) = ψ_{1} (t) + ψ_{2} (t)

,

ψ_{1}

is a polynomial, and

ψ_{2}

is positive non-decreasing on

R_{+}

, we proved the boundedness of

G_{Φ, P, Ψ, ζ}^{α}

on

L_{p} (R^{d + 1})

provided that

ζ \in Θ_{η} (R_{+})

for some

η > 1

and

Φ \in L {(log L)}^{ν} (B^{s - 1}) \cup B_{q}^{(0, ν - 1)} (B^{s - 1})

for some

ν

. The results of this paper are essential refinements, improvements, or extensions to several past known findings as those in [1,2,3,4,5,7,8,9,10,21,22,23].

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Generalized Marcinkiewicz Integral Operators Along Certain Surfaces

Abstract

Keywords:

Subject:

1. Introduction

2. Principle Lemmas

3. Proof of the Main Results

4. Conclusions

References

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