Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels

Zhang, Mingjun; Guo, Yanfeng

doi:10.1186/1029-242X-2014-371

Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels

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Published: 25 September 2014

Volume 2014, article number 371, (2014)
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Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels

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Mingjun Zhang¹ &
Yanfeng Guo¹

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Abstract

In this paper, we prove the weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels.

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1 Introduction

Let $b \in BMO (R^{n})$ and T be the Calderón-Zygmund operator, the commutator $[b, T]$ generated by b and T is defined by $[b, T] (f) (x) = b (x) T (f) (x) - T (b f) (x)$ . A classical result of Coifman et al. (see [1]) proved that the commutator $[b, T]$ is bounded on $L^{p} (R^{n})$ ( $1 < p < \infty$ ). In [2, 3], the boundedness properties of the commutators for the extreme values of p are obtained. In this paper, we will introduce the multilinear commutator of singular integral operators with non-smooth kernels and prove the weighted boundedness properties of the operator for the extreme cases.

First let us introduce some notations (see [3–12]). In this paper, Q will denote a cube of $R^{n}$ with sides parallel to the axes. For a cube Q and a function b, let $b_{Q} = {| Q |}^{- 1} \int_{Q} b (x) d x$ and $b (Q) = \int_{Q} b (x) d x$ , the sharp function of b is defined by

b^{#} (x) = sup_{Q ∋ x} \frac{1}{| Q |} \int_{Q} | b (y) - b_{Q} | d y .

It is well known that (see [6])

b^{#} (x) = sup_{Q ∋ x} inf_{c \in C} \frac{1}{| Q |} \int_{Q} | b (y) - c | d y .

Moreover, for a weight function ω (that is, a non-negative locally integrable function), b is said to belong to $BMO (ω)$ if $b^{#} \in L^{\infty} (ω)$ and define ${∥ b ∥}_{BMO (ω)} = {∥ b^{#} ∥}_{L^{\infty} (ω)}$ , if $ω = 1$ , we denote $BMO (ω) = BMO (R^{n})$ . It is well known that (see [11])

{∥ b - b_{2^{k} Q} ∥}_{BMO} \leq C k {∥ b ∥}_{BMO} .

The $A_{p}$ weight is defined by (see [6])

\begin{matrix} A_{p} = {0 < ω \in L_{loc}^{1} (R^{n}) : sup_{Q} (\frac{1}{| Q |} \int_{Q} ω (x) d x) {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{- 1 / (p - 1)} d x)}^{p - 1} < \infty}, \\ 1 < p < \infty \end{matrix}

and

A_{1} = {0 < ω \in L_{loc}^{1} (R^{n}) : sup_{Q ∋ x} \frac{1}{| Q |} \int_{Q} ω (y) d y \leq c ω (x), a.e.} .

Definition 1 A family of operators $D_{t}$ , $t > 0$ , is said to be an ‘approximation to the identity’ if, for every $t > 0$ , $D_{t}$ can be represented by the kernel $a_{t} (x, y)$ in the following sense:

D_{t} (f) (x) = \int_{R^{n}} a_{t} (x, y) f (y) d y

for every $f \in L^{p} (R^{n})$ with $p \geq 1$ , and $a_{t} (x, y)$ satisfies

| a_{t} (x, y) | \leq h_{t} (x, y) = C t^{- n / 2} s ({| x - y |}^{2} / t),

where s is a positive, bounded, and decreasing function satisfying

lim_{r \to \infty} r^{n + ϵ} s (r^{2}) = 0

for some $ϵ > 0$ .

Definition 2 A linear operator T is called the singular integral operators with non-smooth kernels if T is bounded on $L^{2} (R^{n})$ and associated with a kernel $K (x, y)$ such that

T (f) (x) = \int_{R^{n}} K (x, y) f (y) d y

for every continuous function f with compact support, and for almost all x not in the support of f.

(1)
There exists an ‘approximation to the identity’ ${B_{t}, t > 0}$ such that $T B_{t}$ has associated kernel $k_{t} (x, y)$ and there exist $c_{1}, c_{2} > 0$ so that
$\int_{| x - y | > c_{1} t^{1 / 2}} | K (x, y) - k_{t} (x, y) | d x \leq c_{2} for all y \in R^{n} .$
(2)
There exists an ‘approximation to the identity’ ${A_{t}, t > 0}$ such that $A_{t} T$ has associated kernel $K_{t} (x, y)$ which satisfies
$| K_{t} (x, y) | \leq c_{4} t^{- n / 2} if | x - y | \leq c_{3} t^{1 / 2}$

and
$| K (x, y) - K_{t} (x, y) | \leq c_{4} t^{δ / 2} {| x - y |}^{- n - δ} if | x - y | \geq c_{3} t^{1 / 2}$

for some $c_{3}, c_{4} > 0$ , $δ > 0$ .

Given some locally integrable functions $b_{j}$ ( $j = 1, \dots, m$ ). The multilinear operator associated to T is defined by

T_{b} (f) (x) = \int_{R^{n}} [\prod_{j = 1}^{m} (b_{j} (x) - b_{j} (y))] K (x, y) f (y) d y .

Definition 3 Given the ‘approximations to the identity’ ${A_{t}, t > 0}$ and a weight function ω.

(1)
The weighted BMO space associated with ${A_{t}, t > 0}$ is defined by
${BMO}_{A} (ω) = {f \in L_{loc}^{1} (R^{n}) : {∥ f ∥}_{{BMO}_{A} (ω)} < \infty},$

where
${∥ f ∥}_{{BMO}_{A} (ω)} = sup_{Q} \frac{1}{ω (Q)} \int_{Q} | f (x) - A_{t_{Q}} (f) (x) | ω (x) d x,$

$t_{Q} = l {(Q)}^{2}$ and $l (Q)$ denotes the side length of Q.
(2)
The weighted central BMO space associated with ${A_{t}, t > 0}$ is defined by
${CMO}_{A} (ω) = {f \in L_{loc}^{1} (R^{n}) : {∥ f ∥}_{{CMO}_{A} (ω)} < \infty},$

where
${∥ f ∥}_{CMO (ω)} = sup_{r > 1} \frac{1}{ω (Q (0, r))} \int_{Q} | f (x) - A_{t_{Q}} f (x) | ω (x) d x,$

and $t_{Q} = r^{2}$ .

Definition 4 Let $1 < p < \infty$ and ω be a weighted function on $R^{n}$ . We shall call $B_{p} (ω)$ the space of those functions f on $R^{n}$ , such that

{∥ f ∥}_{B_{p} (ω)} = sup_{r > 1} {[ω (Q (0, r))]}^{- 1 / p} {∥ f χ_{Q (0, r)} ∥}_{L^{p} (ω)} < \infty .

For $b_{j} \in BMO (R^{n})$ ( $j = 1, \dots, m$ ), set ${∥ \vec{b} ∥}_{BMO} = \prod_{j = 1}^{m} {∥ b_{j} ∥}_{BMO}$ . Given a positive integer m and $1 \leq j \leq m$ , we denote by $C_{j}^{m}$ the family of all finite subsets $σ = {σ (1), \dots, σ (j)}$ of ${1, \dots, m}$ of j different elements. For $σ \in C_{j}^{m}$ , set $σ^{c} = {1, \dots, m} ∖ σ$ . For $\vec{b} = (b_{1}, \dots, b_{m})$ and $σ = {σ (1), \dots, σ (j)} \in C_{j}^{m}$ , set ${\vec{b}}_{σ} = (b_{σ (1)}, \dots, b_{σ (j)})$ , $b_{σ} = b_{σ (1)} \dots b_{σ (j)}$ and ${∥ {\vec{b}}_{σ} ∥}_{BMO} = {∥ b_{σ (1)} ∥}_{BMO} \dots {∥ b_{σ (j)} ∥}_{BMO}$ .

2 Theorems and proofs

We begin with some preliminaries lemmas.

Lemma 1 ([5, 7])

Let $ω \in A_{1}$ , $1 < p \leq \infty$ , and T be the singular integral operators with non-smooth kernels. Then T is boundedness on $L^{p} (w)$ .

Lemma 2 Let $ω \in A_{1}$ , ${A_{t}, t > 0}$ be an ‘approximation to the identity’ and $b \in BMO (R^{n})$ . Then

(a)
for every $f \in L^{\infty} (R^{n})$ , $1 \leq p < \infty$ , and any cube Q,
${(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} ((b - b_{Q}) f) (y) |^{p} d y)}^{1 / p} \leq C {∥ b ∥}_{BMO} {∥ f ∥}_{L^{\infty}};$
(b)
for every $f \in B_{p} (ω)$ , $1 \leq r < p < \infty$ , and any cube Q,
${(\frac{1}{ω (Q)} \int_{Q} | A_{t_{Q}} ((b - b_{Q}) f) (y) |^{r} ω (y) d y)}^{1 / r} \leq C {∥ b ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)},$

where $t_{Q} = l {(Q)}^{2}$ and $l (Q)$ denotes the side length of Q.

Proof (a) Write

\begin{matrix} {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} ((b - b_{Q}) f) (y) |^{p} d y)}^{1 / p} \\ \leq {(\frac{1}{| Q |} \int_{Q} \int_{R^{n}} h_{t_{Q}} {(x, y)}^{p} | (b (y) - b_{Q}) f (y) |^{p} d y d x)}^{1 / p} \\ \leq {(\frac{1}{| Q |} \int_{Q} \int_{2 Q} h_{t_{Q}} {(x, y)}^{p} | (b (y) - b_{Q}) f (y) |^{p} d y d x)}^{1 / p} \\ + {(\sum_{k = 1}^{\infty} \frac{1}{| Q |} \int_{Q} \int_{2^{k + 1} Q ∖ 2^{k} Q} h_{t_{Q}} {(x, y)}^{p} | (b (y) - b_{Q}) f (y) |^{p} d y d x)}^{1 / p} \\ = I_{1} + I_{2} . \end{matrix}

We have, by Hölder’s inequality,

\begin{array}{rcl} I_{1} & \leq & {(\frac{C}{| Q | | 2 Q |} \int_{Q} \int_{2 Q} | (b (y) - b_{Q}) f (y) |^{p} d y d x)}^{1 / p} \\ \leq & C {∥ f ∥}_{L^{\infty}} {(\frac{1}{| 2 Q |} \int_{2 Q} | b (y) - b_{Q} |^{p} d y)}^{1 / p} \\ \leq & C {∥ b ∥}_{BMO} {∥ f ∥}_{L^{\infty}} . \end{array}

For $I_{2}$ , for $x \in Q$ and $y \in 2^{k + 1} Q ∖ 2^{k} Q$ , we have $| x - y | \geq 2^{k - 1} t_{Q}$ and $h_{t_{Q}} (x, y) \leq C \frac{s (2^{2 (k - 1)})}{| Q |}$ . Thus

\begin{array}{rcl} I_{2} & \leq & C \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | (b (y) - b_{Q}) f (y) |^{p} d y)}^{1 / p} \\ \leq & C {∥ f ∥}_{L^{\infty}} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | b (y) - b_{2^{k + 1} Q} |^{p} d y)}^{1 / p} \\ + C {∥ f ∥}_{L^{\infty}} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) | b_{Q} - b_{2^{k + 1} Q} | \\ \leq & C {∥ f ∥}_{L^{\infty}} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) (k + 1) {∥ b ∥}_{BMO} \\ \leq & C {∥ b ∥}_{BMO} {∥ f ∥}_{L^{\infty}}, \end{array}

where the last inequality follows from

\sum_{k = 2}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) (k + 1) \leq C \sum_{k = 2}^{\infty} k 2^{- (k - 1) ϵ} < \infty

for some $ϵ > 0$ .

(b)
Write
$\begin{matrix} {(\frac{1}{ω (Q)} \int_{Q} | A_{t_{Q}} ((b - b_{Q}) f) (y) |^{r} ω (y) d y)}^{1 / r} \\ \leq {(\frac{1}{ω (Q)} \int_{Q} \int_{R^{n}} h_{t_{Q}} {(x, y)}^{r} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y d x)}^{1 / r} \\ \leq {(\frac{1}{ω (Q)} \int_{Q} \int_{2 Q} h_{t_{Q}} {(x, y)}^{p} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y d x)}^{1 / r} \\ + {(\sum_{k = 1}^{\infty} \frac{1}{ω (Q)} \int_{Q} \int_{2^{k + 1} Q ∖ 2^{k} Q} h_{t_{Q}} {(x, y)}^{r} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y d x)}^{1 / r} \\ = I + II . \end{matrix}$

For I, since $ω \in A_{1}$ , ω satisfies the reverse of Hölder’s inequality

{(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \leq \frac{C}{| Q |} \int_{Q} ω (x) d x

for some $1 < q < \infty$ , and $\frac{ω (Q_{2})}{| Q_{2} |} \frac{| Q_{1} |}{ω (Q_{1})} \leq C$ for all cubes $Q_{1}$ , $Q_{2}$ with $Q_{1} \subset Q_{2}$ , $ω \in A_{p / r u}$ for $1 < u, v < \infty$ with $u^{'} v = q$ and $p > r u$ (see [6]). We have, by Hölder’s inequality,

\begin{matrix} I \leq {(\frac{C}{ω (Q) | Q |} \int_{Q} \int_{2 Q} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y d x)}^{1 / r} \\ \leq C {(\frac{1}{ω (Q)} \int_{2 Q} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y)}^{1 / r} \\ \leq C {[\frac{| 2 Q |}{ω (Q)} {(\frac{1}{| 2 Q |} \int_{2 Q} | b (y) - b_{Q} |^{r u^{'}} ω {(y)}^{u^{'}} d y)}^{1 / u^{'}} {(\frac{1}{| 2 Q |} \int_{2 Q} | f (y) |^{r u} d y)}^{1 / u}]}^{1 / r} \\ \leq C {(\frac{| 2 Q |}{ω (Q)})}^{1 / r} {(\frac{1}{| 2 Q |} \int_{2 Q} | b (y) - b_{Q} |^{r u^{'} v^{'}} d y)}^{1 / r u^{'} v^{'}} {(\frac{1}{| 2 Q |} \int_{2 Q} ω {(y)}^{u^{'} v} d y)}^{1 / r u^{'} v} \\ \times {(\frac{1}{| 2 Q |} \int_{2 Q} | f (y) |^{r u} d y)}^{1 / r u} \\ \leq C {∥ b ∥}_{BMO} {(\frac{| 2 Q |}{ω (2 Q)})}^{1 / r} {(\frac{ω (2 Q)}{| 2 Q |})}^{1 / r} {(\frac{1}{| 2 Q |} \int_{2 Q} | f (y) |^{r u} ω {(y)}^{\frac{r u}{p}} ω {(y)}^{- \frac{r u}{p}} d y)}^{1 / r u} \\ \leq C {∥ b ∥}_{BMO} {(\frac{1}{| 2 Q |} \int_{2 Q} {(| f (y) |^{r u} ω {(y)}^{\frac{r u}{p}})}^{\frac{p}{r u}} d y)}^{1 / p} {(\frac{1}{| 2 Q |} \int_{2 Q} ω {(y)}^{- \frac{r u}{p} \frac{p}{p - r u}} d y)}^{(p - r u) / p r u} \\ \leq C {∥ b ∥}_{BMO} {(\frac{1}{| 2 Q |})}^{1 / p} {∥ f χ_{2 Q} ∥}_{L^{p} (ω)} {(\frac{1}{| 2 Q |} \int_{2 Q} ω (y) d y)}^{- 1 / p} \\ \times {[(\frac{1}{| 2 Q |} \int_{2 Q} ω (y) d y) {(\frac{1}{| 2 Q |} \int_{2 Q} ω {(y)}^{- \frac{1}{\frac{p}{r u} - 1}} d y)}^{\frac{p}{r u} - 1}]}^{1 / p} \\ \leq C {∥ b ∥}_{BMO} ω {(2 Q)}^{- 1 / p} {∥ f χ_{2 Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ b ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)}; \\ II \leq C {(\frac{| Q |}{ω (Q)})}^{1 / r} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | (b (y) - b_{Q}) f (y) |^{r} ω (y) d y)}^{1 / r} \\ \leq C {(\frac{| Q |}{ω (Q)})}^{1 / r} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | b (y) - b_{2^{k + 1} Q} |^{r u^{'}} ω {(y)}^{u^{'}} d y)}^{1 / r u^{'}} \\ \times {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | f (y) |^{r u} d y)}^{1 / r u} \\ \leq C {(\frac{| Q |}{ω (Q)})}^{1 / r} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} | b (y) - b_{2^{k + 1} Q} |^{r u^{'} v^{'}} d y)}^{1 / r u^{'} v^{'}} \\ \times {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} ω {(y)}^{u^{'} v} d y)}^{1 / r u^{'} v} {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} f {(y)}^{r u} d y)}^{1 / r u} \\ \leq C {∥ b ∥}_{BMO} \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) (k + 1) {(\frac{| Q |}{ω (Q)} \cdot \frac{ω (2^{k + 1} Q)}{| 2^{k + 1} Q |})}^{1 / r} \\ \times {(\frac{1}{| 2^{k + 1} Q |} \int_{2^{k + 1} Q} f {(y)}^{r u} d y)}^{1 / r u} \\ \leq C \sum_{k = 1}^{\infty} 2^{(k - 1) n} s (2^{2 (k - 1)}) (k + 1) {∥ b ∥}_{BMO} ω {(2^{k + 1} Q)}^{- 1 / p} {∥ f χ_{2^{k + 1} Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ b ∥}_{BMO} {∥ f ∥}_{B_{p} (w)} . \end{matrix}

This completes the proof. □

Theorem 1 Let T be the singular integral operators with non-smooth kernels, $ω \in A_{1}$ and $\vec{b} = (b_{1}, \dots, b_{m})$ with $b_{j} \in BMO (R^{n})$ for $1 \leq j \leq m$ . Then $T_{b}$ is bounded from $L^{\infty} (ω)$ to ${BMO}_{A} (ω)$ .

Proof It suffices to prove, for $f \in C_{0}^{\infty} (R^{n})$ , the following inequality holds:

\frac{1}{ω (Q)} \int_{Q} | T_{b} (f) (x) - A_{t_{Q}} T_{b} (f) (x) | ω (x) d x \leq C {∥ f ∥}_{L^{\infty} (ω)} .

We fix a cube $Q = Q (x_{0}, d)$ . We decompose f into $f = f_{1} + f_{2}$ with $f_{1} = f χ_{Q}$ , $f_{2} = f χ_{(R^{n} ∖ Q)}$ .

When $m = 1$ , set ${(b_{1})}_{Q} = {| Q |}^{- 1} \int_{Q} b_{1} (y) d y$ , we have

\begin{array}{rcl} T_{b_{1}} (f) (x) & = & \int_{R^{n}} [(b_{1} (x) - {(b_{1})}_{Q}) - (b_{1} (y) - {(b_{1})}_{Q})] K (x, y) f (y) d y \\ = & (b_{1} (x) - {(b_{1})}_{Q}) \int_{R^{n}} K (x, y) f (y) d y - \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) K (x, y) f (y) d y \end{array}

and

A_{t_{Q}} T_{b_{1}} (f) (x) = (b_{1} (x) - {(b_{1})}_{Q}) \int_{R^{n}} K_{t} (x, y) f (y) d y - \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) K_{t} (x, y) f (y) d y .

Then

\begin{matrix} | T_{b_{1}} (f) (x) - A_{t_{Q}} T_{b_{1}} (f) (x) | \\ \leq | (b_{1} (x) - {(b_{1})}_{Q}) \int_{R^{n}} K (x, y) f (y) d y | \\ + | \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) K (x, y) f_{1} (y) d y | \\ + | (b_{1} (x) - {(b_{1})}_{Q}) \int_{R^{n}} K_{t} (x, y) f (y) d y | \\ + | \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) K_{t} (x, y) f_{1} (y) d y | \\ + | \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) (K (x, y) - K_{t} (x, y)) f_{2} (y) d y | \\ = I_{1} (x) + I_{2} (x) + I_{3} (x) + I_{4} (x) + I_{5} (x) . \end{matrix}

For $I_{1} (x)$ , let $1 / p + 1 / p^{'} = 1$ , $1 / q + 1 / q^{'} = 1$ , by the reverse of Hölder’s inequality with $1 < q < \infty$ , Lemma 1, and Hölder’s inequality, we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | I_{1} (x) | ω (x) d x \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} {(\int_{R^{n}} | T (f) (x) |^{p} ω (x) χ_{Q} (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} {(\int_{R^{n}} | f (x) |^{p} ω (x) χ_{Q} (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} {∥ f ∥}_{L^{\infty} (ω)} {(\int_{Q} ω (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {[{(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p^{'} q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / p^{'}} {∥ f ∥}_{L^{\infty} (ω)} ω {(Q)}^{1 / p} \\ \leq C ω {(Q)}^{1 / p - 1} {| Q |}^{1 / p^{'}} {∥ b_{1} ∥}_{BMO} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / p^{'} q} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $I_{2} (x)$ , taking $p > 1$ , by Hölder’s inequality, we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | I_{2} (x) | ω (x) d x \\ \leq {(\frac{1}{ω (Q)} \int_{R^{n}} | T ((b_{1} - {(b_{1})}_{Q}) f_{1}) (x) |^{p} ω (x) χ_{Q} (x) d x)}^{1 / p} \\ \leq C ω {(Q)}^{- 1 / p} {(\int_{R^{n}} | (b_{1} (x) - {(b_{1})}_{Q}) f_{1} (x) |^{p} ω (x) χ_{Q} (x) d x)}^{1 / p} \\ \leq C ω {(Q)}^{- 1 / p} {[{(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} | f (x) |^{p q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / p} \\ \leq C ω {(Q)}^{- 1 / p} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p q^{'}} d x)}^{1 / p q^{'}} {(\int_{Q} | f (x) |^{p q} ω {(x)}^{q} d x)}^{1 / p q} \\ \leq C ω {(Q)}^{- 1 / p} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p q^{'}} d x)}^{1 / p q^{'}} {(\int_{Q} ω {(x)}^{q} d x)}^{1 / p q} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C ω {(Q)}^{- 1 / p} {| Q |}^{1 / p q^{'}} {∥ b_{1} ∥}_{BMO} {| Q |}^{1 / p q} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / p q} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ b_{1} ∥}_{BMO} {(\frac{| Q |}{ω (Q)})}^{1 / p} {(\frac{1}{| Q |} \int_{Q} ω (x) d x)}^{1 / p} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $I_{3} (x)$ and $I_{4} (x)$ , we get, for $1 < p_{1}, p_{2} < \infty$ with $1 / p_{1} + 1 / p_{2} + 1 / q = 1$ ,

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | I_{3} (x) | ω (x) d x \\ \leq \frac{C}{ω (Q)} \int_{Q} | b_{1} (x) - {(b_{1})}_{Q} | | A_{t_{Q}} (f) (x) | ω (x) d x \\ \leq C \frac{| Q |}{ω (Q)} {(\frac{1}{| Q |} \int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p_{1}} d x)}^{1 / p_{1}} \\ \times {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} (f) (x) |^{p_{2}} d x)}^{1 / p_{2}} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \\ \leq C \frac{| Q |}{ω (Q)} {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} \frac{ω (Q)}{| Q |} \\ \leq C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)}, \\ \frac{1}{ω (Q)} \int_{Q} | I_{4} (x) | ω (x) d x \\ \leq \frac{1}{ω (Q)} \int_{R^{n}} | A_{t_{Q}} ((b_{1} - {(b_{1})}_{Q}) f_{1}) (x) | ω (x) d x \\ \leq C \frac{| Q |}{ω (Q)} {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} ((b_{1} - {(b_{1})}_{Q}) f_{1}) (x) |^{q^{'}} d x)}^{1 / q^{'}} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \\ \leq C \frac{| Q |}{ω (Q)} {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} \frac{ω (Q)}{| Q |} \\ \leq C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $I_{5} (x)$ , we have

\begin{array}{rcl} I_{5} (x) & = & | \int_{R^{n}} (b_{1} (y) - {(b_{1})}_{Q}) (K (x, y) - K_{t} (x, y)) f_{2} (y) d y | \\ \leq & C \sum_{k = 0}^{\infty} \int_{2^{k + 1} Q ∖ 2^{k} Q} | b_{1} (y) - {(b_{1})}_{Q} | | f (y) | \frac{d^{δ}}{{| x_{0} - y |}^{n + δ}} d y \\ \leq & C \sum_{k = 1}^{\infty} \frac{d^{δ}}{{(2^{k - 1} d)}^{n + δ}} | 2^{k} Q | {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | f (y) |^{p} d y)}^{1 / p} \\ \times {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | b_{1} (y) - {(b_{1})}_{Q} |^{p^{'}} d y)}^{1 / p^{'}} \\ \leq & C \sum_{k = 1}^{\infty} k^{m} 2^{- k δ} {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq & C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)}, \end{array}

so

\frac{1}{ω (Q)} \int_{Q} | I_{5} (x) | ω (x) d x \leq C {∥ b_{1} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} .

When $m > 1$ , set ${\vec{b}}_{Q} = ({(b_{1})}_{Q}, \dots, {(b_{m})}_{Q}) \in R^{n}$ , where ${(b_{j})}_{Q} = {| Q |}^{- 1} \int_{Q} b_{j} (y) d y$ , $1 \leq j \leq m$ , we have

\begin{array}{rcl} T_{b} (f) (x) & = & \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K (x, y) f (y) d y \\ + \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(- 1)}^{m - j} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K (x, y) f (y) d y \\ + {(- 1)}^{m} \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K (x, y) f (y) d y \end{array}

and

\begin{array}{rcl} A_{t_{Q}} T_{b} (f) (x) & = & \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K_{t} (x, y) f (y) d y \\ + \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(- 1)}^{m - j} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K_{t} (x, y) f (y) d y \\ + {(- 1)}^{m} \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K_{t} (x, y) f (y) d y, \end{array}

then

\begin{matrix} | T_{b} (f) (x) - A_{t_{Q}} T_{b} (f) (x) | \\ \leq | \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K (x, y) f (y) d y | \\ + | \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K (x, y) f (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K (x, y) f_{1} (y) d y | \\ + | \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K_{t} (x, y) f (y) d y | \\ + | \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K_{t} (x, y) f (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K_{t} (x, y) f_{1} (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) (K (x, y) - K_{t} (x, y)) f_{2} (y) d y | \\ = J_{1} (x) + J_{2} (x) + J_{3} (x) + J_{4} (x) + J_{5} (x) + J_{6} (x) + J_{7} (x) . \end{matrix}

For $J_{1} (x)$ , same as $m = 1$ , for some $1 < q < \infty$ , let $1 / q_{1} + 1 / q_{2} + \dots + 1 / q_{m} + 1 / q = 1$ , $1 / p + 1 / p^{'} = 1$ , by Hölder’s inequality, and the reverse of Hölder’s inequality, we get

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | J_{1} (x) | ω (x) d x \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) |^{p^{'}} ω (x) d x)}^{1 / p^{'}} \\ \times {(\int_{Q} | T (f) (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | b_{1} (x) - {(b_{1})}_{Q} |^{p^{'}} \dots | b_{m} (x) - {(b_{m})}_{Q} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} \\ \times {∥ f ∥}_{L^{\infty} (ω)} {(\int_{Q} ω (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {∥ f ∥}_{L^{\infty} (ω)} ω {(Q)}^{1 / p} \prod_{j = 1}^{m} {[{(\int_{Q} | b_{j} (x) - {(b_{j})}_{Q} |^{p^{'} q_{j}} d x)}^{1 / q_{j}} {(\int_{Q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / p^{'}} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} ω {(Q)}^{1 / p^{'} + 1 / p - 1} {| Q |}^{1 / p^{'} (1 / q_{1} + \dots + 1 / q_{m} + 1 / q - 1)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $J_{2} (x)$ , by Hölder’s inequality and the reverse of Hölder’s inequality, we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | J_{2} (x) | ω (x) d x \\ \leq \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} \frac{C}{ω (Q)} {(\int_{Q} | {(b (x) - b_{Q})}_{σ} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} \\ \times {(\int_{Q} | T ({(b - b_{Q})}_{σ^{c}} f) (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(\frac{1}{ω (Q)} \int_{Q} | {(b (x) - b_{Q})}_{σ} |^{p^{'}} ω (x) d x)}^{1 / p^{'}} \\ \times {(\frac{1}{ω (Q)} \int_{Q} | T ({(b - b_{Q})}_{σ^{c}} f) (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / p^{'}} {[{(\int_{Q} | {(b (x) - b_{Q})}_{σ} |^{p^{'} q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / p^{'}} \\ \times ω {(Q)}^{- 1 / p} {(\int_{R^{n}} | {(b (x) - b_{Q})}_{σ^{c}} f (x) |^{p} ω (x) χ_{Q} (x) d x)}^{1 / p} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / p^{'}} {| Q |}^{1 / p^{'} q^{'} + 1 / p^{'} q - 1 / p^{'}} ω {(Q)}^{1 / p^{'}} {∥ {\vec{b}}_{σ} ∥}_{BMO} \\ \times ω {(Q)}^{- 1 / p} {(\int_{Q} | {(b (x) - b_{Q})}_{σ^{c}} |^{p q^{'}} d x)}^{1 / p q^{'}} {(\int_{Q} | f (x) |^{p q} ω^{q} (x) d x)}^{1 / p q} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {∥ {\vec{b}}_{σ} ∥}_{BMO} {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} {(\frac{| Q |}{ω (Q)})}^{1 / p} \\ \times {(\frac{1}{| Q |} \int_{Q} ω (x) d x)}^{1 / p} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $J_{3} (x)$ , taking $p > 1$ , by the $L^{p} (ω)$ -boundedness of T, we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | J_{3} (x) | ω (x) d x \\ \leq {(\frac{1}{ω (Q)} \int_{R^{n}} | T ((b_{1} - {(b_{1})}_{Q}) \dots (b_{m} - {(b_{m})}_{Q}) f_{1}) (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq C ω {(Q)}^{- 1 / p} {(\int_{R^{n}} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) f_{1} (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq C ω {(Q)}^{- 1 / p} {| Q |}^{1 / p q^{'}} {∥ \vec{b} ∥}_{BMO} {| Q |}^{1 / p q} {(\frac{1}{| Q |} \int_{Q} ω^{q} d x)}^{1 / p q} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {(\frac{| Q |}{ω (Q)})}^{1 / p} {(\frac{ω (Q)}{| Q |})}^{1 / p} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $J_{4} (x)$ , $J_{5} (x)$ , and $J_{6} (x)$ , choose $1 < p, q_{j} < \infty$ , $j = 1, \dots, m$ , such that $1 / p + 1 / q_{1} + \dots + 1 / q_{m} + 1 / q$ , by Lemma 2 and similar to the proofs of $J_{1} (x)$ , $J_{2} (x)$ , and $J_{3} (x)$ , we get

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | J_{4} (x) | ω (x) d x \\ \leq C \frac{| Q |}{ω (Q)} \prod_{j = 1}^{m} {(\frac{1}{| Q |} \int_{Q} | (b_{j} (x) - {(b_{j})}_{Q}) |^{q_{j}} d x)}^{1 / q_{j}} \\ \times {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} (f) (x) |^{p} d x)}^{1 / p} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)}, \\ \frac{1}{ω (Q)} \int_{Q} | J_{5} (x) | ω (x) d x \\ \leq C \frac{| Q |}{ω (Q)} \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(\frac{1}{| Q |} \int_{Q} {| {(b (x) - b_{Q})}_{σ} |}^{q^{'}} d x)}^{1 / q^{'}} \\ \times {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} ({(b - b_{Q})}_{σ^{c}} f) (x) |^{p} d x)}^{1 / p} {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \\ \leq C \frac{| Q |}{ω (Q)} \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {∥ {\vec{b}}_{σ} ∥}_{BMO} {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} \frac{ω (Q)}{| Q |} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)}, \\ \frac{1}{ω (Q)} \int_{Q} | J_{6} (x) | ω (x) d x \\ \leq C \frac{| Q |}{ω (Q)} {(\frac{1}{| Q |} \int_{Q} | A_{t_{Q}} ((b_{1} - {(b_{1})}_{Q}) \dots (b_{m} - {(b_{m})}_{Q}) f_{1}) (x) |^{q^{'}} d x)}^{1 / q^{'}} \\ \times {(\frac{1}{| Q |} \int_{Q} ω {(x)}^{q} d x)}^{1 / q} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} . \end{matrix}

For $J_{7} (x)$ , note that $| x - y | \geq d = t^{1 / 2}$ , taking $1 < q_{j} < \infty$ , $j = 1, \dots, m$ such that $1 / q_{1} + \dots + 1 / q_{m} + 1 / r = 1$ , then

\begin{array}{rcl} J_{7} (x) & \leq & C \sum_{k = 0}^{\infty} \int_{2^{k + 1} Q ∖ 2^{k} Q} \prod_{j = 1}^{m} | (b_{j} (y) - {(b_{j})}_{Q}) | | f (y) | \frac{d^{δ}}{{| x_{0} - y |}^{n + δ}} d y \\ \leq & C \sum_{k = 1}^{\infty} \frac{d^{δ}}{{(2^{k - 1} d)}^{n + δ}} | 2^{k} Q | {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | f (y) |^{r} d y)}^{1 / r} \\ \times \prod_{j = 1}^{m} {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | b_{j} (y) - {(b_{j})}_{Q} |^{q_{j}} d y)}^{1 / q_{j}} \\ \leq & C \sum_{k = 1}^{\infty} 2^{- k δ} {∥ f ∥}_{L^{\infty} (ω)} \prod_{j = 1}^{m} {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | b_{j} (y) - {(b_{j})}_{Q} |^{q_{j}} d y)}^{1 / q_{j}} \\ \leq & C \sum_{k = 1}^{\infty} k^{m} 2^{- k δ} \prod_{j = 1}^{m} {∥ b_{j} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} \\ \leq & C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)}, \end{array}

so

\frac{1}{ω (Q)} \int_{Q} | J_{7} (x) | ω (x) d x \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{L^{\infty} (ω)} .

This completes the proof of Theorem 1. □

Theorem 2 Let $1 < p < \infty$ , $ω \in A_{1}$ and $\vec{b} = (b_{1}, \dots, b_{m})$ with $b_{j} \in BMO (R^{n})$ for $1 \leq j \leq m$ . Then $T_{b}$ is bounded from $B_{p} (ω)$ to ${CMO}_{A} (ω)$ .

Proof It suffices to prove for $f \in C_{0}^{\infty} (R^{n})$ , the following inequality holds:

\frac{1}{ω (Q)} \int_{Q} | T_{b} (f) (x) - A_{t_{Q}} T_{b} (f) (x) | ω (x) d x \leq C {∥ f ∥}_{B_{p} (ω)}

for any cube $Q = Q (0, d)$ with $d > 1$ . Fix a cube $Q = Q (0, d)$ with $d > 1$ . Set $f_{1} = f χ_{Q}$ , $f_{2} = f χ_{(R^{n} ∖ Q)}$ and ${\vec{b}}_{Q} = ({(b_{1})}_{Q}, \dots, {(b_{m})}_{Q}) \in R^{n}$ , where ${(b_{j})}_{Q} = {| Q |}^{- 1} \int_{Q} | b_{j} (y) | d y$ , $1 \leq j \leq m$ , we have

\begin{matrix} | T_{b} (f) (x) - A_{t_{Q}} T_{b} (f) (x) | \\ \leq | \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K (x, y) f (y) d y | \\ + | \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K (x, y) f (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K (x, y) f_{1} (y) d y | \\ + | \prod_{j = 1}^{m} (b_{j} (x) - {(b_{j})}_{Q}) \int_{R^{n}} K_{t} (x, y) f (y) d y | \\ + | \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(b (x) - {(b)}_{Q})}_{σ} \int_{R^{n}} {(b (y) - {(b)}_{Q})}_{σ^{c}} K_{t} (x, y) f (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) K_{t} (x, y) f_{1} (y) d y | \\ + | \int_{R^{n}} \prod_{j = 1}^{m} (b_{j} (y) - {(b_{j})}_{Q}) (K (x, y) - K_{t} (x, y)) f_{2} (y) d y | \\ = L_{1} (x) + L_{2} (x) + L_{3} (x) + L_{4} (x) + L_{5} (x) + L_{6} (x) + L_{7} (x) . \end{matrix}

For $L_{1} (x)$ , we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | L_{1} (x) | ω (x) d x \\ \leq \frac{C}{ω (Q)} {(\int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) |^{p^{'}} ω (x) d x)}^{1 / p^{'}} \\ \times {(\int_{Q} | T (f) (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {[{(\int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) |^{p^{'} q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / p^{'}} \\ \times {(\int_{Q} | f (x) |^{p} ω (x) d x)}^{1 / p} \\ \leq \frac{C}{ω (Q)} {| Q |}^{1 / p^{'} q^{'}} {∥ \vec{b} ∥}_{BMO} {| Q |}^{1 / p^{'} q} {(\frac{ω (Q)}{| Q |})}^{1 / p^{'}} {∥ f χ_{Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} ω {(Q)}^{- 1 / p} {∥ f χ_{Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} . \end{matrix}

For $L_{2} (x)$ , taking $1 < s, s^{'} < \infty$ , and $1 / s + 1 / s^{'} = 1$ , we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | L_{2} (x) | ω (x) d x \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(\frac{1}{ω (Q)} \int_{Q} | {(b (x) - b_{Q})}_{σ} |^{s^{'}} ω (x) d x)}^{1 / s^{'}} \\ \times {(\frac{1}{ω (Q)} \int_{Q} | T ({(b - b_{Q})}_{σ^{c}} f) (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / s^{'}} {[{(\int_{Q} | {(b (x) - b_{Q})}_{σ} |^{s^{'} q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} ω^{q} d x)}^{1 / q}]}^{1 / s^{'}} \\ \times ω {(Q)}^{- 1 / s} {(\int_{Q} | {(b (x) - b_{Q})}_{σ^{c}} f (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / s^{'}} {| Q |}^{1 / s^{'} q^{'} + 1 / s^{'} q - 1 / s^{'}} ω {(Q)}^{1 / s^{'}} {∥ {\vec{b}}_{σ} ∥}_{BMO} \\ \times ω {(Q)}^{- 1 / s} {| Q |}^{1 / r s} {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} {(\int_{Q} | f (x) |^{p} ω (x) d x)}^{1 / p} {(\int_{Q} ω {(x)}^{q} d x)}^{(p - s) / p q s} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {∥ {\vec{b}}_{σ} ∥}_{BMO} {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} ω {(Q)}^{- 1 / p} {∥ f χ_{Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} . \end{matrix}

For $L_{3} (x)$ , we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | L_{3} (x) | ω (x) d x \\ \leq C {(\frac{1}{ω (Q)} \int_{R^{n}} | T ((b_{1} - {(b_{1})}_{Q}) \dots (b_{m} - {(b_{m})}_{Q}) f_{1}) (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C ω {(Q)}^{- 1 / s} {(\int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) f (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C ω {(Q)}^{- 1 / p} {∥ \vec{b} ∥}_{BMO} {∥ f χ_{Q} ∥}_{L^{p} (ω)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} . \end{matrix}

For $L_{4} (x)$ , $L_{5} (x)$ , and $L_{6} (x)$ , by Lemma 2, we have

\begin{matrix} \frac{1}{ω (Q)} \int_{Q} | L_{4} (x) | ω (x) d x \\ \leq C {(\frac{1}{ω (Q)} \int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) |^{s^{'}} ω (x) d x)}^{1 / s^{'}} \\ \times {(\frac{1}{ω (Q)} \int_{Q} | A_{t_{Q}} (f) (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C {(\frac{1}{ω (Q)})}^{1 / s^{'}} [{(\int_{Q} | (b_{1} (x) - {(b_{1})}_{Q}) \dots (b_{m} (x) - {(b_{m})}_{Q}) |^{s^{'} q^{'}} d x)}^{1 / q^{'}} \\ {\times {(\int_{Q} ω {(x)}^{q} d x)}^{1 / q}]}^{1 / s^{'}} {∥ f ∥}_{B_{p} (w)} \\ \leq C {(\frac{1}{ω (Q)})}^{1 / s^{'}} {| Q |}^{1 / s^{'} q^{'}} {∥ \vec{b} ∥}_{BMO} {| Q |}^{1 / s^{'} q} {(\frac{ω (Q)}{| Q |})}^{1 / s^{'}} {∥ f ∥}_{B_{p} (w)} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)}; \\ \frac{1}{ω (Q)} \int_{Q} | L_{5} (x) | ω (x) d x \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} {(\frac{1}{ω (Q)} \int_{Q} | {(b (x) - b_{Q})}_{σ} |^{s^{'}} ω (x) d x)}^{1 / s^{'}} \\ \times {(\frac{1}{ω (Q)} \int_{Q} | A_{t_{Q}} ({(b - b_{Q})}_{σ^{c}} f) (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / s^{'}} {[{(\int_{Q} | {(b (x) - b_{Q})}_{σ} |^{s^{'} q^{'}} d x)}^{1 / q^{'}} {(\int_{Q} ω^{q} d x)}^{1 / q}]}^{1 / s^{'}} \\ \times {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} \\ \leq C \sum_{j = 1}^{m - 1} \sum_{σ \in C_{j}^{m}} ω {(Q)}^{- 1 / s^{'}} {| Q |}^{1 / s^{'} q^{'} + 1 / s^{'} q - 1 / s^{'}} ω {(Q)}^{1 / s^{'}} {∥ {\vec{b}}_{σ} ∥}_{BMO} {∥ {\vec{b}}_{σ^{c}} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} \\ \leq C {∥ {\vec{b}}_{σ} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)}; \\ \frac{1}{ω (Q)} \int_{Q} | L_{6} (x) | ω (x) d x \\ \leq {(\frac{1}{ω (Q)} \int_{R^{n}} | A_{t_{Q}} ((b_{1} - {(b_{1})}_{Q}) \dots (b_{m} - {(b_{m})}_{Q}) f_{1}) (x) |^{s} ω (x) d x)}^{1 / s} \\ \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} . \end{matrix}

For $L_{7} (x)$ , note that $| x - y | \geq d = t^{1 / 2}$ , taking $1 < u < p$ , then

\begin{array}{rcl} L_{7} (x) & \leq & C \int_{Q^{c}} \prod_{j = 1}^{m} | b_{j} (y) - {(b_{j})}_{Q} | | f (y) | \frac{d^{δ}}{{| x_{0} - y |}^{n + δ}} d y \\ \leq & C \sum_{k = 0}^{\infty} \int_{2^{k + 1} Q ∖ 2^{k} Q} \prod_{j = 1}^{m} | b_{j} (y) - {(b_{j})}_{Q} | | f (y) | \frac{d^{δ}}{{| x_{0} - y |}^{n + δ}} d y \\ \leq & C \sum_{k = 1}^{\infty} \frac{d^{δ}}{{(2^{k - 1} d)}^{n + δ}} | 2^{k} Q | {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} | f (y) |^{u} d y)}^{1 / u} \\ \times {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} \prod_{j = 1}^{m} | b_{j} (y) - {(b_{j})}_{Q} |^{u^{'}} d y)}^{1 / u^{'}} \\ \leq & C {∥ \vec{b} ∥}_{BMO} \sum_{k = 1}^{\infty} k^{m} 2^{- k δ} {(\frac{1}{| 2^{k} Q |})}^{1 / u} \\ \times {[{(\int_{2^{k} Q} | f (y) |^{p} ω (y) d y)}^{\frac{u}{p}} {(\int_{2^{k} Q} ω {(y)}^{- \frac{u}{p - u}} d y)}^{\frac{p - u}{p}}]}^{1 / u} \\ \leq & C {∥ \vec{b} ∥}_{BMO} \sum_{k = 1}^{\infty} k^{m} 2^{- k δ} {(\frac{1}{| 2^{k} Q |})}^{1 / u} {∥ f χ_{2^{k} Q} ∥}_{L^{p} (ω)} {(\frac{ω (2^{k} Q)}{| 2^{k} Q |})}^{- 1 / p} | 2^{k} Q |^{(\frac{p}{u} - 1) \frac{1}{p}} \\ \times {[(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} ω (y) d y) {(\frac{1}{| 2^{k} Q |} \int_{2^{k} Q} ω {(y)}^{- \frac{1}{\frac{p}{u} - 1}} d y)}^{\frac{p}{u} - 1}]}^{1 / p} \\ \leq & C {∥ \vec{b} ∥}_{BMO} \sum_{k = 1}^{\infty} k^{m} 2^{- k δ} ω {(2^{k} Q)}^{- 1 / p} {∥ f χ_{2^{k} Q} ∥}_{L^{p} (ω)} \\ \leq & C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)}, \end{array}

so

\frac{1}{ω (Q)} \int_{Q} | L_{7} (x) | ω (x) d x \leq C {∥ \vec{b} ∥}_{BMO} {∥ f ∥}_{B_{p} (ω)} .

This completes the proof of Theorem 2. □

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Project was supported by the National Natural Science Foundation of China (No. 11061003).

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Mingjun Zhang & Yanfeng Guo

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Zhang, M., Guo, Y. Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels. J Inequal Appl 2014, 371 (2014). https://doi.org/10.1186/1029-242X-2014-371

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Received: 09 February 2014
Accepted: 29 August 2014
Published: 25 September 2014
DOI: https://doi.org/10.1186/1029-242X-2014-371

Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels

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Weighted endpoint estimates for multilinear commutator of singular integral operators with non-smooth kernels

Abstract

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An Endpoint Estimate for the Commutators of Singular Integral Operators with Rough Kernels

Multilinear singular integral operators with generalized kernels and their multilinear commutators

Multiple Weighted Norm Inequalities for Multilinear Strongly Singular Integral Operators with Generalized Kernels

1 Introduction

2 Theorems and proofs

References

Acknowledgements

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