The boundedness of commutators of rough p-adic fractional Hardy type operators on Herz-type spaces

Hussain, Amjad; Sarfraz, Naqash; Khan, Ilyas; Alsubie, Abdelaziz; Hamadneh, Nawaf N.

doi:10.1186/s13660-021-02650-7

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Published: 21 July 2021

The boundedness of commutators of rough p-adic fractional Hardy type operators on Herz-type spaces

Amjad Hussain¹,
Naqash Sarfraz²,
Ilyas Khan³,
Abdelaziz Alsubie⁴ &
…
Nawaf N. Hamadneh⁴

Journal of Inequalities and Applications volume 2021, Article number: 123 (2021) Cite this article

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Abstract

In this paper, we obtain some inequalities about commutators of a rough p-adic fractional Hardy-type operator on Herz-type spaces when the symbol functions belong to two different function spaces.

1 Introduction

During the last several decades, the p-adic analysis has cemented its role in the field of mathematical physics (see, for example, [1, 22, 32, 33]). That stimulates researchers to pay attention to harmonic analysis on p-adic fields [18–21, 24, 30, 31, 35], which has direct implications in the stochastic process [2, 3], theoretical biology [6], and p-adic pseudo-differential equations [23, 34]. In continuation of the ongoing research, the present paper considers an extension of the investigation of p-adic Hardy-type operators discussed in [19–21, 25, 36, 37].

For every non-zero rational number x there is a unique $\gamma =\gamma (x)\in \mathbb{Z}$ such that $x=p^{\gamma }m/n$, where $p\geq 2$ is a fixed prime number which is coprime to $m,n\in \mathbb{Z}$. We define a mapping $|\cdot |_{p}:\mathbb{Q}\rightarrow \mathbb{R_{+}}$ as follows:

$$ \vert x \vert _{p}= \textstyle\begin{cases} p^{-\gamma } & \text{if } x\neq 0, \\ 0 & \text{if } x=0. \end{cases} $$

(1.1)

The p-adic absolute value $|\cdot |_{p}$ has many properties of the usual real norm $|\cdot |$ with an additional non-Archimedean property,

$$ \vert x+y \vert _{p}\le \max \bigl\{ \vert x \vert _{p}, \vert y \vert _{p}\bigr\} . $$

The field of p-adic numbers, denoted by $\mathbb{Q}_{p}$, is the completion of rational numbers with respect to the p-adic absolute value $|\cdot |_{p}$. A p-adic number $x\in \mathbb{Q}_{p}$ can be written in the formal power series as [34]:

$$ x=p^{\gamma }\bigl(\beta _{0}+\beta _{1}p+\beta _{2}p^{2}+\cdots \bigr), $$

(1.2)

where $\gamma \in \mathbb{Z}$ and $\beta _{i}\in \{0,1,\ldots ,p-1\}$, $i=0,1,2,\ldots $ . The p-adic absolute value ensures the convergence of series (1.2) in $\mathbb{Q}_{p}$, because the inequality $|p^{\gamma }\beta _{i}p^{i}|_{p}\leq p^{-\gamma -i}$ holds for all $\gamma \in \mathbb{Z}$ and $i \in \mathbb{N}$.

The n-dimensional vector space $\mathbb{Q}_{p}^{n}$, $n \geq 1$, consists of the vectors $\mathbf{x} = (x_{1}, x_{2}, \ldots ,x_{n})$, where $x_{j}\in \mathbb{Q}_{p}$ and $j=1,2,\ldots ,n$, with the following absolute value:

$$ \vert \mathbf{x} \vert _{p}=\max _{1\leq k \leq n} \vert x_{k} \vert _{p}. $$

(1.3)

For $\gamma \in \mathbb{Z}$ and $\mathbf{a}=(a_{1}, a_{2}, \ldots , a_{n}) \in \mathbb{Q}_{p}^{n}$, we denote by

$$ B_{\gamma }(\mathbf{a})=\bigl\{ \mathbf{x} \in \mathbb{Q}_{p}^{n} \colon \vert \mathbf{x}-\mathbf{a} \vert _{p} \leq p^{\gamma }\bigr\} $$

the closed ball with the center a and radius $p^{\gamma }$ and by

$$ S_{\gamma }(\mathbf{a})=\bigl\{ \mathbf{x} \in \mathbb{Q}_{p}^{n} \colon \vert \mathbf{x}-\mathbf{a} \vert _{p} = p^{\gamma }\bigr\} $$

the corresponding sphere. For $\mathbf{a}=\mathbf{0}$, we write $B_{\gamma }(\mathbf{0})=B_{\gamma }$, and $S_{\gamma }(\mathbf{0})=S_{\gamma }$. It is easy to see that the equalities

$$ \mathbf{a}_{0} + B_{\gamma }=B_{\gamma }( \mathbf{a}_{0}) \quad \text{and} \quad \mathbf{a}_{0} + S_{\gamma }= S_{\gamma }(\mathbf{a}_{0}) = B_{\gamma }(\mathbf{a}_{0}) \setminus B_{\gamma -1}( \mathbf{a}_{0}) $$

hold for all $\mathbf{a}_{0}\in \mathbb{Q}_{p}^{n}$ and $\gamma \in \mathbb{Z}$.

Since $\mathbb{Q}_{p}^{n}$ is a locally compact commutative group under addition, there exists a unique Haar measure dx on $\mathbb{Q}_{p}^{n}$, such that

$$ \int _{B_{0}}d\mathbf{x}= \vert B_{0} \vert _{h} =1, $$

where $|B|_{h}$ denotes the Haar measure of measurable subset B of $\mathbb{Q}_{p}^{n}$. Furthermore, a simple calculation shows that

$$ \bigl\vert B_{\gamma }(\mathbf{a}) \bigr\vert _{h} = p^{n\gamma } \quad \text{and}\quad \bigl\vert S_{ \gamma }(\mathbf{a}) \bigr\vert _{h} = p^{n\gamma }\bigl(1-p^{-n}\bigr) $$

hold for all $\mathbf{a}\in \mathbb{Q}_{p}^{n}$ and $\gamma \in \mathbb{Z}$.

The one-dimensional Hardy operator

$$ \mathcal{H}f(x)=\frac{1}{x} \int _{0}^{x}f(y)\,dy,\quad x>0, $$

where $f \colon \mathbb{R}^{+} \to \mathbb{R}^{+}$ is a measurable functions, was introduced by Hardy in [13]. This operator satisfies the inequality:

$$ \Vert \mathcal{H} f \Vert _{L^{q}(\mathbb{R}^{+})}\leq \frac{q}{q-1} \Vert f \Vert _{L^{q}( \mathbb{R}^{+})},\quad 1< q< \infty , $$

(1.4)

where the constant $q/(q-1)$ is sharp. In [7], Faris proposed an extension of the operator $\mathcal{H}$ on higher dimensional Euclidean space $\mathbb{R}^{n}$ which is given by

$$ Hf(\mathbf{x}) = \frac{1}{ \vert \mathbf{x} \vert ^{n}} \int _{ \vert \mathbf{y} \vert \leq \vert \mathbf{x} \vert } f(\mathbf{y}) \,d\mathbf{y}, $$

(1.5)

for $\mathbf{x} = (x_{1}, \ldots , x_{n})$. In addition, Christ and Grafakos [4] obtained the exact value of the norm of operator H defined by (1.5). For boundedness results for these operators on function spaces we refer to some recent publications including [8, 10, 16, 17, 28, 29, 38].

On the other hand, the n-dimensional fractional p-adic Hardy operator

$$ H^{p}_{\alpha } f(\mathbf{x}) = \frac{1}{ \vert \mathbf{x} \vert _{p}^{n-\alpha }} \int _{ \vert \mathbf{y} \vert _{p}\leq \vert \mathbf{x} \vert _{p}}f(\mathbf{y})\,d\mathbf{y} $$

was defined and studied for $f\in L_{1}^{\mathrm{loc}}(\mathbb{Q}_{p}^{n})$ and $0\le \alpha < n$ in [36]. When $\alpha =0$, the operator $H^{p}_{\alpha }$ transfers to the p-adic Hardy-type operator (see [10] for more details). Fu et al. in [9], fixed the optimal bounds of p-adic Hardy operator on $L^{q}(\mathbb{Q}_{p}^{n})$. On the central Morrey space the p-adic Hardy-type operators and their commutators were discussed in [37]. In this connection see also [19, 21, 25].

There is still zero attention towards the rough Hardy operators on the p-adic linear spaces. Motivated by papers cited above and results of Fu et al. in [8], we define the special kind of p-adic rough fractional Hardy operator $H^{p}_{\Omega ,\alpha }$ and its commutators as follows.

Definition 1.1

Let $f \colon \mathbb{Q}_{p}^{n} \to \mathbb{R}$, $b \colon \mathbb{Q}_{p}^{n} \to \mathbb{R}$ be measurable mappings and let $0<\alpha <n$. Then, for $\mathbf{x} \in \mathbb{Q}_{p}^{n} \setminus \{\mathbf{0}\}$, we define the rough p-adic fractional Hardy operator $H^{p}_{\Omega , \alpha }$ by

$$ H^{p}_{\Omega , \alpha } f(\mathbf{x}) = \frac{1}{ \vert \mathbf{x} \vert _{p}^{n-\alpha }} \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f( \mathbf{y}) \,d\mathbf{y}, $$

(1.6)

and its commutator $H^{p,b}_{\Omega ,\alpha }$ by

$$ H^{p,b}_{\Omega ,\alpha } f(\mathbf{x}) = \frac{1}{ \vert \mathbf{x} \vert _{p}^{n-\alpha }} \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \bigl(b (\mathbf{x}) -b(\mathbf{y} )\bigr) \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f( \mathbf{y})\,d\mathbf{y}, $$

(1.7)

whenever

$$ \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \bigl\vert \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f(\mathbf{y}) \bigr\vert \,d\mathbf{y} < \infty $$

(1.8)

and

$$ \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \bigl\vert b(\mathbf{y}) \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f(\mathbf{y}) \bigr\vert \,d\mathbf{y} < \infty , $$

(1.9)

where $\Omega \in L^{s}(S_{0}(\mathbf{0}))$, $1\leq s<\infty $.

Remark 1.2

Obviously

$$ \bigl\{ \vert \mathbf{y} \vert _{p} \colon \mathbf{y} \in \mathbb{Q}_{p}^{n}\bigr\} = \bigl\{ p^{ \gamma } \colon \gamma \in \mathbb{Z}\bigr\} \cup \{0\} $$

holds for every integer $n \geq 1$ and prime $p \geq 2$. Since the inclusion

$$ \{0\} \cup \bigl\{ p^{\gamma } \colon \gamma \in \mathbb{Z}\bigr\} \subseteq \mathbb{Q}_{p} $$

holds and $\mathbb{Q}_{p}^{n}$ is a linear space over field $\mathbb{Q}_{p}$, the product $|\mathbf{y}|_{p} \mathbf{y}$ is well defined. Moreover, if a non-zero $\mathbf{y} \in \mathbb{Q}_{p}^{n}$ has the form $\mathbf{y} = (y_{1}, \ldots , y_{n})$ and

$$ y_{i} = p^{\gamma _{i}} \bigl(\beta _{0, i} + \beta _{1, i} p + \beta _{2, i} p^{2} + \cdots \bigr),\quad i = 1, \ldots , n $$

(1.10)

(see (1.2)), then there is $i_{0} \in \{1, \ldots , n\}$ such that

$$ \vert y_{i_{0}} \vert _{p} = p^{-\gamma _{i_{0}}} \geq p^{-\gamma _{i}} = \vert y_{i} \vert _{p} $$

(1.11)

whenever $y_{i} \neq 0$. Using (1.3) we obtain $|\mathbf{y}|_{p} = p^{-\gamma _{i_{0}}}$. Now from (1.10) and (1.11) it follows that

$$ \bigl\vert \vert \mathbf{y}|_{p} \mathbf{y}\bigr|_{p} = \max _{ \substack{1 \leq i \leq n \\ y_{i} \neq 0}} \bigl\vert p^{\gamma _{i} - \gamma _{i_{0}}} \bigr\vert _{p} = \max_{\substack{1 \leq i \leq n \\ y_{i} \neq 0}} p^{\gamma _{i_{0}} - \gamma _{i}} = p^{\gamma _{i_{0}} - \gamma _{i_{0}}} = 1. $$

Thus, for every non-zero $\mathbf{y} \in \mathbb{Q}_{p}^{n}$, the vector $|\mathbf{y}|_{p} \mathbf{y}$ belongs to the sphere

$$ S_{0}(\mathbf{0}) = \bigl\{ \mathbf{y} \in \mathbb{Q}_{p}^{n} \colon \vert \mathbf{y} \vert _{p} = 1\bigr\} . $$

From (1.8) it directly follows that $H^{p}_{\Omega , \alpha } \in \mathbb{R}$ for every non-zero $\mathbf{x} \in \mathbb{Q}_{p}^{n}$ and using (1.8), (1.9) we have

$$\begin{aligned} \bigl\vert H^{p, b}_{\Omega , \alpha } f(\mathbf{x}) \bigr\vert & \leq \frac{ \vert b(\mathbf{x}) \vert }{ \vert \mathbf{x} \vert _{p}^{n-\alpha }} \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \bigl\vert \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f(\mathbf{y}) \bigr\vert \,d\mathbf{y} \\ & \quad {}+ \frac{1}{ \vert \mathbf{x} \vert _{p}^{n-\alpha }} \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \bigl\vert b(\mathbf{y}) \Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y} \bigr) f(\mathbf{y}) \bigr\vert \,d\mathbf{y} < \infty \end{aligned}$$

for every $\mathbf{x} \in \mathbb{Q}_{p}^{n} \setminus \{\mathbf{0}\}$. Consequently, the operators $H^{p}_{\Omega , \alpha }$ and $H^{p,b}_{\Omega ,\alpha }$ are well defined.

The aim of the current paper is to study the boundedness of $H^{p,b}_{\Omega ,\alpha }$ on p-adic Herz-type spaces by considering the symbol function b belonging to the p-adic CMO and Lipschitz spaces. In Euclidean space $\mathbb{R}^{n}$, Herz spaces and Morrey–Herz spaces were firstly introduced in [14] and [26], respectively. For more recent developments in the said spaces we mention the articles [15, 27, 39] and the references therein. Also, some operators with rough kernels defined on Euclidian space were recently studied on function spaces; see for example [11, 12]. Before turning to our main results, let us recall the definitions of p-adic function spaces first.

Definition 1.3

([9])

Suppose $1< q<\infty $. The p-adic central bounded mean oscillation (CBMO) space $C\dot{M}O^{q}(\mathbb{Q}_{p}^{n})$ is the set of all measurable functions $f \colon \mathbb{Q}_{p}^{n} \to \mathbb{R}$ which satisfy

$$ \Vert f \Vert _{\mathit{CMO}^{q}(\mathbb{Q}_{p}^{n})} = \sup _{\gamma \in \mathbb{Z}} \biggl(\frac{1}{ \vert B_{\gamma } \vert _{h}} \int _{B_{\gamma }} \bigl\vert f(\mathbf{x}) - f_{B_{ \gamma }} \bigr\vert ^{q} \,d\mathbf{x} \biggr)^{1/q} < \infty , $$

(1.12)

where $f_{B_{\gamma }}=\frac{1}{|B_{\gamma }|_{h}} \int _{B_{\gamma }} f( \mathbf{x}) \,d\mathbf{x}$, $|B_{\gamma }|_{h}$ is the Haar measure of $B_{\gamma }$.

Definition 1.4

([9])

Suppose $0< r<\infty $, $0< q<\infty $ and $\beta \in \mathbb{R}$. The homogeneous p-adic Herz space $\dot{K}^{\beta ,r}_{q}(\mathbb{Q}_{p}^{n})$ is defined by

$$ \dot{K}^{\beta ,r}_{q}\bigl(\mathbb{Q}_{p}^{n} \bigr)=\bigl\{ f\in L^{q}\bigl(\mathbb{Q}_{p}^{n} \bigr): \Vert f \Vert _{\dot{K}^{\beta ,r}_{q}(\mathbb{Q}_{p}^{n})}< \infty \bigr\} , $$

where

$$ \Vert f \Vert _{\dot{K}^{\beta ,r}_{q}(\mathbb{Q}_{p}^{n})}= \Biggl(\sum_{k=- \infty }^{\infty }p^{k\beta r} \Vert f\chi _{k} \Vert ^{r}_{L^{q}(\mathbb{Q}_{p}^{n})} \Biggr)^{1/r}, $$

and $\chi _{k}$ is the characteristic function of $S_{k}$.

Obviously, the equalities $\dot{K}^{0,q}_{q}(\mathbb{Q}_{p}^{n})=L^{q}(\mathbb{Q}_{p}^{n})$ and $\dot{K}^{\beta /q,q}_{q}(\mathbb{Q}_{p}^{n})=L^{q}(|\mathbf{x}|_{p}^{ \beta })$ hold.

Definition 1.5

([5])

Suppose $0< r<\infty $, $0< q<\infty $, $\beta \in \mathbb{R}$ and $\lambda \geq 0$. The homogeneous p-adic Morrey–Herz space is defined by

$$ M\dot{K}^{\beta ,\lambda }_{q,r}\bigl(\mathbb{Q}_{p}^{n} \bigr)=\bigl\{ f\in L^{q}_{\mathrm{loc}}\bigl( \mathbb{Q}_{p}^{n} \setminus \{0\}\bigr): \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r,q}( \mathbb{Q}_{p}^{n})}< \infty \bigr\} , $$

where

$$ \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r,q}(\mathbb{Q}_{p}^{n})}=\sup_{k_{0} \in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum_{k=-\infty }^{k_{0}}p^{k \beta r} \Vert f\chi _{k} \Vert ^{r}_{L^{q}(\mathbb{Q}_{p}^{n})} \Biggr)^{1/r}. $$

It is evident that $M\dot{K}^{\beta ,0}_{r,q}(\mathbb{Q}_{p}^{n})=\dot{K}^{\beta ,r}_{q}( \mathbb{Q}_{p}^{n})$ and $M\dot{K}^{\beta /q,0}_{q,q}(\mathbb{Q}_{p}^{n})=L^{q}(|\mathbf{x}|_{p}^{ \alpha })$.

Definition 1.6

([5])

Suppose δ is a positive real number. The Lipschitz space $\Lambda _{\delta }(\mathbb{Q}_{p}^{n})$ is defined to be the space of all measurable function f on $\mathbb{Q}_{p}^{n}$ such that

$$ \Vert f \Vert _{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})}=\sup_{\mathbf{x}, \mathbf{h}\in \mathbb{Q}_{p}^{n},\mathbf{h}\neq 0} \frac{ \vert f(\mathbf{x}+\mathbf{h})-f(\mathbf{x}) \vert }{ \vert \mathbf{h} \vert _{p}^{\delta }}< \infty . $$

2 CBMO estimates for commutators of p-adic rough fractional Hardy operator

The present section discusses the boundedness of p-adic rough fractional Hardy operator on p-adic Herz-type spaces. We begin this section with the following useful lemma.

Lemma 2.1

([36])

Suppose b is a $\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})$ function and suppose $i, j\in \mathbb{Z}$. Then the inequality

$$ \bigl\vert b(\mathbf{y})-b_{B_{j}} \bigr\vert \leq \bigl\vert b( \mathbf{y})-b_{B_{i}} \bigr\vert +p^{n} \vert i-j \vert \Vert b \Vert _{\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})}, $$

holds.

Remark 2.2

From now on the letter C indicates a positive constant which may vary from line to line.

Theorem 2.3

Let $0< r_{1}\leq r_{2}<\infty $, $1\leq q_{1}$, $q_{2}<\infty $. Also, let $\frac{1}{q_{1}}-\frac{1}{q_{2}}=\frac{\alpha }{n}$, $q_{1}'< s< \infty $, $\frac{1}{q_{1}'}-\frac{1}{t}=\frac{1}{s} $. If $\beta <\frac{n}{t}$, then the inequality

$$ \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})}\leq C \Vert f \Vert _{\dot{K}^{\beta ,r_{1}}_{q_{1}}( \mathbb{Q}_{p}^{n})}, $$

holds for all $\Omega \in L^{s}(S_{\mathbf{0}}(\mathbf{0}))$, $b\in \mathit{CMO}^{\max \{q_{2},t\}}(\mathbb{Q}_{p}^{n})$, and $f\in L_{\mathrm{loc}}^{q_{1}}(\mathbb{Q}_{p}^{n})$.

Proof of Theorem 2.3

For the sake of brevity, we write

$$ \sum_{j=-\infty }^{\infty }f(\mathbf{x})\chi _{j}(\mathbf{x})=\sum_{j=- \infty }^{\infty }f_{j}( \mathbf{x}).$$

Since

$$\begin{aligned} \bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr) \chi _{k} \bigr\Vert ^{q_{2}}_{L^{q_{2}}( \mathbb{Q}_{p}^{n})} &= \int _{S_{k}} \vert \mathbf{x} \vert _{p}^{-q_{2}(n-\alpha )} \biggl\vert \int _{ \vert \mathbf{y} \vert _{p} \leq \vert \mathbf{x} \vert _{p}} \Omega \bigl( \vert \mathbf{y} \vert _{p}\mathbf{y}\bigr)f(\mathbf{y}) \bigl(b(\mathbf{x}) -b(\mathbf{y}) \bigr) \,d\mathbf{y} \biggr\vert ^{q_{2}} \,d\mathbf{x} \\ &\leq Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \biggl( \int _{ \vert \mathbf{y} \vert _{p} \leq p^{k}} \bigl\vert \Omega \bigl( \vert \mathbf{y} \vert _{p}\mathbf{y}\bigr) f(\mathbf{y}) \bigl(b( \mathbf{x}) -b( \mathbf{y})\bigr) \bigr\vert \,d\mathbf{y} \biggr)^{q_{2}} \,d\mathbf{x} \\ &=Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert f(\mathbf{y}) \Omega \bigl(p^{j}\mathbf{y}\bigr) \bigl(b(\mathbf{x})-b( \mathbf{y})\bigr)\bigr| \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &\leq Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert f(\mathbf{y}) \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigl(b(\mathbf{x})-b_{B_{k}} \bigr) \bigr\vert \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &\quad {} +Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert f(\mathbf{y}) \Omega \bigl(p^{j}\mathbf{y}\bigr) \bigl(b(\mathbf{y})-b_{B_{k}} \bigr) \bigr\vert \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &=I+\mathit{II}. \end{aligned}$$

(2.1)

For $j,k\in \mathbb{Z}$ with $j\leq k$, we get

$$ \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigr\vert ^{s}\,d\mathbf{y}= \int _{ \vert \mathbf{z} \vert _{p}=1} \bigl\vert \Omega (\mathbf{z}) \bigr\vert ^{s}p^{jn}\,d\mathbf{z}\leq Cp^{kn}. $$

(2.2)

Note that $\frac{1}{q_{1}}+\frac{1}{q_{2}}=\frac{\alpha }{n}$ and $\frac{1}{q_{1}}+\frac{1}{s}+\frac{1}{t}=1$, where $\frac{1}{t}=\frac{1}{q_{1}'}-\frac{1}{s}$. Applying Hölder’s inequality we have

$$\begin{aligned} I&\leq Cp^{-kq_{2}(n-\alpha )} \int _{B_{k}} \bigl\vert b(\mathbf{x})-b_{B_{k}} \bigr\vert ^{q_{2}} \\ & \quad {}\times \Biggl\{ \sum_{j=-\infty }^{k} \biggl( \int _{S_{j}} \bigl\vert f( \mathbf{y}) \bigr\vert ^{q_{1}}\,d\mathbf{y} \biggr)^{1/q_{1}} \biggl( \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigr\vert ^{s}\,d\mathbf{y} \biggr)^{1/s}p^{jn(1/q_{1}'-1/s)} \Biggr\} ^{q_{2}}\,d\mathbf{x} \\ &\leq C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{q_{2}}(\mathbb{Q}_{p}^{n})}p^{kn-kq_{2}(n- \alpha )} \Biggl\{ \sum_{j=-\infty }^{k}p^{jn(1/q_{1}'-1/s)}p^{kn/s} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr\} ^{q_{2}} \\ &=C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{q_{2}}(\mathbb{Q}_{p}^{n})} \Biggl\{ \sum _{j=- \infty }^{k}p^{(j-k)n(1/q_{1}'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr\} ^{q_{2}}. \end{aligned}$$

(2.3)

Lemma 2.1 will be helpful for estimating II. Thus

$$\begin{aligned} \mathit{II}&\leq Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert f(\mathbf{y}) \Omega \bigl(p^{j}\mathbf{y}\bigr) \bigl(b(\mathbf{y})-b_{B_{j}} \bigr) \bigr\vert \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &\quad {} +C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})}p^{-kq_{2}(n- \alpha )} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k}(k-j) \int _{S_{j}} \bigl\vert f( \mathbf{y})\Omega \bigl(p^{j}\mathbf{y}\bigr) \bigr\vert \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &=I_{1}+\mathit{II}_{2}. \end{aligned}$$

(2.4)

We use Hölder’s inequality to estimate $I_{1}$. We have

$$\begin{aligned} I_{1}&\leq Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \Biggl\{ \sum_{j=- \infty }^{k} \biggl( \int _{S_{j}} \bigl\vert b(\mathbf{y})-b_{B_{j}} \bigr\vert ^{t}\,d\mathbf{y} \biggr)^{1/t} \\ &\quad {} \times \biggl( \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigr\vert ^{s}\,d\mathbf{y} \biggr)^{1/s} \biggl( \int _{S_{j}} \bigl\vert f(\mathbf{y}) \bigr\vert ^{q_{1}} \,d\mathbf{y} \biggr)^{1/q_{1}} \Biggr\} ^{q_{2}} \,d\mathbf{x} \\ &\leq \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{t}(\mathbb{Q}_{p}^{n})}\sum _{j=-\infty }^{k} \biggl\{ p^{-kn/q_{1}'}p^{kn/s}p^{jn/t} \biggl(\frac{1}{ \vert B_{j} \vert _{H}} \int _{B_{j}} \bigl\vert b(\mathbf{y})-b_{B_{j}} \bigr\vert ^{t} \biggr)^{1/t} \Vert f_{j} \Vert _{L^{q_{1}}( \mathbb{Q}_{p}^{n})} \biggr\} ^{q_{2}} \\ &=C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{t}(\mathbb{Q}_{p}^{n})} \Biggl\{ \sum _{j=-\infty }^{k}p^{(j-k)n(1/q_{1}'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr\} ^{q_{2}}. \end{aligned}$$

(2.5)

In a similar fashion we can estimate $\mathit{II}_{2}$. Using Hölder’s inequality we have

$$\begin{aligned} \mathit{II}_{2}&\leq C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})}p^{-kq_{2}(n- \alpha )} \\ &\quad {} \times \int _{S_{k}} \Biggl\{ \sum_{j=-\infty }^{k}(k-j) \biggl( \int _{S_{j}} \bigl\vert f(\mathbf{y}) \bigr\vert ^{q_{1}}\,d\mathbf{y} \biggr)^{1/q_{1}} \biggl( \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigr\vert ^{s}\,d\mathbf{y} \biggr)^{1/s}p^{jn/t} \Biggr\} ^{q_{2}}\,d\mathbf{x} \\ &=C \Vert b \Vert ^{q_{2}}_{\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})} \Biggl(\sum _{j=-\infty }^{k}(k-j)p^{(j-k)n(1/q_{1}'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{q_{2}}. \end{aligned}$$

(2.6)

From (2.3), (2.5) and (2.6) together with the Jensen inequality, we have

$$\begin{aligned} & \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})} \\ &\quad = \Biggl(\sum_{k=-\infty }^{\infty }p^{k\beta r_{2}} \bigl\Vert \bigl(H^{p,b}_{\Omega , \alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{2}}_{L^{q_{2}}(\mathbb{Q}_{p}^{n})} \Biggr)^{1/r_{2}} \\ &\quad \leq \Biggl(\sum_{k=-\infty }^{\infty }p^{k\beta r_{1}} \bigl\Vert \bigl(H^{p,b}_{ \Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{1}}_{L^{q_{2}}(\mathbb{Q}_{p}^{n})} \Biggr)^{1/r_{1}} \\ &\quad \leq C \Vert b \Vert _{\mathit{CMO}^{q_{2}}(\mathbb{Q}_{p}^{n})} \Biggl(\sum _{k=-\infty }^{ \infty }p^{k\beta r_{1}} \Biggl(\sum _{j=-\infty }^{k}p^{(j-k)n/t} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\qquad {} +C \Vert b \Vert _{\mathit{CMO}^{t}(\mathbb{Q}_{p}^{n})} \Biggl(\sum _{k=-\infty }^{ \infty }p^{k\beta r_{1}} \Biggl(\sum _{j=-\infty }^{k}p^{(j-k)n/t} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\qquad {} +C \Vert b \Vert _{\mathit{CMO}^{1}(\mathbb{Q}_{p}^{n})} \Biggl(\sum _{k=-\infty }^{ \infty }p^{k\beta r_{1}} \Biggl(\sum _{j=-\infty }^{k}(k-j)p^{(j-k)n/t} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\quad =J. \end{aligned}$$

For brevity, we may choose $\|b\|_{\mathit{CMO}^{\max \{q_{2},t\}}(\mathbb{Q}_{p}^{n})}=1$. Consequently,

$$ J\leq C \Biggl(\sum_{k=-\infty }^{\infty }p^{k\beta r_{1}} \Biggl(\sum_{j=- \infty }^{k} (k-j)p^{(j-k)n/t} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}}. $$

Case 1: When $0< r_{1}\leq 1$, we have

$$\begin{aligned} J^{r_{1}}&=C\sum_{k=-\infty }^{\infty }p^{k\beta r_{1}} \Biggl(\sum_{j=- \infty }^{k}(k-j)p^{(j-k)n/t} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \\ &=C\sum_{k=-\infty }^{\infty } \Biggl(\sum _{j=-\infty }^{k}p^{j\beta } \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})}(k-j)p^{(j-k)(n/t-\beta )} \Biggr)^{r_{1}} \\ &\leq C\sum_{k=-\infty }^{\infty }\sum _{j=-\infty }^{k}p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}(\mathbb{Q}_{p}^{n})}(k-j)^{r_{1}}p^{(j-k)(n/t -\beta )r_{1}} \\ &=C\sum_{k=-\infty }^{\infty }p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}( \mathbb{Q}_{p}^{n})}\sum _{k=j}^{\infty }(k-j)^{r_{1}}p^{(j-k)(n/t - \beta )r_{1}} \\ &=C \Vert f \Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{1}}_{q_{1}}(\mathbb{Q}_{p}^{n})}. \end{aligned}$$

Case 2: When $r_{1}>1$, applying Hölder’s inequality we get

$$\begin{aligned} J^{r_{1}}&=C\sum_{k=-\infty }^{\infty } \Biggl(\sum_{j=-\infty }^{k}p^{j \beta } \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})}(k-j)p^{(j-k)(n/t- \beta )} \Biggr)^{r_{1}} \\ &\leq C\sum_{k=-\infty }^{\infty }\sum _{j=-\infty }^{k}p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}(\mathbb{Q}_{p}^{n})}p^{(j-k)(n/t -\beta )r_{1}/2} \\ &\quad {} \times \Biggl(\sum_{j=-\infty }^{k}(k-j)^{r_{1}'}p^{(j-k)(n/t - \beta )r_{1}'/2} \Biggr)^{r_{1}/r_{1}'} \\ &=C\sum_{k=-\infty }^{\infty }p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}( \mathbb{Q}_{p}^{n})}\sum _{k=j}^{\infty }p^{(j-k)(n/t -\beta )r_{1}/2} \\ &=C \Vert f \Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{1}}_{q_{1}}(\mathbb{Q}_{p}^{n})}. \end{aligned}$$

The proof of Theorem 2.3 is thus completed. □

Theorem 2.4

Let $0< r_{1}\leq r_{2}<\infty $, $1\leq q_{1}$, $q_{2}<\infty $. Also, let $\frac{1}{q_{1}}-\frac{1}{q_{2}}=\frac{\alpha }{n}$, $q_{1}'< s<\infty $, $\frac{1}{q_{1}'}-\frac{1}{t}=\frac{1}{s}$, and $\lambda >0$. If $\beta <\frac{n}{t}+\lambda $, then the inequality

$$ \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{M\dot{K}^{\beta ,\lambda }_{r_{2},q_{2}}( \mathbb{Q}_{p}^{n})}\leq C \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r_{1},q_{1}}( \mathbb{Q}_{p}^{n})}, $$

holds for all $\Omega \in L^{s}(S_{\mathbf{0}}(\mathbf{0}))$, $b\in \mathit{CMO}^{\max \{q_{2},t\}}(\mathbb{Q}_{p}^{n})$ and $f\in L_{\mathrm{loc}}^{q_{1}}(\mathbb{Q}_{p}^{n})$.

Proof of Theorem 2.4

From the proof of Theorem 2.3 and

$$ \bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert _{L^{q_{2}}(\mathbb{Q}_{p}^{n})} \leq C\sum _{j=-\infty }^{k}(k-j)p^{\frac{(j-k)n}{t}} \Vert f_{j} \Vert _{L^{q_{1}}( \mathbb{Q}_{p}^{n})}, $$

together with the definition of a Morrey–Herz space, the Jensen inequality, $\beta < n/t+\lambda $, $\lambda >0$ and $1< r_{1}<\infty $, it follows that

$$ \begin{aligned} & \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{M\dot{K}^{\beta ,\lambda }_{r_{2},q_{2}}( \mathbb{Q}_{p}^{n})} \\ &\quad =\sup_{k_{0}\in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum _{k=-\infty }^{k_{0}}p^{k \beta r_{2}} \bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{2}}_{L^{q_{2}}( \mathbb{Q}_{p}^{n})} \Biggr)^{1/r_{2}} \\ &\quad \leq \sup_{k_{0}\in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum _{k=- \infty }^{k_{0}}p^{k\beta r_{1}} \bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{1}}_{L^{q_{2}}(\mathbb{Q}_{p}^{n})} \Biggr)^{1/r_{1}} \\ &\quad \leq C\sup_{k_{0}\in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum _{k=- \infty }^{k_{0}}p^{k\beta r_{1}} \Biggl(\sum _{j=-\infty }^{k}(k-j)p^{ \frac{(j-k)n}{t}} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\quad \leq C\sup_{k_{0}\in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum _{k=- \infty }^{k_{0}} \Biggl(\sum _{j=-\infty }^{k}p^{k\beta }(k-j)p^{ \frac{(j-k)n}{t}}p^{-j\beta }p^{j\lambda }p^{j\lambda } \\ &\qquad {} \times \Biggl(\sum_{l=-\infty }^{j}p^{l\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}( \mathbb{Q}_{p}^{n})} \Biggr)^{1/r_{1}} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\quad \leq C\sup_{k_{0}\in \mathbb{Z}}p^{-k_{0}\lambda } \Biggl(\sum _{k=- \infty }^{k_{0}}p^{k\lambda r_{1}} \Biggl(\sum _{j=-\infty }^{k}(k-j)p^{(j-k)(n/t- \beta +\lambda )} \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r_{1},q_{1}}( \mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \Biggr)^{1/r_{1}} \\ &\quad \leq C \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r_{1},q_{1}}(\mathbb{Q}_{p}^{n})}. \end{aligned} $$

□

3 Lipschitz estimates for commutators of p-adic rough fractional Hardy operator

The current section deals with the boundedness for the commutators of p-adic rough fractional Hardy operator on homogeneous p-adic Herz-type spaces by considering the symbol function from Lipschitz space. We open the discussion for this section from the following lemma.

Lemma 3.1

Suppose $f\in \Lambda _{\delta }(\mathbb{Q}_{p}^{n})$ and $0<\delta <1$, then

$$ \bigl\vert f(\mathbf{x})-f(\mathbf{y}) \bigr\vert \leq \vert \mathbf{x}- \mathbf{y} \vert _{p}^{\delta } \Vert f \Vert _{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})}. $$

Proof

Proof immediately follows from Definition 1.6. □

Theorem 3.2

Let $1\leq q_{1}$, $q_{2}<\infty $, $0< r_{1}\leq r_{2}<\infty $. Also, let $\frac{1}{q_{1}}-\frac{1}{q_{2}}=\frac{\delta +\alpha }{n}$, $q_{1}'< s<\infty $, $\frac{1}{q_{1}'}-\frac{1}{t}=\frac{1}{s}$, and $0<\delta <1$. If $\beta < n(\frac{1}{q_{1}'}-\frac{1}{s})$, then the inequality

$$ \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})}\leq C \Vert f \Vert _{\dot{K}^{\beta ,r_{1}}_{q_{1}}( \mathbb{Q}_{p}^{n})} $$

holds for all $\Omega \in L^{s}(S_{\mathbf{0}}(\mathbf{0}))$, $b\in \Lambda _{\delta }(\mathbb{Q}_{p}^{n})$, and $f\in L_{\mathrm{loc}}^{q_{1}}(\mathbb{Q}_{p}^{n})$.

Proof of Theorem 3.2

By Hölder’s inequality along with Lemma 3.1, we have

$$ \begin{aligned}[b] &\bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert ^{q_{2}}_{L^{q_{2}}( \mathbb{Q}_{p}^{n})} \\ &\quad = \int _{S_{k}} \vert \mathbf{x} \vert _{p}^{-q_{2}(n-\alpha )} \biggl\vert \int _{ \vert \mathbf{y} \vert _{p}\leq \vert \mathbf{x} \vert _{p}}\Omega \bigl( \vert \mathbf{y} \vert _{p} \mathbf{y}\bigr)f(\mathbf{y}) \bigl(b(\mathbf{x})-b(\mathbf{y}) \bigr)\,d\mathbf{y} \biggr\vert ^{q_{2}}\,d\mathbf{x} \\ &\quad \leq Cp^{-kq_{2}(n-\alpha )} \int _{S_{k}} \biggl( \int _{ \vert \mathbf{y} \vert _{p} \leq p^{k}} \bigl\vert \Omega \bigl( \vert \mathbf{y} \vert _{p}\mathbf{y}\bigr)f(\mathbf{y}) \bigl(b( \mathbf{x})-b( \mathbf{y})\bigr) \bigr\vert \,d\mathbf{y} \biggr)^{q_{2}}\,d\mathbf{x} \\ &\quad \leq Cp^{-kq_{2}(n-\alpha )} \Vert b \Vert ^{q_{2}}_{\Lambda _{\delta }( \mathbb{Q}_{p}^{n})} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr)f(\mathbf{y}) \bigr\vert \vert \mathbf{x}-\mathbf{y} \vert _{p}^{ \delta }\,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &\quad \leq Cp^{-kq_{2}(n-\alpha -\delta )} \Vert b \Vert ^{q_{2}}_{\Lambda _{\delta }( \mathbb{Q}_{p}^{n})} \int _{S_{k}} \Biggl(\sum_{j=-\infty }^{k} \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr)f(\mathbf{y}) \bigr\vert \,d\mathbf{y} \Biggr)^{q_{2}}\,d\mathbf{x} \\ &\quad \leq C \Vert b \Vert ^{q_{2}}_{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})} p^{-kq_{2}(n- \alpha -\delta )+kn} \Biggl(\sum_{j=-\infty }^{k} \biggl( \int _{S_{j}} \bigl\vert \Omega \bigl(p^{j} \mathbf{y}\bigr) \bigr\vert ^{s}\,d\mathbf{y} \biggr)^{1/s} \\ &\qquad {} \times \biggl( \int _{S_{j}} \bigl\vert f(\mathbf{y}) \bigr\vert ^{q_{1}}\,d\mathbf{y} \biggr)^{1/q_{1}} \biggl( \int _{S_{j}}\,d\mathbf{y} \biggr)^{1-1/q-1/s} \Biggr)^{q_{2}} \\ &\quad =I. \end{aligned} $$

(3.1)

By virtue of (2.2), inequality (3.1) takes the following form:

$$ \begin{aligned} I&\leq C \Vert b \Vert ^{q_{2}}_{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})}p^{-kq_{2}(n- \alpha -\delta )+kn} \Biggl(\sum _{j=-\infty }^{k}p^{kn/s+jn(1/q_{1}'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{q_{2}} \\ &\leq C \Vert b \Vert ^{q_{2}}_{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})} \Biggl( \sum _{j=-\infty }^{k}p^{(j-k)n(1/q'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}( \mathbb{Q}_{p}^{n})} \Biggr)^{q_{2}}. \end{aligned} $$

For the sake of brevity, we take $\|b\|^{q_{2}}_{\Lambda _{\delta }(\mathbb{Q}_{p}^{n})}=1$. Now, by definition of Herz spaces and the Jensen inequality, it follows that

$$ \begin{aligned} \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})}&= \Biggl(\sum _{k=-\infty }^{\infty }p^{k\beta r_{2}} \bigl\Vert \bigl(H^{p,b}_{\Omega ,\alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{2}}_{L^{q_{2}}( \mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}/r_{2}} \\ &\leq \sum_{k=-\infty }^{\infty }p^{k\beta r_{1}} \bigl\Vert \bigl(H^{p,b}_{\Omega , \alpha }f\bigr)\chi _{k} \bigr\Vert ^{r_{1}}_{L^{q_{2}}(\mathbb{Q}_{p}^{n})} \\ &\leq C\sum_{k=-\infty }^{\infty }p^{k\beta r_{1}} \Biggl(\sum_{j=- \infty }^{k}p^{(j-k)n(1/q_{1}'-1/s)} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \\ &=C\sum_{k=-\infty }^{\infty } \Biggl(\sum _{j=-\infty }^{k}p^{j\beta }p^{(j-k)(n/q_{1}'-n/s- \beta )} \Vert f_{j} \Vert _{L^{q_{1}}(\mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}}. \end{aligned} $$

Case 1: If $0< r_{1}\leq 1$, then

$$ \begin{aligned} \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})}&\leq C\sum _{k=-\infty }^{\infty }\sum_{j=-\infty }^{k}p^{j \beta r_{1}}p^{(j-k)(n/q_{1}'-n/s-\beta )r_{1}} \Vert f_{j} \Vert _{L^{q_{1}}( \mathbb{Q}_{p}^{n})}^{r_{1}} \\ &=C\sum_{j=-\infty }^{\infty }p^{j\beta r_{1}} \Vert f_{j} \Vert _{L^{q_{1}}( \mathbb{Q}_{p}^{n})}^{r_{1}}\sum _{k=j}^{\infty }p^{(j-k)(n/q_{1}'-n/s- \beta )r_{1}} \\ &\leq C \Vert f \Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{1}}_{q_{2}}(\mathbb{Q}_{p}^{n})}. \end{aligned} $$

Case 2: When $r_{1}>1$, applying Hölder’s inequality, we have

$$ \begin{aligned} \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{2}}_{q_{2}}( \mathbb{Q}_{p}^{n})}&\leq C\sum _{k=-\infty }^{\infty } \Biggl(\sum _{j=- \infty }^{k}p^{j\beta }p^{(j-k)(n/q_{1}'-n/s-\beta )} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}( \mathbb{Q}_{p}^{n})} \Biggr)^{r_{1}} \\ &\leq C\sum_{k=-\infty }^{\infty }\sum _{j=-\infty }^{k}p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}(\mathbb{Q}_{p}^{n})}p^{(j-k)(n/q_{1}'-n/s- \beta )r_{1}/2} \\ &\quad {} \times \Biggl(\sum_{j=-\infty }^{k}p^{(j-k)(n/q_{1}'-n/s-\beta )r_{1}'/2} \Biggr)^{r_{1}/r_{1}'} \\ &\leq C\sum_{j=-\infty }^{\infty }p^{j\beta r_{1}} \Vert f_{j} \Vert ^{r_{1}}_{L^{q_{1}}( \mathbb{Q}_{p}^{n})}\sum _{k=j}^{\infty }p^{(j-k)(n/q_{1}'-n/s-\beta )r_{1}/2} \\ &\leq C \Vert f \Vert ^{r_{1}}_{\dot{K}^{\beta ,r_{1}}_{q_{1}}(\mathbb{Q}_{p}^{n})}. \end{aligned} $$

□

Theorem 3.3

Let $1\leq q_{1}$, $q_{2}<\infty $, $0< r_{1}\leq r_{2}<\infty $. Also, let $\frac{1}{q_{1}}-\frac{1}{q_{2}}=\frac{\delta +\alpha }{n}$, $s>q_{1}'$, $\frac{1}{q_{1}'}-\frac{1}{t}=\frac{1}{s}$, $\lambda \geq 0$ and $0<\delta <1$. If $n(\frac{1}{q_{1}'}-\frac{1}{s})+\lambda >\beta $, then the inequality

$$ \bigl\Vert H^{p,b}_{\Omega ,\alpha }f \bigr\Vert _{M\dot{K}^{\beta ,\lambda }_{r_{2},q_{2}}( \mathbb{Q}_{p}^{n})}\leq C \Vert f \Vert _{M\dot{K}^{\beta ,\lambda }_{r_{1},q_{1}}( \mathbb{Q}_{p}^{n})}, $$

holds for all $\Omega \in L^{s}(S_{\mathbf{0}}(\mathbf{0}))$, $b\in \Lambda _{\delta }(\mathbb{Q}_{p}^{n})$, and $f\in L_{\mathrm{loc}}^{q_{1}}(\mathbb{Q}_{p}^{n})$.

Proof of Theorem 3.3

The proof follows from standard analysis performed in our previous theorems. So, we omit the details. □

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Acknowledgements

Researchers supporting Project number (RSP-2020/33), King Saud University, Riyadh, Saudi Arabia.

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Authors and Affiliations

Department of Mathematics, Quaid-I-Azam University, 45320, Islamabad, 44000, Pakistan
Amjad Hussain
Department of Mathematics, University of Kotli Azad Jammu and Kashmir, Kotly, Pakistan
Naqash Sarfraz
Department of Mathematics, College of Science Al-Zulfi, Majmaah University, Al-Majmaah, 11952, Saudi Arabia
Ilyas Khan
Department of Basic Sciences, College of Science and Theoretical Studies, Saudi Electronic University, Riyadh, 11673, Saudi Arabia
Abdelaziz Alsubie & Nawaf N. Hamadneh

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Amjad Hussain
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Naqash Sarfraz
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Ilyas Khan
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Abdelaziz Alsubie
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Nawaf N. Hamadneh
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Formal analysis, NS, AH; investigation, NS, AH; resources, IK, AA, NNH; funding acquisition, AA, NNH; supervision, AH, IK. All authors read and approved the final manuscript.

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Correspondence to Amjad Hussain or Ilyas Khan.

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Hussain, A., Sarfraz, N., Khan, I. et al. The boundedness of commutators of rough p-adic fractional Hardy type operators on Herz-type spaces. J Inequal Appl 2021, 123 (2021). https://doi.org/10.1186/s13660-021-02650-7

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Received: 12 December 2020
Accepted: 10 June 2021
Published: 21 July 2021
DOI: https://doi.org/10.1186/s13660-021-02650-7

The boundedness of commutators of rough p-adic fractional Hardy type operators on Herz-type spaces

Abstract

1 Introduction

Definition 1.1

Remark 1.2

Definition 1.3

Definition 1.4

Definition 1.5

Definition 1.6

2 CBMO estimates for commutators of p-adic rough fractional Hardy operator

Lemma 2.1

Remark 2.2

Theorem 2.3

Proof of Theorem 2.3

Theorem 2.4

Proof of Theorem 2.4

3 Lipschitz estimates for commutators of p-adic rough fractional Hardy operator

Lemma 3.1

Proof

Theorem 3.2

Proof of Theorem 3.2

Theorem 3.3

Proof of Theorem 3.3

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The boundedness of commutators of rough p-adic fractional Hardy type operators on Herz-type spaces

Abstract

1 Introduction

Definition 1.1

Remark 1.2

Definition 1.3

Definition 1.4

Definition 1.5

Definition 1.6

2 CBMO estimates for commutators of p-adic rough fractional Hardy operator

Lemma 2.1

Remark 2.2

Theorem 2.3

Proof of Theorem 2.3

Theorem 2.4

Proof of Theorem 2.4

3 Lipschitz estimates for commutators of p-adic rough fractional Hardy operator

Lemma 3.1

Proof

Theorem 3.2

Proof of Theorem 3.2

Theorem 3.3

Proof of Theorem 3.3

Availability of data and materials

References

Acknowledgements

Funding

Author information

Authors and Affiliations

Contributions

Corresponding authors

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About this article

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MSC

Keywords