1. 引言

算子是逼近理论重要的研究对象，其中经典的算子之一为Bernstein算子。最早于1912年，Bernstein首次提出。其后，众多研究者开始关注研究Bernstein算子的推广。于是，Bernstein算子的各种变形算子纷纷被讨论，如Szász-Mirakjan-Kantorovich算子 [1]，Baskakov算子 [2] 等。

随着数学与生产生活各领域的交错发展，学者们将q微积分引入逼近理论，构造出大量q型算子。2007年，Dalmanoglu Ö. [3] 研究了q-Bernstein-Kantorovich算子；2011年，Muraru C V [4] 提出q-Bernstein-Schurer算子，并研究其逼近问题；伴随着研究的进一步深化，二元或多元算子相继被提出，故得到了大量二元算子关于逼近的相关理论，详见文献 [5] [6] [7] 等。

q微积分在逼近中的发展推动了(p, q)微分学步入逼近理论。Mursaleen于2015年首次在q-Bernstein算子的基础上提出(p, q)-Bernstein算子 [8]，实现了q-Bernstein算子性质的推广。自此，有关于(p, q)型算子呈现于世人面前。2016年，Acar在文献 [9] 中构建了两元(p, q)-Bernstein-Kantorovich算子并证明该算子一些的逼近结论。由此可知，关于(p, q)型二元算子逼近问题的研究正在持续发展中。本文构建出二元(p, q)Bernstein算子，证明算子的一些逼近相关的定理，从而更进一步推广一元算子的逼近性质，更加丰富逼近理论的完整性。

2. 知识储备

下文中出现的符号： ${\left[n\right]}_{p,q},{\left[n\right]}_{p,q}!,{\left[\begin{array}{l}n\\ k\end{array}\right]}_{p,q}$ 主要定义为：

${\left[n\right]}_{p,q}=\frac{p^n-q^n}{p-q},n=0,1,2,\cdots$

${\left[n\right]}_{p,q}!=\{\begin{array}{l}1,n=0;\\ {\left[n\right]}_{p,q}{\left[n-1\right]}_{p,q}\cdots \left[1\right],n=1,2,\cdots \end{array}$

${\left[\begin{array}{l}n\\ k\end{array}\right]}_{p,q}=\frac{{\left[n\right]}_{p,q}!}{{\left[k\right]}_{p,q}!{\left[n-k\right]}_{p,q}!}$

定义1 [8] ：设 $f\in C\left[0,1\right]$， $0<q<p\le 1$， $\forall x\in \left[0,1\right]$，则(p, q)-Bernstein算子定义为下式：

$B_n^{p,q}\left(f;x\right)={\displaystyle \underset{k=0}{\overset{n}{\sum }}{b}_{n,k}^{p,q}\left(x\right)}f\left(\frac{p^{n-k}{\left[k\right]}_{p,q}}{{\left[n\right]}_{p,q}}\right),$

其中 $b_{n,k}^{p,q}\left(x\right)={\left[\begin{array}{l}n\\ k\end{array}\right]}_{p,q}{p}^{\left[k\left(k-1\right)-n\left(n-1\right)\right]/2}{x}^k{\displaystyle \underset{s=0}{\overset{n-k-1}{\prod }}\left(p^s-q^s\right)}$。

定义2：设 $0<q<p\le 1$， $f\in C\left[0,1\right]$，定义二元(p, q)-Bernstein算子为：

$B_{n_1{n}_2}\left(f;x,y\right)=\frac{1}{p_1^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p_2{}^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}{b}_{n_1{n}_2{k}_1{k}_2}\left(x,y\right)\left(x,y\right)f\left(\frac{p_1^{n_1-k_1}{\left[k_1\right]}_{p_1,q_1}}{{\left[n_1\right]}_{p_1,q_1}},\frac{p_2^{n_2-k_2}{\left[k_2\right]}_{p_2,q_2}}{{\left[n_2\right]}_{p_2,q_2}}\right)}}$

其中

$b_{n_1{n}_2{k}_1{k}_2}\left(x,y\right)={\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{p}_2^{\frac{k_2\left(k_2-1\right)}{2}}{x}^{k_1}{y}^{k_2}{\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right)}{\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)}.$

引理1 [8] ：设 $0<q<p\le 1$， $x\in \left[0,1\right]$，则有

$\begin{array}{l}{B}_n^{p,q}\left(e_0;x\right)=1,B_n^{p,q}\left(e_1;x\right)=x,\\ B_n^{p,q}\left(e_2;x\right)=\frac{p^{n-1}}{{\left[n\right]}_{p,q}}x+\frac{q{\left[n-1\right]}_{p,q}}{{\left[n\right]}_{p,q}}{x}^2.\end{array}$

引理2：设 $0<q_1<p_1\le 1,0<q_2<p_2\le 1$， $e_{ij}:I^2\times I^2,e_{ij}\left(x,y\right)=x^i{y}^j,0\le i+j\le 2$， $I^2=\left[0,1\right]\times \left[0,1\right]$，( $i,j$ 为正整数)，则有下列等式成立：

$\begin{array}{l}{B}_{n_1{n}_2}\left(e_{00};x,y\right)=e_{00}\left(x,y\right);\\ B_{{}_{n_1{n}_2}}\left(e_{10};x,y\right)=e_{10}\left(x,y\right);\\ B_{n_1{n}_2}\left(e_{01};x,y\right)=e_{01}\left(x,y\right);\\ B_{n_1{n}_2}\left(e_{11};x,y\right)=e_{11}\left(x,y\right);\\ B_{n_1{n}_2}\left(e_{20};x,y\right)=e_{20}\left(x,y\right)+\frac{p_1^{n_1-1}x\left(1-x\right)}{{\left[n_1\right]}_{p_1,q_1}};\\ e_{n_1{n}_2}\left(e_{02};x,y\right)=e_{02}\left(x,y\right)+\frac{p_2^{n_2-1}y\left(1-y\right)}{{\left[n_2\right]}_{p_2,q_2}}.\end{array}$

证明：根据算子定义式与引理1，计算可得

$\begin{array}{l}{B}_{n_1}{}_{n_2}\left(e_{00};x,y\right)\\ =\frac{1}{p_1{}^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}{\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}}}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{p}_2^{\frac{k_2\left(k_2-1\right)}{2}}{x}^{k_1}{y}^{k_2}\times {\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right){\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)}}\\ =\frac{1}{p_1{}^{\frac{n_1\left(n_1-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}}{p}^{\frac{k_1\left(k_1-1\right)}{2}}{x}^{k_1}{\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right)}\times \frac{1}{p_2{}^{\frac{n_2\left(n_2-1\right)}{2}}}{{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}}_{p_2,q_2}{p}^{\frac{k_2\left(k_2-1\right)}{2}}{y}^{k_2}{\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)}\\ =B_{n_1}\left(e_0;x\right)B_{n_2}\left(e_0;y\right)=e_{00}\left(x,y\right),\end{array}$

$\begin{array}{l}{B}_{n_1}{}_{n_2}\left(e_{10};x,y\right)\\ =\frac{1}{p^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}{\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}}}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}^{\frac{k_1\left(k_1-1\right)}{2}}{p}^{\frac{k_2\left(k_2-1\right)}{2}}{x}^{k_1}{y}^{k_2}\\ \times {\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right){\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)\frac{{\left[k_1\right]}_{p_1,q_1}}{p_1^{k_1-n_1}{\left[n_1\right]}_{p_1,q_1}}}}\\ =\frac{1}{p^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{x}^{k_1}{\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right)}\frac{{\left[k_1\right]}_{p_1,q_1}}{p_1^{k_1-n_1}{\left[n_1\right]}_{p_1,q_1}}\\ \times {{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}}_{p_2,q_2}{p}^{\frac{k_2\left(k_2-1\right)}{2}}{y}^{k_2}{\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)}\\ =B_{n_1}\left(e_1;x\right)B_{n_2}\left(e_0,y\right)=e_{10}\left(x,y\right)\end{array}$

$\begin{array}{l}{B}_{n_1}{}_{n_2}\left(e_{11};x,y\right)\\ =\frac{1}{p^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p^{\frac{n_2\left(n_2-1\right)}{2}}}{{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}}}_{p_1,q_1}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{p}_2^{\frac{k_2\left(k_2-1\right)}{2}}{x}^{k_1}{y}^{k_2}\\ \times {\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right){\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)\frac{{\left[k_1\right]}_{p_1,q_1}}{p_1^{k_1-n_1}{\left[n_1\right]}_{p_1,q_1}}\frac{{\left[k_2\right]}_{p_2,q_2}}{p_2^{k_2-n_2}{\left[n_2\right]}_{p_2,q_2}}}}\\ =\frac{1}{p_1{}^{\frac{n_1\left(n_1-1\right)}{2}}}{{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}}_{p_1,q_1}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{x}^{k_1}{\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right)}\frac{{\left[k_1\right]}_{p_1,q_1}}{p_1^{k_1-n_1}{\left[n_1\right]}_{p_1,q_1}}\\ \times \frac{1}{p_1{}^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}_2^{\frac{k_2\left(k_2-1\right)}{2}}}{y}^{k_2}{\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)}\frac{{\left[k_2\right]}_{p_2,q_2}}{p_2^{k_2-n_2}{\left[n_2\right]}_{p_2,q_2}}\\ =B_{n_1}\left(e_1,x\right)B_{n_2}\left(e_1,y\right)=e_{11}\left(x,y\right)\end{array}$

$\begin{array}{l}{B}_{n_1}{}_{n_2}\left(e_{02};x,y\right)\\ =\frac{1}{p_1^{\frac{n_1\left(n_1-1\right)}{2}}}\frac{1}{p_2^{\frac{n_2\left(n_2-1\right)}{2}}}{\displaystyle \underset{k_1=0}{\overset{n_1}{\sum }}{\displaystyle \underset{k_2=0}{\overset{n_2}{\sum }}{\left[\begin{array}{c}{n}_1\\ k_1\end{array}\right]}_{p_1,q_1}}}{\left[\begin{array}{c}{n}_2\\ k_2\end{array}\right]}_{p_2,q_2}{p}_1^{\frac{k_1\left(k_1-1\right)}{2}}{p}_2^{\frac{k_2\left(k_2-1\right)}{2}}{x}^{k_1}{y}^{k_2}\\ \times {\displaystyle \underset{s=0}{\overset{n_1-k_1-1}{\prod }}\left(p_1^s-q_1^{s}x\right){\displaystyle \underset{s=0}{\overset{n_2-k_2-1}{\prod }}\left(p_2^s-q_2^{s}y\right)\frac{{\left[k_2\right]}_{p_{2,}{q}_2}^2}{p_2^{2k_2-2n_2}{\left[n_2\right]}_{p_2,q_2}^2}}}\\ =y^2+\frac{\left(q_2{\left[n_2-1\right]}_{p_2,q_2}-{\left[n_2\right]}_{p_2,q_2}\right)y^2+p_2^{n_2-1}y}{{\left[n_2\right]}_{p_2,q_2}}\\ =y^2+\frac{p_2^{n_2-1}y\left(1-y\right)}{{\left[n_2\right]}_{p_2,q_2}}=B_{n_1}\left(e_0,x\right)B_{n_2}\left(e_2,y\right)\\ =e_{02}\left(x,y\right)+\frac{p_2^{n_2-1}y\left(1-y\right)}{{\left[n_2\right]}_{p_2,q_2}}.\end{array}$

同理可证出 $B_{n_1{n}_2}\left(e_{01};x,y\right)=e_{01}\left(x,y\right)$ ； $B_{n_1,n_2}\left(e_{20},x,y\right)=e_{20}\left(x,y\right)+\frac{p_1^{n_1-1}x\left(1-x\right)}{{\left[n_1\right]}_{p_1,q_1}}$，故引理成立。

引理3：设 $0<q_1<p_1\le 1,0<q_2<p_2\le 1$， $x\in \left[0,1\right]$，则有下列等式成立：

$\begin{array}{l}{B}_{n_1{n}_2}\left(e_{10}-x;x,y\right)=0;\\ B_{n_1{n}_2}\left(e_{01}-x;x,y\right)=0;\\ B_{n_1{n}_2}\left({\left(e_{10}-x\right)}^2;x,y\right)=\frac{p_1^{n_1-1}x\left(1-x\right)}{{\left[n_1\right]}_{p_1,q_1}};\\ B_{n_1{n}_2}\left({\left(e_{01}-x\right)}^2;x,y\right)=\frac{p_2^{n_2-1}y\left(1-y\right)}{{\left[n_2\right]}_{p_2,q_2}}.\end{array}$

证明：根据引理2与算子的线性性质易得结论。

3. 主要结果

首先介绍一些记号：设 ${\delta }_1>0,{\delta }_2>0$， $f\in C\left(I^2\right)$， $I^2=\left[0,1\right]\times \left[0,1\right]$，则关于f的连续性模可以表示为：

$\omega \left(f:{\delta }_1,{\delta }_2\right)=\sup \left\{\left|f\left(t,s\right)-f\left(x,y\right)\right|:\left(t,s\right)\left(x,y\right)\in \left(I_1\times I_2\right),\left|t-x\right|\le {\delta }_1,\left|s-y\right|\le {\delta }_2\right\}$ ；

并且 $\omega \left(f:{\delta }_1,{\delta }_2\right)$ 满足以下性质：

$\begin{array}{l}\left(\text{i}\right)\omega \left(f:{\delta }_1,{\delta }_2\right)\to 0,若{\delta }_1,{\delta }_2\to \text{0}\\ \left(\text{ii}\right)f\left(t,s\right)-f\left(x,y\right)\le \omega \left(f:{\delta }_1,{\delta }_2\right)\left(1+\frac{\left|t-x\right|}{{\delta }_1}\right)\left(1+\frac{\left|s-y\right|}{{\delta }_2}\right)\end{array}$

${\alpha }_1,{\alpha }_2$ 阶Lipschitz条件的二元函数f：对于 $\forall \left(t,s\right),\left(x,y\right)\in I^2$， $f\in C\left(I^2\right)$， $0<{\alpha }_1\le 1,0<{\alpha }_2\le 1$，则存在常数 $M>0$，使得 $\left|f\left(t,s\right)-f\left(x,y\right)\right|\le M{\left|t-x\right|}^{{\alpha }_1}{\left|s-y\right|}^{{\alpha }_2}$ ；记为 $f\in Li{p}_M\left({\alpha }_1,{\alpha }_2\right)$。

定理1：若 $p_1=p_{n_1},p_2=p_{n_2},q_1=q_{n_1},q_2=q_{n_2}$，且 $q_1\in \left(0,1\right),p_1\in \left(q_1,1\right],q_2\in \left(0,1\right),p_2\in \left(q_2,1\right]$， $\underset{n\to \infty }{\lim }{p}_{n_1}=1,\underset{n\to \infty }{\lim }{p}_{n_2}=1,\underset{n\to \infty }{\lim }{q}_{n_1}=1,\underset{n\to \infty }{\lim }{q}_{n_2}=1$，则对于 $\forall f\in C\left(I^2\right)$，都有 $\underset{n_1,n_2\to \infty }{\lim }\Vert B_{n_1,n_2}\left(f;x\right)-f\left(x\right)\Vert =0$。

证明：根据引理2得到

$\begin{array}{l}\Vert B_{n_1{n}_2}\left(e_{00}:x,y\right)-e_{00}\Vert =0;\\ \Vert B_{n_1{n}_2}\left(e_{10}:x,y\right)-e_{10}\Vert =0;\\ \Vert B_{n_1{n}_2}\left(e_{01}:x,y\right)-e_{01}\Vert =0;\end{array}$

又因为当时，

故根据Volkov定理的内容可以得到。

定理2：若，有不等式

其中。

证明：根据二元函数连续模的性质，则有

又利用Cauchy-Schwarz不等式与引理3，有

因此，得到

取，即成立。

定理3：设且，则有

其中

证明：因为，可得

又因为

利用算子作用与柯西–施瓦茨不等式计算有

定理4：若，则存在一个常数，有下式成立：

其中。

证明：由，计算可得

利用Hölder不等式，取

取即定理成立。

致谢

本文的写作感谢查星星老师的指导。

基金项目

巢湖学院国家级大学生创新创业训练计划资助项目(201910380035)，巢湖学院省级大学生创新创业训练计划资助项目(S201910380068)。

参考文献