Approximation properties of bivariate extension of q-Szász-Mirakjan-Kantorovich operators

In the present paper, a bivariate generalization of the q-Szász-Mirakjan-Kantorovich operators is constructed by $q_R$-integral and these operators’ weighted A-statistical approximation properties are established. Also, we estimate the rate of pointwise convergence of the proposed operators by modulus of continuity.

MSC:41A25, 41A36.

Dedicated to Professor Hari M Srivastava

In [1] the Kantorovich type generalization of the Szász-Mirakjan operators is defined by

In [2], for each positive integer n, Aral and Gupta defined q-type generalization of Szász-Mirakjan operators as

where $0<q<1$, $f\in C[0,\mathrm{\infty })$, $0\le x<\frac{b_n}{(1-q){[n]}_q}$, $b_n$ is a sequence of positive numbers such that ${lim}_{x\to \mathrm{\infty }}{b}_n=\mathrm{\infty }$.

Recently, q-type generalization of Szász-Mirakjan operators, which was different from that in [2], was introduced, and the convergence properties of these operators were studied by Mahmudov [3]. Weighted statistical approximation properties of the modified q-Szász-Mirakjan operators were obtained in [4]. Also, Durrmeyer and Kantorovich-type generalizations of the linear positive operators based on q-integers were studied by some authors. The Bernstein-Durrmeyer operators related to the q-Bernstein operators were studied by Derriennic [5]. Gupta [6] introduced and studied approximation properties of q-Durrmeyer operators. The generalizations of the q-Baskakov-Kantorovich operators were constructed and weighted statistical approximation properties of these operators were examined in [7] and [8]. The q-extensions of the Szász-Mirakjan, Szász-Mirakjan-Kantorovich, Szász-Schurer and Szász-Schurer-Kantorovich operators were given shortly in [8]. Generalized Szász Durrmeyer operators were studied in [9]. With the help of $q_R$-integral, Örkcü and Doğru [10] introduced a Kantorovich-type modification of the q-Szász-Mirakjan operators as follows:

where $q\in (0,1)$, $0\le x<\frac{q}{1-q^n}$, $f\in C[0,\mathrm{\infty })$.

The paper of Mursaleen et al. [11] is one of the latest references on approximation by q-analogue. They investigated approximation properties for new q-Lagrange polynomials. Also, the q-analogue of Bernstein-Schurer-Stancu operators were introduced in [12].

On the other hand, Stancu [13] first introduced linear positive operators in two and several dimensional variables. Afterward, Barbosu [14] introduced a generalization of two-dimensional Bernstein operators based on q-integers and called them bivariate q-Bernstein operators. In recent years, many results have been obtained in the Korovkin-type approximation theory via A-statistical convergence for functions of several variables (for instance, [15–17]).

In this study, we construct a bivariate generalization of the Szász-Mirakjan-Kantorovich operators based on q-integers and obtain the weighted A-statistical approximation properties of these operators.

Now we recall some definitions about q-integers. For any non-negative integer r, the q-integer of the number r is defined by

where q is a positive real number. The q-factorial is defined as

Two q-analogues of the exponential function $e^x$ are given as

The following relation between q-exponential functions $E_q(x)$ and ${\epsilon }_q(x)$ holds

In the fundamental books about q-calculus (see [18, 19]), the q-integral of the function f over the interval $[0,b]$ is defined by

If f is integrable over $[0,b]$, then

A generally accepted definition for q-integral over an interval $[a,b]$ is

In order to generalize and spread the existing inequalities, Marinkovic et al. considered a new type of q-integral. So, the problems that ensue from the general definition of q-integral were overcome. The Riemann-type q-integral [20] in the interval $[a,b]$ was defined as

This definition includes only a point inside the interval of the integration.

The aim of this part is to construct a bivariate extension of the operators defined by (1.1).

For $n\in \mathbb{N}$, $0<q_1,q_2<1$ and $0\le x<\frac{q_{1_{}}}{1-q_1^n}$, $0\le y<\frac{q_{2_{}}}{1-q_2^n}$, the bivariate extension of the operators $K_n^q(f;x)$ is as follows:

where

Also, f is a $q_R$-integrable function, so the series in (2.2) converges. It is clear that the operators given in (2.1) are linear and positive.

First, let us give the following lemma.

Lemma 1 Let $e_{ij}=x^i{y}^j$, $(i,j)\in {\mathbb{N}}_0\times {\mathbb{N}}_0$ with $i+j\le 2$ be the two-dimensional test functions. Then the following results hold for the operators given by (2.1):

Proof From ${\int }_{q_2{[l]}_{q_2}/{[n]}_{q_2}}^{{[l+1]}_{q_2}/{[n]}_{q_2}}{\int }_{q_1{[k]}_{q_1}/{[n]}_{q_1}}^{{[k+1]}_{q_1}/{[n]}_{q_1}}{d}_{q_1}^{R}t{d}_{q_2}^{R}s=\frac{1}{{[n]}_{q_1}{[n]}_{q_2}}$ and the equality in (1.2), we have

Since ${\int }_{q_2{[l]}_{q_2}/{[n]}_{q_2}}^{{[l+1]}_{q_2}/{[n]}_{q_2}}{\int }_{q_1{[k]}_{q_1}/{[n]}_{q_1}}^{{[k+1]}_{q_1}/{[n]}_{q_1}}t{d}_{q_1}^{R}t{d}_{q_2}^{R}s=\frac{1}{{[n]}_{q_1}{[n]}_{q_2}}(\frac{q_1{[k]}_{q_1}}{{[n]}_{q_1}}+\frac{1}{{[2]}_{q_1}}\frac{1}{{[n]}_{q_1}})$, we get from the linearity of $K_n^{q_1,q_2}$ that

Then we have from the definition of q-factorial and $K_n^{q_1,q_2}(e_{00};x,y)=1$

Similarly, we write that

Now we compute the value $K_n^{q_1,q_2}(e_{20};x,y)$. Applying the equalities ${\int }_{q_2{[l]}_{q_2}/{[n]}_{q_2}}^{{[l+1]}_{q_2}/{[n]}_{q_2}}\times {\int }_{q_1{[k]}_{q_1}/{[n]}_{q_1}}^{{[k+1]}_{q_1}/{[n]}_{q_1}}{t}^2{d}_{q_1}^{R}t{d}_{q_2}^{R}s=\frac{1}{{[n]}_{q_1}{[n]}_{q_2}}(\frac{q_1^2{[k]}_{q_1}^2}{{[n]}_{q_1}^2}+\frac{1}{{[2]}_{q_1}}\frac{2q_1{[k]}_{q_1}}{{[n]}_{q_1}^2}+\frac{1}{{[3]}_{q_1}}\frac{1}{{[n]}_{q_1}^2})$, $K_n^{q_1,q_2}(e_{10};x,y)=x+\frac{1}{{[2]}_{q_1}}\frac{1}{{[n]}_{q_1}}$ and $K_n^{q_1,q_2}(e_{00};x,y)=1$, we obtain

Next, using the fact that ${[k]}_{q_1}=q_1{[k-1]}_{q_1}+1$, we obtain

Similarly, we write

which completes the proof. □

The Korovkin-type theorem for functions of two variables was proved by Volkov [21]. The theorem on weighted approximation for functions of several variables was proved by Gadjiev in [22].

Let $B_{\omega }$ be the space of real-valued functions defined on ${\mathbb{R}}^2$ and satisfying the bounded condition $|f(x,y)|\le M_f\omega (x,y)$, where $\omega (x,y)\ge 1$ for all $(x,y)\in {\mathbb{R}}^2$ is called a weight function if it is continuous on ${\mathbb{R}}^2$ and ${lim}_{\sqrt{x^2+y^2}\to \mathrm{\infty }}\omega (x,y)=\mathrm{\infty }$. We denote by $C_{\omega }$ the space of all continuous functions in the $B_{\omega }$ with the norm

Theorem 1 [22]

Let ${\omega }_1(x,y)$ and ${\omega }_2(x,y)$ be weight functions satisfying

Assume that $T_n$ is a sequence of linear positive operators acting from $C_{{\omega }_1}$ to $B_{{\omega }_2}$. Then, for all $f\in C_{{\omega }_1}$,

if and only if

where $F_0(x,y)=\frac{{\omega }_1(x)}{1+x^2+y^2}$, $F_1(x,y)=\frac{x{\omega }_1(x)}{1+x^2+y^2}$, $F_2(x,y)=\frac{y{\omega }_1(x)}{1+x^2+y^2}$, $F_3(x,y)=\frac{(x^2+y^2){\omega }_1(x)}{1+x^2+y^2}$.

In [16], using the concept of A-statistical convergence, Erkuş and Duman investigated a Korovkin-type approximation result for a sequence of positive linear operators defined on the space of all continuous real-valued functions on any compact subset of the real m-dimensional space.

Now we recall the concepts of regularity of a summability matrix and A-statistical convergence. Let $A:=(a_{nk})$ be an infinite summability matrix. For a given sequence $x:=(x_k)$, the A-transform of x, denoted by $Ax:=({(Ax)}_n)$, is defined as ${(Ax)}_n:={\sum }_{k=1}^{\mathrm{\infty }}{a}_{nk}{x}_k$ provided the series converges for each n. A is said to be regular if ${lim}_n{(Ax)}_n=L$ whenever $limx=L$ [23]. Suppose that A is a non-negative regular summability matrix. Then x is A-statistically convergent to L if for every $\epsilon >0$, ${lim}_n{\sum }_{k:|x_k-L|\ge \epsilon }{a}_{nk}=0$, and we write ${\mathit{st}}_A\text{-}limx=L$ [24]. Actually, x is A-statistically convergent to L if and only if, for every $\epsilon >0$, ${\delta }_A(k\in \mathbb{N}:|x_k-L|\ge \epsilon )=0$, where ${\delta }_A(K)$ denotes the A-density of the subset K of the natural numbers and is given by ${\delta }_A(K):={lim}_n{\sum }_{k=1}^{\mathrm{\infty }}{a}_{nk}{\chi }_K(k)$ provided the limit exists, where ${\chi }_K$ is the characteristic function of K. If $A=C_1$, the Cesáro matrix of order one, then A-statistical convergence reduces to the statistical convergence [25]. Also, taking $A=I$, the identity matrix, A-statistical convergence coincides with the ordinary convergence.

We consider ${\omega }_1(x,y)=1+x^2+y^2$ and ${\omega }_2(x,y)={(1+x^2+y^2)}^{1+\alpha }$ for $\alpha >0$, $(x,y)\in {\mathbb{R}}_0^2$, where ${\mathbb{R}}_0^2:=\{(x,y)\in {\mathbb{R}}^2:x\ge 0,y\ge 0\}$.

We obtain statistical approximation properties of the operator defined by (2.1) with the help of Korovkin-type theorem given in [26]. Let $(q_{1,n})$ and $(q_{2,n})$ be two sequences in the interval $(0,1)$ so that

Theorem 2 Let $A=(a_{nk})$ be a nonnegative regular summability matrix, and let $(q_{1,n})$ and $(q_{2,n})$ be two sequences satisfying (3.1). Then, for any function $f\in C_{{\omega }_1}({\mathbb{R}}_0^2)$ and $q_R$-integrable function, for $\alpha >0$, we have

Proof Let ${\tilde{K}}_n^{q_{1,n},q_{2,n}}$ be defined as

From Lemma 1, since $|K_n^{q_{1,n},q_{2,n}}(1+t^2+s^2;x,y)|\le c{(1+x^2+y^2)}^{1+\alpha }$ for $x\in [0,\frac{q_{1,n}}{1-q_{1,n}^n})$ and $y\in [0,\frac{q_{{2,n}_{}}}{1-q_{2,n}^n})$, $\{{\tilde{K}}_n^{q_{1,n},q_{2,n}}(f;\cdot )\}$ is a sequence of linear positive operators acting from $C_{{\omega }_1}({\mathbb{R}}_0^2)$ to $B_{{\omega }_2}({\mathbb{R}}_0^2)$.

From (i) of Lemma 1, it is clear that

holds. By (ii) of Lemma 1, we get

Since ${\mathit{st}}_A\text{-}{lim}_n\frac{1}{{[n]}_{q_{1,n}}}=0$, ${\mathit{st}}_A\text{-}{lim}_n{\parallel {\tilde{K}}_n^{q_{1,n},q_{2,n}}(e_{10};\cdot )-e_{10}\parallel }_{{\omega }_1}=0$. Similarly, since ${\mathit{st}}_A\text{-}{lim}_n\frac{1}{{[n]}_{q_{2,n}}}=0$, ${\mathit{st}}_A\text{-}{lim}_n{\parallel {\tilde{K}}_n^{q_{1,n},q_{2,n}}(e_{01};\cdot )-e_{01}\parallel }_{{\omega }_1}=0$. Also, we have from (iv) of Lemma 1

So, we can write

Since ${\mathit{st}}_A\text{-}{lim}_n(1-q_{1,n})=0$, ${\mathit{st}}_A\text{-}{lim}_n(\frac{q_{1,n}}{2}+\frac{1}{{[2]}_{q_{1,n}}})\frac{1}{{[n]}_{q_{1,n}}}=0$ and ${\mathit{st}}_A\text{-}{lim}_n\frac{1}{{[3]}_{q_{1,n}}}\frac{1}{{[n]}_{q_{1,n}}^2}=0$, for each $\epsilon >0$, we define the following sets.

By (3.2), it is clear that $D\subseteq D_1\cup D_2\cup D_3$, which implies that for all $n\in \mathbb{N}$,

Taking limit as $n\to \mathrm{\infty }$, we have

Similarly, since ${\mathit{st}}_A\text{-}{lim}_n(1-q_{2,n})=0$, ${\mathit{st}}_A\text{-}{lim}_n(\frac{q_{2,n}}{2}+\frac{1}{{[2]}_{q_{2,n}}})\frac{1}{{[n]}_{q_{2,n}}}=0$ and ${\mathit{st}}_A\text{-}{lim}_n\frac{1}{{[3]}_{q_{2,n}}}\times \frac{1}{{[n]}_{q_{2,n}}^2}=0$, we write ${\mathit{st}}_A\text{-}{lim}_n{\parallel {\tilde{K}}_n^{q_{1,n},q_{2,n}}(e_{02};\cdot )-e_{02}\parallel }_{{\omega }_1}=0$. So, the proof is completed. □

If we define the function ${\phi }_{x,y}(t,s)={(t-x)}^2+{(s-y)}^2$, $(x,y)\in [0,\frac{q_{1_{}}}{1-q_1^n})\times [0,\frac{q_{2_{}}}{1-q_2^n})$, then by Lemma 1 one gets the following result

We use the modulus of continuity $\omega (f,\delta )$ defined as follows:

where $\delta >0$ and $f\in C_B({\mathbb{R}}_0^2)$ the space of all bounded and continuous functions on ${\mathbb{R}}_0^2$. Observe that, for all $f\in C_B({\mathbb{R}}_0^2)$ and $\lambda ,\delta >0$, we have

where $[\lambda ]$ is defined to be the greatest integer less than or equal to λ.

By the definition of modulus of continuity, we have

and by (3.3), for any $\delta >0$,

which implies that

Using the linearity and positivity of the operators $K_n^{q_1,q_2}$, we get from (3.4) and $K_n^{q_1,q_2}(e_{00};x,y)=1$ that, for any $n\in \mathbb{N}$,

Now, if we replace $q_{1,n}$ and $q_{2,n}$ by sequences $(q_{1,n})$ and $(q_{2,n})$ to be two sequences satisfying (3.1), and we take $\delta :={\delta }_n(x,y)=\sqrt{K_n^{q_{1,n},q_{2,n}}({\phi }_{x,y}(t,s);x,y)}$, $0\le x<\frac{q_{{1,n}_{}}}{1-q_{1,n}^n}$, $0\le y<\frac{q_{{2,n}_{}}}{1-q_{2,n}^n}$, then we can write

The author is grateful to the referees for their useful remarks.

Authors and Affiliations

1. Department of Mathematics, Faculty of Sciences, Teknik-okullar, Gazi University, Ankara, 06500, Turkey

   Mediha Örkcü