Properties of q-analogue of Beta operator

Gupta, Vijay; Sharma, Honey; Kim, Taekyun; Lee, Sang-Hun

doi:10.1186/1687-1847-2012-86

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Open access
Published: 25 June 2012

Properties of q-analogue of Beta operator

Vijay Gupta¹,
Honey Sharma²,
Taekyun Kim³ &
…
Sang-Hun Lee⁴

Advances in Difference Equations volume 2012, Article number: 86 (2012) Cite this article

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Abstract

In this article, we introduce the q-variant of Beta operator. We find the recurrence formula for m th-order moments. Here, we establish some direct theorems in terms of modulus of continuity for these operators. We also propose conditions for better approximation. In the end, we also propose the Stancu-type generalization.

Mathematical Subject Classification: 41A25; 41A35.

1. Introduction

In the last four decades after the integral modification of Bernstein polynomials by Durrmeyer, several new Durrmeyer-type operators were introduced and their approximation properties were discussed. In 2007, Gupta et al. [1]proposed a family of linear positive operators as

B_{n} (f, x) = \frac{1}{(n + 1)} \sum_{k = 1}^{\infty} b_{n, k} (x) \int_{0}^{\infty} b_{n, k} (t) f (t) d t, x \in [0, \infty),

(1.1)

where

b_{n, k} (t) = \frac{1}{B (k, n + 1)} t^{k - 1} {(1 + t)}^{- n - k - 1},

for f ∈ C_γ [0, ∞), where C_γ [0, ∞), γ > 0 be the class of all continuous functions defined on [0, ∞) satisfying the growth condition |f (t)| ≤ Ct^γ, C > 0 and B(k, n + 1) is beta function. They [1] established the direct and inverse results for these operators.

In the recent years, q-calculus was used in approximation theory and several new operators were introduced and their approximation properties were discussed (see [2–6], etc.). Motivated by these operators, we now introduce the q-analogue of (1.1). For f ∈ C[0,∞) and 0 < q < 1, we propose the q-Beta operators as

B_{n}^{q} (f, x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) f (t) d_{q} t, x \in [0, \infty),

(1.2)

where

b_{n, k}^{q} (t) = \frac{q^{{(k - 1)}^{2} / 2}}{B_{q} (k, n + 1)} t^{k - 1} {(1 + t)}_{q}^{- n - k - 1},

and B_q(t, s) denote the q-Beta function [7] is given by

B_{q} (t, s) = K (A, t) \int_{0}^{\infty / A} \frac{x^{t - 1}}{{(1 + x)}_{q}^{t + s}} d_{q} x,

where $K (x, t) = \frac{1}{1 + x} x^{t} {(1 + 1 / x)}_{q}^{t} {(1 + x)}_{q}^{1 - t}$ . In particular, for any positive integer n, $K (x, n) = q^{\frac{n (n - 1)}{2}}$ , K(x,0) = 1, $B_{q} (t, s) = \frac{Γ_{q} (t) Γ_{q} (s)}{Γ_{q} (t + s)}$ and ${(a + b)}_{q}^{n} = \prod_{s = 0}^{n - 1} (a + q^{s} b)$ , n ∈ ℕ, a, b ∈ ℝ.

This article is the extension of the earlier work of [1]. Here, we consider the q variant of the operators discussed in [1] and obtain the recurrence relations for moments. We also obtain some direct results for the q operators, which also include the asymptotic formula. In the end, we establish the conditions for better approximation.

2. Preliminaries

To make the article self-content, here we mention certain basic definitions of q-calculus, details can be found in [8, 9] and the other recent articles. For each nonnegative integer k, the q-integer [k]_q and the q-factorial [k]_q! are, respectively, defined by

{[k]}_{q} = \{\begin{matrix} (1 - q^{k}) / (1 - q), & q \neq 1 \\ k, & q = 1 \end{matrix},

and

{[k]}_{q}! = \{\begin{matrix} {[k]}_{q} {[k - 1]}_{q} \dots {[1]}_{q}, & k \geq 1 \\ 1 & k = 0 \end{matrix} .

For the integers n, k satisfying n ≥ k ≥ 0, the q-binomial coecients are defined by

{[\begin{matrix} n \\ k \end{matrix}]}_{q} = \frac{{[n]}_{q}!}{{[k]}_{q}! {[n - k]}_{q}!} .

The q-derivative of a function $f : ℝ \to ℝ$ is defined by

D_{q} f (x) = \frac{f (x) - f (q x)}{(1 - q) x}, x \neq 0,

and the q-improper integral (see [10]) is given by

\int_{0}^{\infty / A} f (t) d_{q} t = (1 - q) \sum_{j = - \infty}^{\infty} f (q^{j} / A) (q^{j} / A), A > 0 .

The q-integral by parts is given by

\int_{b}^{a} f (t) D_{q} (g (t)) d_{q} t = {[f (t) g (t)]}_{a}^{b} - \int_{a}^{b} g (q t) D_{q} (f (t)) d_{q} t .

Lemma 1. For n, k ≥ 0, we have

D_{q} {(1 + x)}_{q}^{n + k + 1} = {[n + k + 1]}_{q} {(1 + q x)}_{q}^{n + k},

(2.1)

D_{q} (\frac{1}{{(1 + x)}_{q}^{n + k + 1}}) = - \frac{{[n + k + 1]}_{q}}{{(1 + x)}_{q}^{n + k + 2}} .

(2.2)

Proof. Using q-derivative operator, we can write

\begin{matrix} D_{q} {(1 + x)}_{q}^{n + k + 1} = \frac{1}{(q - 1) x} (\prod_{j = 0}^{n + k} (1 + q^{j + 1} x) - \prod_{j = 0}^{n + k} (1 + q^{j} x)) \\ = \frac{(q^{n + k + 1} - 1)}{(q - 1)} \prod_{j = 0}^{n + k - 1} (1 + q^{j + 1} x) \\ = {[n + k + 1]}_{q} {(1 + q x)}_{q}^{n + k} . \end{matrix}

Equation (2.2) can be obtained directly by using q-quotient rule as follows:

\begin{matrix} D_{q} (\frac{1}{{(1 + x)}_{q}^{n + k + 1}}) = \frac{- {[n + k + 1]}_{q} {(1 + q x)}_{q}^{n + k}}{{(1 + x)}_{q}^{n + k + 1} {(1 + q x)}_{q}^{n + k + 1}} \\ = \frac{- {[n + k + 1]}_{q}}{{(1 + x)}_{q}^{n + k + 1} (1 + q^{n + k + 1} x)} \\ = \frac{- {[n + k + 1]}_{q}}{{(1 + x)}_{q}^{n + k + 2}} . \end{matrix}

□

Remark 1. By using (2.1) and D_qx^{k− 1}= [k − 1]_qx^{k− 2}, we get

\begin{matrix} D_{q} (\frac{x^{k - 1}}{{(1 + x)}_{q}^{n + k + 1}}) = \frac{{(1 + x)}_{q}^{n + k + 1} {[k - 1]}_{q} x^{k - 2} - x^{k - 1} {[n + k + 1]}_{q} {(1 + q x)}_{q}^{n + k}}{{(1 + x)}_{q}^{n + k + 1} {(1 + q x)}_{q}^{n + k + 1}} \\ = \frac{{[k - 1]}_{q} x^{k - 2}}{{(1 + q x)}_{q}^{n + k + 1}} - \frac{{[n + k + 1]}_{q} x^{k - 1}}{(1 + q^{n + k + 1} x) {(1 + x)}_{q}^{n + k + 1}} \\ = \frac{x^{k - 1}}{x (1 + x) {(1 + q x)}_{q}^{n + k + 1}} [(1 + x) {[k - 1]}_{q} - x {[n + k + 1]}_{q}] \\ = \frac{x^{k - 1}}{x (1 + x) {(1 + q x)}_{q}^{n + k + 1}} [{[k - 1]}_{q} - q^{k - 1} {[n + 2]}_{q} x] . \end{matrix}

Hence, we obtain

x (1 + x) D_{q} (\frac{x^{k - 1}}{{(1 + x)}_{q}^{n + k + 1}}) = \frac{x^{k - 1}}{{(1 + q x)}_{q}^{n + k + 1}} ({[k - 1]}_{q} - q^{k - 1} {[n + 2]}_{q} x) .

(2.3)

Lemma 2. We have following equalities

q x (1 + x) D_{q} (b_{n, k}^{q} (x)) = {[n + 2]}_{q} b_{n, k}^{q} (q x) (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - q x),

(2.4)

\frac{t}{q} (1 + \frac{t}{q}) D_{q} (b_{n, k}^{q} (\frac{t}{q})) = \frac{{[n + 2]}_{q}}{q^{2}} b_{n, k}^{q} (t) (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - t) .

(2.5)

Proof. Above equalities can be obtained by direct computations using definition of operator and (2.3). □

Theorem 1. If mth (m > 0, m ∈ ℕ)-order moment of operator (1.2) is defined as

B_{n, m}^{q} (x) : = B_{n}^{q} (t^{m}, x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) t^{m} d_{q} t, x \in [0, \infty),

then $B_{n, 0}^{q} (x) = 1$ and for n> m, we have following recurrence relation,

({[n + 2]}_{q} - {[m + 2]}_{q}) B_{n, m + 1}^{q} (q x) = q ({[m + 1]}_{q} + x {[n + 2]}_{q}) B_{n, m}^{q} (q x) + q x (1 + x) D_{q} (B_{n, m}^{q} (x)) .

(2.6)

Proof. By using (2.4), we have

\begin{matrix} q x (1 + x) D_{q} (B_{n, m}^{q} (x)) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} q x (1 + x) D_{q} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) t^{m} d_{q} t \\ = \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - t) b_{n, k}^{q} (t) t^{m} d_{q} t \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) t^{m + 1} d_{q} t \\ - q x \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) t^{m} d_{q} t \\ = I + {[n + 2]}_{q} B_{n, m + 1}^{q} (q x) - q x {[n + 2]}_{q} B_{n, m}^{q} (q x), \end{matrix}

by (2.5) and q-integration by parts, we get

\begin{array}{l} I & = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} (q t^{m + 1} + t^{m + 2}) D_{q} b_{n, k}^{q} (t / q) d_{q} t \\ = - \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} (q {[m + 1]}_{q} t^{m} + {[m + 2]}_{q} t^{m + 1}) b_{n, k}^{q} (t) d_{q} t \\ = - {[m + 1]}_{q} q B_{n, m}^{q} (q x) - {[m + 2]}_{q} B_{n, m + 1}^{q} (q x), \end{array}

by combining above two equations, we can write

\begin{array}{l} q x (1 + x) D_{q} (B_{n, m}^{q} (x)) & = - {[m + 1]}_{q} q B_{n, m}^{q} (q x) - {[m + 2]}_{q} B_{n, m + 1}^{q} (q x) \\ + {[n + 2]}_{q} B_{n, m + 1}^{q} (q x) - q x {[n + 2]}_{q} B_{n, m}^{q} (q x) \\ = ({[n + 2]}_{q} - {[m + 2]}_{q}) B_{n, m + 1}^{q} (q x) - q ({[m + 1]}_{q} + x {[n + 2]}_{q}) B_{n, m}^{q} (q x) . \end{array}

Hence, the result follows. □

Corollary 2. We have

B_{n, 1}^{q} (x) = \frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})},

(2.7)

B_{n, 2}^{q} (x) = \frac{(q {[2]}_{q} + x {[n + 2]}_{q}) (q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} + \frac{x (q + x) {[n + 2]}_{q}}{q ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})}

(2.8)

Corollary 3. If we denote central moments by $ϕ_{n, m}^{q} (x) = B_{n}^{q} ({(t - x)}^{m}, x)$ , m = 1,2, then we have

ϕ_{n, 1}^{q} (x) = \frac{(q + x {[2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})},

(2.9)

ϕ_{n, 2}^{q} (x) = \frac{x^{2} ((\frac{1 + q^{3}}{q}) {[n + 2]}_{q} + {[2]}_{q} {[3]}_{q}) + x ((q^{2} + 1) {[n + 2]}_{q} + 2 q {[3]}_{q}) + q^{2} {[2]}_{q}}{({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})}

(2.10)

Remark 2. As a special case when q → 1^-, we have

\begin{array}{l} B_{n, 1} (x) & = \frac{(2 + n) x + 1}{n}, \\ B_{n, 2} (x) & = \frac{(n + 3) (n + 2)}{n (n - 1)} x^{2} + 4 \frac{(n + 2)}{n (n - 1)} x + \frac{2}{n (n - 1)} . \end{array}

The first two central moments for q → 1⁻ are

\begin{gathered} B_{n} ((t - x), x) = \frac{2 x + 1}{n}, \\ B_{n} ({(t - x)}^{2}, x) = \frac{x (1 + x) (2 n + 10) + 2}{n (n - 1)} . \end{gathered}

which are the moments obtained by Gupta et al. [1] for Beta operator.

3. Ordinary approximation

Let C_B [0, ∞) be the space of all real valued continuous bounded function f on [0, ∞) endowed with the norm || f || = sup{|f(x)| : x ∈ [0, ∞)}. Further let us consider the following K-functional:

K_{2} (f, δ) = inf_{g \in W^{2}} {| | f - g | | + δ | | g^{″} | |},

where δ > 0 and

W^{2} = {g \in C_{B} [0, \infty) : g^{'}, g^{″} \in C_{B} [0, \infty)} .

From [11], there exist an absolute constant C > 0 such that

K_{2} (f, δ) \leq C ω_{2} (f, δ^{1 / 2}),

(3.1)

where

ω_{2} (f, δ^{1 / 2}) = sup_{0 < h \leq \sqrt{δ}} sup_{x \in [0, \infty)} | f (x + 2 h) - 2 f (x + h) + f (x) |

is the second-order modulus of smoothness of f ∈ C_B [0, ∞). By

ω (f, δ) = sup_{0 < h \leq δ} sup_{x \in [0, \infty)} | f (x + h) - f (x) |

we denote the usual modulus of continuity of f ∈ C_B [0, ∞).

Theorem 4. Let 0 < q < 1, we have

| B_{n}^{q} (f, x) - f (x) | \leq C ω_{2} (f, \sqrt{ϕ_{n, 2}^{q} (x) + ϕ_{n, 1}^{q}^{2} (x)}) + ω (f, ϕ_{n, 1}^{q} (x))

for every x ∈ [0, ∞) and f ∈ C_B [0, ∞), where C is a positive constant.

Proof. We consider modified operators $\bar{B_{n}^{q}}$ defined by

{\bar{B}}_{n}^{q} (f, x) = B_{n}^{q} (f, x) - f (\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}}) + f (x),

(3.2)

x ∈ [0, ∞). The operators ${\bar{B}}_{n}^{q}$ preserve the linear functions:

{\bar{B}}_{n}^{q} (t - x, x) = 0

(3.3)

Let g ∈ W² and t ∈ [0, ∞). Using Taylor's expansion, we have

g (t) = g (x) - g^{'} (x) (t - x) + \int_{x}^{t} (t - u) g^{″} (u) d u,

and (3.3), we have

{\bar{B}}_{n}^{q} (g, x) = g (x) + {\bar{B}}_{n}^{q} (\int_{x}^{t} (t - u) g^{″} (u) d u, x) .

Therefore, from (3.2), we have

\begin{array}{l} | {\bar{B}}_{n}^{q} (g, x) - g (x) | & \leq |B_{n}^{q} (\int_{x}^{t} (t - u) g^{″} (u) d u, x)| + |\int_{x}^{\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}}} (\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}} - u) g^{″} (u) d u| \\ \leq B_{n}^{q} (\int_{x}^{t} | t - u | | g^{″} (u) | d u, x) + \int_{x}^{\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}}} |\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}} - u| | g^{″} (u) | d u \\ \leq [B_{n}^{q} ({(t - x)}^{2}, x) + (\frac{q + {[2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}})] | | g^{″} | | . \end{array}

(3.4)

From Corollary 3, we get

| {\bar{B}}_{n}^{q} (g, x) - g (x) | \leq (ϕ_{n, 2}^{q} (x) + ϕ_{n, 1}^{q 2} (x)) | | g^{″} | | .

(3.5)

By (3.2) and Corollary 1, we have

| {\bar{B}}_{n}^{q} (f, x) | \leq | B_{n}^{q} (f, x) | + 2 | | f | | \leq | | f | | B_{n}^{q} (1, x) + 2 | | f | | \leq 3 | | f | | .

(3.6)

Now using (3.2), (3.5), and (3.6), we obtain

\begin{array}{l} | B_{n, q} (f, x) - f (x) | & \leq | {\bar{B}}_{n}^{q} (f - g, x) - (f - g) (x) | + | {\bar{B}}_{n}^{q} (g, x) - g (x) | + |f (\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}}) - f (x)| \\ \leq 4 | | f - g | | + (ϕ_{n, 2}^{q} (x) + ϕ_{n, 1}^{q 2} (x)) | | g^{″} | | + |f (\frac{q + {[n + 2]}_{q} x}{{[n + 2]}_{q} - {[2]}_{q}}) - f (x)| . \end{array}

Thus taking infimum on the right-hand side over all g ∈ W², we get

| B_{n}^{q} (f, x) - f (x) | \leq 4 K_{2} (f, ϕ_{n, 2}^{q} (x) + ϕ_{n, 1}^{q 2} (x)) + ω (f, ϕ_{n, 1}^{q} (x)) .

In the view of (3.1), we get

| B_{n}^{q} (f, x) - f (x) | \leq C ω_{2} (f, \sqrt{ϕ_{n 2}^{q} (x) + ϕ_{n 1}^{q 2} (x)}) + ω (f, ϕ_{n, 1}^{q} (x)) .

This completes the proof of the theorem. □

4. Weighted approximation

Here, we give weighted approximation theorem for the operator $B_{n}^{q} (f, x)$ . Similar type of results are given in [3].

Let $B_{x^{2}} [0, \infty)$ be the set of all functions f defined on the interval [0, ∞) satisfying the condition

| f (x) | \leq M_{f} (1 + x^{2}),

where M_f is a constant depending on f. $B_{x^{2}} [0, \infty)$ is a normed space with the norm

{∥f∥}_{x^{2}} = sup_{x \in [0, \infty)} \frac{| f (x) |}{1 + x^{2}}, f \in B_{x^{2}} [0, \infty) .

$C_{x^{2}} [0, \infty)$ denotes the subspace of all continuous functions in $B_{x^{2}} [0, \infty)$ and $C_{x^{2}}^{*} [0, \infty)$ denotes the subspace of all functions $f \in C_{x^{2}} [0, \infty)$ with $lim_{x \to \infty} \frac{f (x)}{1 + x^{2}} = k$ .

Theorem 5. Let q = q_n ∈ (0, 1) such that q_n→ 1 as n → ∞, then for each $f \in C_{x^{2}}^{*} [0, \infty)$ , we have

l i m_{n \to \infty} {∥B_{n}^{q_{n}} (f, x) - f (x)∥}_{x^{2}} = 0 .

(4.1)

Proof. By the Korovkin's theorem (see [12]), $B_{n}^{q_{n}} (f, x)$ converges to f uniformly as n → ∞ for $f \in C_{x^{2}}^{*} [0, \infty)$ if it satisfies $B_{n}^{q_{n}} (t^{i}; x) \to x^{i}$ for i = 0, 1, 2 uniformly as n → ∞.

As, $B_{n}^{q_{n}} (1, x) = 1$ ,

| | B_{n}^{q_{n}} (1, x) - 1 | |_{x^{2}} = 0 .

(4.2)

By Corollary 2, for n > 1,

\begin{array}{l} | | B_{n}^{q_{n}} (t, x) - x | |_{x^{2}} & = sup_{x \in [0, \infty)} \frac{| B_{n}^{q_{n}} (t, x) - x |}{1 + x^{2}} \\ \leq \frac{q_{n}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}})} + \frac{{[n + 2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}})} sup_{x \in [0, \infty)} \frac{x}{1 + x^{2}} \\ \leq \frac{q_{n}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}})} + \frac{{[n + 2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}})}, \end{array}

as n → ∞, we get

| | B_{n}^{q_{n}} (t, x) - f (x) | |_{x^{2}} \to 0 .

(4.3)

Similarly for n > 1, we have

\begin{matrix} {‖ B_{n}^{q_{n}} (t^{2}, x) - x^{2} ‖}_{x^{2}} = \sup_{x \in [0, \infty)} \frac{| B_{n}^{q_{n}} (t^{2}, x) - x^{2} |}{1 + x^{2}} \\ \leq \frac{{[n + 2]}_{q_{n}}^{2} + {[n + 2]}_{q_{n}} / q_{n}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})} \sup_{x \in [0, \infty)} \frac{x^{2}}{1 + x^{2}} \\ + \frac{(1 + q_{n} + q_{n} {[2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})} \sup_{x \in [0, \infty)} \frac{x}{1 + x^{2}} + \frac{q_{n}^{2} {[2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}})} \\ \leq \frac{{[n + 2]}_{q_{n}}^{2} + {[n + 2]}_{q_{n}} / q_{n}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})} + \frac{(1 + q_{n} + q_{n} {[2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})} \\ + \frac{q_{n}^{2} {[2]}_{q_{n}}}{({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})}, \end{matrix}

as n → ∞, we get

| | B_{n}^{q_{n}} (t^{2}, x) - x^{2} | |_{x^{2}} \to 0 .

(4.4)

By (4.2), (4.3), (4.4), and Korovkin's theorem, we get the desired result. □

Theorem 6. Let q = q_n ∈ (0, 1) such that q_n → 1 as n → ∞, then for each $f \in C_{x^{2}} [0, \infty)$ and α> 0, we have

l i m_{n \to \infty} sup_{x \in [0, \infty)} \frac{| B_{n}^{q_{n}} (f, x) - f (x) |}{{(1 + x^{2})}^{α + 1}} = 0 .

(4.5)

Proof. For any fixed x₀ > 0, we have

\begin{array}{l} sup_{x \in [0, \infty)} \frac{| B_{n}^{q_{n}} (f, x) - f (x) |}{{(1 + x^{2})}^{α + 1}} & \leq sup_{x \leq x_{0}} \frac{| B_{n}^{q_{n}} (f, x) - f (x) |}{{(1 + x^{2})}^{α + 1}} + sup_{x \geq x_{0}} \frac{| B_{n}^{q_{n}} (f, x) - f (x) |}{{(1 + x^{2})}^{α + 1}} \\ \leq | | B_{n}^{q_{n}} (f, x) - f (x) | |_{C [0, x_{0}]} + | | f | | sup_{x \geq x_{0}} \frac{| B_{n}^{q_{n}} (1 + t^{2}, x) |}{{(1 + x^{2})}^{α + 1}} \\ + sup_{x \geq x_{0}} \frac{| f (x) |}{{(1 + x^{2})}^{α + 1}} . \end{array}

By Theorem 5 and Corollary 2 first two terms of above inequality tends to 0 as n → ∞. Last term of inequality can be made small enough for large x₀ > 0. This completes the proof.

□

5. Central moments and asymptotic formula

In this section, we observe that it is not possible to estimate recurrence formula $B_{n}^{q} ({(t - x)}^{m}, x)$ in q calculus, there may be some techniques, but at the moment it can be considered as an open problem. Here we establish the recurrence relation for the central moments and obtain asymptotic formula.

Lemma 3. If we de ne the central moments as

T_{n, m} (x) = B_{n}^{q} ({(t - x)}_{q}^{m}, x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t, x \in [0, \infty),

then

\begin{array}{l} T_{n, 0} (x) & = 1, \\ T_{n, 1} (x) & = \frac{(q + x {[2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}, \\ T_{n, 2} (x) & = \frac{(q {[2]}_{q} + x {[n + 2]}_{q}) (q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} + \frac{x (q + x) {[n + 2]}_{q}}{q ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} \\ - \frac{(q x + x) (q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})} + q x^{2} . \end{array}

and for n > m, we have the following recurrence relation:

\begin{gathered} ({[n + 2]}_{q} - {[m + 2]}_{q}) T_{n, m + 1} (q x) = q x (1 + x) [D_{q} T_{n, m} (x) + {[m]}_{q} T_{n, m - 1} (q x)] \\ + ({[3]}_{q} q^{m} x + q - x) {[m + 1]}_{q} T_{n, m} (q x) \\ + [{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x] {[m]}_{q} T_{n, m - 1} (q x) \\ + [q^{m} x \{{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x\} + q^{2 m + 1} x^{2} \{q^{2} x - {[3]}_{q} q^{m} x - q + x\}] {[m - 1]}_{q} T_{n, m - 2} (q x) \\ + x (1 - q^{m + 1}) {[n + 2]}_{q} T_{n, m} (q x) + q x (1 - q^{m - 1}) {[n + 2]}_{q} T_{n, m} (q x) - q x^{2} (1 - q^{m - 1}) (1 - q^{m}) {[n + 2]}_{q} T_{n, m - 1} (q x) . \end{gathered}

proof. Using the identity

q x (1 + x) D_{q} [b_{n, k}^{q} (x)] = (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - q x) {[n + 2]}_{q} b_{n, k}^{q} (q x)

and q derivatives of product rule, we have

\begin{array}{l} q x (1 + x) D_{q} [T_{n, m}] & = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} q x (1 + x) D_{q} (b_{n, k}^{q} (x)) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \\ - \frac{{[m]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} q x (1 + x) b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - q x)}_{q}^{m - 1} d_{q} t \end{array}

Thus

\begin{gathered} E : = q x (1 + x) [D_{q} (T_{n, m} (x)) + {[m]}_{q} T_{n, m - 1} (q x)] \\ = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} q x (1 + x) D_{q} (b_{n, k}^{q} (x)) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \\ = \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \\ = \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} (\frac{{[k - 1]}_{q}}{q^{k - 2} {[n + 2]}_{q}} - t + t - q^{m} x - q x + q^{m} x) b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \\ = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} q^{2} [\frac{t}{q} (1 + \frac{t}{q})] D_{q} [b_{n, k}^{q} (\frac{t}{q})] {(t - x)}_{q}^{m} d_{q} t \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m + 1} d_{q} t \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} q x (q^{m - 1} - 1) \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \\ = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} (t q + t^{2}) D_{q} [b_{n, k}^{q} (\frac{t}{q})] {(t - x)}_{q}^{m} d_{q} t \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m + 1} d_{q} t \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} q x (q^{m - 1} - 1) \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t . \end{gathered}

Using the identities

(t - q^{m} x) (t - q^{m + 1} x) = t^{2} - {[2]}_{q} q^{m} x t + q^{2 m + 1} x^{2}

and

(t - q^{m} x) (t - q^{m + 1} x) (t - q^{m + 2} x) = t^{3} - {[3]}_{q} q^{m} x t^{2} + {[3]}_{q} q^{2 m + 1} x^{2} t - q^{3 m + 3} x^{3}

we obtain the following identity after simple computation

\begin{matrix} (q t + t^{2}) {(t - x)}_{q}^{m} = (q t + t^{2}) (t - x) {(t - q x)}_{q}^{m - 1} = [t^{3} + (q - x) t^{2} - q x t] {(t - q x)}_{q}^{m - 1} \\ = {(t - q x)}_{q}^{m + 2} + ({[3]}_{q} q^{m} x + q - x) {(t - q x)}_{q}^{m + 1} \\ + [{[2]}_{q} q^{m} x {{[3]}_{q} q^{m} x + q - x} - {[3]}_{q} q^{2 m + 1} x^{2} - q x)] {(t - q x)}_{q}^{m} \\ + [q^{m} x {{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x} + q^{2 m + 1} x^{2} {q^{2} x - {[3]}_{q} q^{m} x - q + x}] {(t - q x)}_{q}^{m - 1} . \end{matrix}

Using the above identity and q integral by parts

\int_{a}^{b} u (t) D_{q} (v (t)) d_{q} t = {[u (t) v (t)]}_{a}^{b} - \int_{a}^{b} v (q t) D_{q} [u (t)] d_{q} t,

we have

\begin{gathered} E = - {[m + 2]}_{q} T_{n, m + 1} (q x) - ({[3]}_{q} q^{m} x + q - x) {[m + 1]}_{q} T_{n, m} (q x) \\ - [{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x] {[m]}_{q} T_{n, m - 1} (q x) \\ - [q^{m} x \{{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x\} + q^{2 m + 1} x^{2} \{q^{2} x - {[3]}_{q} q^{m} x - q + x\}] {[m - 1]}_{q} T_{n, m - 2} (q x) \\ + \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m + 1} d_{q} t \\ - \frac{{[n + 2]}_{q}}{{[n + 1]}_{q}} q x (1 - q^{m - 1}) \sum_{k = 1}^{\infty} b_{n, k}^{q} (q x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) {(t - x)}_{q}^{m} d_{q} t \end{gathered}

Finally, using

{(t - x)}_{q}^{m + 1} = (t - x) {(t - q x)}_{q}^{m} = {(t - q x)}_{q}^{m + 1} - x (1 - q^{m + 1}) {(t - q x)}_{q}^{m}

and

{(t - x)}_{q}^{m} = (t - x) {(t - q x)}_{q}^{m - 1} = {(t - q x)}_{q}^{m} - x (1 - q^{m}) {(t - q x)}_{q}^{m - 1},

we get

\begin{gathered} E = - {[m + 2]}_{q} T_{n, m + 1} (q x) - ({[3]}_{q} q^{m} x + q - x) {[m + 1]}_{q} T_{n, m} (q x) \\ - [{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} - q x] {[m]}_{q} T_{n, m - 1} (q x) \\ - [q^{m} x \{{[2]}_{q} q^{m} x ({[3]}_{q} q^{m} x + q - x) - {[3]}_{q} q^{2 m + 1} x^{2} + q x\} + q^{2 m + 1} x^{2} \{q^{2} x - {[3]}_{q} q^{m} x - q + x\}] {[m - 1]}_{q} T_{n, m - 2} (q x) \\ + {[n + 2]}_{q} T_{n, m + 1} (q x) - x (1 - q^{m + 1}) {[n + 2]}_{q} T_{n, m} (q x) \\ - q x (1 - q^{m - 1}) {[n + 2]}_{q} T_{n, m} (q x) + q x^{2} (1 - q^{m - 1}) (1 - q^{m}) {[n + 2]}_{q} T_{n, m - 1} (q x) . \end{gathered}

This completes the proof of recurrence relation.

□

Theorem 7. Let f ∈ C [0, ∞) be a bounded function and (q_n) denote a sequence such that 0 < q_n < 1 and q_n → 1 as n → ∞. Then we have for a point x ∈ (0, ∞)

lim_{n \to \infty} {[n]}_{q_{n}} (B_{n}^{q_{n}} (f, x) - f (x)) = (2 x + 1) lim_{n \to \infty} D_{q_{n}} f (x) + x (1 + x) lim_{n \to \infty} D_{q_{n}}^{2} f (x) .

Proof. By q-Taylor's formula [7] on f, we have

f (t) = f (x) + D_{q} f (x) (t - x) + \frac{1}{{[2]}_{q}} D_{q}^{2} f (x) {(t - x)}_{q}^{2} + Φ_{q} (x; t) {(t - x)}_{q}^{2}

for 0 < q < 1, where

Φ_{q} (x; t) = \{\begin{matrix} \frac{f (t) - f (x) - D_{q} f (x) (t - x) - \frac{1}{{[2]}_{q}} D_{q}^{2} f (x) {(t - x)}_{q}^{2}}{{(t - x)}_{q}^{2}}, & if x \neq t \\ 0, & if x = t . \end{matrix}

(5.1)

We know that for n large enough

lim_{t \to x} Φ_{q_{n}} (x; t) = 0 .

(5.2)

That is for any ε > 0, A > 0, there exists a δ > 0 such that

| Φ_{q_{n}} (x; t) | < ε

(5.3)

for |t − x| < δ and n sufficiently large. Using (5.1), we can write

B_{n}^{q_{n}} (f, x) - f (x) = D_{q_{n}} f (x) T_{n, 1} (x) + \frac{D_{q_{n}}^{2} f (x)}{{[2]}_{q_{n}}} T_{n, 2} (x) + E_{n}^{q_{n}} (x),

where

E_{n}^{q} (x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) Φ_{q} (x; t) {(t - x)}_{q}^{2} d_{q} t .

We can easily see that

lim_{n \to \infty} {[n]}_{q_{n}} T_{n, 1} (x) = 2 x + 1 and lim_{n \to \infty} {[n]}_{q_{n}} T_{n, 2} (x) = 2 x (1 + x) .

In order to complete the proof of the theorem, it is suffficient to show that $l i m_{n \to \infty} {[n]}_{q_{n}} E_{n}^{q_{n}} (x) = 0$ . We proceed as follows:

Let

R_{n, 1}^{q_{n}} (x) = {[n]}_{q_{n}} \frac{1}{{[n + 1]}_{q_{n}}} \sum_{k = 1}^{\infty} b_{n, k}^{q_{n}} (x) \int_{0}^{\infty / A} b_{n, k}^{q_{n}} (t) Φ_{q_{n}} (x; t) {(t - x)}_{q_{n}}^{2} χ_{x} (t) d_{q} t

and

R_{n, 2}^{q_{n}} (x) = {[n]}_{q_{n}} \frac{1}{{[n + 1]}_{q_{n}}} \sum_{k = 1}^{\infty} b_{n, k}^{q_{n}} (x) \int_{0}^{\infty / A} b_{n, k}^{q_{n}} (t) Φ_{q_{n}} (x; t) {(t - x)}_{q_{n}}^{2} (1 - χ_{x} (t)) d_{q} t,

so that

{[n]}_{q_{n}} E_{n}^{q_{n}} (x) = R_{n, 1}^{q_{n}} (x) + R_{n, 2}^{q_{n}} (x),

where χ_x (t) is the characteristic function of the interval {t : |t − x| < δ}.

It follows from (5.1)

| R_{n, 1}^{q_{n}} (x) | < ε 2 x (x + 1) as n \to \infty .

if |t − x| ≥ δ, then $| Φ_{q_{n}} (x; t) | \leq \frac{M}{δ^{2}} {(t - x)}^{2}$ , where M > 0 is a constant. Since

\begin{array}{l} {(t - x)}^{2} & = (t - q^{2} x + q^{2} x - x) (t - q^{3} x + q^{3} x - x) \\ = (t - q^{2} x) (t - q^{3} x) + x (q^{3} - 1) (t - q^{2} x) + x (q^{2} - 1) (t - q^{2} x) \\ + x^{2} (q^{2} - 1) (q^{2} - q^{3}) + x^{2} (q^{2} - 1) (q^{3} - 1), \end{array}

we have

\begin{array}{l} | R_{n, 2}^{q_{n}} (x) | & \leq \frac{M}{δ^{2}} {[n]}_{q_{n}} \frac{1}{{[n + 1]}_{q_{n}}} \sum_{k = 1}^{\infty} b_{n, k}^{q_{n}} (x) \int_{0}^{\infty / A} b_{n, k}^{q_{n}} (t) {(t - x)}_{q_{n}}^{4} d_{q} t \\ + \frac{M}{δ^{2}} x (| (q_{n}^{3} - 1) + (q_{n}^{2} - 1) |) {[n]}_{q_{n}} \frac{1}{{[n + 1]}_{q_{n}}} \sum_{k = 1}^{\infty} b_{n, k}^{q_{n}} (x) \int_{0}^{\infty / A} q_{n}^{k} b_{n, k}^{q_{n}} (t) {(t - x)}_{q_{n}}^{3} d_{q} t \\ + \frac{M}{δ^{2}} x^{2} {(q_{n}^{2} - 1)}^{2} {[n]}_{q_{n}} \frac{1}{{[n + 1]}_{q_{n}}} \sum_{k = 1}^{\infty} b_{n, k}^{q_{n}} (x) \int_{0}^{\infty / A} q_{n}^{k} b_{n, k}^{q_{n}} (t) {(t - x)}_{q_{n}}^{2} d_{q} t \end{array}

and

| R_{n, 2}^{q_{n}} (x) | \leq \frac{M}{δ^{2}} \{{[n]}_{q_{n}} T_{n, 4} (x) + x (2 - q_{n}^{2} - q_{n}^{3}) {[n]}_{q_{n}} T_{n, 3} (x) + x^{2} {(q_{n}^{2} - 1)}^{2} {[n]}_{q_{n}} T_{n, 2} (x)\} .

Using Lemma 3, we have

T_{n, 4} (x) \leq \frac{C_{1, x}}{{[n]}_{q_{n}}^{2}}, T_{n, 3} (x) \leq \frac{C_{2, x}}{{[n]}_{q_{n}}^{2}} and T_{n, 4} (x) \leq \frac{C_{3, x}}{{[n]}_{q_{n}}} .

Thus, for n suciently large $R_{n, 2}^{q_{n}} (x) \to 0$ . This completes the proof of theorem. □

Corollary 8. Let f ∈ C [0, ∞) be a bounded function and (q_n) denote a sequence such that 0 < q_n < 1 and q_n → 1 as n → ∞. Suppose that the first and second derivative f '(x)

and f '' (x) exist at a point x ∈ (0, ∞), we have

lim_{n \to \infty} {[n]}_{q_{n}} (B_{n}^{q_{n}} (f, x) - f (x)) = f^{'} (x) (2 x + 1) + x (1 + x) f^{″} (x) .

6. Better error approximation

King [13] in 2003 proposed a new approach to modify the Bernstein polynomials to improve rate of convergence, by making operator to preserve test functions e₀ and e₁. As the q-Beta operators $B_{n}^{q} (f, x)$ reproduce only constant functions, this motivated us to propose the modification of (1.2), so that they reproduce constant as well as linear functions.

Define sequence {u_n,q(x)} of real valued continues functions on [0, ∞) with 0 ≤ u_n,q(x) < ∞, as

u_{n, q} (x) = \frac{x ({[n + 2]}_{q} - {[2]}_{q}) - q}{{[n + 2]}_{q}} .

We replace x in definition of operator (1.2) with u_n,q(x). Therefore, modified operator is given as

\tilde{B_{n}^{q}} (f; x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (u_{n, q} (x)) \int_{0}^{\infty / A} b_{n, k}^{q} (t) f (t) d_{q} t, x \in I \equiv [1 / q {[n]}_{q}, \infty),

(6.1)

Remark 3. By simple computation we can write

\begin{array}{l} \tilde{B_{n}^{q}} (1; x) & = 1, \tilde{B_{n}^{q}} (t; x) = x \\ \tilde{B_{n}^{q}} (t^{2}; x) & = x^{2} (\frac{{[n + 3]}_{q} ({[n + 2]}_{q} - {[2]}_{q})}{q {[n + 2]}_{q} ({[n + 2]}_{q} - {[3]}_{q})}) + x (\frac{{[n + 2]}_{q} - 2 + q}{{[n + 2]}_{q} ({[n + 2]}_{q} - {[3]}_{q})}) \\ - \frac{q ({[n + 2]}_{q} - 1)}{{[n + 2]}_{q} ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} . \end{array}

Therefore,

\begin{matrix} {\tilde{B}}_{n}^{q} {(t - x)}^{2}; x) = x^{2} (\frac{{[n + 3]}_{q} ({[n + 2]}_{q} - {[2]}_{q})}{q {[n + 2]}_{q} ({[n + 2]}_{q} - {[3]}_{q})} - 1) + x (\frac{{[n + 2]}_{q} - 2 + q}{{[n + 2]}_{q} ({[n + 2]}_{q} - {[3]}_{q})}) \\ \frac{q ({[n + 2]}_{q} - 1)}{{[n + 2]}_{q} ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} . \end{matrix}

Theorem 9. Let f ∈ C_B(I), then for every x ∈ I and for n > 1, C > 0, we have

| \tilde{B_{n}^{q}} (f; x) - f (x) | \leq C ω_{2} (f, δ_{n}),

(6.2)

where $δ_{n} = \sqrt{\tilde{B_{n}^{q}} ({(t - x)}^{2}; x)}$ .

Proof. Let $g \in W_{\infty}^{2}$ , by Taylor's series

g (t) - g (x) = g^{'} (x) (t - x) + \int_{x}^{t} g^{″} (s) (t - s) d s

therefore, by linearity and Remark 3, we get

\begin{array}{l} | \tilde{B_{n}^{q}} (g; x) - g (x) | & \leq \tilde{B_{n}^{q}} (t - x, x) ∥g^{'}∥ + \frac{∥g^{″}∥}{2} \tilde{B_{n}^{q}} ({(t - x)}^{2}; x) \\ \leq \tilde{B_{n}^{q}} ({(t - x)}^{2}; x) ∥g^{″}∥ . \end{array}

Also

| \tilde{B_{n}^{q}} (f, x) | \leq | | f | | | \tilde{B_{n}^{q}} (1, x) | = ∥f∥ .

Therefore,

\begin{array}{l} | \tilde{B_{n}^{q}} (f; x) - f (x) | & \leq | \tilde{B_{n}^{q}} (f - g; x) - (f - g) (x) | + | \tilde{B_{n}^{q}} (g; x) - g (x) | \\ \leq 2 ∥f - g∥ + \bar{B_{n}^{q}} ({(t - x)}^{2}; x) ∥g^{″}∥ \end{array}

on choosing $δ_{n} = \sqrt{\tilde{B_{n}^{q}} ({(t - x)}^{2}; x)}$ , taking infimum over $g \in W_{\infty}^{2}$ , we get the desired result.

□

Theorem 10. Let q = q_nsatisfies 0 < q_n< 1 and let q_n→ 1 as n → ∞. For each $f \in C_{x^{2}}^{*} (I)$ we have

lim_{n \to \infty} {∥{\tilde{B}}_{n}^{q_{n}} (f) - f∥}_{x^{2}} = 0 .

Proof. To prove theorem (Using the Theorem in [14]), it is sufficient to verify the following three conditions

lim_{n \to \infty} {∥{\tilde{B}}_{n}^{q_{n}} - (t^{ν}, x) - x^{ν}∥}_{x^{2}} = 0, ν = 0, 1, 2 .

(6.3)

By Remark 3, we have ${\tilde{B}}_{n}^{q_{n}} (1, x) = 1$ and ${\tilde{B}}_{n}^{q_{n}} (t, x) = x$ , the first and second condition of (6.3) is fulfilled for ν = 0 and ν = 1.

And

\begin{array}{l} {∥{\tilde{B}}_{n}^{q_{n}} (t^{2}, x) - x^{2}∥}_{x^{2}} & \leq |\frac{{[n + 3]}_{q_{n}} ({[n + 2]}_{q_{n}} - {[2]}_{q_{n}})}{q_{n} {[n + 2]}_{q_{n}} ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})} - 1| sup_{x \in [0, \infty)} \frac{x^{2}}{1 + x^{2}} \\ + (\frac{{[n + 2]}_{q_{n}} - 2 + q_{n}}{{[n + 2]}_{q_{n}} ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})}) sup_{x \in [0, \infty)} \frac{x}{1 + x^{2}} \\ + \frac{|q_{n} ({[n + 2]}_{q_{n}} - 1)|}{{[n + 2]}_{q_{n}} ({[n + 2]}_{q_{n}} - {[2]}_{q_{n}}) ({[n + 2]}_{q_{n}} - {[3]}_{q_{n}})}, \end{array}

which implies that as n → ∞

lim_{n \to \infty} {∥{\tilde{B}}_{n}^{q_{n}} (t^{2}, x) - x^{2}∥}_{x^{2}} = 0 .

Thus, the proof is completed. □

7. Stancu approach

In 1968, Stancu introduced Bernstein-Stancu operators in [15] a linear positive operator depending on two non-negative parameters α and β satisfying the condition 0 ≤ α ≤ β. Recently, many researcher applied this approach to many operators, for detail see [16, 17, 2], etc.

For f ∈ C[0, ∞) and 0 < q < 1, we define the q-Beta Stancu operators as

\hat{B_{n}^{q}} (f, x) = \frac{1}{{[n + 1]}_{q}} \sum_{k = 1}^{\infty} b_{n, k}^{q} (x) \int_{0}^{\infty / A} b_{n, k}^{q} (t) f (\frac{{[n]}_{q} t + α}{{[n]}_{q} + β}) d_{q} t, x \in [0, \infty),

(7.1)

where 0 ≤ α ≤ β.

In each of following theorems, we assume that q = q_n, where q_n is a sequence of real numbers such that 0 < q_n < 1 for all n and lim_n→∞ q_n = 1.

Theorem 11. For $\hat{B_{n}^{q}} (t^{s}, x)$ , s = 0, 1, 2 the following identities hold:

\begin{array}{l} \hat{B_{n}^{q}} (1, x) & = 1, \\ \hat{B_{n}^{q}} (t, x) & = \frac{{[n]}_{q}}{{[n]}_{q} + β} (\frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}) + \frac{α}{{[n]}_{q} + β}, \\ \hat{B_{n}^{q}} (t^{2}, x) & = \frac{{[n]}_{q}^{2}}{{({[n]}_{q} + β)}^{2}} (\frac{(q {[2]}_{q} + x {[n + 2]}_{q}) (q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} + \frac{x (q + x) {[n + 2]}_{q}}{q ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})}) \\ + \frac{2 α {[n]}_{q}}{{({[n]}_{q} + β)}^{2}} (\frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}) + \frac{α^{2}}{{({[n]}_{q} + β)}^{2}} . \end{array}

Proof of the theorem can be obtained directly by using linearity of operator and Corollary 2.

Corollary 12. If we denote central moments by $Φ_{n, m}^{q} (x) = \hat{B_{n}^{q}} ({(t - x)}^{m}, x)$ , m = 1, 2, then we have

\begin{array}{l} Φ_{n, 1}^{q} (x) & = \frac{{[n]}_{q}}{{[n]}_{q} + β} (\frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}) + \frac{α}{{[n]}_{q} + β} - x, \\ Φ_{n, 2}^{q} (x) & = x^{2} + \frac{{[n]}_{q}^{2}}{{({[n]}_{q} + β)}^{2}} (\frac{(q {[2]}_{q} + x {[n + 2]}_{q}) (q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})} + \frac{x (q + x) {[n + 2]}_{q}}{q ({[n + 2]}_{q} - {[2]}_{q}) ({[n + 2]}_{q} - {[3]}_{q})}) \\ + \frac{2 α {[n]}_{q}}{{({[n]}_{q} + β)}^{2}} (\frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}) + \frac{α^{2}}{{({[n]}_{q} + β)}^{2}} - 2 x (\frac{{[n]}_{q}}{{[n]}_{q} + β} (\frac{(q + x {[n + 2]}_{q})}{({[n + 2]}_{q} - {[2]}_{q})}) + \frac{α}{{[n]}_{q} + β}) . \end{array}

Theorem 13. Let 0 < q < 1, we have

|\hat{B_{n}^{q}} (f, x) - f (x)| \leq C ω_{2} (f, \sqrt{Φ_{n 2}^{q} (x) + Φ_{n 1}^{q 2} (x)}) + ω (f, Φ_{n, 1}^{q} (x))

for every α, β ≥ 0, x ∈ [0, ∞) and f ∈ C_B [0, ∞), where C is a positive constant.

Proof of theorem is just similar to Theorem 4.

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The authors would like to express their deep gratitude to the referees for their valuable suggestions and comments.

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School of Applied Science, Netaji Subhas Institute of Technology, Sector 3 Dwarka, New Delhi, 110078, India
Vijay Gupta
Department of Mathematics, Dr. B. R. Ambedkar National Institute of Technology, Jalandhar, 144011, Punjab, India
Honey Sharma
Department of Mathematics, Kwangwoon University, Seoul, 139-701, South Korea
Taekyun Kim
Division of General Education, Kwangwoon University, Seoul, 139-701, South Korea
Sang-Hun Lee

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Gupta, V., Sharma, H., Kim, T. et al. Properties of q-analogue of Beta operator. Adv Differ Equ 2012, 86 (2012). https://doi.org/10.1186/1687-1847-2012-86

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Received: 20 April 2012
Accepted: 25 June 2012
Published: 25 June 2012
DOI: https://doi.org/10.1186/1687-1847-2012-86

Properties of q-analogue of Beta operator

Abstract

1. Introduction

2. Preliminaries

3. Ordinary approximation

4. Weighted approximation

5. Central moments and asymptotic formula

6. Better error approximation

7. Stancu approach

References

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