Volume 2013, Issue 1 814824

Research Article

Open Access

Some Approximation Properties of q-Baskakov-Beta-Stancu Type Operators

Corresponding Author

Vishnu Narayan Mishra

[email protected]

Department of Applied Mathematics and Humanities, Sardar Vallabhbhai National Institute of Technology, Ichchhanath Mahadev Road, Surat, Gujarat 395 007, India svnit.ac.in

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Kejal Khatri,

Kejal Khatri

Department of Applied Mathematics and Humanities, Sardar Vallabhbhai National Institute of Technology, Ichchhanath Mahadev Road, Surat, Gujarat 395 007, India svnit.ac.in

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Lakshmi Narayan Mishra,

Lakshmi Narayan Mishra

L. 1627 Awadhpuri Colony Beniganj, Opp. I.T.I. Ayodhya Main Road, Faizabad, Uttar Pradesh 224 001, India

Department of Mathematics, National Institute of Technology, Silchar, Cachar District, Assam 788 010, India

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Vishnu Narayan Mishra,

Corresponding Author

Vishnu Narayan Mishra

[email protected]

Department of Applied Mathematics and Humanities, Sardar Vallabhbhai National Institute of Technology, Ichchhanath Mahadev Road, Surat, Gujarat 395 007, India svnit.ac.in

Search for more papers by this author

Kejal Khatri,

Kejal Khatri

Department of Applied Mathematics and Humanities, Sardar Vallabhbhai National Institute of Technology, Ichchhanath Mahadev Road, Surat, Gujarat 395 007, India svnit.ac.in

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Lakshmi Narayan Mishra,

Lakshmi Narayan Mishra

L. 1627 Awadhpuri Colony Beniganj, Opp. I.T.I. Ayodhya Main Road, Faizabad, Uttar Pradesh 224 001, India

Department of Mathematics, National Institute of Technology, Silchar, Cachar District, Assam 788 010, India

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First published: 16 December 2013

https://doi.org/10.1155/2013/814824

Citations: 2

Academic Editor: Adam Kowalewski

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Abstract

This paper deals with new type q-Baskakov-Beta-Stancu operators defined in the paper. First, we have used the properties of q-integral to establish the moments of these operators. We also obtain some approximation properties and asymptotic formulae for these operators. In the end we have also presented better error estimations for the q-operators.

1. Introduction

In the recent years, the quantum calculus (q-calculus) has attracted a great deal of interest because of its potential applications in mathematics, mechanics, and physics. Due to the applications of q-calculus in the area of approximation theory, q-generalization of some positive operators has attracted much interest, and a great number of interesting results related to these operators have been obtained (see, for instance, [1–3]). In this direction, several authors have proposed the q-analogues of different linear positive operators and studied their approximation behaviors. Also, Aral and Gupta [4] defined q-generalization of the Baskakov operators and investigated some approximation properties of these operators. Subsequently, Finta and Gupta [5] obtained global direct error estimates for these operators using the second-order Ditzian Totik modulus of smoothness. To approximate Lebesgue integrable functions on the interval [0, ∞), modified Beta operators [6] are defined as

()

where b_n,k(x) = (1/B(k + 1, n))(x^k/(1 + x) ^n+k+1) and

The discrete q-Beta operators are defined as

()

Recently, Maheshwari and Sharma [7] introduced the q-analogue of the Baskakov-Beta-Stancu operators and studied the rate of approximation and weighted approximation of these operators. Motivated by the Stancu type generalization of q-Baskakov operators, we propose the q-analogue of the operators

, recently introduced and studied for special values α = β = 0 by Gupta and Kim [8] as

()

where

and

We know that and . We mention that (see [8]).

Very recently, Gupta et al. [9] introduced some direct results in simultaneous approximation for Baskakov-Durrmeyer-Stancu operators. The aim of this paper is to study the approximation properties of a new generalization of the Baskakov type Beta Stancu operators based on q-integers. We estimate moments for these operators. Also, we study asymptotic formula for these operators. Finally, we give better error estimations for the operator (3). First, we recall some definitions and notations of q-calculus. Such notations can be found in [10, 11]. We consider q as a real number satisfying q > 0. For n ∈ ℕ,

()

The q-binomial coefficients are given by

()

The q-derivative 𝒟_qf of a function f is given by

()

The q-analogues of product and quotient rules are defined as

()

The q-Jackson integrals and the q-improper integrals are defined as [12, 13]

()

provided that the sums converge absolutely. Using (9), De Sole and Kac [14] defined the q-analogue of Beta functions of second kind

as follows:

()

where

. This function is q-constant in x; that is, K(qx, t) = K(x, t). It was observed in [14] that B_q(t, s) is independent of A; this is because from the integral and K(A, t) the term A cancels out. In particular for any positive integer n, we have

()

Also, we have

()

In [8], Gupta and Kim obtained recurrence formula for the moments of the operators as follows.

Theorem 1 (see [8].)If one defined the central moments as

()

then, for n > m + 2, one has the following recurrence relation:

()

2. Moment Estimates

Lemma 2 (see [8].)The following equalities hold.

(i)
.
(ii)
.
(iii)
([2] _q/q³[n − 2] _q[n − 3] _q), for n > 3.

Lemma 3. The following equalities hold.

(i)
.
(ii)
, for n > 2.
(iii)
([n] _q + β) ² + 2α[n] _q/q[n − 2] _q([n] _q + β) ² + α²/([n] _q + β) ², for n > 3.

Proof. The operators are well defined on function 1, t, t². By Lemma 2, for every n > 0 and x ∈ [0, ∞), we have

()

Similarly,

()

Remark 4. For all m ∈ {0,1, 2, …}, 0 ≤ α ≤ β, we have the following recursive relation for the images of the monomials t^m under in terms of , r = 0,1, 2, …, m, as

()

Remark 5. If we put q = 1 and α = β = 0, we get the moments of the modified Beta operators [6] as

()

Remark 6. From Lemma 3, we have

()

3. Direct Result and Asymptotic Formula

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

()

where δ > 0 and

. By [15, page 177, Theorem 2.4], there exists an absolute constant M > 0 such that

()

where

()

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

()

Theorem 7. Let f ∈ C_B[0, ∞) and q = q_n ∈ (0,1) such that q_n → 1 as n → ∞. Then for all x ∈ [0, ∞) and n > 3, there exists an absolute constant C > 0 such that

()

Proof. We are introducing the auxiliary operators as follows:

()

From (25) and Lemma 3, we have

()

Let x ∈ [0, ∞) and

. Using Taylor’s formula

()

applying

, and by (26), we get

()

On the other hand, since

()

We conclude by Remark 6 that

()

From (25), we can write that

()

Now, taking into account the boundedness of

and from (31), we get

()

Now, taking infimum on the right-hand side over all

and from (21), we get

()

where 4C₁ = C > 0. This proves the theorem.

Our next result in this section is an asymptotic formula.

Theorem 8. Let f be bounded and integrable function on the interval [0, ∞); the second derivative of f exists at a fixed point x ∈ [0, ∞) and q = q_n ∈ (0,1) such that q_n → 1 as n → ∞. Consider

()

Proof. Using Taylor’s expansion of f, we can write

()

where ε is bounded and lim _t→0ε(t) = 0. Applying the operator to the above relation, we get

()

where D_n,α,β(x) and E_n,α,β(x) are defined in Remark 6.

Using Cauchy-Schwarz inequality, we have

()

Using Theorem 1 with the help of Remark 4, we can easily find that

()

Also, since

()

Thus,

()

which completes the proof.

4. Better Estimation

It is well known that the operators preserve constant as well as linear functions. To make the convergence faster, King [16] proposed an approach to modify the classical Bernstein polynomials, so that this sequence preserves two test functions: e₀ and e₂. After this, several researchers have studied that many approximating operators, L, possess these properties; that is, L(e_i; x) = e_i(x), where e_i(x) = xⁱ (i = 0,1) or xⁱ (i = 0,2), for example, Bernstein, Baskakov, and Baskakov-Durrmeyer-Stancu operators (see [4, 5, 17–19]).

As the operators

introduced in (3) preserve only the constant functions, further modification of these operators is proposed to be made so that the modified operators preserve the constant as well as linear functions. For this purpose, the modification of

is as follows:

()

where

()

Lemma 9. For each x ∈ I_n,q, one has

()

Lemma 10. For each x ∈ I_n,q, the following equalities hold:

()

Theorem 11. Let f ∈ C_B(I_n,q) and q = q_n ∈ (0,1) such that q_n → 1 as n → ∞. Then for all x ∈ I_n,q and n > 3, there exists an absolute constant C > 0 such that

()

Proof. Let x, t ∈ I_n,q and . Using Taylor’s formula, we get

()

Applying

, we get

()

Obviously, we have

()

Therefore,

()

Since

, thus

()

Now, taking infimum on the right-hand side over all and from (21), we get

()

which proves the theorem.

Theorem 12. Let f be bounded and integrable function on the interval I_n,q; the second derivative of f exists at a fixed point x ∈ I_n,q and q = q_n ∈ (0,1) such that q_n → 1 as n → ∞; then

()

The proof follows along the same lines of Theorem 8.

Conflict of Interests

The authors declare that there is no conflict of interests.

Acknowledgments

The authors thank the anonymous learned reviewers for their valuable suggestions, which substantially improved the standard of the paper. Special thanks are due to Professor Adam Kowalewski, for kind cooperation and smooth behavior during communication and for his efforts to send the reports of the paper timely.

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Some Approximation Properties of q-Baskakov-Beta-Stancu Type Operators

Abstract

1. Introduction

2. Moment Estimates

3. Direct Result and Asymptotic Formula

4. Better Estimation

Conflict of Interests

Acknowledgments

References

Citing Literature

References

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Some Approximation Properties of q-Baskakov-Beta-Stancu Type Operators

Abstract

1. Introduction

2. Moment Estimates

3. Direct Result and Asymptotic Formula

4. Better Estimation

Conflict of Interests

Acknowledgments

References

Citing Literature

References

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