On the Approximation by Bivariate Szász–Jakimovski–Leviatan-Type Operators of Unbounded Sequences of Positive Numbers

Alotaibi, Abdullah

doi:10.3390/math11041009

Open AccessArticle

On the Approximation by Bivariate Szász–Jakimovski–Leviatan-Type Operators of Unbounded Sequences of Positive Numbers

by

Abdullah Alotaibi

Operator Theory and Applications Research Group, Department of Mathematics, Faculty of Science, King Abdulaziz University, Jeddah 21589, Saudi Arabia

Mathematics 2023, 11(4), 1009; https://doi.org/10.3390/math11041009

Submission received: 31 December 2022 / Revised: 2 February 2023 / Accepted: 3 February 2023 / Published: 16 February 2023

(This article belongs to the Topic Approximation Theory in Computer and Computational Sciences)

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Abstract

:

In this paper, we construct the bivariate Szász–Jakimovski–Leviatan-type operators in Dunkl form using the unbounded sequences

α_{n}

,

β_{m}

and

ξ_{m}

of positive numbers. Then, we obtain the rate of convergence in terms of the weighted modulus of continuity of two variables and weighted approximation theorems for our operators. Moreover, we provide the degree of convergence with the help of bivariate Lipschitz-maximal functions and obtain the direct theorem.

Keywords:

bivariate functions; weight function; Dunkl analogue; Appell polynomial; Szász operator; Szász–Jakimovski–Levitian operator; Lipschitz function

MSC:

41A25; 41A36; 33C45

1. Introduction and Preliminaries

In 1912, S. N. Bernstein [1] introduced a positive linear operator for the set of all continuous functions on

[0, 1]

, which provides the shortest proof of the well-known Weierstrass approximation theorem while, later, another positive linear operator on

[0, \infty)

, constructed by Szász in 1950, known as the Szász operator (see [2]), is given by

S_{r} (f; u_{1}) = e^{- r u_{1}} \sum_{k = 0}^{\infty} \frac{{(r u_{1})}^{k}}{k!} f (\frac{k}{r}), u_{1} \geq 0, r \in N and f \in C [0, \infty) .

(1)

Due to development of the Szász operator, another sequence of positive linear operator constructed by the mathematician Jakimovski and Leviatan in 1969 using the well-known Appell polynomial is given by (see [3])

L_{r} (f; u_{1}) = \frac{e^{- r u_{1}}}{C (1)} \sum_{k = 0}^{\infty} P_{k} (r u_{1}) f (\frac{k}{r}),

(2)

where the Appell polynomial is given by

C (v_{1}) e^{v_{1} y} = \sum_{r = 0}^{\infty} P_{r} (y_{1}) v_{1}^{r}

, with the following identities

C (1) \neq 0

,

C (v_{1}) = \sum_{r = 0}^{\infty} c_{r} v_{1}^{r}

,

P_{r} (u_{1}) = \sum_{j = 0}^{r} c_{j} \frac{u_{1}^{r - j}}{(r - j)!} (r \in N)

.

Recently, with the help of the exponential generating function, the Szász operators were introduced by Sucu [4]. These types of ideas are influenced by the generalized Hermite polynomials in terms of the hypergeometric functions (see [5]). Thus, for the classes of all continuous functions f on

[0, \infty)

and a parameter

χ \geq 0

, the Szász operators given in another form, known as Szász Dunkl operators, are given by

S_{r}^{*} (f; u_{1}) : = \frac{1}{e_{χ} (r u_{1})} \sum_{k = 0}^{\infty} \frac{{(r u_{1})}^{k}}{γ_{χ} (k)} f (\frac{k + 2 χ θ_{k}}{r}), u_{1} \geq 0, r \in N,

(3)

where the exponential generating functions are given by

e_{χ} (u_{1}) = \sum_{k = 0}^{\infty} \frac{u_{1}^{k}}{γ_{χ} (k)} .

(4)

γ_{χ} (2 ρ) = \frac{2^{2 ρ} ρ! Γ (ρ + χ + \frac{1}{2})}{Γ (χ + \frac{1}{2})},

(5)

γ_{χ} (2 ρ + 1) = \frac{2^{2 ρ + 1} ρ! Γ (ρ + χ + \frac{3}{2})}{Γ (χ + \frac{1}{2})},

(6)

and for all

ρ = 0, 1, 2, \dots

a recursion

γ_{χ}

is defined as

\frac{γ_{χ} (ρ + 1)}{(ρ + 1 + 2 χ θ_{ρ + 1})} = γ_{χ} (ρ),

where

θ_{ρ} = \{\begin{matrix} 0 & if ρ = 2 r, r \in {0, 2, 4, 6, \dots}, \\ 1 & if ρ = 2 r + 1, r \in {1, 3, 5, 7, \dots} . \end{matrix}

(7)

Most recently, a new version of the Szász operators studied by Nasiruzzaman and Aljohani [6], and these types of Szász operators, provide the generalized version of some earlier operators, such as Szász operators, Szász–Jakimovski operators and Szász–Dunkl operators, where the operators are given by, for example, all

f \in C [0, \infty), u_{1} \in [0, \infty), r \in N, C (1) \neq 0

and

χ \geq 0

,

K_{r, χ} (f; u_{1}) = \frac{1}{C (1) e_{χ} (r u_{1})} \sum_{k = 0}^{\infty} P_{k} (r u_{1}) f (\frac{k + 2 χ θ_{k}}{r}) .

(8)

There are many published articles related to these works, for example, those by Kajla et al. [7], Mursaleen et al. [8,9,10,11], Mohiuddine et al. [12,13,14,15,16], Nasiruzzaman et al. [6,17,18,19,20,21,22], Özger et al. [23]. For studies on Bernstein and Szász types operators involving the idea of Chlodowsky and Charlier polynomials, we refer to [24,25,26,27,28].

The organization of this manuscript is as follows: in Section 2, we present a generalization of the operators defined and studied by Nasiruzzaman and Aljohani [6] in bivariate sense using the unbounded sequences

α_{n}

,

β_{m}

and

ξ_{m}

of positive numbers, such that

lim_{n \to \infty} \frac{α_{n}}{n} = 0,

lim_{m \to \infty} \frac{1}{ξ_{m}} = 0

and

\frac{β_{m}}{ξ_{m}} = 1 + O (\frac{1}{ξ_{m}})

as

m \to \infty

, and estimation of moments and central moments. In Section 3, we discuss the rate of convergence by means of the weighted modulus of continuity and weighted approximation properties. In this section, we obtain the degree of convergence using Lipschitz-type maximal functions of two variables, as well as the direct theorem. In Section 4, we close the paper and provide conclusions.

2. Construction of New Operators and Estimation of Moments

Here, we construct the operators and prove some auxillary lemmas, which will be used to prove the approximation results.

Let

I_{α_{n}} = {(x_{1}, y_{1}) : 0 \leq x_{1} \leq α_{n}, y_{1} \in [0, \infty)}

and

C (I_{α_{n}}) = {f : I_{α_{n}} \to R is continuous}

, such that it satisfies the norm equipped by

{| | f | |}_{C (I_{α_{n}})} = sup_{(x_{1}, y_{1}) \in I_{α_{n}}} | f (x_{1}, y_{1}) | .

Then, for all

f \in C (I_{α_{n}})

and

n, m \in N

, and any

ν, τ \geq 0

, we define

\begin{matrix} B_{n, m}^{ν, τ} (f; x_{1}, y_{1}) & : = & \frac{1}{e_{ν} (\frac{n x_{1}}{α_{n}}) e_{τ} (β_{m} y_{1}) C (1) D (1)} \sum_{k, l = 0}^{\infty} P_{k} (\frac{n x_{1}}{α_{n}}) \\ \times Q_{l} (β_{m} y_{1}) f (\frac{α_{n} (k + 2 ν θ_{k})}{n}, \frac{l + 2 τ θ_{l}}{ξ_{m}}), \end{matrix}

(9)

where

α_{n}, β_{m}

and

ξ_{m}

are the unbounded sequences of positive numbers, such that

lim_{n \to \infty} \frac{α_{n}}{n} = 0,

lim_{m \to \infty} \frac{1}{ξ_{m}} = 0

and

\frac{β_{m}}{ξ_{m}} = 1 + O (\frac{1}{ξ_{m}})

as

m \to \infty

. Moreover, the Appell polynomial

D (u_{1})

is given by

D (u_{1}) e^{u y} = \sum_{r = 0}^{\infty} Q_{l} (y_{1}) u_{1}^{r}

with the following identities:

D (1) \neq 0

,

D (u_{1}) = \sum_{r = 0}^{\infty} c_{r} u_{1}^{r}

,

Q_{l} (y_{1}) = \sum_{i = 0}^{l} c_{j} \frac{y_{1}^{l - i}}{(l - i)!} (l \in N)

and

P_{k} (x_{1})

and

C (1) \neq 0

.

Lemma 1.

For all

y_{1} \in [0, \infty), P_{l} (y_{1}) \geq 0, τ \geq 0

and

D (1) \neq 0

, if we define

D (α) e_{τ} (α y_{1}) = \sum_{l = 0}^{\infty} Q_{l} (y_{1}) α^{l},

(10)

then, for any unbounded sequence

β_{m}

, we have

\sum_{l = 0}^{\infty} Q_{l} (β_{m} y_{1}) = D (1) e_{τ} (β_{m} y_{1}),

(11)

\sum_{l = 0}^{\infty} l Q_{l} (β_{m} y_{1}) = (D^{'} (1) + β_{m} y_{1} D (1)) e_{τ} (β_{m} y_{1}),

(12)

\sum_{l = 0}^{\infty} l^{2} Q_{l} (β_{m} y_{1}) = (D^{″} (1) + (2 β_{m} y_{1} + 1) D^{'} (1) + β_{m} y_{1} (β_{m} y_{1} + 1) D (1)) e_{τ} (β_{m} y_{1}),

(13)

\begin{matrix} \sum_{l = 0}^{\infty} l^{3} Q_{l} (β_{m} y_{1}) & = & (D^{‴} (1) + 3 (β_{m} y_{1} + 1) D^{″} (1) + (3 β_{m}^{2} y_{1}^{2} + 6 β_{m} y_{1} + 2) D^{'} (1) \\ + β_{m} y_{1} (β_{m}^{2} y_{1}^{2} + 3 β_{m} y_{1} + 2) D (1)) e_{τ} (β_{m} y_{1}), \end{matrix}

\begin{matrix} \sum_{l = 0}^{\infty} l^{4} Q_{l} (β_{m} y_{1}) & = & (D^{⁗} (1) + (4 β_{m} y_{1} + 6) D^{‴} (1) + (6 β_{m}^{2} y_{1}^{2} + 18 β_{m} y_{1} + 11) D^{″} (1) \\ + (4 β_{m}^{3} y_{1}^{3} + 18 β_{m}^{2} y_{1}^{2} + 22 β_{m} y_{1} + 6) D^{'} (1) \\ + β_{m} y_{1} (β_{m}^{3} y_{1}^{3} + 6 β_{m}^{2} y_{1}^{2} + 11 β_{m} y_{1} + 6) D (1)) e_{τ} (β_{m} y_{1}) . \end{matrix}

Lemma 2.

For all

x_{1} \in [0, \infty), P_{k} (x_{1}) \geq 0, ν \geq 0

and

C (1) \neq 0

, if we define

C (β) e_{ν} (β x_{1}) = \sum_{k = 0}^{\infty} P_{k} (x_{1}) β^{k},

(14)

then, for any unbounded sequence of positive numbers

α_{n}

, we have

\sum_{k = 0}^{\infty} P_{k} (\frac{n x_{1}}{α_{n}}) = C (1) e_{ν} (\frac{n x_{1}}{α_{n}}),

(15)

\sum_{k = 0}^{\infty} k P_{k} (\frac{n x_{1}}{α_{n}}) = (C^{'} (1) + (\frac{n x_{1}}{α_{n}}) C (1)) e_{ν} (\frac{n x_{1}}{α_{n}}),

(16)

\begin{matrix} \sum_{k = 0}^{\infty} k^{2} P_{k} (\frac{n x_{1}}{α_{n}}) & = & (C^{″} (1) + (2 (\frac{n x_{1}}{α_{n}}) + 1) C^{'} (1) \\ + (\frac{n x_{1}}{α_{n}}) ((\frac{n x_{1}}{α_{n}}) + 1) C (1)) e_{ν} (\frac{n x_{1}}{α_{n}}), \end{matrix}

(17)

\begin{matrix} \sum_{k = 0}^{\infty} k^{3} P_{k} (\frac{n x_{1}}{α_{n}}) & = & (C^{‴} (1) + 3 ((\frac{n x_{1}}{α_{n}}) + 1) C^{″} (1) \\ + (3 {(\frac{n x_{1}}{α_{n}})}^{2} + 6 (\frac{n x_{1}}{α_{n}}) + 2) C^{'} (1) \\ + (\frac{n x_{1}}{α_{n}}) ({(\frac{n x_{1}}{α_{n}})}^{2} + 3 (\frac{n x_{1}}{α_{n}}) + 2) C (1)) e_{ν} (\frac{n x_{1}}{α_{n}}), \end{matrix}

\begin{matrix} \sum_{k = 0}^{\infty} k^{4} P_{k} (\frac{n x_{1}}{α_{n}}) & = & (C^{⁗} (1) + (4 (\frac{n x_{1}}{α_{n}}) + 6) C^{‴} (1) \\ + (6 {(\frac{n x_{1}}{α_{n}})}^{2} + 18 (\frac{n x_{1}}{α_{n}}) + 11) C^{″} (1) \\ + (4 {(\frac{n x_{1}}{α_{n}})}^{3} + 18 {(\frac{n x_{1}}{α_{n}})}^{2} + 22 (\frac{n x_{1}}{α_{n}}) + 6) C^{'} (1) \\ + (\frac{n x_{1}}{α_{n}}) ({(\frac{n x_{1}}{α_{n}})}^{3} + 6 {(\frac{n x_{1}}{α_{n}})}^{2} + 11 (\frac{n x_{1}}{α_{n}}) + 6) C (1)) e_{ν} (\frac{n x_{1}}{α_{n}}) . \end{matrix}

Lemma 3.

For the operators

B_{n, m}^{ν, τ}

, defined by (9), as demonstrated here:

R_{n}^{*} (f; x_{1}, y_{1}) = \frac{1}{e_{ν} (\frac{n x_{1}}{α_{n}}) C (1)} \sum_{k = 0}^{\infty} P_{k} (\frac{n x_{1}}{α_{n}}) f (\frac{α_{n} (k + 2 ν θ_{k})}{n}, y_{1})

(18)

S_{m} (f; x_{1}, y_{1}) = \frac{1}{e_{τ} (β_{m} y_{1}) D (1)} \sum_{l = 0}^{\infty} Q_{l} (β_{m} y_{1}) f (x_{1}, \frac{l + 2 τ θ_{l}}{ξ_{m}}),

(19)

then

B_{n, m}^{ν, τ} (f; x_{1}, y_{1}) = R_{n}^{*} (S_{m} (f; x_{1}, y_{1})) = S_{m} (R_{n}^{*} (f; x_{1}, y_{1})) .

Proof.

We can easily see that

\begin{matrix} R_{n}^{*} (S_{m} (f; x_{1}, y_{1})) & = & R_{n}^{*} (\frac{1}{e_{τ} (β_{m} y_{1}) D (1)} \sum_{l = 0}^{\infty} Q_{l} (β_{m} y_{1}) f (x_{1}, \frac{l + 2 τ θ_{l}}{ξ_{m}})) \\ = & \frac{1}{e_{τ} (β_{m} y_{1}) D (1)} \sum_{l = 0}^{\infty} R_{n}^{*} (f (x_{1}, \frac{l + 2 τ θ_{l}}{ξ_{m}})) Q_{l} (β_{m} y_{1}) \\ = & \frac{1}{e_{τ} (β_{m} y_{1}) D (1)} \sum_{l = 0}^{\infty} Q_{l} (β_{m} y_{1}) \\ \times \sum_{k = 0}^{\infty} \frac{1}{e_{ν} (\frac{n x_{1}}{α_{n}})} f (\frac{α_{n} (k + 2 ν θ_{k})}{n}, \frac{l + 2 τ θ_{l}}{ξ_{m}}) P_{k} (\frac{n x_{1}}{α_{n}}) \\ = & \frac{1}{e_{ν} (\frac{n x_{1}}{α_{n}}) e_{τ} (β_{m} y_{1}) C (1) D (1)} \sum_{k, l = 0}^{\infty} P_{k} (\frac{n x_{1}}{α_{n}}) Q_{l} (β_{m} y_{1}) \\ \times f (\frac{α_{n} (k + 2 ν θ_{k})}{n}, \frac{l + 2 τ θ_{l}}{ξ_{m}}) \\ = & B_{n, m}^{ν, τ} (f; x_{1}, y_{1}) . \end{matrix}

Similarly, we prove

S_{m} (R_{n}^{*} (f; x_{1}, y_{1})) = B_{n, m}^{ν, τ} (f; x_{1}, y_{1})

. □

Let

R_{+}^{2} = R_{+} \times R_{+}

with

R_{+} = [0, \infty)

, and suppose

γ_{m}

is the sequence, such that

{lim}_{m \to \infty} γ_{m} = \infty

and

I_{α_{n} γ_{m}} = {(x_{1}, y_{1}) : 0 \leq x_{1} \leq α_{n}, 0 \leq y_{1} \leq γ_{m}}

. We also consider the operators

T_{n, m}^{*} (f; x_{1}, y_{1})

, such that

T_{n, m}^{*} (f; x_{1}, y_{1}) = \{\begin{matrix} B_{n, m}^{ν, τ} (f; x_{1}, y_{1}), & for (x_{1}, y_{1}) \in I_{α_{n} γ_{m}} \\ f (x_{1}, y_{1}), & for (x_{1}, y_{1}) \in R_{+}^{2} \ I_{α_{n} γ_{m}} . \end{matrix}

(20)

Lemma 4.

Let

n, m \in N

and

ϕ_{j, i} = u_{1}^{j} v_{1}^{i}

for any

j, i = 0, 1, 2, 3, 4,

then, we have the following identities:

\begin{matrix} (1) B_{n, m}^{ν, τ} (ϕ_{0, 0}; x_{1}, y_{1}) & = & 1; \\ (2) B_{n, m}^{ν, τ} (ϕ_{1, 0}; x_{1}, y_{1}) & = & x_{1} + \frac{α_{n}}{n} (\frac{C^{'} (1)}{C (1)} + 2 ν); \\ (3) B_{n, m}^{ν, τ} (ϕ_{0, 1}; x_{1}, y_{1}) & = & \frac{1}{ξ_{m}} (\frac{D^{'} (1)}{D (1)} + β_{m} y_{1}) + \frac{2 τ}{ξ_{m}}; \\ (4) B_{n, m}^{ν, τ} (ϕ_{2, 0}; x_{1}, y_{1}) & = & x_{1}^{2} + \frac{α_{n}}{n} (2 \frac{C^{'} (1)}{C (1)} + 2 ν + 1) x_{1} \\ + {(\frac{α_{n}}{n})}^{2} (\frac{C^{″} (1)}{C (1)} + \frac{C^{'} (1)}{C (1)} + 4 ν^{2}); \\ (5) B_{n, m}^{ν, τ} (ϕ_{0, 2}; x_{1}, y_{1}) & = & \frac{1}{ξ_{m}^{2}} [\frac{D^{″} (1)}{D (1)} + (2 β_{m} y_{1} + 1) \frac{D^{'} (1)}{D (1)} + β_{m} y_{1} (β_{m} y_{1} + 1)] \\ + \frac{2 τ}{ξ_{m}^{2}} [\frac{D^{'} (1)}{D (1)} + β_{m} y_{1}] + \frac{4 τ^{2}}{ξ_{m}^{2}}; \\ (6) B_{n, m}^{ν, τ} (ϕ_{3, 0}; x_{1}, y_{1}) & = & \frac{α_{n}^{3}}{n^{3}} [\frac{C^{‴} (1)}{C (1)} + 3 ((\frac{n x_{1}}{α_{n}}) + 1) \frac{C^{″} (1)}{C (1)} \\ + (3 {(\frac{n x_{1}}{α_{n}})}^{2} + 6 (\frac{n x_{1}}{α_{n}}) + 2) \frac{C^{'} (1)}{C (1)} \\ + (\frac{n x_{1}}{α_{n}}) ({(\frac{n x_{1}}{α_{n}})}^{2} + 3 (\frac{n x_{1}}{α_{n}}) + 2)] \\ + \frac{6 ν α_{n}^{3}}{n^{3}} [\frac{C^{″} (1)}{C (1)} + (2 (\frac{n x_{1}}{α_{n}}) + 1) \frac{C^{'} (1)}{C (1)} \\ + (\frac{n x_{1}}{α_{n}}) ((\frac{n x_{1}}{α_{n}}) + 1)] \\ + \frac{12 ν^{2} α_{n}^{3}}{n^{3}} [\frac{C^{'} (1)}{C (1)} + (\frac{n x_{1}}{α_{n}})] + \frac{8 ν^{3} α_{n}^{3}}{n^{3}}; \\ (7) B_{n, m}^{ν, τ} (ϕ_{0, 3}; x_{1}, y_{1}) & = & \frac{1}{ξ_{m}^{3}} [\frac{D^{‴} (1)}{D (1)} + 3 (β_{m} y_{1} + 1) \frac{D^{″} (1)}{D (1)} \\ + (3 β_{m}^{2} y_{1}^{2} + 6 β_{m} y_{1} + 2) \frac{D^{'} (1)}{D (1)} \\ + β_{m} y_{1} (β_{m}^{2} y_{1}^{2} + 3 β_{m} y_{1} + 2)] + \frac{6 τ}{ξ_{m}^{3}} [\frac{D^{″} (1)}{D (1)} \\ + (2 β_{m} y_{1} + 1) \frac{D^{'} (1)}{D (1)} + β_{m} y_{1} (β_{m} y_{1} + 1)] \\ + \frac{6 τ^{2}}{ξ_{m}^{3}} [\frac{D^{'} (1)}{D (1)} + β_{m} y_{1}] + \frac{8 τ^{3}}{ξ_{m}^{3}}; \\ (8) B_{n, m}^{ν, τ} (ϕ_{4, 0}; x_{1}, y_{1}) & = & \frac{α_{n}^{4}}{n^{4}} [(\frac{C^{⁗} (1)}{C (1)} + (4 (\frac{n x_{1}}{α_{n}}) + 6) \frac{C^{‴} (1)}{C (1)} + (6 {(\frac{n x_{1}}{α_{n}})}^{2} \\ + 18 (\frac{n x_{1}}{α_{n}}) + 11) \frac{C^{″} (1)}{C (1)} \\ + (4 {(\frac{n x_{1}}{α_{n}})}^{3} + 18 {(\frac{n x_{1}}{α_{n}})}^{2} + 22 (\frac{n x_{1}}{α_{n}}) + 6) \frac{C^{'} (1)}{C (1)} \\ + (\frac{n x_{1}}{α_{n}}) ({(\frac{n x_{1}}{α_{n}})}^{3} + 6 {(\frac{n x_{1}}{α_{n}})}^{2} + 11 (\frac{n x_{1}}{α_{n}}) + 6)] \\ + \frac{8 ν α_{n}^{4}}{n^{4}} [(\frac{C^{‴} (1)}{C (1)} + 3 ((\frac{n x_{1}}{α_{n}}) + 1) \frac{C^{″} (1)}{C (1)} \\ + (3 {(\frac{n x_{1}}{α_{n}})}^{2} + 6 (\frac{n x_{1}}{α_{n}}) + 2) \frac{C^{'} (1)}{C (1)} \\ + (\frac{n x_{1}}{α_{n}}) ({(\frac{n x_{1}}{α_{n}})}^{2} + 3 (\frac{n x_{1}}{α_{n}}) + 2)] \\ + \frac{24 ν^{2} α_{n}^{4}}{n^{4}} [(\frac{C^{″} (1)}{C (1)} + (2 (\frac{n x_{1}}{α_{n}}) + 1) \frac{C^{'} (1)}{C (1)} \\ + (\frac{n x_{1}}{α_{n}}) ((\frac{n x_{1}}{α_{n}}) + 1)] \\ + \frac{32 ν^{3} α_{n}^{4}}{n^{4}} [(\frac{C^{'} (1)}{C (1)} + (\frac{n x_{1}}{α_{n}}))] + \frac{16 ν^{4} α_{n}^{4}}{n^{4}}; \end{matrix}

\begin{matrix} (9) B_{n, m}^{ν, τ} (ϕ_{0, 4}; x_{1}, y_{1}) & = & \frac{1}{ξ_{m}^{4}} [\frac{D^{⁗} (1)}{D (1)} + (4 β_{m} y_{1} + 6) \frac{D^{‴} (1)}{D (1)} \\ + (6 β_{m}^{2} y_{1}^{2} + 18 β_{m} y_{1} + 11) \frac{D^{″} (1)}{D (1)} \\ + (4 β_{m}^{3} y_{1}^{3} + 18 β_{m}^{2} y_{1}^{2} + 22 β_{m} y_{1} + 6) \frac{D^{'} (1)}{D (1)} \\ + β_{m} y_{1} (β_{m}^{3} y_{1}^{3} + 6 β_{m}^{2} y_{1}^{2} + 11 β_{m} y_{1} + 6)] \\ + \frac{8 τ}{ξ_{m}^{4}} [\frac{D^{‴} (1)}{D (1)} + 3 (β_{m} y_{1} + 1) \frac{D^{″} (1)}{D (1)} \\ + (3 β_{m}^{2} y_{1}^{2} + 6 β_{m} y_{1} + 2) \frac{D^{'} (1)}{D (1)} \\ + β_{m} y_{1} (β_{m}^{2} y_{1}^{2} + 3 β_{m} y_{1} + 2)] \\ + \frac{24 τ^{2}}{ξ_{m}^{4}} [\frac{D^{″} (1)}{D (1)} + (2 β_{m} y_{1} + 1) \frac{D^{'} (1)}{D (1)} + β_{m} y_{1} (β_{m} y_{1} + 1)] \\ + \frac{32 τ^{3}}{ξ_{m}^{4}} [\frac{D^{'} (1)}{D (1)} + β_{m} y_{1}] + \frac{16 τ^{4}}{ξ_{m}^{3}} . \end{matrix}

Proof.

Taking

j = i = 0

and using the operators (9), we have

\begin{matrix} B_{n, m}^{ν, τ} (ϕ_{0, 0}; x_{1}, y_{1}) & = & \frac{1}{e_{ν} (\frac{n x_{1}}{α_{n}}) e_{τ} (β_{m} y_{1}) C (1) D (1)} \sum_{k, l = 0}^{\infty} P_{k} (\frac{n x_{1}}{α_{n}}) Q_{l} (β_{m} y_{1}) \\ = & 1 . \end{matrix}

Taking

j = 1

and

i = 0