1. Introduction and Preliminaries
Approximation theory is a significant tool especially for the solution of problems put forward in functional analysis theory. The problem of approximating continuous functions was first addressed by Weierstrass in 1885, ref. [
1]. Weierstrass showed the existence of polynomials that converge properly to functions that are continuous in a closed interval
. This theorem was later proved by Bernstein in the interval
with the help of polynomials named after him [
2].
Bohman in 1952 and Korovkin in 1953, based on this theorem, proved an outstanding theorem regarding the uniform convergence of linear positive operators to continuous functions. It has been proven by this theorem that only three conditions should be investigated to achieve uniform convergence in the finite interval. Afterwards, new linear positive operators were defined by many researchers and their approximation properties were examined with the help of the Korovkin type theorem. Some of these operators are: Bernstein Chlodowsky operators, Szasz operators, Gadjiev Ibragimov operators, Meyer–König and Zeller operators, etc. For more details, see [
3].
One of these operators is defined as
by Meyer–König and Zeller in 1960 and is named as the Meyer–König and Zeller operator in the literature. A number of researchers have been interested in the
n-th order moment of this operator, especially second-order moment. It is uncomplicated to determine the
required by the Korovkin Theorem in the Bernstein, Szasz–Mirakjan and Baskakov operators. For Meyer–König and Zeller operators, a number of authors only dealt with the second moment,
, instead of an explicit statement of
in the literature. Some of these studies are presented by Müller [
4] in 1967, Sikkema [
5] in 1970, Lupaş and Müller [
6] in 1970, Becker and Nessel [
7] in 1978, Alkamade [
8] in 1984, and Abel [
9] in 1995. Alkamade obtained
for the second moment with the help of hypergeometric series [
8]. In addition to these, authors have presented some results of Meyer–König and Zeller operators for
calculus in [
10,
11].
Moreover, in [
12], Cardenes-Morales et al. dealt with the Bernstein types operators disparately and deduced the new type operator introduced by
with a certain presumptions and proved its approximation properties. Hereby, the most crucial feature of the defined Bernstein operator is that it fixes the set of
instead of the standard Korovkin’s test functions,
. In this direction, in [
13] Gamma type operators by Erençin et al., in [
14] Bernstein–Durrmeyer type operators by Acar et al., in [
15,
16] Szász–Mirakyan types operators by Aral et al., and in [
17] Lupaş type operators by Qasim et al., in [
18] Bernsrtein–Chlodowksi types operators, in [
19] Balazs types operators and in [
20] Baskakov type operators by Usta have been introduced.
In this regard, in [
21], the authors made a similar research for the Meyer–König and Zeller operators and deduced the following operator:
for the function
such that
is a continuous and infinite times differentiable function that holds
- ()
, , and for almost each x;
- ()
is a continuously differentiable function on .
Although the given Meyer–König and Zeller operators are useful, the use of the function in three different locations in the definition has confined the use of the operators. Thus, in this paper, we aimed to obtain a more comprehensive and more specific new type Meyer–König and Zeller operator by replacing the term in the operator with . By determining the functions and , we will have obtained a more competitive Meyer-König and Zeller operator.
The body of the paper is composed of seven sections, including this section. The remaining of this paper is composed as follows: In
Section 2, the new Meyer–König and Zeller type operators are formed with
,
and
while the basic properties of the new definition are discussed in this section. In
Section 3, Voronovskaya type theorems of these newly defined operators are given. Then, quantitative type theorem is given in
Section 4 for classical modulus of continuity and second-order of modulus of continuity. In
Section 5, we present local approximation properties of these operators, while some computational experiments are discussed in
Section 6. In
Section 7, we give some concluding remarks and advanced directions of the research.
2. Construction of Operators
Let
be a continuous function on
. Then, for arbitrary given
, define
. Furthermore, let
be positive functions on
for any
and
. In the circumstances, the new Meyer–König and Zeller operators are defined in the following form:
where
is a function fulfils the requirements
and
.
There are, of course, some assumptions that must be met in order for this new operator family to be an approximation procedure. Now let us express these assumptions and decide what the functions and are using these assumptions.
First of all, we assume that, for
,
where
. Then, utilizing (
3), we deduce that,
which immediately yields
for any
and any
.
Second of all, we impose that
maps
to the same functions, that is to say, for
,
where
. Similarly, with the aid of (
3), we obtain,
thus we get,
for any
and any
.
We can now provide
and
from (
4) and (
5), more precisely, we deduce that,
Thus, by substituting
and
into (
3), we have
for any
and any
.
There are some conditions that the functions
and
must fulfil in order to obtain a weighted approximation process from this new operator family. On the other hand, the following inequalities must be hold to get weighted approximation processes, that is to say,
and
for
. In other words, the relations (
8) and (
9) and the functions
and
ensure that
is an approximation procedure on
in terms of weighted Bohman–Korovkin theorem.
Some Particular Cases of
We know that this newly constructed Meyer-König and Zeller operator includes the same type of operators that exist in the literature. We can now demonstrate that this newly defined operator will be reduced to the operators that exist in the literature for the appropriate selection of , , and .
In case of
,
, and
, the operators (
7) turn out to be classical Meyer–König and Zeller operators given in (
1) introduced in [
22];
In case of
and
, the operators (
7) turn out to be the operators given in (
2) introduced in [
21];
In case of
,
and
where
is a sequence of real numbers having the properties
the operators (
7) turn out to be the operators given in [
23], by
In case of
,
and
, where
a is a parameter such that
and
is given above, the operators (
7) turn out to be the operators given in [
24], by
In case of
,
, and
, the operators (
7) turn out to be the operators given in [
25], by
In order to prove the fundamental approximation properties of the introduced operators, we need some basic results given in the following lemmas:
Lemma 1. For any , the operators introduced by (7) confirm the following identities, On the other hand, the value of
for
has always been difficult to calculate since the Meyer–König and Zeller operator was defined. Even a number of mathematicians have only dealt with estimates of this value [
5,
8,
9]. We now provide the
.
Lemma 2. For all and all integers , the following relationholds. Proof. Let fix an integer
as well as a values
. We will use the operator given in (
3) for convenience. Then we deduce,
where
It follows that we can write
on
by using the above results. Then, by using the function
and
given in (
6), we deduce the required relation. □
On the other hand, let
be as usually the linear space of real-valued functions
u, defined and continuous on
and normed by the uniform norm
We can now present the basic convergence theorem for the introduced Meyer–König and Zeller operators as follows.
Theorem 1. Assume that . Then, uniformly in .
Proof. According to the results of Lemmas 1 and 2, we deduce that , and as , uniformly in . By the well-recognized Bohman–Korovkin theorem, it follows that as , uniformly in . □
Theorem 2. For , we have .
Proof. By the definition of the introduced operator
and using Lemma 1, we deduced
which completes the proof. □
Now, let us define the following central moments of the newly defined Meyer-König and Zeller operators of degree
n, that is to say,
Then, with the aid of Lemmas 1 and 2 and using the linearity of the introduced operator, the central moments can be provided as follows:
Lemma 3. For any , the central moments of can be given as follows,
We left the proof of Lemma 3 to the reader as the above relations are readily deduced by direct calculation via binomial expansion.
Finally, in order to present local approximation properties that will be provided in the next sections, we require the following lemma.
Lemma 4. For all and , we obtain Proof. Using the definition of introduced operators, we may write that
due the fact that
Then, by using the results of Lemma 1, we obtain the desired result thus the proof is completed. □
4. Quantitative Results
In this section, the order of approximation given by the sequence of the introduced Meyer–König and Zeller operators is studied. The obtained relations are deduced as immediate results of some general theorems on the order of approximation through the instrumentality of a certain sequence of positive linear operators. First of all, we need to define the following functions spaced which are used in the next theorems.
On the other hand, for each
and
, the standard modulus of continuity of order one, i.e.,
and the second-order modulus of continuity, i.e.,
We can now provide the main theorem of this section as follows.
Theorem 4. Let is introduced Meyer–König and Zeller operators given in (3). Then, for each and , we have the estimationwhere is given in (8) and Proof. Let
,
, and
. According to theorem given in [
26], one can readily deduce the following inequality, that is to say
Then, with the help of the expression
given in [
27] such that
is a constant. At the same study, the existence of
was proved. Therefore, we obtain that
which yields
where
given in (
10). As a consequence, the proof is completed taking into account the first moment of introduced Meyer–König and Zeller operators and relations (
15) and (
16). □
Theorem 5. Let is introduced Meyer–König and Zeller operators given in (3). Then, for each and , we have the estimationwhere given in (10) and is given as above. Proof. Let
,
and
. Thanks to the theorem given in [
28], the following inequality is easily deduced, that is to say
Utilizing from the well-known Cauchy–Schwarz inequality, we obtain that
Similarly, by using the relations (
17) and (
18) and the moment values of the introduced operators, the proof is completed. □