Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials

El-Deeb, Sheza M.; Alb Lupaş, Alina

doi:10.3390/fractalfract6070360

Open AccessArticle

Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials

by

Sheza M. El-Deeb

^1,2,†

and

Alina Alb Lupaş

^3,*,†

¹

Department of Mathematics, Faculty of Science, Damietta University, New Damietta 34517, Egypt

²

Department of Mathematics, College of Science and Arts, Al-Badaya, Qassim University, Buraidah 52571, Saudi Arabia

³

Department of Mathematics and Computer Science, University of Oradea, 1 Universitatii Street, 410087 Oradea, Romania

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Fractal Fract. 2022, 6(7), 360; https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract6070360

Submission received: 3 June 2022 / Revised: 24 June 2022 / Accepted: 28 June 2022 / Published: 29 June 2022

(This article belongs to the Section General Mathematics, Analysis)

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Abstract

:

By using Lucas polynomials, we define a new subclass of analytic bi-univalent functions, class

Σ

, in the open unit disc with respect to symmetric conjugate points connected with the combination Binomial series and Babalola operator. The bounds on the initial coefficients

|a_{2}|

and

|a_{3}|

for the functions in this new subclass of

Σ

are investigated. Moreover, we obtain an estimation for the Fekete–Szego problem for the function subclass defined in this paper. Relevant connections of these results are presented here as corollaries.

Keywords:

symmetric conjugate points; bi-univalent functions; Lucas polynomials; binomial series; Babalola operator

MSC:

05A30; 30C45

1. Introduction

Let

A

represent the family of analytic functions whose members are

T (ζ) = ζ + \sum_{j = 2}^{\infty} a_{j} ζ^{j}, (Ω = {ζ : | ζ | < 1, ζ \in C},

(1)

with the normalization condition

T (0) = 0, T^{'} (0) = 1,

and

S

be a class of all functions belonging to

A,

which are univalent functions. Furthermore, let

P

be the family of functions

p (ζ) \in A .

If

T

and

Υ

are analytic functions in

Ω

, then

T

is subordinate to

Υ

, written

T ≺ Υ

if there exists an analytic Schwarz function w, in

Ω

with

w (0) = 0

and

|w (z)| < 1

for all

ζ \in Ω,

such that

T (ζ) = Υ (w (ζ)) .

Moreover, if the function

Υ

is univalent in

Ω,

then we have (see [1,2]):

T (ζ) ≺ Υ (ζ) \Leftrightarrow T (0) = Υ (0) and T (Ω) \subset Υ (Ω) .

Babalola defined the operator

L_{υ}^{ρ} : Ω \to Ω

as

L_{υ}^{σ} T (ζ) = (ρ_{σ} * ρ_{σ, υ}^{- 1} * T) (ζ),

(2)

where

ρ_{σ, υ} (ζ) = \frac{ζ}{{(1 - ζ)}^{σ - υ + 1}}, σ - υ + 1 > 0, ρ_{σ} = ρ_{σ, 0},

and

ρ_{σ, υ}^{- 1}

is

(ρ_{σ, υ} * ρ_{σ, υ}^{- 1}) (ζ) = \frac{ζ}{1 - ζ} (σ, υ \in N = {1, 2, 3, \dots}) .

For

T \in Ω,

then (2) is equivalent to

L_{υ}^{σ} T (ζ) = ζ + \sum_{j = 2}^{\infty} [\frac{Γ (σ + j)}{Γ (σ + 1)} \cdot \frac{(σ - υ)!}{(σ + j - υ - 1)!}] a_{j} ζ^{j} .

Making use of the binomial series

{(1 - δ)}^{n} = \sum_{i = 0}^{n} (\begin{matrix} n \\ i \end{matrix}) {(- 1)}^{i} δ^{i} (n \in N),

for

T \in Ω,

we introduce the linear differential operator as follows:

D_{n, δ, υ}^{σ, 0} T (ζ) = T (ζ),

\begin{matrix} D_{n, δ, υ}^{σ, 1} T (ζ) & = & D_{n, δ, υ}^{σ} T (ζ) = {(1 - δ)}^{n} L_{υ}^{σ} T (ζ) + [1 - {(1 - δ)}^{n}] ζ {(L_{υ}^{σ} T)}^{^{'}} (ζ) \\ = & z + \sum_{j = 2}^{\infty} [1 + (j - 1) c^{n} (δ)] [\frac{Γ (σ + j)}{Γ (σ + 1)} \cdot \frac{(σ - υ)!}{(σ + j - υ - 1)!}] a_{j} ζ^{j} \\ ⋮ \\ D_{n, δ, υ}^{σ, m} T (ζ) & = & D_{n, δ, υ}^{σ} (D_{n, δ, υ}^{σ, m - 1} T (ζ)) \\ = & {(1 - δ)}^{n} D_{n, δ, υ}^{σ, m - 1} T (ζ) + [1 - {(1 - δ)}^{n}] ζ {(D_{n, δ, υ}^{σ, m - 1} T (ζ))}^{^{'}} \\ = & ζ + \sum_{j = 2}^{\infty} {[1 + (j - 1) c^{n} (δ)]}^{m} [\frac{Γ (σ + j)}{Γ (σ + 1)} \cdot \frac{(σ - υ)!}{(σ + j - υ - 1)!}] a_{j} ζ^{j} \\ = & ζ + \sum_{j = 2}^{\infty} ψ_{j} a_{j} ζ^{j}, \\ (δ > 0; n, σ, υ \in N; m \in N_{0} = N \cup {0}), \end{matrix}

(3)

where

ψ_{j} = {[1 + (j - 1) c^{n} (δ)]}^{m} [\frac{Γ (σ + j)}{Γ (σ + 1)} \cdot \frac{(σ - υ)!}{(σ + j - υ - 1)!}],

(4)

and

c^{n} (δ) = \sum_{i = 1}^{n} (\begin{matrix} n \\ i \end{matrix}) {(- 1)}^{i + 1} δ^{i} (n \in N) .

From (3), we obtain that

c^{n} (δ) ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{^{'}} = D_{n, δ, υ}^{σ, m + 1} T (ζ) - [1 - c^{n} (δ)] D_{n, δ, υ}^{σ, m} T (ζ) .

(5)

Definition 1.

Let

p (ϰ)

and

r (ϰ)

be polynomials with real coefficients. The

(p, r)

-polynomials

L_{p, r, n} (ϰ)

are given by the following recurrence relation (see [3,4]):

L_{p, r, n} (ϰ) = p (ϰ) L_{p, r, n - 1} (ϰ) + r (ϰ) L_{p, r, n - 2} (ϰ) (n \in N ∖ {1}),

with

\begin{matrix} L_{p, r, 0} (ϰ) = 2, \\ L_{p, r, 1} (ϰ) = p (ϰ), \\ L_{p, r, 2} (ϰ) = p^{2} (ϰ) + 2 r (ϰ), \\ L_{p, r, 3} (ϰ) = p^{3} (ϰ) + 3 p (x) r (ϰ), \\ ⋮ \end{matrix}

The generating function of the Lucas polynomials

L_{p, r, n} (ϰ)

(see [5]) is given by:

G_{L_{p, r, n} (ϰ)} (ζ) : = \sum_{n = 0}^{\infty} L_{p, r, n} (ϰ) ζ^{n} = \frac{2 - p (ϰ) ζ}{1 - p (ϰ) ζ - r (ϰ) ζ^{2}} .

(6)

Note that for particular values of p and r, the

(p, r)

-polynomial

L_{p, r, n} (ϰ)

includes various polynomials; among these, we have the following cases (see [5] for more details; also [6,7]):

Putting $p (ϰ) = ϰ$ and $r (ϰ) = 1,$ we obtain the Lucas polynomials $L_{n} (ϰ)$ ;
Putting $p (ϰ) = 2 ϰ$ and $r (ϰ) = 1,$ we attain the Pell–Lucas polynomials $Q_{n} (ϰ)$ ;
Putting $p (ϰ) = 1$ and $r (ϰ) = 2 ϰ,$ we attain the Jacobsthal–Lucas polynomials $j_{n} (ϰ)$ ;
Putting $p (ϰ) = 3 ϰ$ and $r (ϰ) = - 2,$ we attain the Fermat–Lucas polynomials $f_{n} (ϰ)$ ;
Putting $p (ϰ) = 2 ϰ$ and $r (ϰ) = - 1,$ we have the Chebyshev polynomials $T_{n} (ϰ)$ of the first kind.

By the Koebe one quarter theorem (see [8]), we have that the image of

Ω

under every univalent function

T \in S

contains a disk of radius

\frac{1}{4} .

Therefore, every function

T \in S

has an inverse

T^{- 1}

that satisfies

T^{- 1} (T (ζ)) = ζ (ζ \in Ω)

and

T (T^{- 1} (w)) = w (|w| < r_{0} (T); r_{0} (T) \geq \frac{1}{4}),

where

T^{- 1} (w) = w - a_{2} w^{2} + (2 a_{2}^{2} - a_{3}) w^{3} - (5 a_{2}^{3} - 5 a_{2} a_{3} + a_{4}) w^{4} + \dots

(7)

A function

T \in A

is said to be bi-univalent in

Ω

if both

T (ζ)

and

T^{- 1} (ζ)

are univalent in

Ω

. Let

Σ

denote the class of bi-univalent functions in

Ω

given by (1). For a brief history and interesting examples in the class

Σ

, see [9]. Brannan and Taha [10] (see also [11,12,13]) introduced certain subclasses of the bi-univalent functions class

Σ

similar to the familiar subclasses

S^{*} (δ)

and

K (δ)

of starlike and convex functions of order

δ (0 \leq δ < 1)

, respectively (see [9]). The classes

S_{Σ}^{*} (δ)

and

K_{Σ} (δ)

of bi-starlike functions of order

δ

and bi-convex functions of order

δ

(0 < δ \leq 1),

corresponding to the function classes

S^{*} (δ)

and

K (δ),

were also introduced analogously. For each of the function classes

S_{Σ}^{*} (δ)

and

K_{Σ} (δ),

they found non-sharp estimates on the first two Taylor–Maclaurin coefficients

|a_{2}|

and

|a_{3}|

(for details, see [10,13]).

Note that the functions

f_{1} (ζ) = \frac{ζ}{1 - ζ}, f_{2} (ζ) = \frac{1}{2} log \frac{1 + ζ}{1 - ζ}, f_{3} (ζ) = - log (1 - ζ)

(8)

with their corresponding inverses

f_{1}^{- 1} (w) = \frac{w}{1 + w}, f_{2}^{- 1} (w) = \frac{e^{2 w} - 1}{e^{2 w} + 1}, f_{3}^{- 1} (w) = \frac{e^{w} - 1}{e^{w}}

(9)

are elements of

Σ .

El-Ashwah and Thomas [14] introduced the class

S_{s c}^{*}

of starlike with respect to symmetric conjugate points as follows:

ℜ \{\frac{ζ T^{^{'}} (ζ)}{T (ζ) - \bar{T (- \bar{ζ})}}\} > 0, ζ \in Ω .

Ping and Janteng [15] introduced the class

S_{s c}^{*}

(A, B)

of starlike with respect to symmetric conjugate points as follows:

\frac{2 ζ T^{^{'}} (ζ)}{T (ζ) - \bar{T (- \bar{ζ})}} ≺ \frac{1 + A ζ}{1 + B ζ}, ζ \in Ω .

It is perceived that this formalism facilitates further mathematical exploration and also helps us to understand the symmetric and geometric properties of such operators better. Inspired by aforementioned works on bi-univalent functions and by using the combination of binomial series and the Babalola operator in the present paper, we define a new subclass as in Definition 2 of the function class

Σ

and determine the estimates of the coefficients

|a_{2}|

and

|a_{3}|

for the function in this new subclass of the function class

Σ

. We also discuss the Fekete–Szego inequalities’ results [16] for f

\in S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

.

Definition 2.

A function

T (ζ) \in A

is said to be in the class

S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ)) (0 \leq γ \leq 1; δ > 0; n, σ, υ \in N; m \in N_{0})

if

\begin{matrix} \frac{2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})}} + \frac{2 {(ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} T (ζ) - D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))}^{'}} \\ - \frac{2 γ ζ^{2} {(D_{n, δ, υ}^{σ, m} T (ζ))}^{″} + 2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{γ ζ (D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))^{^{'}}} + (1 - γ) (D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))}} \\ ≺ G_{L_{p, r, n} (ϰ)} (ζ) - 1, \end{matrix}

(10)

and

\begin{matrix} \frac{2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})}} + \frac{2 {(w {(D_{n, δ, υ}^{σ, m} G (w))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'}} \\ - \frac{2 γ w^{2} {(D_{n, δ, υ}^{σ, m} G (w))}^{″} + 2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{γ w {(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'} + (1 - γ) (D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w}))}} \\ ≺ G_{L_{p, r, n} (ϰ)} (w) - 1, \end{matrix}

(11)

with

0 \leq γ \leq 1; δ > 0; n, σ, υ \in N; m \in N_{0},

where the function

G = T^{- 1}

is given by (7).

Example 1.

A function

T (ζ) \in A

is said to be in the class

S_{s c}^{0} (n, δ, υ, σ, m, p (ϰ), r (ϰ)) \equiv M_{s c} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

if

\frac{2 {(ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} T (ζ) - D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))}^{'}} ≺ G_{L_{p, r, n} (ϰ)} (ζ) - 1,

and

\frac{2 {(w {(D_{n, δ, υ}^{σ, m} G (w))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w}))})}^{'}} ≺ G_{L_{p, r, n} (ϰ)} (w) - 1,

where

δ > 0; n, σ, υ \in N; m \in N_{0},

where the function

G = T^{- 1}

is given by (7).

Example 2.

A function

T (ζ) \in A

is said to be in the class

S_{s c}^{1} (n, δ, υ, σ, m, p (ϰ), r (ϰ)) \equiv N_{s c} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

if

\frac{2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})}} ≺ G_{L_{p, r, n} (ϰ)} (ζ) - 1,

(12)

and

\frac{2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})}} ≺ G_{L_{p, r, n} (ϰ)} (w) - 1,

(13)

where

δ > 0; n, σ, υ \in N; m \in N_{0},

where the function

G = T^{- 1}

is given by (7).

The following lemma will be needed later.

Lemma 1

([17]). If

ω (ζ) = \sum_{j = 1}^{\infty} p_{j} ζ^{j}

is a Schwarz function for

ζ \in Ω

, then

| p_{1} | \leq 1, | p_{j} | \leq 1 - | p_{1} |^{2}, j \geq 1 .

2. Coefficient Bounds for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$

Throughout this paper, we shall assume that

0 \leq γ \leq 1; δ > 0; n, σ, υ \in N; m \in N_{0} .

Theorem 1.

If the function

T

given by (1) is in the class

S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

, then

|a_{2}| \leq \frac{| p (ϰ) | \sqrt{|p (ϰ)|}}{\sqrt{2 |(3 - 2 γ) p^{2} (ϰ) ψ_{3} - 2 (p^{2} (ϰ) + 2 r (ϰ)) {(2 - γ)}^{2} ψ_{2}^{2}|}},

and

|a_{3}| \leq \frac{| p (ϰ) |}{2 (3 - 2 γ) ψ_{3}} + \frac{p^{2} (ϰ)}{4 {(2 - γ)}^{2} ψ_{2}^{2}},

where

ψ_{j}

,

j \in {2, 3}

, are given by (4).

Proof.

Let

T \in S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

. Then, there exist two analytic functions

R

and

S

in

Ω

with

R (0) = S (0) = 0

, and

| R (ζ) | < 1

,

| S (w) | < 1

for all

ζ, w \in Ω

given by

R (ζ) = \sum_{j = 1}^{\infty} v_{j} ζ^{j} and S (w) = \sum_{j = 1}^{\infty} s_{j} w^{j}, ζ, w \in Ω,

from Lemma 1, we have

|v_{j}| \leq 1 and |s_{j}| \leq 1, j \in N .

(14)

In view of (10) and (11), we obtain

\frac{2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})}} + \frac{2 {(ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})})}^{'}}

\begin{matrix} - \frac{2 γ ζ^{2} {(D_{n, δ, υ}^{σ, m} T (ζ))}^{″} + 2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{γ ζ {(D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})})}^{'} + (1 - γ) (D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))}} \\ = & G_{L_{p, r, n} (ϰ)} (R (ζ)) - 1, \end{matrix}

(15)

and

\frac{2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})}} + \frac{2 {(w {(D_{n, δ, υ}^{σ, m} G (w))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'}}

\begin{matrix} - \frac{2 γ w^{2} {(D_{n, δ, υ}^{σ, m} G (w))}^{″} + 2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{γ w {(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'} + (1 - γ) (D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w}))}} \\ = & G_{L_{p, r, n} (ϰ)} (S (w)) - 1 . \end{matrix}

(16)

After some basic calculations, we obtain

\frac{2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})}} + \frac{2 {(ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})})}^{'}}

\begin{matrix} - \frac{2 γ ζ^{2} {(D_{n, δ, υ}^{σ, m} T (ζ))}^{″} + 2 ζ {(D_{n, δ, υ}^{σ, m} T (ζ))}^{'}}{γ ζ {(D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ})})}^{'} + (1 - γ) (D_{n, δ, υ}^{σ, m} T (ζ) - \bar{D_{n, δ, υ}^{σ, m} T (- \bar{ζ}))}} \\ = & 1 + 2 (2 - γ) ψ_{2} a_{2} ζ + 2 (3 - 2 γ) ψ_{3} a_{3} ζ^{2} + \dots, \end{matrix}

(17)

\frac{2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})}} + \frac{2 {(w {(D_{n, δ, υ}^{σ, m} G (w))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'}}

\begin{matrix} - \frac{2 γ w^{2} {(D_{n, δ, υ}^{σ, m} G (w))}^{″} + 2 w {(D_{n, δ, υ}^{σ, m} G (w))}^{'}}{γ w {(D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w})})}^{'} + (1 - γ) (D_{n, δ, υ}^{σ, m} G (w) - \bar{D_{n, δ, υ}^{σ, m} G (- \bar{w}))}} \\ = & 1 - 2 (2 - γ) ψ_{2} a_{2} w + 2 (3 - 2 γ) (2 a_{2}^{2} - a_{3}) ψ_{3} w^{2} + \dots, \end{matrix}

(18)

G_{L_{p, r, n} (ϰ)} (R (ζ)) - 1 = 1 + L_{p, r, 1} (ϰ) v_{1} ζ + (L_{p, r, 1} (ϰ) v_{2} + L_{p, r, 2} (ϰ) v_{1}^{2}) ζ^{2} + \dots,

(19)

and

G_{L_{p, r, n} (ϰ)} (S (w)) - 1 = 1 + L_{p, r, 1} (ϰ) s_{1} w + (L_{p, r, 1} (ϰ) s_{2} + L_{p, r, 2} (ϰ) s_{1}^{2}) w^{2} + \dots

(20)

Next, using (17) and (19), equating the corresponding coefficients of

ζ

in (15), we obtain

2 (2 - γ) ψ_{2} a_{2} = L_{p, r, 1} (ϰ) v_{1},

(21)

2 (3 - 2 γ) ψ_{3} a_{3} = L_{p, r, 1} (ϰ) v_{2} + L_{p, r, 2} (ϰ) v_{1}^{2} .

(22)

By using (18) and (20), equating the corresponding coefficients of w in (16), we obtain

- 2 (2 - γ) ψ_{2} a_{2} = L_{p, r, 1} (ϰ) s_{1},

(23)

2 (3 - 2 γ) (2 a_{2}^{2} - a_{3}) ψ_{3} = L_{p, r, 1} (ϰ) s_{2} + L_{p, r, 2} (ϰ) s_{1}^{2} .

(24)

From (21) and (23), we have

v_{1} = - s_{1} .

(25)

Squaring (21) and (23), and then adding the new relations, we obtain

8 {(2 - γ)}^{2} a_{2}^{2} ψ_{2}^{2} = L_{p, r, 1}^{2} (ϰ) (v_{1}^{2} + s_{1}^{2}) .

(26)

Furthermore, by adding (22) and (24), we have

4 (3 - 2 γ) ψ_{3} a_{2}^{2} = L_{p, r, 1} (ϰ) (v_{2} + s_{2}) + L_{p, r, 2} (ϰ) (v_{1}^{2} + s_{1}^{2}) .

(27)

Now, (26) can be written as

v_{1}^{2} + s_{1}^{2} = \frac{8 {(2 - γ)}^{2}}{L_{p, r, 1}^{2} (ϰ)} a_{2}^{2} ψ_{2}^{2} .

Using the above equation and (27), we have

a_{2}^{2} = \frac{L_{p, r, 1}^{3} (ϰ) (v_{2} + s_{2})}{4 (3 - 2 γ) L_{p, r, 1}^{2} (ϰ) ψ_{3} - 8 L_{p, r, 2} (ϰ) {(2 - γ)}^{2} ψ_{2}^{2}},

(28)

and from (2) and (14), we have

|a_{2}| \leq \frac{| p (ϰ) | \sqrt{|p (ϰ)|}}{\sqrt{2 |(3 - 2 γ) p^{2} (ϰ) ψ_{3} - 2 (p^{2} (ϰ) + 2 r (ϰ)) {(2 - γ)}^{2} ψ_{2}^{2}|}},

which gives the bound for

|a_{2}|

.

To derive the coefficient bound of

|a_{3}|

, subtracting (24) from (22), we obtain

4 (3 - 2 γ) ψ_{3} (a_{3} - a_{2}^{2}) = L_{p, r, 1} (ϰ) (v_{2} - s_{2}) + L_{p, r, 2} (ϰ) (v_{1}^{2} - s_{1}^{2}) .

(29)

Form (25), (26) and (29), we obtain

a_{3} = \frac{L_{p, r, 1} (ϰ) (v_{2} - s_{2})}{4 (3 - 2 γ) ψ_{3}} + \frac{L_{p, r, 1}^{2} (ϰ) (v_{1}^{2} + s_{1}^{2})}{8 {(2 - γ)}^{2} ψ_{2}^{2}} .

(30)

Again, using (2) and (14), we obtain

|a_{3}| \leq \frac{| p (ϰ) |}{2 (3 - 2 γ) ψ_{3}} + \frac{p^{2} (ϰ)}{4 {(2 - γ)}^{2} ψ_{2}^{2}} .

□

Corollary 1.

Putting

γ = 0

in Theorem 1, we obtain the following corollary:

M_{s c} (n, δ, υ, σ, m,

p (ϰ), r (ϰ))

|a_{2}| \leq \frac{| p (ϰ) | \sqrt{|p (ϰ)|}}{\sqrt{2 |3 p^{2} (ϰ) ψ_{3} - 8 (p^{2} (ϰ) + 2 r (ϰ)) ψ_{2}^{2}|}},

and

|a_{3}| \leq \frac{| p (ϰ) |}{6 ψ_{3}} + \frac{p^{2} (ϰ)}{16 ψ_{2}^{2}},

where

ψ_{j}

,

j \in {2, 3}

, are given by (4).

Putting

γ = 1

in Theorem 1, we obtain the following corollary:

N_{s c} (n, δ, υ, σ, m,

p (ϰ), r (ϰ))

.

Corollary 2.

If the function

T

given by (1) is in the class

N_{s c} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

, then, where

ψ_{j}

,

j \in {2, 3}

are given by (4).

|a_{2}| \leq \frac{| p (ϰ) | \sqrt{|p (ϰ)|}}{\sqrt{2 |p^{2} (ϰ) ψ_{3} - 2 (p^{2} (ϰ) + 2 r (ϰ)) ψ_{2}^{2}|}},

and

|a_{3}| \leq \frac{| p (ϰ) |}{2 ψ_{3}} + \frac{p^{2} (ϰ)}{4 ψ_{2}^{2}},

where

ψ_{j}

,

j \in {2, 3}

, are given by (4).

3. Fekete–Szego Problem for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$

Theorem 2.

If the function

T

given by (1) is in the class

S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

, then

|a_{3} - μ a_{2}^{2}| \leq | p (ϰ) | (| K + L | + | K - L |),

(31)

where

K = \frac{(1 - μ) p^{2} (ϰ)}{2 [(3 - 2 γ) p^{2} (ϰ) ψ_{3} - (p^{2} (ϰ) + 2 r (ϰ)) {(2 - γ)}^{2} ψ_{2}^{2}]},

(32)

and

L = \frac{1}{2 (3 - 2 γ) ψ_{3}},

where

μ \in C

, and

ψ_{j}

,

j \in {2, 3}

, are given by (4).

Proof.

If

T \in S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

. From (25) and (29), we have

a_{3} - a_{2}^{2} = \frac{L_{p, r, 1} (ϰ) (v_{2} - s_{2})}{4 (3 - 2 γ) ψ_{3}} .

(33)

Multiplying (28) by

(1 - μ)

, we obtain

\begin{matrix} (1 - μ) a_{2}^{2} \\ = & \frac{(1 - μ) L_{p, r, 1}^{3} (ϰ) (v_{2} + s_{2})}{4 (3 - 2 γ) L_{p, r, 1}^{2} (ϰ) ψ_{3} - 8 L_{p, r, 2} (ϰ) {(2 - γ)}^{2} ψ_{2}^{2}} . \end{matrix}

(34)

Adding (33) and (34), we obtain

a_{3} - μ a_{2}^{2} = L_{p, r, 1} (ϰ) [(K + L) v_{2} + (K - L) s_{2}],

(35)

where

K

and

L

are given by (32), and taking the absolute value of (35), from (14), we obtain the inequality (31). The proof is complete. □

Remark 1.

A simple computation shows that the inequality

|K| \leq L

is equivalent to

\begin{matrix} |μ - 1| \\ \leq & |1 - \frac{(p^{2} (ϰ) + 2 r (ϰ)) {(2 - γ)}^{2} ψ_{2}^{2}}{(3 - 2 γ) p^{2} (ϰ) ψ_{3}}|, \end{matrix}

and then from Theorem 2, we obtain the next result:

(i) If the function

T

given by (1) belongs to the class

S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

, then

|a_{3} - μ a_{2}^{2}| \leq \frac{|p (ϰ)|}{(3 - 2 γ) ψ_{3}},

where

μ \in C

, with

|μ - 1| \leq |1 - \frac{(p^{2} (ϰ) + 2 r (ϰ)) {(2 - γ)}^{2} ψ_{2}^{2}}{(3 - 2 γ) p^{2} (ϰ) ψ_{3}}|,

and

ψ_{j}

,

j \in {2, 3}

, are given by (4);

(ii) If the function

T

given by (1) belongs to the class

S_{s c}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))

, then

|a_{3} - μ a_{2}^{2}| \leq \frac{|p (ϰ)|}{3 ψ_{3}},

where

μ \in C

, with

|μ - 1| \leq |1 - \frac{4 (p^{2} (ϰ) + 2 r (ϰ)) ψ_{2}^{2}}{3 p^{2} (ϰ) ψ_{3}}|,

and

ψ_{j}

,

j \in {2, 3}

, are given by (4).

4. Conclusions

We defined a subclass of bi-univalent functions connected with the combination binomial series and Babalola operator and Lucas polynomials. We obtained non-sharp bounds for the initial coefficients and the Fekete–Szegö inequalities for the functions in this new class. Some interesting corollaries and applications of the results were also discussed. One can take special cases of Lucas’s polynomial

G_{L_{p, r, n} (ϰ)}

, to give special results for Definition 2. In conclusion, another opportunity to further this topic is provided by substituting Lucas’s polynomial

G_{L_{p, r, n} (ϰ)}

for the Horadam polynomials

h_{n} (x) .

Author Contributions

Conceptualization, A.A.L. and S.M.E.-D.; methodology, S.M.E.-D.; software, A.A.L.; validation, A.A.L. and S.M.E.-D.; formal analysis, A.A.L. and S.M.E.-D.; investigation, A.A.L.; resources, S.M.E.-D.; data curation, S.M.E.-D.; writing—original draft preparation, A.A.L.; writing—review and editing, A.A.L. and S.M.E.-D.; visualization, A.A.L.; supervision, S.M.E.-D.; project administration, A.A.L.; funding acquisition, S.M.E.-D. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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El-Deeb, S.M.; Alb Lupaş, A. Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials. Fractal Fract. 2022, 6, 360. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract6070360

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El-Deeb SM, Alb Lupaş A. Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials. Fractal and Fractional. 2022; 6(7):360. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract6070360

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El-Deeb, Sheza M., and Alina Alb Lupaş. 2022. "Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials" Fractal and Fractional 6, no. 7: 360. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract6070360

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Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials

Abstract

1. Introduction

2. Coefficient Bounds for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$

3. Fekete–Szego Problem for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$

4. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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Coefficient Estimates for the Functions with Respect to Symmetric Conjugate Points Connected with the Combination Binomial Series and Babalola Operator and Lucas Polynomials

Abstract

1. Introduction

2. Coefficient Bounds for the Function Class S sc γ n , δ , υ , σ , m , p ( ϰ ) , r ( ϰ )

3. Fekete–Szego Problem for the Function Class S sc γ n , δ , υ , σ , m , p ( ϰ ) , r ( ϰ )

4. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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Further Information

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2. Coefficient Bounds for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$

3. Fekete–Szego Problem for the Function Class $S_{sc}^{γ} (n, δ, υ, σ, m, p (ϰ), r (ϰ))$