Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series

El-Deeb, Sheza M.; Cotîrlă, Luminita-Ioana

doi:10.3390/math12111691

Open AccessArticle

Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series

by

Sheza M. El-Deeb

^1,2,*

and

Luminita-Ioana Cotîrlă

³

¹

Department of Mathematics, College of Science, Qassim University, Buraydah 51452, Saudi Arabia

²

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

³

Department of Mathematics, Technical University of Cluj-Napoca, 400114 Cluj-Napoca, Romania

^*

Author to whom correspondence should be addressed.

Mathematics 2024, 12(11), 1691; https://doi.org/10.3390/math12111691

Submission received: 25 April 2024 / Revised: 24 May 2024 / Accepted: 25 May 2024 / Published: 29 May 2024

(This article belongs to the Special Issue Advanced Research in Complex Analysis Operators and Special Classes of Analytic Functions)

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Abstract

:

In this paper, we create a new subclass of convex functions given with tangent functions applying the combination of Babalola operators and Binomial series. Moreover, we obtain several important geometric results, including sharp coefficient bounds, sharp Fekete–Szego inequality, Kruskal inequality, and growth and distortion estimates. Furthermore, for functions with logarithmic coefficients, we compute sharp Fekete–Szego inequality and sharp coefficient bounds.

Keywords:

convex functions; convolution; tangent function; Kruskal inequality; logarithmic coefficients; binomial series; Babalola operator

MSC:

30C45

1. Introduction

Let

A

represent the family of analytic functions as follows:

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

(1)

and

S

be a class of all functions belonging to

A

which are univalent functions.

If

G

and Υ are analytic functions in

A

, then

G

is subordinate to Υ, written

G ≺ Υ

if there exists an analytic Schwarz function

ϖ

in

A

with

ϖ (0) = 0

and

|ϖ (ζ)| < 1

for all

ζ \in Ω,

such that

G (ζ) = Υ (ϖ (ζ)) .

Furthermore, if the function

Υ

is univalent in

A,

then we have

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

Furthermore, let the function

H \in A

be given by

H (ζ) = ζ + \sum_{j = 2}^{\infty} c_{j} ζ^{j} (ζ \in Ω) .

The Hadamard product or convolution of

F

and

H

is given by

(G * H) (ζ) = ζ + \sum_{j = 2}^{\infty} a_{j} c_{j} ζ^{j}, (ζ \in Ω) .

(2)

The function

G

is a convex function of order

β,

0 \leq β < 1

, such that

K : = \{G \in A : R e \frac{{(ζ G^{'} (ζ))}^{'}}{G^{'} (ζ)} > β, 0 \leq β < 1, ζ \in Ω\} .

(3)

Babalola [1] defined the operator

L_{υ}^{σ} : A \to A

as

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

(4)

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}^{- 1} (ζ) = ζ + \sum_{j = 2}^{\infty} \frac{(σ - υ)!}{(σ + j - υ - 1)!} ζ^{j} (σ, υ \in N = {1, 2, 3, \dots}) .

For

ζ \in Ω,

then (4) is equivalent to

L_{υ}^{σ} G (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) .

In 2022, El-Deeb and Lupas [2] introduced the linear differential operator as follows:

D_{n, δ, υ}^{σ, 0} G (ζ) = G (ζ),

\begin{matrix} D_{n, δ, υ}^{σ, 1} G (ζ) & = & D_{n, δ, υ}^{σ} G (ζ) = {(1 - δ)}^{n} L_{υ}^{σ} G (ζ) + [1 - {(1 - δ)}^{n}] ζ {(L_{υ}^{σ} G)}^{'} (ζ) \\ = & ζ + \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} G (ζ) & = & D_{n, δ, υ}^{σ} (D_{n, δ, υ}^{σ, m - 1} G (ζ)) \\ = & {(1 - δ)}^{n} D_{n, δ, υ}^{σ, m - 1} G (ζ) + [1 - {(1 - δ)}^{n}] ζ {(D_{n, δ, υ}^{σ, m - 1} G (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}

(5)

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)!}],

(6)

and

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

From (5), we obtain that

c^{n} (δ) ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'} = D_{n, δ, υ}^{σ, m + 1} G (ζ) - [1 - c^{n} (δ)] D_{n, δ, υ}^{σ, m} G (ζ) .

(7)

The integrated families of starlike and convex functions were developed in 1985 by Padmanabhan et al. [3], utilizing the theory of convolution along with the function

\frac{ζ}{{(1 - ζ)}^{a}}

, where

a \in R

. By taking a regular function

ϕ (ζ)

with

ϕ (0) = 1

and

h (ζ) \in A,

Shanmugam [4] expanded on the concept of [3] and introduced the functions class

S_{h}^{*} (ϕ)

as

S_{h}^{*} (ϕ) = \{G \in A : \frac{ζ {(G * h)}^{'}}{(G * h)} ≺ ϕ (ζ), ζ \in Ω\} .

(8)

By taking

h (ζ) = \frac{ζ}{1 - ζ}

or

\frac{ζ}{{(1 - ζ)}^{2}}

, we derive the famous classes

S^{*} (ϕ)

and

C (ϕ)

of Ma- and Minda-type starlike and convex functions defined by [5]. Further, by choosing

ϕ (ζ) = \frac{1 + ζ}{1 - ζ}

, these classes reduce to

S^{*}

and

C

.

By choice

ϕ (ζ)

in the generic form of

S^{*} (ϕ)

and

C (ϕ)

, numerous scholars have defined and investigated a variety of intriguing subclasses of analytic and univalent functions in the recent past. Here are a few of them highlighted:

Let

ϕ (ζ) = \frac{1 + F ζ}{1 + G ζ},

- 1 \leq G < F \leq 1

. Then

S^{*} [F, G] = S^{*} (\frac{1 + F ζ}{1 + G ζ})

is the class of Janowski starlike functions; see [6]. For

ϕ (ζ) = cos ζ,

the class

S_{cos ζ}^{*}

was studied by Bano et al. [7], whereas for

ϕ (ζ) = cosh ζ,

the function class

S_{cosh ζ}^{*}

was introduced and studied by Alotaibi et al. [8]. For

ϕ (ζ) = e^{ζ},

the class

S_{e}^{*}

was defined and studied by Mendiratta [9]; see [10]. For

ϕ (ζ) = 1 + sin ζ,

the class

S^{*} (ϕ)

reduces to

S_{sin}^{*}

; it was presented and examined by Cho et al. [11]. For

ϕ (ζ) = 1 + {sinh}^{- 1} (ζ)

, the family

S^{*} (ϕ)

was established and studied by Kumar et al. [12]; for more details, see [13]. For

ϕ (ζ) = \frac{2}{1 + e^{- ζ}},

the class

S^{*} (ϕ)

reduces to

S_{s i g}^{*}

; see [14,15,16]. The class

S_{tanh ζ}^{*} = S^{*} (ϕ (ζ)),

for

ϕ (ζ) = 1 + tanh ζ,

was established by Khalil et al. [17]; see [18].

Taking motivation and inspiration from the work mentioned above, we present the following subfamily of holomorphic functions.

Definition 1.

Let

G

be given in (1). Then

G \in C_{tan}^{σ, m, n, δ, υ} \Leftrightarrow G \in A and \frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} ≺ 1 + \frac{tan ζ}{2}, ζ \in Ω .

(9)

Geometrically, the family

C_{tan}^{σ, m, n, δ, υ}

includes all the functions

G

that the image domain of

1 + \frac{tan ζ}{2},

for a specified radius.

2. Set of Lemmas

We use the following lemmas in our results.

Let

P

stand for the family of all holomorphic functions p that have a positive real portion and be represented by the following series:

p (ζ) = 1 + \sum_{j = 1}^{\infty} α_{j} ζ^{j}, ζ \in Ω .

(10)

Lemma 1

([19]). If

p \in P

, then the following estimations hold:

|c_{j}| \leq 2, j \geq 1,

(11)

and

|c_{j + n} - μ c_{j} c_{n}| < 2, 0 < μ \leq 1,

(12)

and for

η \in C

, we have

|p_{2} - η p_{1}^{2}| < 2 max \{1, |2 η - 1|\} .

(13)

Lemma 2

([20]). If

p \in P

and has the form (10), then

| α_{1} p_{1}^{3} - α_{2} p_{1} p_{2} + α_{3} p_{3} | \leq 2 | α_{1} | + 2 | α_{2} - 2 α_{1} | + 2 | α_{1} - α_{2} + α_{3} |,

(14)

where

α_{1}, α_{2}

, and

α_{3}

are real numbers.

Lemma 3

([21]). Let

χ_{1}, σ_{1}, ψ_{1}

, and

ϱ_{1}

satisfy the inequalities

χ_{1}, ϱ_{1} \in (0, 1)

and

\begin{matrix} 8 ϱ_{1} (1 - ϱ_{1}) [{(χ_{1} σ_{1} - 2 ψ_{1})}^{2} + {(χ_{1} (ϱ_{1} + χ_{1}) - σ_{1})}^{2}] \\ + χ_{1} (1 - χ_{1}) {(σ_{1} - 2 ϱ_{1} χ_{1})}^{2} \\ \leq 4 χ_{1}^{2} {(1 - χ_{1})}^{2} ϱ_{1} (1 - ϱ_{1}) . \end{matrix}

If

h \in P

and is of the form (10), then

|ψ_{1} p_{1}^{4} + ϱ_{1} p_{2}^{2} + 2 χ_{1} p_{1} p_{3} - \frac{3}{2} σ_{1} p_{1}^{2} p_{2} - p_{4}| \leq 2 .

Lemma 4

([22]). Let

p \in P

and x and ζ belong to Ω; then, we have

\begin{matrix} 2 c_{2} & = & c_{1}^{2} + x (4 - c_{1}^{2}), \\ 4 c_{3} & = & 2 x (4 - c_{1}^{2}) c_{1} - x^{2} (4 - c_{1}^{2}) c_{1} + 2 ζ (1 - {|x|}^{2}) (4 - c_{1}^{2}) + c_{1}^{3} . \end{matrix}

where

c_{2}

and

c_{3}

are studied in [21].

The current study attempts to determine the necessary and sufficient conditions, the radius of convexity, growth and distortion estimates, the Kruskal inequality, sharp coefficient bounds, sharp Fekete–Szego inequality, and logarithmic coefficient estimates for the subclass

C_{tan}^{σ, m, n, δ, υ}

of class

A

associated with tangent functions.

3. Main Results

Theorem 1.

Let

G \in C_{tan}^{σ, m, n, δ, υ}

given in (1). Then,

\frac{1}{ζ} [D_{n, δ, υ}^{σ, m} G (ζ) * (\frac{ζ - M ζ^{2}}{{(1 - ζ)}^{3}})] \neq 0,

(15)

where

M = \frac{4 + tan (e^{i θ})}{2} .

(16)

Proof.

As

G \in C_{tan}^{σ, m, n, δ, υ}

is analytic in

A,

so

\frac{1}{ζ} G (ζ) \neq 0

for all

ζ

in

Ω,

then by using the definition of subordination and (9), we have

\frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} = 1 + tan ω (ζ),

(17)

where

ω (ζ)

is a Schwarz function. Let

ω (ζ) = e^{i θ},

- π \leq θ \leq π .

Then, (17) becomes

\frac{ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} \neq \frac{tan (e^{i θ})}{2},

which implies

ζ^{2} {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″} - ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'} \frac{tan (e^{i θ})}{2} \neq 0 .

(18)

It can be easily seen that

ζ^{2} {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″} - ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'} = D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ (1 + ζ)}{{(1 - ζ)}^{3}},

(19)

and

ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'} = D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ}{{(1 - ζ)}^{2}} .

Using (19) and some simple calculations, (18) becomes

D_{n, δ, υ}^{σ, m} G (ζ) * (\frac{ζ - M ζ^{2}}{{(1 - ζ)}^{3}}) \neq 0 .

(20)

From (20), we will obtain (15), where

M

is given in (16). □

Theorem 2.

Let

G \in A

. Then,

G \in C_{tan}^{σ, m, n, δ, υ}

if

\sum_{j = 2}^{\infty} [\frac{2 j (2 + tan (e^{i θ})) - 4 j^{2}}{tan (e^{i θ})}] ψ_{j} a_{j} ζ^{j - 1} - 1 \neq 0 .

(21)

Proof.

If

G \in C_{tan}^{σ, m, n, δ, υ}

, then from Theorem 1, we have

\frac{1}{ζ} [D_{n, δ, υ}^{σ, m} G (ζ) * (\frac{ζ - M ζ^{2}}{{(1 - ζ)}^{3}})] \neq 0,

where

M

is given in (16). The above relation implies that

\frac{1}{ζ} [(D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ}{{(1 - ζ)}^{3}}) - (D_{n, δ, υ}^{σ, m} G (ζ) * \frac{M ζ^{2}}{{(1 - ζ)}^{3}})] \neq 0 .

Since

ζ^{2} = ζ (1 + ζ) - ζ,

we have

\frac{1}{ζ} [(D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ}{{(1 - ζ)}^{3}}) - M (D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ (1 + ζ)}{{(1 - ζ)}^{3}} - D_{n, δ, υ}^{σ, m} G (ζ) * \frac{ζ}{{(1 - ζ)}^{3}})] \neq 0 .

(22)

Now, applying (19) and some properties of convolution, (22) reduces to

\frac{1}{ζ} [(\frac{1}{2} ζ^{2} {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″} + ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}) - M (ζ^{2} {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″})] \neq 0 .

Using (1) and after some simplification, we obtain (21). □

Theorem 3.

Let

G \in A

be given in (1). Then,

G \in C_{tan}^{σ, m, n, δ, υ}

if

\sum_{j = 2}^{\infty} (|\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}|) |ψ_{j}| |a_{j}| < 1 .

(23)

Proof.

To demonstrate the necessary outcome, we employ relation (21) as

\begin{matrix} |1 - \sum_{j = 2}^{\infty} \frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})} ψ_{j} a_{j} ζ^{j - 1}| \\ > & 1 - \sum_{j = 2}^{\infty} |\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}| |ψ_{j}| |a_{j}| {|ζ|}^{j - 1} . \end{matrix}

(24)

From (23), we have

1 - \sum_{j = 2}^{\infty} |\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}| |ψ_{j}| |a_{j}| > 0 .

(25)

From (24) and (25), we obtain the intended outcome by applying Theorem 2. □

Theorem 4.

Let

G \in C_{tan}^{σ, m, n, δ, υ} .

Then,

G

is convex of order

β,

0 \leq β < 1

and

|ζ| < r_{1}

, where

r_{1} = inf_{j \geq 2} {(|\frac{(1 - β) (4 j - 2 (2 + tan (e^{i θ}))) ψ_{j}}{(j - β) tan (e^{i θ})}|)}^{\frac{1}{j - 1}} .

(26)

Proof.

It is sufficient to show that

|\frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} - 1| \leq 1 - β .

(27)

From (1), we have

|\frac{ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{″}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}}| \leq \frac{\sum_{j = 2}^{\infty} j (j - 1) ψ_{j} a_{j} {|ζ|}^{j - 1}}{1 - \sum_{j = 2}^{\infty} j ψ_{j} a_{j} {|ζ|}^{j - 1}} .

(28)

The inequality (28) is bounded above by

1 - β,

if

\sum_{j = 2}^{\infty} [\frac{j (j - 1) + j (1 - β)}{1 - β}] ψ_{j} |a_{j}| {|ζ|}^{j - 1} \leq 1 .

(29)

However, by Theorem 3, the above inequality is true if

\sum_{j = 2}^{\infty} |\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})} ψ_{j}| |a_{j}| < 1 .

(30)

Then, the inequality (29) becomes

[\frac{j (j - β)}{1 - β}] {|ζ|}^{j - 1} \leq |\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})} ψ_{j}| .

Simple math provides

r_{1} = inf_{j \geq 2} {(|\frac{(1 - β) (4 j - 2 (2 + tan (e^{i θ}))) ψ_{j}}{(j - β) tan (e^{i θ})}|)}^{\frac{1}{j - 1}} .

The desired outcome is demonstrated. □

4. Growth and Distortion Estimates

Theorem 5.

Let

G \in C_{tan}^{σ, m, n, δ, υ}

and

|ζ| = r

. Then,

r - |\frac{tan (e^{i θ})}{(8 - 4 tan (e^{i θ})) ψ_{2}}| r^{2} \leq |G (ζ)| \leq r + |\frac{tan (e^{i θ})}{(8 - 4 tan (e^{i θ})) ψ_{2}}| r^{2} .

(31)

Proof.

Consider

\begin{matrix} |G (ζ)| & = & |ζ + \sum_{j = 2}^{\infty} a_{j} ζ^{j}| \\ \leq & r + \sum_{j = 2}^{\infty} |a_{j}| r^{j} . \end{matrix}

Since

r^{j} \leq r^{2}

for

j \geq 2

and

r < 1,

we have

|G (ζ)| \leq r + r^{2} \sum_{j = 2}^{\infty} |a_{j}| .

(32)

Similarly,

|G (ζ)| \geq r - r^{2} \sum_{j = 2}^{\infty} |a_{j}| .

(33)

Now, from (23) it is implied

\sum_{j = 2}^{\infty} (|\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}|) |ψ_{j}| |a_{j}| < 1 .

Since

|\frac{16 - 4 (2 + tan (e^{i θ}))}{tan (e^{i θ})} ψ_{2}| \sum_{j = 2}^{\infty} |a_{j}| \leq \sum_{j = 2}^{\infty} (|\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}|) |ψ_{j}| |a_{j}|,

we obtain

|\frac{8 - 4 tan (e^{i θ})}{tan (e^{i θ})} ψ_{2}| \sum_{j = 2}^{\infty} |a_{j}| < 1,

one can easily write this as

\sum_{j = 2}^{\infty} |a_{j}| < |\frac{tan (e^{i θ})}{16 - 4 (2 + tan (e^{i θ})) ψ_{2}}|,

and placing this value in (32) and (33), the necessary inequality is obtained. □

Theorem 6.

Let

G \in C_{tan}^{σ, m, n, δ, υ}

and

|ζ| = r

. Then,

1 - 2 |\frac{tan (e^{i θ})}{(8 - 4 tan (e^{i θ})) ψ_{2}}| r \leq |G^{'} (ζ)| \leq 1 + 2 |\frac{tan (e^{i θ})}{(8 - 4 tan (e^{i θ})) ψ_{2}}| r .

Proof.

Consider

\begin{matrix} |G^{'} (ζ)| & = & |1 + \sum_{j = 2}^{\infty} j a_{j} ζ^{j - 1}| \\ \leq & 1 + \sum_{j = 2}^{\infty} j |a_{j}| r^{j - 1} . \end{matrix}

Since

r^{j - 1} \leq r^{2}

for

j \geq 2

and

r < 1,

we have

|G^{'} (ζ)| \leq 1 + 2 r \sum_{j = 2}^{\infty} |a_{j}| .

(34)

Similarly,

|G^{'} (ζ)| \geq 1 - 2 r \sum_{j = 2}^{\infty} |a_{j}| .

(35)

Now, from (23) it is implied that

\sum_{j = 2}^{\infty} |\frac{4 n^{2} - 2 n (2 + tan (e^{i θ}))}{tan (e^{i θ})}| |a_{j}| < 1 .

Since

|\frac{16 - 4 (2 + tan (e^{i θ}))}{tan (e^{i θ})} ψ_{2}| \sum_{j = 2}^{\infty} |a_{j}| \leq \sum_{j = 2}^{\infty} (|\frac{4 j^{2} - 2 j (2 + tan (e^{i θ}))}{tan (e^{i θ})}|) |ψ_{j}| |a_{j}|,

we obtain

|\frac{8 - 4 tan (e^{i θ})}{tan (e^{i θ})} ψ_{2}| \sum_{j = 2}^{\infty} |a_{j}| < 1,

we have

\sum_{j = 2}^{\infty} |a_{j}| < |\frac{tan (e^{i θ})}{(8 - 4 tan (e^{i θ})) ψ_{2}}|,

setting this value in (34) and (35), we thus accomplish what is needed. □

Theorem 7.

For

G \in C_{tan}^{σ, m, n, δ, υ},

the coefficient bounds are

\begin{matrix} |a_{2}| & \leq & \frac{1}{4 ψ_{2}}, \end{matrix}

(36)

\begin{matrix} |a_{3}| & \leq & \frac{1}{12 ψ_{3}}, \end{matrix}

(37)

\begin{matrix} |a_{4}| & \leq & \frac{1}{24 ψ_{4}}, \end{matrix}

(38)

\begin{matrix} |a_{5}| & \leq & \frac{1}{40 ψ_{5}}, \end{matrix}

(39)

and

|a_{3} - ϑ a_{2}^{2}| \leq \frac{1}{12 ψ_{3}} max \{1, |\frac{3 ϑ ψ_{3} - 2 ψ_{2}^{2}}{4 ψ_{2}^{2}}|\} .

(40)

The above outcomes (36), (37), (38), and (39) are sharp for functions given below, respectively:

G_{1} (ζ) = \int_{0}^{ζ} exp \int_{0}^{ζ} \frac{\frac{tan x}{2}}{x} d x = ζ + \frac{1}{4} ζ^{2} + \frac{1}{24} ζ^{3} + \dots,

(41)

\begin{matrix} G_{2} (ζ) & = & \int_{0}^{ζ} exp \int_{0}^{ζ} \frac{\frac{tan x^{2}}{2}}{x} d x = ζ + \frac{ζ^{3}}{12} + \frac{ζ^{5}}{160} + \dots, \end{matrix}

(42)

\begin{matrix} G_{3} (ζ) & = & \int_{0}^{ζ} exp \int_{0}^{ζ} \frac{\frac{tan x^{3}}{2}}{x} d x = ζ + \frac{ζ^{4}}{24} + \frac{ζ^{7}}{504} + \dots, \end{matrix}

(43)

\begin{matrix} G_{4} (ζ) & = & \int_{0}^{ζ} exp \int_{0}^{ζ} \frac{\frac{tan x^{4}}{2}}{x} d x = ζ + \frac{ζ^{5}}{40} + \frac{ζ^{9}}{1152} + \dots, \end{matrix}

(44)

and the bound (40) is extreme for the function defined in (42).

Proof.

As

G \in C_{tan}^{σ, m, n, δ, υ},

then by the definition

\frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} ≺ \frac{2 + tan (ζ)}{2},

which can be written as

\frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} = \frac{2 + tan (ω (ζ))}{2},

where

ω (ζ)

is Schwarz function with properties that

ζ (0) = 0 and |ω (ζ)| < 1 .

Now, let

\frac{{(ζ {(D_{n, δ, υ}^{σ, m} G (ζ))}^{'})}^{'}}{{(D_{n, δ, υ}^{σ, m} G (ζ))}^{'}} = 1 + 2 a_{2} ψ_{2} ζ + (6 ψ_{3} a_{3} - 4 ψ_{2}^{2} a_{2}^{2}) ζ^{2} + (12 ψ_{4} a_{4} - 18 ψ_{2} ψ_{3} a_{2} a_{3} + 8 ψ_{2}^{3} a_{2}^{3}) ζ^{3} + \dots,

(45)

and

\begin{matrix} 1 + \frac{tan (ζ (χ))}{2} & = & 1 + \frac{1}{4} c_{1} ζ + (\frac{1}{4} c_{2} - \frac{1}{8} c_{1}^{2}) ζ^{2} + (\frac{1}{12} c_{1}^{3} - \frac{1}{4} c_{2} c_{1} + \frac{1}{4} c_{3}) ζ^{3} \\ + (- \frac{1}{16} c_{1}^{4} + \frac{1}{4} c_{1}^{2} c_{2} - \frac{1}{4} c_{3} c_{1} - \frac{1}{8} c_{2}^{2} + \frac{1}{4} c_{4}) ζ^{4} + \dots . \end{matrix}

(46)

Comparing (45) and (46), we have

\begin{matrix} a_{2} & = & \frac{1}{8 ψ_{2}} c_{1}, \end{matrix}

(47)

\begin{matrix} a_{3} & = & \frac{1}{24 ψ_{3}} c_{2} - \frac{1}{96 ψ_{3}} c_{1}^{2}, \end{matrix}

(48)

\begin{matrix} a_{4} & = & \frac{17}{4608 ψ_{4}} c_{1}^{3} - \frac{5}{384 ψ_{4}} c_{2} c_{1} + \frac{1}{48 ψ_{4}} c_{3}, \end{matrix}

(49)

\begin{matrix} a_{5} & = & - \frac{1}{80} (\frac{157}{1152 ψ_{5}} c_{1}^{4} - \frac{29}{48 ψ_{5}} c_{1}^{2} c_{2} + \frac{2}{3 ψ_{5}} c_{3} c_{1} + \frac{3}{8 ψ_{5}} c_{2}^{2} - c_{4}) . \end{matrix}

(50)

Then, by applying (11) to (47), we have

|a_{2}| \leq \frac{1}{4 ψ_{2}} .

Furthermore, applying (12) with

n = 1

to (48), we obtain

|a_{3}| \leq \frac{1}{12 ψ_{3}} .

For Equation (49), applying Lemma 2, we obtain

|a_{4}| \leq \frac{1}{24 ψ_{4}},

and from (50), we have

\begin{matrix} |a_{5}| & = & |- \frac{1}{80}| |\frac{157}{1152} c_{1}^{4} - \frac{29}{48} c_{1}^{2} c_{2} + \frac{2}{3} c_{3} c_{1} + \frac{3}{8} c_{2}^{2} - c_{4}| \\ \leq & \frac{1}{40 ψ_{5}} (by Lemma 3) . \end{matrix}

Now, from (47) and (48), we have

|a_{3} - ϑ a_{2}^{2}| = \frac{1}{24 ψ_{3}} |c_{2} - \frac{3 ϑ ψ_{3} - 2 ψ_{2}^{2}}{4 ψ_{2}^{2}} c_{1}^{2}| .

Furthermore, applying (13) to the above relation, we achieve our goals. □

Theorem 8.

Let

G \in C_{tan}^{σ, m, n, δ, υ},

then

|a_{2} a_{3} - a_{4}| \leq \frac{1}{24 ψ_{4}} .

The outcome is sharp for the function defined in (43).

Proof.

From (47)–(49), we have

|a_{2} a_{3} - a_{4}| = |(\frac{1}{768 ψ_{2} ψ_{3}} + \frac{17}{4608 ψ_{4}}) c_{1}^{3} - (\frac{1}{192 ψ_{2} ψ_{3}} + \frac{5}{384 ψ_{4}}) c_{2} c_{1} + \frac{1}{48 ψ_{4}} c_{3}|,

applying Lemma 2, we achieve the intended outcomes. □

5. Kruskal Inequality

Here, we will provide direct evidence of the inequality

|a_{j}^{p} - a_{2}^{p (j - 1)}| \leq 2^{p (j - 1)} - j^{p},

over the class

C_{tan}^{σ, m, n, δ, υ}

for the choice of

j = 4,

p = 1

, and for

j = 5,

p = 1

. For a class of univalent functions as a whole, Kruskal introduced and demonstrated this inequality in [23]. For some recent investigations on Kruskal inequality, we refer the readers to see [15,24].

Theorem 9.

If

G \in C_{tan}^{σ, m, n, δ, υ},

then

|a_{4} - a_{2}^{3}| \leq \frac{1}{24 ψ_{4}} .

The outcome is sharp for the function defined in (43).

Proof.

From (47) and (49), we have

|a_{4} - a_{2}^{3}| = |(\frac{17}{4608 ψ_{4}} - \frac{1}{512 ψ_{2}^{3}}) c_{1}^{3} - \frac{5}{384 ψ_{4}} c_{2} c_{1} + \frac{1}{48 ψ_{4}} c_{3}|,

by applying Lemma 2, we obtain

|a_{4} - a_{2}^{3}| \leq \frac{1}{24 ψ_{4}} .

□

Theorem 10.

If

G \in C_{tan}^{σ, m, n, δ, υ},

then

|a_{5} - a_{2}^{4}| \leq \frac{1}{40 ψ_{5}} .

The outcome is sharp for the function defined in (44).

Proof.

From (47) and (50), we have

\begin{matrix} |a_{5} - a_{2}^{4}| & = & |- \frac{1}{80 ψ_{5}}| |((\frac{157}{1152} - \frac{ψ_{5}}{4096 ψ_{2}^{4}}) c_{1}^{4} - \frac{29}{48} c_{1}^{2} c_{2} + \frac{2}{3} c_{3} c_{1} + \frac{3}{8} c_{2}^{2} - c_{4})| \\ \leq & \frac{1}{40 ψ_{5}} (by Lemma 3) . \end{matrix}

□

6. Logarithmic Coefficients for the Family $C_{tan}^{σ, m, n, δ, υ}$

The logarithmic coefficients of

D_{n, δ, υ}^{σ, m} G \in S

, denoted by

κ_{n} = κ_{n} (G),

are defined by the following series expansion:

log \frac{D_{n, δ, υ}^{σ, m} G (ζ)}{ζ} = 2 \sum_{j = 1}^{\infty} κ_{j} ζ^{j} .

For the function

D_{n, δ, υ}^{σ, m} G

, given by (5), the logarithmic coefficients are as follows:

\begin{matrix} κ_{1} & = & \frac{1}{2} ψ_{2} a_{2}, \end{matrix}

(51)

\begin{matrix} κ_{2} & = & \frac{1}{2} (ψ_{3} a_{3} - \frac{1}{2} ψ_{2}^{2} a_{2}^{2}), \end{matrix}

(52)

\begin{matrix} κ_{3} & = & \frac{1}{2} (ψ_{4} a_{4} - ψ_{2} ψ_{3} a_{2} a_{3} + \frac{1}{3} ψ_{2}^{3} a_{2}^{3}), \end{matrix}

(53)

\begin{matrix} κ_{4} & = & \frac{1}{2} (ψ_{5} a_{5} - ψ_{2} ψ_{4} a_{2} a_{4} - ψ_{2}^{2} ψ_{3} a_{2}^{2} a_{3} - \frac{1}{2} ψ_{3}^{2} a_{3}^{2} - \frac{1}{4} ψ_{2}^{4} a_{2}^{4}) . \end{matrix}

(54)

Theorem 11.

If

G

has the form (1) and belongs to

C_{tan}^{σ, m, n, δ, υ},

then

\begin{matrix} |κ_{1}| & \leq & \frac{1}{8 ψ_{2}}, \\ |κ_{2}| & \leq & \frac{1}{24 ψ_{3}}, \\ |κ_{3}| & \leq & \frac{1}{48 ψ_{4}}, \\ |κ_{4}| & \leq & \frac{1}{80 ψ_{5}} . \end{matrix}

The bounds of Theorem 11 are precise and cannot be improved further.

Proof.

Now, from (51)–(54) and (47)–(50), we obtain

\begin{matrix} κ_{1} & = \frac{1}{16 ψ_{2}} c_{1}, \end{matrix}

(55)

\begin{matrix} κ_{2} & = \frac{1}{48 ψ_{3}} c_{2} - \frac{7}{768 ψ_{2}^{2}} c_{1}^{2}, \end{matrix}

(56)

\begin{matrix} κ_{3} & = \frac{13}{4608 ψ_{2}^{3}} c_{1}^{3} - \frac{7}{768 ψ_{2} ψ_{3}} c_{2} c_{1} + \frac{1}{96 ψ_{4}} c_{3}, \end{matrix}

(57)

\begin{matrix} κ_{4} & = - \frac{1561}{1474 560 ψ_{2}^{4}} c_{1}^{4} + \frac{413}{92 160 ψ_{2}^{2} ψ_{3}} c_{1}^{2} c_{2} - \frac{7}{1280 ψ_{2} ψ_{4}} c_{3} c_{1} - \frac{1}{360 ψ_{2}^{2}} c_{2}^{2} + \frac{1}{160 ψ_{5}} c_{4}, \end{matrix}

(58)

|κ_{1}| \leq \frac{1}{8 ψ_{2}} .

From (56) and using (12), we obtain

|κ_{2}| \leq \frac{1}{24 ψ_{3}} .

Applying Lemma 2 to Equation (57), we obtain

|κ_{3}| \leq \frac{1}{48 ψ_{4}} .

Furthermore, using Lemma 3 to (58) we obtain

|κ_{4}| \leq \frac{1}{80 ψ_{5}} .

Proof for sharpness: since

\begin{matrix} log \frac{D_{n, δ, υ}^{σ, m} G_{1} (ζ)}{ζ} & = & 2 \sum_{j = 2}^{\infty} κ (G_{1}) ζ^{j} = \frac{1}{4 ψ_{2}} ζ + \dots, \\ log \frac{D_{n, δ, υ}^{σ, m} G_{2} (ζ)}{ζ} & = & 2 \sum_{j = 2}^{\infty} κ (G_{2}) ζ^{j} = \frac{1}{12 ψ_{3}} ζ^{2} + \dots, \\ log \frac{D_{n, δ, υ}^{σ, m} G_{3} (ζ)}{ζ} & = & 2 \sum_{j = 2}^{\infty} κ (G_{3}) ζ^{j} = \frac{1}{24 ψ_{4}} ζ^{3} + \dots, \\ log \frac{D_{n, δ, υ}^{σ, m} G_{4} (ζ)}{ζ} & = & 2 \sum_{j = 2}^{\infty} κ (G_{4}) ζ^{j} = \frac{1}{40 ψ_{5}} ζ^{4} + \dots, \end{matrix}

it follows that these inequalities are obtained for the functions

G_{n} (ζ)

for

n = 1, 2, 3

, and 4 defined in (41)–(44). □

Theorem 12.

Let

G \in C_{tan}^{σ, m, n, δ, υ} .

Then, for complex number

λ,

we have

|κ_{2} - λ κ_{1}^{2}| \leq \frac{1}{24 ψ_{3}} max \{1, \frac{|3 λ ψ_{3} - ψ_{2}^{2}|}{8 ψ_{2}^{2}}\} .

The result is the best possible.

Proof.

From (55) and (56), we have

|κ_{2} - λ κ_{1}^{2}| = \frac{1}{48 ψ_{3}} |c_{2} - \frac{7 ψ_{2}^{2} + 3 ψ_{3} λ}{16 ψ_{2}^{2}} c_{1}^{2}| .

Applying (13) to the preceding equation yields the desired outcome. □

Theorem 13.

If

G \in C_{tan}^{σ, m, n, δ, υ},

then

|κ_{1} κ_{2} - κ_{3}| \leq \frac{1}{48 ψ_{4}} .

The outcome is extremal.

Proof.

From (55)–(57), we have

|κ_{1} κ_{2} - κ_{3}| = |\frac{125}{36 864 ψ_{2}^{3}} c_{1}^{3} - \frac{1}{96 ψ_{2} ψ_{3}} c_{2} c_{1} + \frac{1}{96 ψ_{4}} c_{3}|,

applying Lemma 2, we achieve the intended outcomes. □

7. Conclusions

In the present investigation, we investigated a new subclass of holomorphic convex functions associated with tangent functions. We focused our attention on deriving necessary and sufficient conditions based on the convolution operator, radius of convexity, growth and distortion approximation, sharp initial four coefficient bounds, sharp Fekete–Szegö approximation, and sharp Kruskal inequality for functions belonging to this class. Hopefully, this work will open new directions for research in GFT and related areas.

Author Contributions

Conceptualization S.M.E.-D.; Methodology, L.-I.C.; Formal analysis, S.M.E.-D. and L.-I.C.; Investigation, S.M.E.-D. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

No new data were created or analyzed in this study.

Conflicts of Interest

The authors declare no competing interests

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El-Deeb, S.M.; Cotîrlă, L.-I. Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series. Mathematics 2024, 12, 1691. https://doi.org/10.3390/math12111691

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El-Deeb SM, Cotîrlă L-I. Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series. Mathematics. 2024; 12(11):1691. https://doi.org/10.3390/math12111691

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El-Deeb, Sheza M., and Luminita-Ioana Cotîrlă. 2024. "Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series" Mathematics 12, no. 11: 1691. https://doi.org/10.3390/math12111691

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Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series

Abstract

1. Introduction

2. Set of Lemmas

3. Main Results

4. Growth and Distortion Estimates

5. Kruskal Inequality

6. Logarithmic Coefficients for the Family $C_{tan}^{σ, m, n, δ, υ}$

7. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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Sufficiency Conditions for a Class of Convex Functions Connected with Tangent Functions Associated with the Combination of Babalola Operators and Binomial Series

Abstract

1. Introduction

2. Set of Lemmas

3. Main Results

4. Growth and Distortion Estimates

5. Kruskal Inequality

6. Logarithmic Coefficients for the Family C tan σ , m , n , δ , υ

7. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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6. Logarithmic Coefficients for the Family $C_{tan}^{σ, m, n, δ, υ}$