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1. Introduction

Suppose $f \in A$ , where A is the set of analytic functions having the form

$f (z) = z + \sum_{m = 2}^{\infty} a_{m} z^{m},$

E = {z : | z | < 1}

. Then, in geometric function theory, E is replaced with an arbitrary domain by Riemann mapping theorem [1].

Let us consider P as the class of the positive real part given by

$p (z) = 1 + \sum_{m = 1}^{\infty} a_{m} z^{m},$

such that

ℜ (p (z)) > 0

According to [2], the definition of $U C V$ is

$|\frac{z f^{^{″}} (z)}{f^{^{″}} (z)}| < ℜ (1 + \frac{z f^{^{''}} (z)}{f^{^{'}} (z)}), z \in E .$

Similarly, any convex function having the property that the image curve of any circular arc

γ

given by

f (γ)

is a convex arc; then, for every circular arc,

γ

, which belongs to E with center

ξ

also in E is called uniformly convex.

According to [2], the definition of $U S T$ is

(1) $|\frac{z f^{'} (z)}{f (z)} - 1| < ℜ (\frac{z f^{^{'}} (z)}{f (z)}), z \in E .$

We can also define the class of

U S T

by the Alexander relation if

z f^{^{'}} \in U S T

, then

f \in U C V

. Goodman [3] introduced these classes, and several other researchers have also worked on these classes in various repects.

If any function w with conditions $w (0) = 0$ and $| w (z) | < 1$ exists, then it is called a Schwartz function. We can relate any two functions f and g using the Schwartz function w such that $f (z) = g (w (z))$ ; in this case, it is called “f is subordinate to g” and can be written as $f ≺ g$ . Similarly, if g is univalent in E, then in particular $f (0) = g (0)$ and $f (E) \subset g (E)$ .

The conic region $Ω_{k}$ with $k \in [0, \infty)$ is studied by [4]:

(2) $Ω_{k} = [u + i v : k \sqrt{{(u - 1)}^{2} + v^{2}} < u] .$

For any fixed k,

Ω_{k}

denotes the set of conic regions successively bounded by the imaginary axis

(k = 0)

, a parabola

v^{2} = u - 1

(k = 1)

, and the right branch of a hyperbolic

(0 < k < 1)

. For

k > 1

, it represents the interior of the ellipse, where the domain becomes a bounded domain.

In our condition, we taking $k \in [0, 1]$ . Then, using $Ω_{k}$ , our functions are $p_{k} (z)$ , where k belongs to the closed interval $[0, 1]$ , which plays the role of extremal functions mapping in E onto $Ω_{k}$ :

(3) $p_{k} (z) = \{\begin{matrix} \frac{1 + z}{1 - z}, (k = 0) \\ 1 + \frac{2}{π^{2}} {(log \frac{1 + \sqrt{z}}{1 - \sqrt{z}})}^{2}, (k = 1) \\ 1 + \frac{2}{1 - k^{2}} {sinh}^{2} [(\frac{2}{π} arccos k) arctan h \sqrt{z}], (0 < k < 1) \end{matrix} .$

These functions are in class P and univalent in E. Using the subordination technique, the class

P (p_{k})

was introduced in the following form.

Suppose $p (z) \in A$ with the condition $p (0) = 1$ . Then, $p (z)$ belongs to $P (p_{k})$ iff $p ≺ p_{k}$ in E. Furthermore, $p_{k} (z)$ is represented by Equation (3).

The generalized conic domain $Ω_{k, β}$ is given by

$Ω_{k, β} = (1 - β) Ω_{k} + β,$

with the extremal function

$p_{k, β} (z) = (1 - β) p_{k} + β, w i t h (0 \leq β < 1, k \in [0, 1]) .$

The function

p \in P (p_{k, β})

p (z) ≺ p_{k, β} (z)

in E.

Similarly, it is known from [5] that $P (p_{k, β})$ is a convex set. So,

$P (p_{k}) \subset P (\frac{k}{k + 1}) \subset P .$

For

p \in P (p_{k})

, we also know that

$| arg p (z) | \leq σ \frac{π}{2},$

with

(4) $σ = \frac{2}{π} arctan \frac{1}{k} .$

Thus,

p (z) = h^{σ} (z)

, with

h \in P

. Similarly,

$P (p_{k, β}) \subset P (\frac{k + β}{k + 1}) \subset P .$

The starlike functions w.r.t. symmetrical points $S_{s}^{*}$ was introduced by Sakaguchi [6]. A necessary and sufficient condition of this class was studied in [6] and is represented as

$(\frac{2 z f^{'} (z)}{f (z) - f (- z)}) \in P, z \in E .$

The convex functions w.r.t. symmetrical points $C_{s}$ was introduced by Das and Singh [7]. A necessary and sufficient condition of this class was studied in [7] and is represented as

$\frac{2 {(z f^{'} (z))}^{^{'}}}{{(f (z) - f (- z))}^{^{'}}} \in P, z \in E,$

and we know that

f \in C_{s}

⇔

z f^{^{'}} \in S_{s}^{*}

[7].

According to [8], suppose that $f \in A$ . Then f may be in the class $k - S T_{s} (β)$ iff,

$\frac{2 z f^{'} (z)}{f (z) - f (- z)} \in P (p_{k, β}), z \in E .$

Moreover, an integral operator

ℑ_{c, a}

, defined by [9], is

$ℑ_{c, a} f (z) = z + \sum_{k = 2}^{\infty} {(\frac{1 + a}{k + a})}^{c} b_{k} z^{k}, z \in E .$

2. Definitions

In this section, we introduce the following new subclasses of univalent function $k - S T_{s} (p, β)$ and $k - U K_{s} (p, β)$ .

Definition 1.

Consider $f \in A$ . Then f belongs to class of $k - S T_{c} (p, β)$ iff

$\frac{(2 + c) z {(ℑ_{c, a} f)}^{'} (z)}{ℑ_{c, a} (f) (z) - ℑ_{c, a} (f) (- z)} - \frac{c}{2} \in P (p_{k, β}),$

where z belongs to E.

Definition 2.

Suppose a function f belongs from the class of analytic functions A. Then f is in the class $k - U C V_{c} (p, β)$ iff $z f^{'}$ belongs to $k - S T_{c} (p, β)$ .

Definition 3.

Let f be an analytic function of class A. Then f belongs to $k - U K_{c} (p, β)$ iff there exists g which is in class $k - S T_{c} (p, β)$ . Thus,

$\frac{(2 + c) z {(ℑ_{c, a} f)}^{'} (z)}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} - \frac{c}{2} \in P (p_{k, β}),$

where z is in E.

3. Preliminary Results

Our main results depend on the following lemmas:

Lemma 1.

[10] Consider any two functions. Let $q (z)$ and $p (z)$ be convex and analytic functions, respectively, in E with $q (0) = 1 = p (0)$ , and function $h_{*} : E$ $\to C$ for $ℜ (f h_{*} (z)) > 0$ , whenever

$(h_{*} (z) z p^{'} (z) + p (z)) ≺ q (z), z \in E .$

Then, $p (z) ≺ q (z)$ , where $z \in E .$

Lemma 2.

[8] Consider two analytic functions $N (z)$ , $D (z)$ in E such that $N (0) = 0 = D (0)$ . Suppose that D is in the class of starlike functions, that is, $S^{*}$ for $z \in E$ , then $\frac{N^{*} (z)}{D^{*} (z)} \in P (p_{k, β})$ implies that $\frac{N (z)}{D (z)} \in P (p_{k, β})$ for $z \in E$ .

Lemma 3.

[4] For any two complex numbers $γ_{2}, δ_{2}$ with $γ_{2} \neq 0$ and $ℜ (\frac{γ_{2} k}{k + 1}) + δ_{2} > β$ , the analytic function $h_{*} (z)$ ∈E, we have

(5) $(h_{*} (z) + \frac{z h_{*}^{'} (z)}{γ_{2} h_{*} (z) + δ_{2}}) ≺ p_{k, β} (z) .$

If $q_{k, β}$ is the analytic solution of equation

$p_{k, β} (z) = (\frac{z q_{k, β}^{'} (z)}{γ_{2} q_{k, β} (z) + δ_{2}} q_{k, β} (z)),$

then $q_{k, β}$ is a univalent function whenever

$h_{*} ≺ q_{k, β} ≺ p_{k, β} .$

Hence, $q_{k, β} (z)$ is said to be the best dominant of Equation (5).

4. Main Results

In this section, we study certain properties of our newly defined subclasses of univalent function $k - S T_{s} (p, β)$ and $k - U K_{s} (p, β)$ . The desired results are also compared with existing results.

Theorem 1.

(6) $Ψ (z) = \frac{1}{2} [- ℑ_{c, a} f (- z) + ℑ_{c, a} f (z)]$

is an odd $S^{*}$ function of order $β_{1} = \frac{k + β}{k + 1}$ in E, where $ℑ_{c, a} f (z)$ is in the class of k-starlike related with symmetrical points of $(p, β)$ , then $Ψ (z) \in k - S T (p, β)$ .

Proof. Let,

$Ψ (z) = \frac{1}{2} [- ℑ_{c, a} f (- z) + ℑ_{c, a} f (z)] .$

Then, after simplification

$\frac{z Ψ^{'} (z)}{Ψ (z)} = \frac{1}{2 + c} [p_{2} (z) + p_{1} (z)] + \frac{c}{2 + c} \in P (p_{k, β}) .$

Here,

\frac{z Ψ^{'} (z)}{Ψ (z)} \in P (p_{k, β})

because

P (p_{k, β})

is a convex set. Therefore,

$Ψ (z) \in k - S T (β) .$

□

Theorem 2.

Let $ℑ_{c, a} f (z) \in k - S T_{s} (p, β)$ . Then, with $z = e^{i θ}$ , $0 \leq θ_{1} < θ_{2} \leq 2 π, 1 > β > 0$ and $1 \geq k \geq 0$ , we can say

$\int_{θ_{1}}^{θ_{2}} ℜ [\frac{{(z {(ℑ_{c, a} f)}^{'} (z))}^{'}}{{(ℑ_{c, a} f)}^{'} (z)}] d θ > - σ π + 2 {cos}^{- 1} [\frac{2 (1 - β)}{1 - (1 - 2 β) r^{2}}] + β_{1} (θ_{2} - θ_{1}),$

where $σ = \frac{π}{2} arctan (\frac{1}{k})$ and $β_{1} = \frac{k + β}{k + 1}$ .

Proof.

Suppose,

$\frac{{[ℑ_{c, a} f]}^{'}}{Ψ^{'}} \in P (p_{β, k}),$

$Ψ (z) = \frac{1}{2} (- ℑ_{c, a} f (- z) + ℑ_{c, a} f (z)),$

where

Ψ \in k - U C V (p, β)

and

C (β, p) \supset k - U C V (β, p)

Therefore,

${[ℑ_{c, a} f]}^{'} = {(Ψ^{'})}^{(- β_{1} + 1)} h^{σ} (z),$

with

$h \in P (p, β), Ψ_{1} \in C, z = e^{i θ}, 0 \leq θ_{1} < θ_{2} \leq 2 π a n d 0 \leq r < 1,$

takes the form

$\begin{matrix} \int_{θ_{1}}^{θ_{2}} ℜ [\frac{{(z {(ℑ_{c, a} f)}^{'} (z))}^{'}}{{(ℑ_{c, a} f)}^{'} (z)}] d θ = (1 - β_{1}) \int_{θ_{1}}^{θ_{2}} ℜ [\frac{{(z Ψ^{'} (z))}^{'}}{Ψ^{'} (z)}] d θ \\ + σ \int_{θ_{1}}^{θ_{2}} ℜ [\frac{2 h^{'} (z)}{h (z)}] d θ + β_{1} (θ_{2} - θ_{1}) . \end{matrix}$

Let us consider, for

h \in P (p, β)

$\frac{\partial}{\partial θ} arg h (r e^{i θ}) = \frac{\partial}{\partial θ} ℜ (- i ln (r e^{i θ})),$

$\frac{\partial}{\partial θ} arg h (r e^{i θ}) = ℜ (r e^{i θ} \frac{h^{'} r e^{i θ}}{h r e^{i θ}}) .$

Therefore,

$\int_{θ_{1}}^{θ_{2}} ℜ [\frac{r e^{i θ} h^{'} r e^{i θ}}{h r e^{i θ}}] d θ = arg h (r e^{i θ_{2}}) - arg h (r e^{i θ_{1}}),$

and

$max_{h \in P (p, β)} |\int_{θ_{1}}^{θ_{2}} ℜ [\frac{r e^{i θ} h^{'} r e^{i θ}}{h r e^{i θ}}] d θ| = max_{h \in P (p, β)} |arg h (r e^{i θ_{2}}) - arg h (r e^{i θ_{1}})| .$

So, from above equations

$p (z) = \frac{1}{- β + 1} (- β + h (z)), a s p \in P (p_{k, β}) .$

With known results

| z | = r < 1

and

$|p (z) - \frac{1 + r^{2}}{1 - r^{2}}| \leq \frac{2 r}{1 - r^{2}},$

we can write

$\frac{2 (1 - β) r}{1 - r^{2}} \geq |h (z) - \frac{1 + (1 - 2 β) r^{2}}{1 - r^{2}}| .$

An Apollonius circle encloses all the values of h. Its diameter is a line-segment which is the combination of points from $\frac{1 + (- 2 β + 1) r}{1 + r}$ to $\frac{1 + (1 - 2 β) r}{1 - r}$ , and its radius is $\frac{2 (1 - β) r}{1 - r^{2}}$ . Therefore, $| arg h (z) |$ approaches its max. value wherever a ray passing through the origin is tangent to the circle, i.e.,

(7) $arg h (z) = \pm {sin}^{- 1} [\frac{2 (- β + 1) r}{1 - (- 2 β + 1) r^{2}}] .$

We can observe from Equation (7) that

$max_{h \in P (β, p)} |\int_{θ_{1}}^{θ_{2}} ℜ [\frac{r e^{i θ} h^{'} r e^{i θ}}{h r e^{i θ}}] d θ| \leq 2 {sin}^{- 1} (\frac{2 (1 - β) r}{1 - (1 - 2 β) r^{2}}),$

(8) $max_{h \in P (p, β)} |\int_{θ_{1}}^{θ_{2}} ℜ [\frac{r e^{i θ} h^{'} r e^{i θ}}{h r e^{i θ}}] d θ| = π - 2 {cos}^{- 1} (\frac{2 (1 - β) r}{1 - (1 - 2 β) r^{2}}),$

and for

Ψ_{1} \in C

(9) $\int_{θ_{1}}^{θ_{2}} ℜ [1 + r e^{i θ} \frac{Ψ_{1}^{''} (r e^{i θ})}{Ψ_{1}^{'} (r e^{i θ})}] d θ \geq 0 .$

Using Equations (7)–(9), we obtain

$\int_{θ_{1}}^{θ_{2}} ℜ [\frac{{(z {(ℑ_{c, a} f)}^{'} (z))}^{'}}{{(ℑ_{c, a} f)}^{'} (z)}] d θ > - σ π + 2 {cos}^{- 1} [\frac{2 (1 - β)}{1 - (1 - 2 β) r^{2}}] + β_{1} (θ_{2} - θ_{1}) .$

□

Theorem 3.

Let $ℑ_{c, a} f (z) \in k - S T_{s} (p, β)$ ; then its integral representation is

${(ℑ_{c, a} f (z))}^{'} = \frac{1}{2 + c} p (z) exp \int_{0}^{z} \frac{1}{t (2 + c)} (- p (- t) + p (t) - (2 + c)) d t,$

where $z \in E$ and $p \in P (p_{k, β})$ .

Proof.

Let $ℑ_{c, a} f$ be taken from $k - S T_{s} (p, β)$ ; then

$p (z) = \frac{(2 + c) z {(ℑ_{c, a} f (z))}^{'}}{ℑ_{c, a} f (z) - ℑ_{c, a} f (- z)} - \frac{c}{2}, p \in P (p, β) .$

$\frac{{[ℑ_{c, a} f (z) - ℑ_{c, a} f (- z)]}^{'}}{- ℑ_{c, a} f (- z) + ℑ_{c, a} f (z)} - \frac{1}{z} = \frac{1}{(2 + c) z} [p (z) - p (- z) - (2 + c)] .$

After simplification, we can get

$(2 + c) {(ℑ_{c, a} f (z))}^{'} \frac{1}{p (z)} = exp \int_{0}^{z} \frac{1}{(2 + c) t} [p (t) - p (- t) - (2 + c)] d t .$

By putting

F^{'} (z) = {(ℑ_{c, a} f (z))}^{'}

, we obtain

$F^{'} (z) = \frac{p (z)}{2 + s} exp \int_{0}^{z} \frac{1}{(2 + c) t} [p (t) - p (- t) - (2 + c)] d t .$

□

Special case:

If $c = 0,$ one can get the result in the form

$\frac{p (z)}{2} exp \int_{0}^{z} \frac{1}{2 t} [p (t) - p (- t) - 2] d t = f^{'} (z),$

proved by K. I. Noor [8].

Theorem 4.

Let $ℑ_{c, a} g (z) \in k - S T_{s} (p, β)$ and $m = 1, 2, 3, 4, \dots, G$ , where

(10) $G (z) = \frac{m + c + 1}{2 z^{(m + c)}} \int_{0}^{z} t^{(m + c - 1)} [ℑ_{c, a} g (t) - ℑ_{c, a} g (- t)] d t .$

Then $G (z) \in k - S T (p, β) .$

Proof.

Let

$J (z) = \int_{0}^{z} t^{(m + c - 1)} [\frac{1}{2} [ℑ_{c, a} g (t) - ℑ_{c, a} g (- t)]] d t .$

since

ℑ_{c, a} g (z) \in k - S T_{s} (p, β)

\frac{1}{2} [ℑ_{c, a} g (t) - ℑ_{c, a} g (- t)] \in k - S T (p, β) \subset S^{*} (β_{1}) \subset S^{*}

and

β_{1} = \frac{k + β}{k + 1}

. Therefore, using [8], we can say that

J (z)

is a function and

(1 + m)

-valently starlike

(S^{*})

in E. So Equation (10) can be written as,

$z^{(m + c)} G (z) = (m + c + 1) \int_{0}^{z} t^{(m + c - 1)} [\frac{1}{2} [ℑ_{c, a} g (t) - ℑ_{c, a} g (- t)]] d t,$

$z^{(m + c)} G (z) = (m + c + 1) J (z) .$

After simplification,

(11) $z \frac{G^{'} (z)}{G (z)} = \frac{N (z)}{D (z)} = \frac{z J^{'} (z) - (m + c) J (z)}{J (z)} .$

As $D (0) = 0$ and $N (0) = 0$ . Furthermore, $D (z)$ is $(1 + m)$ -valently $S^{*}$ . Let $\frac{N (z)}{D (z)} = h (z)$ , then

$h^{'} (z) D (z) + h (z) D^{'} (z) = N^{'} (z) .$

Therefore,

$h (z) + \frac{z h^{z}}{h_{\circ} (z)} = \frac{N^{'} (z)}{D^{'} (z)} .$

Let, $h_{\circ} (z) = \frac{z D^{'} (z)}{D (z)} \in P (p_{k, β})$ and $H_{\circ} (z) = \frac{1}{h_{\circ} (z)} \in P (p_{k, β})$ . Then,

$\frac{N^{'} (z)}{D^{'} (z)} = h (z) + H_{\circ} (z) (z h^{z}) .$

From Equation (11), we have

$\frac{N (z)}{D (z)} = \frac{z J^{'} (z) - (m + s) J (z)}{J (z)} .$

This implies

$\frac{N^{'} (z)}{D^{'} (z)} = [\frac{{(z J^{'})}^{'}}{J^{'} (z)} - (m + c)] \in P (p_{k, β}) .$

Using Lemma (2), we can say

$\frac{N (z)}{D (z)} = \frac{z G (z)}{G (z)} \in P (p_{p, β}), z \in E .$

Therefore, $G \in k - S T (p, β)$ in E. □

Theorem 5.

Let $ℑ_{c, a} f, ℑ_{c, a} g \in k - S T_{s} (p, β)$ , and $ℑ_{c, a} F (z)$ be defined as

(12) $\begin{matrix} ℑ_{c, a} F (z) = (γ + s + \frac{1}{δ}) z^{(1 - c - \frac{1}{δ})} \int_{0}^{z} t^{(\frac{1}{δ} + c - 2)} {[\frac{ℑ_{c, a} f (t) - ℑ_{c, a} f (- t)}{2}]}^{\frac{1}{1 + γ}} \\ [\frac{ℑ_{c, a} g (t) - ℑ_{c, a} g (- t)}{2}] d t, \end{matrix}$

where $z \in E$ , $0 < δ$ , $c \geq 0$ , $γ = 0$ and $\frac{k (1 + γ)}{k + 1} + (c + \frac{1}{δ} - 1) > β$ . Then $ℑ_{c, a} F (z) \in k - s t a r l i k e$ with $(p, β)$ where $z \in E$ . If $z = ℑ_{c, a} g (z)$ and $γ = c = 0$ , then we can get the Bernardi operator in its generalized form [11]. For $ℑ_{c, a} g (z) = z$ , $γ = 0$ , $δ = \frac{1}{2}$ and $c = 0$ , we can get an integral operator introduced by Libra that preserves geometric properties of close-to-convexity, convexity, and starlikeness [12,13].

Proof.

Let, $\frac{ℑ_{c, a} f (z) - ℑ_{c, a} f (- z)}{2} = Ψ_{1} (z)$ and $\frac{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)}{2} = Ψ_{2} (z)$ . Then, $Ψ_{1}, Ψ_{2} \in k - S T (p, β)$ in E, and we can write Equation (12) as

(13) $F_{1} = ℑ_{c, a} F (z) = (γ + c + \frac{1}{δ}) z^{(1 - c - \frac{1}{δ})} \int_{0}^{z} t^{(\frac{1}{δ} + c - 2)} {[Ψ_{1} (t)]}^{\frac{1}{1 + γ}} [Ψ_{2} (t)] d t .$

p (z) = \frac{z F_{1}^{'} (z)}{F_{1} (z)}

, then after simplification, we have

(14) $\frac{γ}{1 + γ} \frac{z Ψ_{1}^{'}}{Ψ_{1} (z)} + \frac{1}{1 + γ} \frac{z Ψ_{2}^{'}}{Ψ_{2} (z)} = p (z) + \frac{z p^{'} (z)}{(1 + γ) p (z) + (c + \frac{1}{δ} - 1)} .$

Since

Ψ_{1}

and

Ψ_{2} \in k - S T (p, β)

, which implies that

\frac{z Ψ_{1}^{'}}{Ψ_{1}}

and

\frac{z Ψ_{2}^{'}}{Ψ_{2}}

∈

P (p_{k, β})

in E, and

P (p_{k, β})

also belongs to convex set. It follows that

(15) $(\frac{γ}{1 + γ} \frac{z Ψ_{1}^{'}}{Ψ_{1} (z)} + \frac{1}{1 + γ} \frac{z Ψ_{2}^{'}}{Ψ_{2} (z)}) \in P (p_{k, β}), z \in E .$

Similarly, Equations (14) and (15) give

$(p (z) + \frac{z p^{'} (z)}{(1 + γ) p (z) + (c + \frac{1}{δ} - 1)}) ≺ p_{k, β} (z) .$

Using Lemma (3), we can also say

$p (z) ≺ q_{k, β} (z) ≺ p_{k, β} (z) .$

Hence,

F_{1} \in k - S T (p, β)

. □

5. The Class $k - {UK}_{s} (p, β)$

In this work, we study certain properties of $k - U K_{s} (p, β)$ , which consists of $k - U K$ functions with symmetrical points of order $β$ [14].

Theorem 6.

Let $ℑ_{c, a} f \in k - U K_{s} (k, β)$ and $F_{1} (z) = ℑ_{c, a} F$ be defined by

(16) $F_{1} (z) = \frac{m + c + 1}{2 z^{(m + c)}} \int_{0}^{z} t^{(m + c - 1)} [ℑ_{c, a} f (t) - ℑ_{c, a} f (- t)] d t .$

Then $F_{1} (z)$ belongs to the class $k - U K_{s} (p, β)$ in E.

Proof.

Since $ℑ_{c, a} f \in k - U K_{s} (k, β)$ , we have

$\frac{2 z ℑ_{c, a} f^{'} (z)}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} \in P (p_{k, β}),$

and

$ℑ_{c, a} g \in k - S T_{s} (k, β) \subset S_{s}^{*} (k β_{1}) .$

Let

G_{1} = \frac{ℑ_{c, a} g_{1} (z) - ℑ_{c, a} g_{1} (- z)}{2}

be defined by Theorem 4, also

g_{1} \in k - S T (p, β)

and

G_{1} \in k - S T_{s} (p, β) \subset S_{s}^{*} (p, β_{1})

. Similarly,

G = z G_{1}^{'}

, then

$G^{'} = \frac{1}{2} {[z g_{1} (z) - (- z) g (- z)]}^{'},$

$G \in k - U C V_{s} (p, β),$

$g = z ℑ_{c, a} g_{1}^{'},$

and

$g \in C_{s} (p, β_{1}) .$

From Equation (16), we have

$\frac{2}{m + c + 1} [(m + c) z^{(m + c - 1)} F_{1} + z^{(m + c)} F_{1}^{'}] = z^{(m + c - 1)} [ℑ_{c, a} f (z) - ℑ_{c, a} f (- z)],$

which implies that

$\frac{2 F_{1}^{'}}{G_{1}^{'}} = \frac{N (z)}{D (z)} .$

We can conclude that

D (0) = N (0) = 0

, also

g \in C_{s} (p, β_{1})

$\frac{{(z D^{'} (z))}^{'}}{D^{'} (z)} = (m + c) + \frac{{[z {ℑ_{c, a} g_{1} (z) - ℑ_{c, a} g_{1} (- z)}^{'}]}^{'}}{{[ℑ_{c, a} g_{1} (z) - ℑ_{c, a} g_{1} (- z)]}^{'}},$

and

$\frac{{(z D^{'} (z))}^{'}}{D^{'} (z)} = (m + c) + h_{1}, h_{1} \in P (p, β_{1}) .$

Since

P (p, β_{1})

belongs to the convex set, where

D \in C_{s} (p, β_{1}) \subset S^{*} (p, β_{1})

in E [8]. Therefore,

$\frac{N (z)}{D (z)} = \frac{2 F_{1}^{'}}{G_{1}^{'}} \in P (p_{k, β}), f o r z \in E .$

Hence,

F_{1} (z)

∈

k - U K_{s} (p, β)

in E. □

Theorem 7.

Let us consider,

$(\frac{(2 + c) z ℑ_{c, a} f^{'} (z)}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} - \frac{c}{2}) ≺ p_{k, β} (z)$

in E, and

(17) $F_{1} (z) = \frac{1}{1 + m} z^{(1 - m)} {[z^{m} ℑ_{c, a} f (z)]}^{'},$

where $m = 1, 2, 3, 4, \dots$ . Thus, $F_{1} \in K_{s} (p, β_{1})$ for $| z | < r_{1}$ , with

(18) $r_{1} = \frac{1 + m - \frac{c}{2}}{(2 - β) + \sqrt{{(2 - β)}^{2} - (1 + m - \frac{c}{2}) (- m - 2 β_{1} + 1 + \frac{c}{2})}},$

where

$β_{1} = \frac{k + β}{k + 1} .$

Proof.

For $p \in P (p, α)$ with $1 > α \geq 0$ , we require the following results [15]:

(19) $\frac{1 + (1 - 2 α) r}{1 - r} \geq | p (z) | \geq \frac{1 - (1 - 2 α) r}{1 + r},$

with

(20) $\frac{2 [ℜ (p (z)) - α] r}{1 - r^{2}} \geq | p^{'} (z) | .$

Since

ℑ_{c, a} f \in k - U K_{s} (p, β)

, ∃

ℑ_{c, a} g \in S_{s}^{*} (p, β_{1})

, such that, for

z \in E

$[\frac{(2 + c) z ℑ_{c, a} f^{'} (z)}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} - \frac{c}{2}] = p (z),$

where

$p \in P_{k, β} \subset P (α), a n d α = \frac{k}{k + 1} .$

From Equation (17), we have

$F_{1} (z) = \frac{1}{m + 1} z^{(1 - m)} [m z^{(m - 1)} ℑ_{c, a} f (z) + z^{m} ℑ_{c, a} f^{'} (z)] .$

After simplification, we can write

$\frac{(2 + c) z F_{1}^{'} (z)}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} - \frac{c}{2} = \frac{1}{1 + m} [m p (z) + z p^{'} (z) + (p (z) + \frac{c}{2}) h (z) - \frac{c}{2}],$

with

$h (z) = \frac{z Ψ^{'} (z)}{Ψ (z)} \in P (p, β_{1}), a n d Ψ (z) = ℑ_{c, a} g (z) - ℑ_{c, a} g (- z) .$

By the use of Equations (19) and (20), we have

(21) $\begin{matrix} ℜ [\frac{(2 + c) z F_{1}^{'}}{ℑ_{c, a} g (z) - ℑ_{c, a} g (- z)} - \frac{c}{2}] \geq \frac{ℜ [p (z) - α]}{1 + m} \\ [\frac{2 m (1 - r^{2}) - 4 r + 2 (1 - (1 - 2 β_{1} r)) (1 - r)}{2 (1 - r^{2})} - \frac{c (1 - r^{2})}{2 (1 - r^{2})}], \end{matrix}$

where

$T (r) = 2 m (1 - r^{2}) - 4 r + 2 (1 - (1 - 2 β_{1} r)) (1 - r) - c (1 - r^{2}),$

$T (r) = (- 2 m - 4 β_{1} + c + 2) r^{2} - 4 (2 - β_{1}) r + (2 m - c + 2) .$

So,

$r_{1} = \frac{1 + m - \frac{c}{2}}{(2 - β) + \sqrt{{(2 - β)}^{2} - (1 + m - \frac{c}{2}) (- m - 2 β_{1} + 1 + \frac{c}{2})}} .$

Therefore,

F_{1} \in K_{s} (p, β_{1})

for

| z_{1} | < r_{1}

. □

Special cases:

For $c = 0$ , we have the result obtained by [8].
For $β = k = 0, f \in K_{s}$ and $c = 0$ . Then, $F_{1} \in K_{s}$ for $r_{\circ} = \frac{1 + m}{2 + \sqrt{3 + m^{2}}} > | z |$ , defined by Equation (17).
When $β_{1} = 0$ $(β = 0 = k)$ , $c = 0$ and $m = 1$ ; then $F_{1} (z) = \frac{{[z f (z)]}^{'}}{2}$ is in the class for $| z | < \frac{1}{2}$ , which is proved by Livingston [16] for $S^{*}$ and C functions.

6. Conclusions

New subclasses $k - S T_{s} (p, β)$ and $k - U K_{s} (p, β)$ of analytic and univalent functions have been defined in canonical domain associated with the Srivastava and Attiya operator. Furthermore, several results including integral representation and radius problems of these subclasses have been derived and compared with different known results in this work.

Author Contributions

Conceptualization, I.A.; Formal analysis, M.Y.; Funding acquisition, J.-S.R.; Investigation, M.Y.; Methodology, M.Y., I.A. and S.M.H.; Supervision, I.A.; Visualization, S.M.H. and J.-S.R.; Writing—original draft, M.Y. and I.A.; Writing—review & editing, S.M.H. and J.-S.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by: 1. Basic Science Research Program through the National Research Foundation of Korea funded by the Ministry of Education (2016R1D1A1B01008058). 2. The Human Resources Development (No. 20204030200090) of the Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Korea government Ministry of Trade, Industry and Energy.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

The authors would like to acknowledge: 1. Basic Science Research Program through the National Research Foundation of Korea funded by the Ministry of Education (2016R1D1A1B01008058). 2. The Human Resources Development (No. 20204030200090) of the Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Korea government Ministry of Trade, Industry and Energy.

Conflicts of Interest

The authors declare no conflict of interest.

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Abstract

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In this paper, we introduce new subclasses $k - S T_{s} (p, β)$ and $k - U K_{s} (p, β)$ of analytic and univalent functions in the canonical domain associated with the Srivastava and Attiya operator. The radius problems of these subclasses regarding symmetrical points are investigated and compared with previous known results. Certain properties and conditions of these subclasses such as integral representation are also discussed in this work.

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Title

Subclasses of Uniform Univalent Functions Associated with Srivastava and Attiya Operator

Author

Yaseen, Mohammad¹; Ali, Irfan¹; Sardar Muhammad Hussain¹; Jong-Suk Ro²

¹ Department of Mathematical Sciences, Balochistan University of Information Technology, Engineering and Management Sciences (BUITEMS), Quetta 87300, Pakistan; [email protected] (M.Y.); [email protected] (I.A.); [email protected] (S.M.H.)
² School of Electrical and Electronics Engineering, Chung-Ang University, Dongjak-gu, Seoul 06974, Korea; Department of Intelligent Energy and Industry, Chung-Ang University, Dongjak-gu, Seoul 06974, Korea

First page

1536

Publication year

2021

Publication date

2021

Publisher

MDPI AG

e-ISSN

20738994

Source type

Scholarly Journal

Language of publication

English

DOI

https://doi.org/10.3390/sym13081536

ProQuest document ID

2565715153

Subclasses of Uniform Univalent Functions Associated with Srivastava and Attiya Operator

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