Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator

Cătaş, Adriana; Borşa, Emilia-Rodica; El-Deeb, Sheza M.

doi:10.3390/math11071742

Open AccessArticle

Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator

by

Adriana Cătaş

^1,*,†

,

Emilia-Rodica Borşa

^1,†

and

Sheza M. El-Deeb

^2,3,†

¹

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

²

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

³

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

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Mathematics 2023, 11(7), 1742; https://doi.org/10.3390/math11071742

Submission received: 15 February 2023 / Revised: 22 March 2023 / Accepted: 31 March 2023 / Published: 5 April 2023

(This article belongs to the Special Issue Fractional Calculus and Mathematical Applications)

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Abstract

:

The aim of the present paper is to introduce and study some new subclasses of p-valent functions by making use of a linear q-differential Borel operator.We also deduce some properties, such as inclusion relationships of the newly introduced classes and the integral operator

J_{μ, p}

.

Keywords:

p-valent; analytic function; starlike functions; convex functions; close-to-convex functions; fractional derivative; linear q-differential Borel operator

MSC:

05A30; 30C45; 11B65; 47B38

1. Introduction

Let

A_{p}

denote the class of functions of the form:

F (ς) = ς^{p} + \sum_{j = p + 1}^{\infty} a_{j} ς^{j} (p \in N = {1, 2, . . .}),

(1)

which are analytic in the open unit disc

Δ = \{ς \in C : |ς| < 1\} .

Let

P_{p, k} (α)

be the class of functions

h (ς)

analytic in

Δ

satisfying the properties

h (0) = p

and

\int_{0}^{2 π} |\frac{ℜ \{h (ς)\} - α}{p - α}| d θ \leq k π,

(2)

where

ς = r e^{i θ}, k \geq 2

and

0 \leq α < p .

This class was introduced by (Aouf [1] with

λ = 0

).

We note that

(i): $P_{1, k} (α) = P_{k} (α)$ $(k \geq 2, 0 \leq α < 1)$ (see Padmanabhan and Parvatham [2]);
(ii): $P_{1, k} (0) = P_{k} (k \geq 2)$ (see Pinchuk [3] and Robertson [4]);
(iii): $P_{p, 2} (α) = P (p, α) (0 \leq α < p, p \in N),$ where $P (p, α)$ is the class of functions with a positive real part greater than $α$ (see [1]);
(iv): $P_{p, 2} (0) = P (p) (p \in N),$ where $P (p)$ is the class of functions with a positive real part (see [1]).

From (2), we have

h (ς) \in P_{p, k} (α)

if and only if there exists

h_{1}, h_{2} \in P_{p} (α)

such that

G (ς) = (\frac{k}{4} + \frac{1}{2}) h_{1} (ς) - (\frac{k}{4} - \frac{1}{2}) h_{2} (ς) (ς \in Δ) .

(3)

For two functions

F (ς)

given by (1) and

H (ς)

given by

H (ς) = ς^{p} + \sum_{j = p + 1}^{\infty} b_{j} ς^{j}

the Hadamard product (or convolution) is defined by

(F * H) (ς) = ς^{p} + \sum_{j = p + 1}^{\infty} a_{j} b_{j} ς^{j} = (H * F) (ς) .

(4)

Define here a Borel distribution with parameter

λ

, which is a discrete random variable denoted by

χ

. This variable takes the values

1, 2, 3, . . .

with the probabilities

\frac{e^{- λ}}{1!}, \frac{2 λ e^{- 2 λ}}{2!}, \frac{9 λ^{2} e^{- 3 λ}}{3!}, . . .

, respectively.

Wanas and Khuttar [5] recently introduced the Borel distribution (BD) whose probability mass function is (see [6,7])

P (χ = ρ) = \frac{{(ρ λ)}^{ρ - 1} e^{- λ ρ}}{ρ!}, ρ = 1, 2, 3, . . .

Wanas and Khuttar studied a series

M (λ; ς)

whose coefficients are probabilities of the Borel distribution (BD)

\begin{matrix} M_{p} (λ; ς) & = & ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{(j - p)!} ς^{j}, (0 < λ \leq 1), \\ = & ς^{p} + \sum_{j = p + 1}^{\infty} ϕ_{j, p} (λ) ς^{k}, (0 < λ \leq 1), \end{matrix}

(5)

where

ϕ_{j, p} (λ) = \frac{{[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{(j - p)!}

(6)

We propose a linear operator

D (p, λ; ς) F : A_{p} \to A_{p}

as follows

\begin{matrix} D (p, λ; ς) F (ς) & = & M_{p} (λ; ς) * F (ς) \\ = & ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{(j - p)!} a_{j} ς^{j}, (0 < λ \leq 1) . \end{matrix}

In a recent paper, Srivastava [8] studied various types of operators regarding q-calculus. We recall further some important definitions and notations. The q-shifted factorial is defined for

λ, q \in C

and

n \in N_{0} = N \cup {0}

as follows

{(μ; q)}_{j} = \{\begin{matrix} 1 & j = 0, \\ (1 - μ) (1 - μ q) . . . (1 - μ q^{j - 1}) & j \in N . \end{matrix}

By using the q-gamma function

Γ_{q} (ς),

we get

{(q^{μ}; q)}_{j} = \frac{{(1 - q)}^{j} Γ_{q} (μ + j)}{Γ_{q} (μ)}, (j \in N_{0}),

where (see [9])

Γ_{q} (ς) = {(1 - q)}^{1 - ς} \frac{{(q; q)}_{\infty}}{{(q^{ς}; q)}_{\infty}}, (|q| < 1) .

Furthermore, we note that

{(μ; q)}_{\infty} = \prod_{j = 0}^{\infty} (1 - μ q^{j}), (|q| < 1),

and, the q-gamma function

Γ_{q} (ς)

is known

Γ_{q} (ς + 1) = {[j]}_{q} Γ_{q} (ς),

where

{[j]}_{q}

denotes the basic q-number defined as follows

{[j]}_{q} : = \{\begin{matrix} \frac{1 - q^{j}}{1 - q}, j \in C, \\ 1 + \sum_{i = 1}^{j - 1} q^{i}, j \in N . \end{matrix}

(7)

Using the definition from (7), we have the next two products:

(i): For a non negative integer j, the q-shifted factorial is defined by

${[j]}_{q}! : = \{\begin{matrix} 1, & if & j = 0, \\ \prod_{n = 1}^{j} {[n]}_{q}, & if & j \in N . \end{matrix}$
(ii): For a positive number r, the q-generalized Pochhammer symbol is given by

${[r]}_{q, j} : = \{\begin{matrix} 1, & if & j = 0, \\ \prod_{n = r}^{r + j - 1} {[n]}_{q}, & if & j \in N . \end{matrix}$

In terms of the classical (Euler’s) gamma function

Γ (ς)

, we have

Γ_{q} (ς) \to Γ (ς) as q \to 1^{-} .

Furthermore, we notice that

lim_{q \to 1^{-}} \{\frac{{(q^{μ}; q)}_{j}}{{(1 - q)}^{j}}\} = {(μ)}_{j} .

2. Preliminaries

In order to establish our new results, we have to recall the construct of a q-derivative operator. Considering

0 < q < 1

, the q-derivative operator [10] (see also other specific and generalized results [11,12,13,14,15]) for

D (p, λ; ς) F

is defined by

\begin{matrix} D_{q} (D (p, λ; ς) F (ς)) & : & = \frac{D (p, λ; ς) F (ς) - D (p, λ; ς) F (q ς)}{ς (1 - q)} \\ = & {[p]}_{q} ς^{p - 1} + \sum_{j = p + 1}^{\infty} {[j]}_{q} \frac{{[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{(j - p)!} a_{j} ς^{j - 1}, \end{matrix}

where

{[j]}_{q}

is defined in (7)

For

α > - 1

and

0 < q < 1

, we obtain the linear operator

D_{p, λ}^{μ, q} F : A_{p} \to A_{p}

by

D_{p, λ}^{μ, q} F (ς) * N_{p, μ + 1}^{q} (ς) = \frac{ς}{{[p]}_{q}} D_{q} (D (p, λ; ς) F (ς)), ς \in Δ,

where the function

N_{p, α + 1}^{q}

is given by

N_{p, μ + 1}^{q} (ς) : = ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[μ + 1]}_{q, j - p}}{{[j - 1]}_{q}!} ς^{j}, ς \in Δ .

A simple computation shows that

\begin{matrix} D_{p, λ}^{μ, q} F (ς) & : & = ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[j]}_{q}! {[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{{[p]}_{q} {[μ + 1]}_{q, j - p} (j - p)!} a_{j} ς^{j} \\ = & z^{p} + \sum_{j = p + 1}^{\infty} ϕ_{j} a_{j} ς^{j} (0 < λ \leq 1, μ > p, 0 < q < 1, ς \in Δ) . \end{matrix}

(8)

where

ϕ_{j} = \frac{{[j]}_{q}! {[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{{[p]}_{q} {[μ + 1]}_{q, j - p} (j - p)!} .

(9)

For

δ \geq 0,

with the aid of the operator

D_{p, λ}^{μ, q}

one can defined the linear q-differential Borel operator

A_{p} \to A_{p}

as follows:

\begin{matrix} G_{p, q, λ, δ}^{μ, 0} F (ς) & : & = D_{p, λ}^{μ, q} F (ς) \\ G_{p, q, λ, δ}^{μ, 1} F (ς) & : & = (1 - δ) G_{p, q, λ, δ}^{μ, 0} F (ς) + δ \frac{ς}{p} {(G_{p, q, λ, δ}^{μ, 0} F (ς))}^{'} \\ = & ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[j]}_{q}! {[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{{[p]}_{q} {[μ + 1]}_{q, j - p} (j - p)!} [1 + δ (\frac{j}{p} - 1)] a_{j} ς^{j} \\ G_{p, q, λ, δ}^{μ, 2} F (ς) & : & = (1 - δ) G_{p, q, λ, δ}^{μ, 1} F (ς) + δ \frac{ς}{p} {(G_{p, q, λ, δ}^{μ, 1} F (ς))}^{^{'}} \\ = & ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[j]}_{q}! {[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{{[p]}_{q} {[μ + 1]}_{q, j - p} (j - p)!} {[1 + δ (\frac{j}{p} - 1)]}^{2} a_{j} ς^{j} \\ . \\ . \\ . \\ G_{p, q, λ, δ}^{μ, m} F (ς) & : & = ς^{p} + \sum_{j = p + 1}^{\infty} \frac{{[j]}_{q}! {[λ (j - p)]}^{j - p - 1} e^{- λ (j - p)}}{{[p]}_{q} {[μ + 1]}_{q, j - p} (j - p)!} {[1 + δ (\frac{j}{p} - 1)]}^{m} a_{j} ς^{j}, \\ (m \in N_{0} = N \cup \{0\}, δ \geq 0, 0 < λ \leq 1, μ > p, 0 < q < 1) . \end{matrix}

(10)

From the relation (10), we can easily deduce that the next relations held for all

F \in A_{p}

:

(i) ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{'} = μ G_{p, q, λ, δ}^{μ - 1, m} F (ς) - (μ - p) G_{p, q, λ, δ}^{μ, m} F (ς),

(11)

and

(ii) δ ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{'} = p G_{p, q, λ, δ}^{μ, m + 1} F (ς) - p (1 - δ) G_{p, q, λ, δ}^{μ, m} F (ς)

(12)

Remark 1.

By particularizing the parameters

p

and

m,

we derive the following operators based on Borel distribution:

(1): Letting $p = 1,$ we obtain that $G_{1, q, λ, δ}^{μ, m} = : I_{q, λ, δ}^{μ, m}$ , where the operator $I_{q, λ, δ}^{μ, m}$ is defined as follows:

$I_{q, λ, δ}^{μ, m} F (ς) : = ς + \sum_{j = 2}^{\infty} \frac{{[j]}_{q}! {[λ (j - 1)]}^{j - 2} e^{- λ (j - 1)}}{{[μ + 1]}_{q, j - 1} (j - 1)!} {[1 + δ (j - 1)]}^{m} a_{j} ς^{j};$
(2): Letting $p = 1$ and $m = 0,$ we deduce that $G_{1, q, λ, δ}^{μ, 0} = : B_{λ}^{μ, q}$ , where the operator $B_{λ}^{μ, q}$ , introduced by El-Deeb and Murugusundaramoorthy [16];
(3): Letting $q \to 1^{-}$ and $p = 1$ , we deduce that $lim_{q \to 1^{-}} G_{1, q, λ, δ}^{μ, m} : = R_{λ, δ}^{μ, m},$ where the operator $R_{λ, δ}^{μ, m}$ is defined as follows

$R_{λ, δ}^{μ, m} F (ς) : = ς + \sum_{j = 2}^{\infty} \frac{j {[λ (j - 1)]}^{j - 2} e^{- λ (j - 1)}}{{(μ + 1)}_{j - 1}} {[1 + δ (j - 1)]}^{m} a_{j} ς^{j};$
(4): Putting $q \to 1^{-},$ $p = 1$ and $m = 0$ , we obtain that $lim_{q \to 1^{-}} G_{1, q, λ, δ}^{μ, 0} : = M_{λ}^{μ},$ where the operator $M_{λ}^{μ}$ , studied byEl-Deeb and Murugusundaramoorthy [16].

Now we introduce the following classes

S_{p}^{k} (α), C_{p}^{k} (α)

and

K_{p}^{k} (β, α)

of the class

A_{p}

for

0 \leq α, β < p, p \in N

and

k \geq 2

as follows:

S_{p}^{k} (α) = \{F : F \in A_{p} and \frac{ς F^{^{'}} (ς)}{F (ς)} \in P_{p, k} (α), ς \in Δ\},

C_{p}^{k} (α) = \{F : F \in A_{p} and 1 + \frac{ς F^{^{^{''}}} (ς)}{F^{^{'}} (ς)} \in P_{p, k} (α), ς \in Δ\},

and

K_{p}^{k} (β, α) = \{F : F \in A_{p}, g \in S_{p}^{2} (α) and \frac{ς F^{^{'}} (ς)}{g (ς)} \in P_{p, k} (β), ς \in Δ\} .

Obviously, we know that

F (ς) \in C_{p}^{k} (α) \Leftrightarrow \frac{ς F^{^{'}} (ς)}{p} \in S_{p}^{k} (α) .

(13)

Remark 2.

By particularizing the parameter

k,

we obtain the following classes:

(i): $S_{p}^{2} (α) = S_{p}^{*} (α)$ $(0 \leq α < p, p \in N),$ where $S_{p}^{*} (α)$ is the well-known class of $p -$ valently starlike functions of order α and was studied by Patil and Thakare [17];
(ii): $C_{p}^{2} (α) = C_{p} (α)$ $(0 \leq α < p, p \in N),$ where $C_{p} (α)$ is the well-known class of $p -$ valently convex functions of order α and was studied by Owa [18];
(iii): $K_{p}^{2} (β, α) = K_{p} (β, α)$ $(0 \leq α < p, p \in N),$ where $K_{p} (β, α)$ is the class of all $p -$ valently close-to-convex functions of order β and type $α$ and was introduced by Aouf [19].

Next, by making use of the operator defined by (10), we obtain the following subclasses

S_{p, q, λ, δ}^{μ, m, k} (α)

,

C_{p, q, λ, δ}^{μ, m, k} (α)

and

K_{p, q, λ, δ}^{μ, m, k} (β, α)

of the class

A_{p}

as follows:

S_{p, q, λ, δ}^{μ, m, k} (α) = \{F : F \in A_{p} and G_{p, q, λ, δ}^{μ, m} F (ς) \in S_{p}^{k} (α), ς \in Δ\},

(14)

C_{p, q, λ, δ}^{μ, m, k} (α) = \{F : F \in A_{p} and G_{p, q, λ, δ}^{μ, m} F (ς) \in C_{p}^{k} (α), ς \in Δ\},

(15)

and

K_{p, q, λ, δ}^{μ, m, k} (β, α) = \{F : F \in A_{p} and G_{p, q, λ, δ}^{μ, m} F (ς) \in K_{p}^{k} (β, α), ς \in Δ\} .

(16)

We can easily see that

F (ς) \in C_{p, q, λ, δ}^{μ, m, k} (α) \Leftrightarrow \frac{ς F^{^{'}} (ς)}{p} \in S_{p, q, λ, δ}^{μ, m, k} (α)

(17)

In order to establish our main results, we will require the following lemmas.

Lemma 1

([20,21]). Let

Φ (r, s)

be complex valued function,

Φ :

D \to C,

D \subset C \times C

(C

is the complex plane) and let

r = r_{1} + i r_{2},

s = s_{1} + i s_{2} .

Suppose that

Φ (r, s)

satisfies the following conditions:

(i): $Φ (r, s)$ is continuous in a domain $D;$
(ii): $(1, 0) \in D$ and $ℜ \{Φ (1, 0)\} > 0;$
(iii): $ℜ \{Φ (i r_{2}, s_{1})\} \leq 0$ for all $(i r_{2}, s_{1}) \in D$ and such that $s_{1} \leq - \frac{1}{2} (1 + r_{2}^{2}) .$

Let

h (ς) = 1 + \sum_{m = 1}^{\infty} c_{m} ς^{m},

be regular in Δ such that

(h (ς), ς h^{^{'}} (ς)) \in D

for all

ς \in Δ .

If

ℜ \{Φ (h (ς), ς h^{^{'}} (ς))\} > 0 (ς \in Δ),

then

ℜ \{h (ς)\} > 0 (ς \in Δ) .

Lemma 2

([22]). Let Φ be convex and

F

be starlike in Δ. Then, for Υ analytic in Δ with

Υ (0) = 1

,

\frac{Φ * Υ F}{Φ * F}

is contained in the convex hull of

Υ (Δ)

.

3. Inclusion Properties Involving the Operator $G_{p, q, λ, δ}^{μ, m}$

Further, we assume throughout this paper that

k \geq 2, p \in N, m \in N_{0}, δ \geq 0, 0 < λ \leq 1, 0 < q < 1, ς \in Δ

and the power are the principal values.

Theorem 1.

For

0 \leq ζ \leq α < p

and

μ > p,

then

S_{p, q, λ, δ}^{μ - 1, m, k} (α) \subset S_{p, q, λ, δ}^{μ, m, k} (ζ),

where ζ is given by

ζ = \frac{2 [p - 2 α (p - μ)]}{\sqrt{{(2 μ - 2 p - 2 α + 1)}^{2} + 8 (p - 2 α (p - μ))} + (2 μ - 2 p - 2 α + 1)} .

(18)

Proof.

Assume that

F \in S_{p, q, λ, δ}^{μ - 1, m, k} (α)

and let

\frac{ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} F (ς)} = M (ς) = (p - ζ) h (ς) + ζ .

(19)

where

h (ς) = (\frac{k}{4} + \frac{1}{2}) h_{1} (ς) - (\frac{k}{4} - \frac{1}{2}) h_{2} (ς)

(20)

and

h_{i} (z)

(i = 1, 2)

are analytic in

Δ

with

h_{i} (0) = 1, i = 1, 2 .

Using (11) and (19), we have

μ \frac{G_{p, q, λ, δ}^{μ - 1, m} F (ς)}{G_{p, q, λ, δ}^{μ, m} F (ς)} = (p - ζ) h (ς) + ζ - μ + p .

(21)

By computing the logarithmical derivative of (21) with respect to

ς

, we have

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} F (ς)} - α = ζ - α + (p - ζ) h (ς) + \frac{(p - ζ) ς h^{^{'}} (ς)}{(p - ζ) h (ς) + ζ - μ + p} .

(22)

Now we show that

M (ς) \in P_{p, k} (α)

or

h_{i} (ς) \in P, i = 1, 2 .

From (20) and (22), we have

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} F (ς)} - α = (\frac{k}{4} + \frac{1}{2}) \{ζ - α + (p - ζ) h_{1} (ς) + \frac{(p - ζ) ς h_{1}^{^{'}} (ς)}{(p - ζ) h_{1} (ς) + ζ - μ + p}\}

- (\frac{k}{4} - \frac{1}{2}) \{ζ - α + (p - ζ) h_{2} (ς) + \frac{(p - ζ) ς h_{2}^{^{'}} (ς)}{(p - ζ) h_{2} (ς) + ζ - μ + p}\}

and this implies that

ℜ \{ζ - α + (p - ζ) h_{i} (ς) + \frac{(p - ζ) ς h_{i}^{^{'}} (ς)}{(p - ζ) h_{i} (ς) + ζ - μ + p}\} > 0 (ς \in Δ; i = 1, 2) .

We form the function

Φ (r, s)

by choosing

r = h_{i} (ς)

and

s = ς h_{i}^{^{'}} (ς) .

Thus

Φ (r, s) = ζ - α + (p - ζ) r + \frac{(p - ζ) s}{(p - ζ) r + ζ - μ + p} .

Then, we have

(i): $Φ (r, s)$ is continuous function in $D = (C \ \frac{ζ - μ + p}{ζ - p}) \times C;$
(ii): $(1, 0) \in D$ and $ℜ \{Φ (1, 0)\} = p - α > 0;$
(iii): $\begin{matrix} ℜ \{Φ (i r_{2}, s_{1})\} & = & ℜ \{ζ - α + (p - ζ) i r_{2} + \frac{(p - ζ) s_{1}}{(p - ζ) i r_{2} + ζ - μ + p}\} \\ = & ζ - α + \frac{(p - ζ) (ζ - μ + p) s_{1}}{{(p - ζ)}^{2} r_{2}^{2} + {(ζ - μ + p)}^{2}} \\ \leq & ζ - α - \frac{(p - ζ) (ζ - μ + p) (1 + r_{2}^{2})}{2 [{(p - ζ)}^{2} r_{2}^{2} + {(ζ - μ + p)}^{2}]} \\ = & \frac{R + E r_{2}^{2}}{2 C}, \end{matrix}$

for all

(i r_{2}, s_{1}) \in D

such that

s_{1} \leq - \frac{1}{2} (1 + r_{2}^{2}),

where

R = 2 (ζ - α) {(ζ - μ + p)}^{2} - (p - ζ) (ζ - μ + p),

E = 2 (ζ - α) {(p - ζ)}^{2} - (p - ζ) (ζ - μ + p),

C = {(p - ζ)}^{2} r_{2}^{2} + {(ζ - μ + p)}^{2} .

We note that

ℜ \{Φ (i r_{2}, s_{1})\} < 0

, if and only if

R \leq 0, E < 0

and

C > 0 .

From

R \leq 0

, we obtain

ζ

as given by (18), and from

0 \leq ζ < α < p,

we have

E < 0 .

By applying Lemma 1,

h_{i} (ς) \in P (i = 1, 2)

and consequently

M (ς) \in P_{p, k} (γ)

for

ς \in Δ .

This completes the proof of Theorem 1. □

Theorem 2.

For

0 \leq ζ \leq α < p

and

μ > p,

then

C_{p, q, λ, δ}^{μ - 1, m, k} (α) \subset C_{p, q, λ, δ}^{μ, m, k} (ζ),

where ζ is given by (18).

Proof.

Let

\begin{matrix} F & \in & C_{p, q, λ, δ}^{μ - 1, m, k} (α) \Rightarrow G_{p, q, λ, δ}^{μ - 1, m} F (ς) \in C_{p}^{k} (α) \\ \Rightarrow & \frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{p} \in S_{p}^{k} (α) \\ \Rightarrow & G_{p, q, λ, δ}^{μ - 1, m} (\frac{ς F^{^{'}} (ς)}{p}) \in S_{p}^{k} (α) \\ \Rightarrow & \frac{ς F^{^{'}} (ς)}{p} \in S_{p, q, λ, δ}^{μ - 1, m, k} (α) \subset S_{p, q, λ, δ}^{μ, m, k} (ζ) \\ \Rightarrow & G_{p, q, λ, δ}^{μ, m} (\frac{ς F^{^{'}} (ς)}{p}) \in S_{p}^{k} (ζ) \\ \Rightarrow & G_{p, q, λ, δ}^{μ, m} F (ς) \in C_{p}^{k} (ζ) \\ \Rightarrow & F \in C_{p, q, λ, δ}^{μ, m, k} (ζ) . \end{matrix}

This completes the proof of Theorem 2. □

Theorem 3.

For

0 \leq β \leq α < p

and

μ > p,

then

K_{p, q, λ, δ}^{μ - 1, m, k} (β, α) \subset K_{p, q, λ, δ}^{μ, m, k} (β, α) .

Proof.

Let

F \in K_{p, q, λ, δ}^{μ - 1, m, k} (β, α) .

Then, there exists

G (ς) \in S_{p}^{2} (α) \equiv S_{p}^{*} (α)

such that

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G (ς)} \in P_{p, k} (β) .

(23)

Then

G (ς) = G_{p, q, λ, δ}^{μ - 1, m} g (ς) \in S_{p, q, λ, δ}^{μ - 1, m, 2} (α) .

We set

\frac{ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} g (ς)} = R (ς) = (p - β) h (ς) + β,

(24)

where

h (ς)

is given by (20). By using (11) in (23), we get

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} g (ς)} = \frac{ς {(G_{p, q, λ, δ}^{μ, m} (ς F^{^{'}} (ς)))}^{^{'}} + (μ - p) G_{p, q, λ, δ}^{μ, m} (ς F^{^{'}} (ς))}{ς {(G_{p, q, λ, δ}^{μ, m} g (ς))}^{^{'}} + (μ - p) G_{p, q, λ, δ}^{μ, m} g (ς)} .

(25)

Furthermore,

G (ς) \in S_{p, q, λ, δ}^{μ - 1, m, 2} (α)

and by using Theorem 1, with

k = 2,

we have

G (ς) \in S_{p, q, λ, δ}^{μ, m, 2} (α) .

Therefore, we can write

\frac{ς {(G_{p, q, λ, δ}^{μ, m} g (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} g (ς)} = R_{0} (ς) = (p - α) q (ς) + α (q \in P_{k}),

(26)

where

q (ς) = 1 + c_{1} ς + c_{2} ς^{2} + . . .

is analytic and

q (0) = 1

in

Δ

. By differentiating (24) with respect to

ς

, we have

ς {(G_{p, q, λ, δ}^{μ, m} (ς F^{^{'}} (ς)))}^{^{'}} = ς {(G_{p, q, λ, δ}^{μ, m} g (ς))}^{^{'}} R (ς) + ς R^{^{'}} (ς) G_{p, q, λ, δ}^{μ, m} g (ς)

then

\frac{ς {(G_{p, q, λ, δ}^{μ, m} (ς f^{^{'}} (ς)))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} g (ς)} = ς R^{^{'}} (ς) + R_{0} (ς) R (ς) .

(27)

From (25) and (27), we obtain

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} g (ς)} = \frac{ς R^{^{'}} (ς) + R_{0} (ς) R (ς) + (μ - p) R (ς)}{R_{0} (ς) + (μ - p)}

so that

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} f (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} g (ς)} = R (ς) + \frac{ς R^{^{'}} (ς)}{R_{0} (ς) + (μ - p)} .

(28)

Let

R (ς) = (\frac{k}{4} + \frac{1}{2}) \{(p - β) h_{1} (ς) + β\} - (\frac{k}{4} - \frac{1}{2}) \{(p - β) h_{2} (ς) + β\}

and

R_{0} (ς) + (μ - p) = (p - α) q (ς) + (α + μ - p) .

We intend to show that

R \in P_{p, k} (β)

or

h_{i} \in P

for

i = 1, 2 .

Then, we can say that

ℜ \{R_{0} (ς) + (μ - p)\} > 0 .

From (24) and (28), we have

\frac{ς {(G_{p, q, λ, δ}^{μ - 1, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ - 1, m} g (ς)} - β = (\frac{k}{4} + \frac{1}{2}) \{(p - β) h_{1} (ς) + \frac{(p - β) ς h_{1}^{^{'}} (ς)}{(p - α) q (ς) + (α + μ - p)}\}

- (\frac{k}{4} - \frac{1}{2}) \{(p - β) h_{2} (ς) + \frac{(p - β) ς h_{2}^{^{'}} (ς)}{(p - α) q (ς) + (α + μ - p)}\}

and this implies that

ℜ \{(p - β) h_{i} (ς) + \frac{(p - β) ς h_{i}^{^{'}} (ς)}{(p - α) q (ς) + (α + μ - p)}\} > 0 (ς \in Δ, i = 1, 2) .

We form the function

Φ (r, s)

by choosing

r = h_{i} (ς)

and

s = ς h_{i}^{^{'}} (ς) .

Thus,

Φ (r, s) = (p - β) r + \frac{(p - β) s}{(p - α) q (ς) + (α + μ - p)} .

(29)

Then

(i): $Φ (r, s)$ is continuous in $D = C \times C;$
(ii): $(1, 0) \in D$ and $ℜ \{Φ (1, 0)\} = p - β > 0;$
(iii): $\begin{matrix} ℜ \{Φ (i r_{2}, s_{1})\} & = & ℜ \{(p - β) i u_{2} + \frac{(p - β) v_{1}}{(p - α) (q_{1} + i q_{2}) + (α + μ - p)}\} \\ = & \frac{(p - β) [(p - α) q_{1} + α + μ - p] s_{1}}{{[(p - α) q_{1} + α + μ - p]}^{2} + {(p - α)}^{2} q_{2}^{2}} \\ \leq & - \frac{(p - β) [(p - α) q_{1} + α + μ - p] (1 + r_{2}^{2})}{2 \{{[(p - α) q_{1} + α + μ - p]}^{2} + {(p - α)}^{2} q_{2}^{2}\}} < 0, \end{matrix}$

for all

(i r_{2}, s_{1}) \in D

such that

s_{1} \leq - \frac{1}{2} (1 + r_{2}^{2}) .

Byapplying Lemma 1, we have

ℜ \{h_{i} (ς)\} > 0

for

(i = 1, 2)

and consequently

R (ς) \in P_{p, k} (β)

for

ς \in Δ .

This completes the proof of Theorem 3. □

4. Inclusion Properties Involving the Integral Operator $J_{δ, p}$

The generalized Bernardi operator is defined by (see [23])

J_{δ, p} (F) (ς) = \frac{δ + p}{ς^{δ}} \int_{0}^{ς} t^{δ - 1} F (t) d t (δ > - p),

(30)

which satisfies the following relationship:

ς {(J_{δ, p} (F) (ς))}^{^{'}} = (δ + p) F (ς) - δ J_{δ, p} (F) (ς) .

(31)

Theorem 4.

If

0 \leq α < p,

k \geq 2

and

F \in S_{p, q, λ, δ}^{μ, m, k} (α),

then

J_{δ, p} (F) \in S_{p, q, λ, δ}^{μ, m, k} (α) (δ \geq 0) .

Proof.

Let

\frac{ς {(G_{p, q, λ, δ}^{μ, m} J_{δ, p} (F) (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} J_{δ, p} (F) (ς)} = R (ς) = (p - α) h (ς) + α,

(32)

where

h (ς)

, given by (20). Using (31), we have

ς {(G_{p, q, λ, δ}^{μ, m} J_{δ, p} (F) (ς))}^{^{'}} = (δ + p) G_{p, q, λ, δ}^{μ, m} F (ς) - δ G_{p, q, λ, δ}^{μ, m} J_{δ, p} (F) (ς) .

(33)

From (32) and (33), we have

(δ + p) \frac{G_{p, q, λ, δ}^{μ, m} F (ς)}{G_{p, q, λ, δ}^{μ, m} J_{δ, p} (F) (ς)} = (p - α) h (ς) + α + δ .

(34)

By computing the logarithmical derivative of (34) with respect to

ς

and multiplying by

ς

, we have

\frac{ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} F (ς)} - α = (p - α) h (ς) + \frac{(p - α) ς h^{^{'}} (ς)}{(p - α) h (ς) + α + δ} .

(35)

Now, we show that

R (ς) \in P_{p, k} (α)

or

h_{i} \in P

for

i = 1, 2 .

From (20) and (35), we have

\frac{ς {(G_{p, q, λ, δ}^{μ, m} F (ς))}^{^{'}}}{G_{p, q, λ, δ}^{μ, m} F (ς)} - α = (\frac{k}{4} + \frac{1}{2}) \{(p - α) h_{1} (ς) + \frac{(p - α) ς h_{1}^{^{'}} (ς)}{(p - α) h_{1} (ς) + α + δ}\}

- (\frac{k}{4} - \frac{1}{2}) \{(p - α) h_{2} (ς) + \frac{(p - α) ς h_{2}^{^{'}} (ς)}{(p - α) h_{2} (ς) + α + δ}\}

and this implies that

ℜ \{(p - α) h_{i} (ς) + \frac{(p - α) ς h_{i}^{^{'}} (ς)}{(p - α) h_{i} (ς) + α + δ}\} > 0 (ς \in Δ; i = 1, 2) .

We form the function

Φ (r, s)

by choosing

r = h_{i} (ς)

and

s = ς h_{i}^{^{'}} (ς) .

Thus

Φ (r, s) = (p - α) r + \frac{(p - α) s}{(p - α) r + α + δ} .

(36)

Clearly, conditions (i), (ii) and (iii) of Lemma 1 are satisfied. Byapplying Lemma 1, we have

ℜ \{h_{i} (ς)\} > 0

for

(i = 1, 2)

and consequently

J_{δ, p} (F) \in S_{p, q, λ, δ}^{μ, m, k} (α)

for

ς \in Δ .

This completes the proof of Theorem 1. □

Theorem 5.

If

0 \leq α < p,

k \geq 2

and

F \in C_{p, q, λ, δ}^{μ, m, k} (α),

then

J_{δ, p} (F) \in C_{p, q, λ, δ}^{μ, m, k} (α) (δ \geq 0) .

Proof.

Let

F \in C_{p, q, λ, δ}^{μ, m, k} (α) \Leftrightarrow \frac{ς F^{^{'}} (ς)}{p} \in S_{p, q, λ, δ}^{μ, m, k} (α) .

By applying Theorem 4, we have

J_{δ, p} (\frac{ς F^{^{'}} (ς)}{p}) \in S_{p, q, λ, δ}^{μ, m, k} (α) \Leftrightarrow \frac{ς {(J_{δ, p} (F) (ς))}^{^{'}}}{p} \in S_{p, q, λ, δ}^{μ, m, k} (α) \Leftrightarrow J_{δ, p} (F) (ς) \in C_{p, q, λ, δ}^{μ, m, k} (α),

which evidently proves Theorem 5. □

5. Inclusion Properties by Convolution

Theorem 6.

Let Φ be a convex function and

F \in S_{p, q, λ, δ}^{μ, m, 2} (p γ),

then

G \in S_{p, q, λ, δ}^{μ, m, 2} (p γ),

where

G = F * Φ

and

0 \leq γ < 1 .

Proof.

To show that

G = F * Φ \in S_{p, q, λ, δ}^{μ, m, 2} (p γ) (0 \leq γ < 1),

it sufficient to show that

\frac{ς {(G_{p, q, λ, δ}^{μ, m} G)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} G}

contained in the convex hull of

Υ (Δ) .

Now

\frac{ς {(G_{p, q, λ, δ}^{μ, m} G)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} G} = \frac{Φ * Υ G_{p, q, λ, δ}^{μ, m} F}{Φ * G_{p, q, λ, δ}^{μ, m} F},

(37)

where

Υ = \frac{ς {(G_{p, q, λ, δ}^{μ, m} F)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} F}

is analytic in

Δ

and

Υ (0) = 1 .

From Lemma 2, we can see that

\frac{ς {(G_{p, q, λ, δ}^{μ, m} G)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} G}

is contained in the convex hull of

Υ (Δ),

since

\frac{ς {(G_{p, q, λ, δ}^{μ, m} G)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} G}

is analytic in

Δ

and

Υ (Δ) \subseteq Ω = \{w : \frac{ς {(G_{p, q, λ, δ}^{μ, m} w (ς))}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} w (ς)} \in P (γ)\},

(38)

then

\frac{ς {(G_{p, q, λ, δ}^{μ, m} G)}^{^{'}}}{p G_{p, q, λ, δ}^{μ, m} G}

lies in

Ω,

this implies that

G = F * Φ \in S_{p, q, λ, δ}^{μ, m, 2} (p γ)

. □

Theorem 7.

Let Φ be a convex function and

F \in C_{p, q, λ, δ}^{μ, m, 2} (p γ),

then

G \in C_{p, q, λ, δ}^{μ, m, 2} (p γ),

where

G = F * Φ

and

0 \leq γ < 1 .

Proof.

Let

F \in C_{p, q, λ, δ}^{μ, m, 2} (p γ),

then, by using (13), we have

\frac{ς F^{^{'}} (ς)}{p} \in S_{p, q, λ, δ}^{μ, m, 2} (p γ)

and hence by using Theorem 6, we get

\begin{matrix} \frac{ς F^{^{'}} (ς)}{p} * Φ (ς) & \in & S_{p, q, λ, δ}^{μ, m, 2} (p γ) \\ \Rightarrow & \frac{ς {(F * Φ)}^{^{'}} (ς)}{p} \in S_{p, q, λ, δ}^{μ, m, 2} (p γ) . \end{matrix}

Now applying (13) again, we obtain

G = F * Φ \in C_{p, q, λ, δ}^{μ, m, 2} (p γ)

, which evidently proves Theorem 7. □

Remark 3.

Particularizing the parameters

q

and

m

in the results of this paper, we derive various results for different operators.

6. Conclusions

In the present survey, we propose new subclasses of p-valent functions by making use of the linear q-differential Borel operator. The applications of this interesting operator are discussed. Inclusion properties and certain integral preserving relations were aimed to be our main concern.

Author Contributions

Conceptualization, A.C. and S.M.E.-D.; methodology, S.M.E.-D.; validation, A.C., E.-R.B. and S.M.E.-D.; formal analysis, E.-R.B.; investigation, A.C., E.-R.B. and S.M.E.-D.; writing—original draft, S.M.E.-D.; writing—review & editing, A.C. and S.M.E.-D.; visualization, E.-R.B.; supervision, S.M.E.-D.; project administration, S.M.E.-D. All authors have read and agreed to the published version of the manuscript.

Funding

The research was funded by the University of Oradea, Romania.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

No data were used to support this study.

Conflicts of Interest

The authors declare no conflict of interest.

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Cătaş, A.; Borşa, E.-R.; El-Deeb, S.M. Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator. Mathematics 2023, 11, 1742. https://doi.org/10.3390/math11071742

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Cătaş A, Borşa E-R, El-Deeb SM. Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator. Mathematics. 2023; 11(7):1742. https://doi.org/10.3390/math11071742

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Cătaş, Adriana, Emilia-Rodica Borşa, and Sheza M. El-Deeb. 2023. "Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator" Mathematics 11, no. 7: 1742. https://doi.org/10.3390/math11071742

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Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator

Abstract

1. Introduction

2. Preliminaries

3. Inclusion Properties Involving the Operator $G_{p, q, λ, δ}^{μ, m}$

4. Inclusion Properties Involving the Integral Operator $J_{δ, p}$

5. Inclusion Properties by Convolution

6. Conclusions

Author Contributions

Funding

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References

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Subclasses of p-Valent Functions Associated with Linear q-Differential Borel Operator

Abstract

1. Introduction

2. Preliminaries

3. Inclusion Properties Involving the Operator G p , q , λ , δ μ , m

4. Inclusion Properties Involving the Integral Operator J δ , p

5. Inclusion Properties by Convolution

6. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

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References

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3. Inclusion Properties Involving the Operator $G_{p, q, λ, δ}^{μ, m}$

4. Inclusion Properties Involving the Integral Operator $J_{δ, p}$