New Applications of the Fractional Integral on Analytic Functions

Alb Lupaş, Alina

doi:10.3390/sym13030423

Open AccessArticle

New Applications of the Fractional Integral on Analytic Functions

by

Alina Alb Lupaş

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

Symmetry 2021, 13(3), 423; https://0-doi-org.brum.beds.ac.uk/10.3390/sym13030423

Submission received: 24 February 2021 / Revised: 3 March 2021 / Accepted: 4 March 2021 / Published: 5 March 2021

(This article belongs to the Section Mathematics)

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Abstract

:

The fractional integral is a function known for the elegant results obtained when introducing new operators; it has proved to have interesting applications. In the present paper, differential subordinations and superodinations for the fractional integral of the confluent hypergeometric function introduced in a previously published paper are presented. A sandwich-type theorem at the end of the original part of the paper connects the outcomes of the studies done using the dual theories.

Keywords:

differential subordination; differential superordination; fractional integral; confluent hypergeometric function

1. Introduction

It is a known fact that the notion of an operator was used from the early stage of the study of complex-valued functions; many already known results can be proven easier with them, and new results are being obtained with them.

Many papers, such as [1,2], studied different operators defined by using the fractional integral of order

λ

also used earlier by S. Owa [3]. Despite that, we also refer to [4,5,6] for theoretical and numerical analyses from real models described by classical PDEs and related operators. The results contained in the present paper were inspired by the outstanding results previously obtained using fractional integrals, and the study was done by applying them to a confluent hypergeometric function. The definition of a fractional integral can be seen in [3] as follows:

Definition 1

([3]). The fractional integral of order α is defined by

D_{z}^{- α} f (z) = \frac{1}{Γ (α)} \int_{0}^{z} \frac{f (ζ)}{{(ζ - z)}^{1 - α}} d ζ,

where α is a positive real number,

f (z)

is an analytic function in a simply connected region of the z-plane containing the origin and the multiplicity of

{(ζ - z)}^{α - 1}

is removed by requiring

ln (ζ - z)

to be real when

(ζ - z) > 0 .

In paper [7] a new operator was introduced by using a fractional integral on the confluent (Kummer) hypergeometric function. The introduction of this operator was inspired by the studies done on this function having in view many aspects, from its combination with other functions, as can be seen in papers [8,9], to its univalence in paper [10].

The confluent (Kummer) hypergeometric function of the first kind is defined in [11] as follows:

Definition 2

([11]). Let

a, c \in C,

c \neq 0, - 1, - 2, \dots

and consider

ϕ (a, c; z) =_{1} F_{1} (a, c; z) = 1 + \frac{a}{c} \frac{z}{1!} + \frac{a (a + 1)}{c (c + 1)} \frac{z^{2}}{2!} + \dots, z \in U .

(1)

This function is called a confluent (Kummer) hypergeometric function, is analytic in

C

and satisfies Kummer’s differential equation:

z w^{″} (z) + (c - z) w^{'} (z) - a w (z) = 0 .

Considering

{(d)}_{k} = \frac{Γ (d + k)}{Γ (d)} = d (d + 1) (d + 2) \dots (d + k - 1) with {(d)}_{0} = 1,

the confluent (Kummer) hypergeometric function can be written as

ϕ (a, c; z) = \sum_{k = 0}^{\infty} \frac{{(a)}_{k}}{{(c)}_{k}} \frac{z^{k}}{k!} = \frac{Γ (c)}{Γ (a)} \sum_{k = 0}^{\infty} \frac{Γ (a + k)}{Γ (c + k)} \frac{z^{k}}{k!} .

(2)

The definition of the operator introduced in [7] is the following:

D_{z}^{- λ} ϕ (a, c; z) = \frac{1}{Γ (λ)} \int_{0}^{z} \frac{ϕ (a, c; t)}{{(z - t)}^{1 - λ}} d t =

(3)

\frac{1}{Γ (λ)} \frac{Γ (c)}{Γ (a)} \sum_{k = 0}^{\infty} \frac{Γ (a + k)}{Γ (c + k) Γ (k + 1)} \int_{0}^{z} \frac{t^{k}}{{(z - t)}^{1 - λ}} d t,

where

λ > 0,

a,

c \in C,

c \neq 0, - 1, - 2, \dots

.

The fractional integral of a confluent hypergeometric function can be written as

D_{z}^{- λ} ϕ (a, c; z) = \frac{Γ (c)}{Γ (a)} \sum_{k = 0}^{\infty} \frac{Γ (a + k)}{Γ (c + k) Γ (λ + k + 1)} z^{k + λ},

(4)

after a simple calculation. Evidently,

D_{z}^{- λ} ϕ (a, c; z) \in H [0, λ] .

The original results which are shown in the next part of this paper were obtained by using this operator and differential subordination and superodination theories, synthesized in the monography [12] published by Miller and Mocanu in 2000 and in paper [13], respectively. The usual notion and definitions are considered.

U = {z \in C : | z | < 1}

is the unit disc of the complex plane,

H (U)

the class of analytic functions in U and

H [a, n] = {f \in H (U) : f (z) = a + a_{n} z^{n} + a_{n + 1} z^{n + 1} + \dots, z \in U},

with n a positive integer and

a \in C

.

Definition 3

([12]). Let

f,

F \in

H (U)

. The function f is said to be subordinate to F if there exists a Schwarz function

w,

analytic in U, with

w (0) = 0

and

| w (z) | < 1

,

z \in U,

such that

f (z) = F (w (z)),

z \in U

. In such a case, we write

f ≺ F

. If F is univalent, then

f ≺ F

if and only if

f (0) = g (0)

and

f (U) \subset g (U)

.

Definition 4

([12]). Let

ψ : C^{3} \times U \to C

and let h be univalent in U. If p is analytic and satisfies the differential subordination

ψ (p (z), z p^{'} (z), z^{2} p^{″} (z); z) ≺ h (z), z \in U,

(5)

then p is called a solution of the differential subordination. The univalent function q is called a dominant of the solutions of the differential subordination, or more simply a dominant, if

p ≺ q

for all p satisfying (5). A dominant

\tilde{q}

that satisfies

\tilde{q} ≺ q

for all dominants q of (5) is said to be the best dominant of (5).

The notion related to differential superordinations was introduced in [13].

Definition 5

([13]). Let

φ : C^{3} \times \bar{U} \to C

and let h be analytic in U. If p and

φ (p (z), z p^{'} (z),

z^{2} p^{″} (z); z)

are univalent in U and satisfy the differential superordination

h (z) ≺ φ (p (z), z p^{'} (z), z^{2} p^{″} (z); z), z \in U,

(6)

then p is called a solution of the differential superordination (6). An analytic function q is called a subordinant of the solutions of the differential superordination or more simply a subordinant, if

q ≺ p

for all p satisfying (6). A subordinant

\tilde{q}

that satisfies

q ≺ \tilde{q}

for all subordinants q of (6) is said to be the best subordinant of (6).

In the process of obtaining the original results from this paper, the following lemmas are needed:

Lemma 1

([12]). Let the function q be univalent in the unit disc U and θ and ϕ be analytic in a domain D containing

q (U)

with

ϕ (w) \neq 0

when

w \in q (U)

. Set

Q (z) = z q^{'} (z) ϕ (q (z))

and

h (z) = θ (q (z)) + Q (z)

. Suppose that Q is star-like univalent in U and

R e (\frac{z h^{'} (z)}{Q (z)}) > 0

,

z \in U

.

If p is analytic with

p (0) = q (0)

,

p (U) \subseteq D

and

θ (p (z)) + z p^{'} (z) ϕ (p (z)) ≺ θ (q (z)) + z q^{'} (z) ϕ (q (z)),

then

p (z) ≺ q (z)

and q is the best dominant.

Lemma 2

([14]). Let the function q be convex univalent in the open unit disc U and ν and ϕ be analytic in a domain D containing

q (U)

. Suppose that

R e (\frac{ν^{'} (q (z))}{ϕ (q (z))}) > 0,

z \in U

and

ψ (z) = z q^{'} (z) ϕ (q (z))

is star-like univalent in U.

If

p (z) \in H [q (0), 1] \cap Q

, with

p (U) \subseteq D

and

ν (p (z)) + z p^{'} (z) ϕ (p (z))

is univalent in U and

ν (q (z)) + z q^{'} (z) ϕ (q (z)) ≺ ν (p (z)) + z p^{'} (z) ϕ (p (z)),

then

q (z) ≺ p (z)

and q is the best subordinant.

2. Main Results

Continuing the work from [7], we get:

Theorem 1.

Let q be an analytic and univalent function in U with

q (z) \neq 0

, ∀

z \in U

and

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in H (U)

, where

λ > 0

and a,

c \in C,

c \neq 0, - 1, - 2, \dots

Suppose that

\frac{z q^{'} (z)}{q (z)}

is star-like univalent in U. Consider

R e (\frac{2 μ}{β} q^{2} (z) + \frac{ξ}{β} q (z) + 1 - z \frac{q^{'} (z)}{q (z)} + z \frac{q^{''} (z)}{q^{'} (z)}) > 0, z \in U,

(7)

with

μ, β, ξ, α \in C

,

β \neq 0

, and

ψ_{λ}^{a, b} (α, β, ξ, μ; z) : = α + β + (ξ - β) \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} +

(8)

μ {(\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2} + β \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}} .

If the following subordination is satisfied by

q,

ψ_{λ}^{a, b} (α, β, ξ, μ; z) ≺ α + ξ q (z) + μ {(q (z))}^{2} + β \frac{z q^{'} (z)}{q (z)},

(9)

then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q (z),

(10)

and q is the best dominant.

Proof.

Consider

p (z) : = \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U, z \neq 0 .

By differentiating with respect to z, we get

p^{'} (z) = \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} + z \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{D_{z}^{- λ} ϕ (a, c; z)} - z {(\frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2}

and

\frac{z p^{'} (z)}{p (z)} = 1 - z \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} + z \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}} .

(11)

By setting

ϕ (w) : = \frac{β}{w}

and

θ (w) : = α + ξ w + μ w^{2},

evidently

ϕ

is analytic in

C \ {0},

ϕ (w) \neq 0,

∀

w \in C \ {0}

and

θ

is analytic in

C .

Considering

Q (z) = z q^{'} (z) ϕ (q (z)) = β \frac{z q^{'} (z)}{q (z)}

and

h (z) = θ (q (z)) + Q (z) = α + ξ q (z) + μ {(q (z))}^{2} + β \frac{z q^{'} (z)}{q (z)},

which reveals that Q is a star-like univalent function in U.

By differentiating, we obtain

h^{'} (z) = ξ q^{'} (z) + 2 μ q (z) q^{'} (z) + β \frac{q^{'} (z)}{q (z)} + β z \frac{q^{″} (z)}{q (z)} - β z {(\frac{q^{'} (z)}{q (z)})}^{2}

and

\frac{z h^{'} (z)}{Q (z)} = \frac{2 μ}{β} q^{2} (z) + \frac{ξ}{β} q (z) + 1 - z \frac{q^{'} (z)}{q (z)} + z \frac{q^{″} (z)}{q (z)} .

We deduce that

R e (\frac{z h^{'} (z)}{Q (z)}) = R e (\frac{2 μ}{β} q^{2} (z) + \frac{ξ}{β} q (z) + 1 - z \frac{q^{'} (z)}{q (z)} + z \frac{q^{″} (z)}{q (z)}) > 0

.

By using (11), we obtain

α + ξ p (z) + μ {(p (z))}^{2} + β \frac{z p^{'} (z)}{p (z)} =

α + β + (ξ - β) \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} + μ {(\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2} + β \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}} .

By using (9), we have

α + ξ p (z) + μ {(p (z))}^{2} + β \frac{z p^{'} (z)}{p (z)} ≺ α + ξ q (z) + μ {(q (z))}^{2} + β \frac{z q^{'} (z)}{q (z)} .

By applying Lemma 1, we get

p (z) ≺ q (z)

, ∀

z \in U,

which means

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q (z)

, ∀

z \in U

and the function q is the best dominant. □

Corollary 1.

Let

λ > 0,

a,

c,

α,

β,

ξ,

μ \in C,

c \neq 0, - 1, - 2, \dots,

β \neq 0,

and relation (7) holds for

q (z) = \frac{1 + A z}{1 + B z}

, with

- 1 \leq B < A \leq 1

. If

ψ_{λ}^{a, b} (α, β, ξ, μ; z) ≺ α + ξ \frac{1 + A z}{1 + B z} + μ {(\frac{1 + A z}{1 + B z})}^{2} + \frac{β (A - B) z}{(1 + A z) (1 + B z)},

with

ψ_{λ}^{a, b}

, which is defined in (8), then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ \frac{1 + A z}{1 + B z},

and

\frac{1 + A z}{1 + B z}

is the best dominant.

Proof.

We get the corollary considering

q (z) = \frac{1 + A z}{1 + B z}

,

- 1 \leq B < A \leq 1

in Theorem 1. □

Corollary 2.

Let

λ > 0

, a,

c,

α,

β,

ξ,

μ \in C

,

c \neq 0, - 1, - 2, \dots,

β \neq 0 .

Assume that (7) holds for

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

,

0 < γ \leq 1

. If

ψ_{λ}^{a, b} (α, β, ξ, μ; z) ≺ α + ξ {(\frac{1 + z}{1 - z})}^{γ} + μ {(\frac{1 + z}{1 - z})}^{2 γ} + \frac{2 β γ z}{1 - z^{2}},

with

ψ_{λ}^{a, b}

is defined in (8), then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ {(\frac{1 + z}{1 - z})}^{γ},

and

{(\frac{1 + z}{1 - z})}^{γ}

is the best dominant.

Proof.

Put

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

,

0 < γ \leq 1

in Theorem 1 to obtain the corollary. □

Theorem 2.

Let q be an analytic and univalent function in U with

q (z) \neq 0,

∀

z \in U,

such that

\frac{z q^{'} (z)}{q (z)}

is a star-like univalent function in U and

R e (\frac{2 μ}{β} q^{2} (z) q^{'} (z) + \frac{ξ}{β} q (z) q^{'} (z)) > 0, for μ, β, ξ \in C, β \neq 0 .

(12)

If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

ψ_{λ}^{a, b} (α, β, ξ, μ; z)

is an univalent function in U, where

ψ_{λ}^{a, b} (α, β, ξ, μ; z)

is defined by (8) and

λ > 0,

a,

c \in C

,

c \neq 0, - 1, - 2, \dots

, then

α + ξ q (z) + μ {(q (z))}^{2} + \frac{β z q^{'} (z)}{q (z)} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z)

(13)

implies

q (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U,

(14)

and function q is the best subordinant.

Proof.

Define the function p by

p (z) : = \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U, z \neq 0 .

Considering

ϕ (w) : = \frac{β}{w}

and

ν (w) : = α + ξ w + μ w^{2},

it is easy to show that

ϕ

is analytic in

C \ {0}

,

ϕ (w) \neq 0

,

w \in C \ {0}

and

ν

is also analytic in

C .

Since

\frac{ν^{'} (q (z))}{ϕ (q (z))} = \frac{q (z) [ξ + 2 μ q (z)] q^{'} (z)}{β}

, it yields

R e (\frac{ν^{'} (q (z))}{ϕ (q (z))}) = R e (\frac{2 μ}{β} q^{2} (z) q^{'} (z) + \frac{ξ}{β} q (z) q^{'} (z)) > 0

, where

μ, β, α \in C,

μ \neq 0 .

From (11) and (13) we get

α + ξ q (z) + μ {(q (z))}^{2} + \frac{β z q^{'} (z)}{q (z)} ≺ α + ξ p (z) + μ {(p (z))}^{2} + \frac{β z p^{'} (z)}{p (z)} .

Applying Lemma 2, we obtain

q (z) ≺ p (z)

; therefore,

q (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U,

and the best subordinant is function q. □

Corollary 3.

Consider

λ > 0

and a,

c,

α,

ξ,

μ,

β \in C

,

c \neq 0, - 1, - 2, \dots,

β \neq 0 .

Assume that (12) holds for

q (z) = \frac{1 + A z}{1 + B z}

,

- 1 \leq B < A \leq 1

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

α + ξ \frac{1 + A z}{1 + B z} + μ {(\frac{1 + A z}{1 + B z})}^{2} + \frac{β (A - B) z}{(1 + A z) (1 + B z)} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z),

where

ψ_{λ}^{a, b}

is defined in (8), then

\frac{1 + A z}{1 + B z} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)},

and the best subordinant is

\frac{1 + A z}{1 + B z}

.

Proof.

When

- 1 \leq B < A \leq 1

, consider

q (z) = \frac{1 + A z}{1 + B z}

in Theorem 2 and obtain the corollary. □

Corollary 4.

Let

λ > 0,

a,

c,

α,

ξ,

μ,

β \in C

,

c \neq 0, - 1, - 2, \dots,

β \neq 0 .

Assume that (12) holds for

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

,

0 < γ \leq 1

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

α + ξ {(\frac{1 + z}{1 - z})}^{γ} + μ {(\frac{1 + z}{1 - z})}^{2 γ} + \frac{2 β γ z}{1 - z^{2}} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z),

where

ψ_{λ}^{a, b}

is defined in (8), then

{(\frac{1 + z}{1 - z})}^{γ} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)},

and the best subordinant is

{(\frac{1 + z}{1 - z})}^{γ} .

Proof.

Put in Theorem 2

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

, when

0 < γ \leq 1

. □

The sandwich theorem is obtained combining Theorems 1 and 2.

Theorem 3.

(Sandwich-type result) Consider

q_{1}

and

q_{2}

analytic and univalent functions in

U,

with

q_{1} (z) \neq 0

and

q_{2} (z) \neq 0

, ∀

z \in U

, such that

\frac{z q_{1}^{'} (z)}{q_{1} (z)}

and

\frac{z q_{2}^{'} (z)}{q_{2} (z)}

are star-like univalent. Assume that

q_{1}

satisfies relation (7) and

q_{2}

satisfies relation (12). If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

ψ_{λ}^{a, b} (α, β, ξ, μ; z)

is defined by (8) and is univalent in

U,

λ > 0

and a,

c \in C

,

c \neq 0, - 1, - 2, \dots

, then

α + ξ q_{1} (z) + μ {(q_{1} (z))}^{2} + \frac{β z q_{1}^{'} (z)}{q_{1} (z)} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z) ≺ α + ξ q_{2} (z) + μ {(q_{2} (z))}^{2} + \frac{β z q_{2}^{'} (z)}{q_{2} (z)},

for

α, β, μ, ξ \in C

,

β \neq 0,

implies

q_{1} (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q_{2} (z),

and

q_{1}

and

q_{2}

are, respectively, the best subordinant and the best dominant.

For

q_{1} (z) = \frac{1 + A_{1} z}{1 + B_{1} z}

,

q_{2} (z) = \frac{1 + A_{2} z}{1 + B_{2} z}

, where

- 1 \leq B_{2} < B_{1} < A_{1} < A_{2} \leq 1

, we have the following corollary.

Corollary 5.

Let a,

c,

α,

ξ,

μ,

β \in C,

c \neq 0, - 1, - 2, \dots,

β \neq 0

and

λ > 0 .

Assume that (7) and (12) hold for

q_{1} (z) = \frac{1 + A_{1} z}{1 + B_{1} z}

, and

q_{2} (z) = \frac{1 + A_{2} z}{1 + B_{2} z}

,

- 1 \leq B_{2} \leq B_{1} < A_{1} \leq A_{2} \leq 1

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in H [q (0), 1] \cap Q

and

α + ξ \frac{1 + A_{1} z}{1 + B_{1} z} + μ {(\frac{1 + A_{1} z}{1 + B_{1} z})}^{2} + \frac{β (A_{1} - B_{1}) z}{(1 + A_{1} z) (1 + B_{1} z)} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z)

≺ α + ξ \frac{1 + A_{2} z}{1 + B_{2} z} + μ {(\frac{1 + A_{2} z}{1 + B_{2} z})}^{2} + \frac{β (A_{2} - B_{2}) z}{(1 + A_{2} z) (1 + B_{2} z)},

with

ψ_{λ}^{a, b}

defined by (8), then

\frac{1 + A_{1} z}{1 + B_{1} z} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ \frac{1 + A_{2} z}{1 + B_{2} z},

hence

\frac{1 + A_{1} z}{1 + B_{1} z}

and

\frac{1 + A_{2} z}{1 + B_{2} z}

are the best subordinant and the best dominant.

For

q_{1} (z) = {(\frac{1 + z}{1 - z})}^{γ_{1}}

,

q_{2} (z) = {(\frac{1 + z}{1 - z})}^{γ_{2}}

, where

0 < γ_{1} < γ_{2} \leq 1

, we have the following corollary.

Corollary 6.

Let

λ > 0,

a,

c,

α,

β,

μ,

ξ \in C,

c \neq 0, - 1, - 2, \dots,

β \neq 0 .

Assume that (7) and (12) hold for

q_{1} (z) = {(\frac{1 + z}{1 - z})}^{γ_{1}}

, and

q_{2} (z) = {(\frac{1 + z}{1 - z})}^{γ_{2}}

,

0 < γ_{1} < γ_{2} \leq 1

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}

\in Q \cap H [q (0), 1]

and

α + ξ {(\frac{1 + z}{1 - z})}^{γ_{1}} + μ {(\frac{1 + z}{1 - z})}^{2 γ_{1}} + \frac{2 β γ_{1} z}{1 - z^{2}} ≺ ψ_{λ}^{a, b} (α, β, ξ, μ; z)

≺ α + ξ {(\frac{1 + z}{1 - z})}^{γ_{2}} + μ {(\frac{1 + z}{1 - z})}^{2 γ_{2}} + \frac{2 β γ_{2} z}{1 - z^{2}},

where

ψ_{λ}^{a, b}

is defined in (8), then

{(\frac{1 + z}{1 - z})}^{γ_{1}} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ {(\frac{1 + z}{1 - z})}^{γ_{2}},

hence

{(\frac{1 + z}{1 - z})}^{γ_{1}}

and

{(\frac{1 + z}{1 - z})}^{γ_{2}}

are the best subordinant and the best dominant, respectively.

By changing the functions

ϕ

and

θ

in Theorem 1, we get:

Theorem 4.

Consider

λ > 0,

a,

c \in C,

c \neq 0, - 1, - 2, \dots,

the convex and univalent function q in U with

q (0) = λ

and

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in H (U),

∀

z \in U

. Suppose that

R e (z \frac{q^{″} (z)}{q^{'} (z)} + \frac{α}{β} + 1) > 0, z \in U,

(15)

where

α, β \in C

, β

\neq 0

, and

ψ_{λ}^{a, b} (α, β; z) : = (α + β) \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} - β {(\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2}

(16)

+ β \frac{z^{2} {(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{D_{z}^{- λ} ϕ (a, c; z)} .

If the following subordination is satisfied by

q,

ψ_{λ}^{a, b} (α, β; z) ≺ α q (z) + β z q^{'} (z), z \in U,

(17)

then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q (z), z \in U,

(18)

and the best dominant is the function q.

Proof.

Define

p (z) : = \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U, z \neq 0

with

p (0) = λ

, an analytic function in U. Differentiating with respect to z we get

p^{'} (z) = \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} - z {(\frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2} + z \frac{{(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{D_{z}^{- λ} ϕ (a, c; z)}

and

z p^{'} (z) = \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} - {(\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2} + \frac{z^{2} {(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{D_{z}^{- λ} ϕ (a, c; z)} .

(19)

Let

ϕ (w) : = β

be analytic in

C \ {0}

with

ϕ (w) \neq 0,

w \in C \ {0}

and

θ (w) : = α w

analytic in

C .

Consider

Q (z) = z q^{'} (z) ϕ (q (z)) = β z q^{'} (z)

star-like univalent in U and

h (z) = θ (q (z)) + Q (z) = α q (z) + β z q^{'} (z) .

We obtain

R e (\frac{z h^{'} (z)}{Q (z)}) = R e (z \frac{q^{″} (z)}{q^{'} (z)} + \frac{α}{β} + 1) > 0

.

From (19), we get

α p (z) + β z p^{'} (z) =

(α + β) \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} - β {(\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)})}^{2} + β \frac{z^{2} {(D_{z}^{- λ} ϕ (a, c; z))}^{″}}{D_{z}^{- λ} ϕ (a, c; z)} .

By using (17), we get

α p (z) + β z p^{'} (z)

≺ α q (z) + β z q^{'} (z) .

Lemma 1 gives

p (z) ≺ q (z)

, ∀

z \in U,

so we obtain

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q (z)

, ∀

z \in U,

and the best dominant is function q. □

Corollary 7.

Let

- 1 \leq B < A \leq 1,

λ > 0,

a,

c,

α,

β \in C,

c \neq 0, - 1, - 2, \dots,

β \neq 0,

and

q (z) = \frac{1 + A z}{1 + B z}

,

z \in U,

fulfilling the relation (15). If

ψ_{λ}^{a, b} (α, β; z) ≺ \frac{β (A - B) z}{{(1 + B z)}^{2}} + α \frac{1 + A z}{1 + B z},

with

ψ_{λ}^{a, b}

defined by (16), then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ \frac{1 + A z}{1 + B z},

and the best dominant is

\frac{1 + A z}{1 + B z}

.

Proof.

In Theorem 4 consider

q (z) = \frac{1 + A z}{1 + B z}

, with

- 1 \leq B < A \leq 1 .

□

Corollary 8.

Let

λ > 0,

a,

c,

α,

β

\in C,

c \neq 0, - 1, - 2, \dots

,

β \neq 0

and

q (z) = {(\frac{1 + z}{1 - z})}^{γ},

0 < γ \leq 1,

fulfilling the relation (15). If

ψ_{λ}^{a, b} (α, β; z) ≺ \frac{2 β γ z}{1 - z^{2}} {(\frac{1 + z}{1 - z})}^{γ} + α {(\frac{1 + z}{1 - z})}^{γ},

with

ψ_{λ}^{a, b}

defined by (16), then

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ {(\frac{1 + z}{1 - z})}^{γ},

and

{(\frac{1 + z}{1 - z})}^{γ}

is the best dominant.

Proof.

In Theorem 4 put

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

, with

0 < γ \leq 1 .

□

By changing the functions

ϕ

and

θ

in Theorem 3 to be the same as in Theorem 4, we get:

Theorem 5.

Let

λ > 0,

a,

c \in C,

c \neq 0, - 1, - 2, \dots

and q be a convex and univalent function in U with

q (0) = λ

. Suppose that

R e (\frac{α}{β} q^{'} (z)) > 0, α, β \in C, β \neq 0 .

(20)

If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}

\in Q \cap H [q (0), 1]

and

ψ_{λ}^{a, b} (α, β; z)

defined in (16) is univalent in U, then

α q (z) + β z q^{'} (z) ≺ ψ_{λ}^{a, b} (α, β; z)

(21)

implies

q (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, \forall z \in U,

(22)

and the best subordinant is the function q.

Proof.

Define the analytic function

p (z) : = \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U, z \neq 0

and

p (0) = λ .

Set

ϕ (w) : = β

to be analytic in

C \ {0}

with

ϕ (w) \neq 0

, ∀

w \in C \ {0}

and

ν (w) : = α w

analytic in

C .

Since

\frac{ν^{'} (q (z))}{ϕ (q (z))} = \frac{α}{β} q^{'} (z)

, from (20) we get

R e (\frac{ν^{'} (q (z))}{ϕ (q (z))}) = R e (\frac{α}{β} q^{'} (z)) > 0

, with

α, β \in C,

β \neq 0 .

Relation (21) gives the differential superordination

α q (z) + β z q^{'} (z) ≺ α p (z) + β z p^{'} (z), z \in U,

and by applying Lemma 2, we obtain

q (z) ≺ p (z)

, which means

q (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)}, z \in U,

and the best subordinant is the function q. □

Corollary 9.

Assume that (20) holds for

q (z) = \frac{1 + A z}{1 + B z}

,

z \in U,

with

- 1 \leq B < A \leq 1,

λ > 0,

a,

c \in C,

c \neq 0, - 1, - 2, \dots

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1],

and

α \frac{1 + A z}{1 + B z} + \frac{β (A - B) z}{{(1 + B z)}^{2}} ≺ ψ_{λ}^{a, b} (α, β; z),

where

ψ_{λ}^{a, b}

is defined in (16),

α, β \in C

,

β \neq 0,

then

\frac{1 + A z}{1 + B z} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)},

and the best subordinant is

\frac{1 + A z}{1 + B z}

.

Proof.

In Theorem 5 consider

q (z) = \frac{1 + A z}{1 + B z}

, with

- 1 \leq B < A \leq 1

. □

Corollary 10.

Assume that (20) holds for

q (z) = {(\frac{1 + z}{1 - z})}^{γ},

0 < γ \leq 1

,

λ > 0,

a,

c \in C,

c \neq 0, - 1, - 2, \dots

If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

α {(\frac{1 + z}{1 - z})}^{γ} + \frac{2 β γ z}{1 - z^{2}} {(\frac{1 + z}{1 - z})}^{γ} ≺ ψ_{λ}^{a, b} (α, β; z),

where

ψ_{λ}^{a, b}

is defined in (16),

α, β \in C

and

β \neq 0,

then

{(\frac{1 + z}{1 - z})}^{γ} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)},

and the best subordinant is

{(\frac{1 + z}{1 - z})}^{γ} .

Proof.

In Theorem 5 consider

q (z) = {(\frac{1 + z}{1 - z})}^{γ}

, with

0 < γ \leq 1 .

□

The sandwich theorem is obtained combining Theorem 4 and Theorem 5.

Theorem 6.

(Sandwich-type result) Consider

q_{1}

and

q_{2}

convex and univalent functions in U with

q_{1} (z) \neq 0

and

q_{2} (z) \neq 0

, ∀

z \in U

. Assume that relation (15) is satisfied by

q_{1}

and relation (20) is satisfied by

q_{2}

. If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

ψ_{λ}^{a, b} (α, β; z)

is univalent in U defined by (16),

λ > 0,

a,

c,

α,

β \in C,

c \neq 0, - 1, - 2, \dots,

β \neq 0

, then

α q_{1} (z) + β z q_{1}^{'} (z) ≺ ψ_{λ}^{a, b} (α, β; z) ≺ α q_{2} (z) + β z q_{2}^{'} (z),

implies

q_{1} (z) ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ q_{2} (z), \forall z \in U,

and the best subordinant is

q_{1}

and the best dominant is

q_{2}

.

Letting

q_{1} (z) = \frac{1 + A_{1} z}{1 + B_{1} z}

,

q_{2} (z) = \frac{1 + A_{2} z}{1 + B_{2} z}

, where

- 1 \leq B_{2} < B_{1} < A_{1} < A_{2} \leq 1

, in Theorem 6 we get

Corollary 11.

Assume that (15) and (20) hold for

q_{1} (z) = \frac{1 + A_{1} z}{1 + B_{1} z}

and

q_{2} (z) = \frac{1 + A_{2} z}{1 + B_{2} z}

, and

λ > 0

, a,

c,

α,

β \in C,

c \neq 0, - 1, - 2, \dots

,

β \neq 0,

- 1 \leq B_{2} \leq B_{1} < A_{1} \leq A_{2} \leq 1 .

If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

α \frac{1 + A_{1} z}{1 + B_{1} z} + \frac{β (A_{1} - B_{1}) z}{{(1 + B_{1} z)}^{2}} ≺ ψ_{λ}^{a, b} (α, β; z)

≺ α \frac{1 + A_{2} z}{1 + B_{2} z} + \frac{β (A_{2} - B_{2}) z}{{(1 + B_{2} z)}^{2}}, \forall z \in U,

where

ψ_{λ}^{a, b}

is defined in (16),

α, β \in C

and

β \neq 0,

then

\frac{1 + A_{1} z}{1 + B_{1} z} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ \frac{1 + A_{2} z}{1 + B_{2} z}, z \in U;

hence, the best subordinant is

\frac{1 + A_{1} z}{1 + B_{1} z}

and the best dominant is

\frac{1 + A_{2} z}{1 + B_{2} z}

.

By setting

q_{1} (z) = {(\frac{1 + z}{1 - z})}^{γ_{1}}

and

q_{2} (z) = {(\frac{1 + z}{1 - z})}^{γ_{2}}

, where

0 < γ_{1} < γ_{2} \leq 1

, in Theorem 6 we obtain

Corollary 12.

Assume that (15) and (20) hold for

q_{1} (z) = {(\frac{1 + z}{1 - z})}^{γ_{1}}

and

q_{2} (z) = {(\frac{1 + z}{1 - z})}^{γ_{2}}

, and

λ > 0,

a,

c,

α,

β \in C,

c \neq 0, - 1, - 2, \dots

,

β \neq 0,

0 < γ_{1} < γ_{2} \leq 1 .

If

\frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} \in Q \cap H [q (0), 1]

and

α {(\frac{1 + z}{1 - z})}^{γ_{1}} + \frac{2 β γ_{1} z}{1 - z^{2}} {(\frac{1 + z}{1 - z})}^{γ_{1}} ≺ ψ_{λ}^{a, b} (α, β; z)

≺ α {(\frac{1 + z}{1 - z})}^{γ_{2}} + \frac{2 β γ_{2} z}{1 - z^{2}} {(\frac{1 + z}{1 - z})}^{γ_{2}}, z \in U,

where

ψ_{λ}^{a, b}

is defined by (16), then

{(\frac{1 + z}{1 - z})}^{γ_{1}} ≺ \frac{z {(D_{z}^{- λ} ϕ (a, c; z))}^{'}}{D_{z}^{- λ} ϕ (a, c; z)} ≺ {(\frac{1 + z}{1 - z})}^{γ_{2}}, \forall z \in U;

hence, the best subordinant is

{(\frac{1 + z}{1 - z})}^{γ_{1}}

and the best dominant is

{(\frac{1 + z}{1 - z})}^{γ_{2}}

.

3. Discussion

Using the previously introduced operator involving the fractional integral of confluent hypergeometric function, further study was done and new subordinations and superordinations were obtained; we also gave their best subordinants and best dominants. Interesting corollaries were stated using particular functions as best subordinants and best dominants of the subordinations and superordinations studied in the theorems stated in this paper. An investigation on this operators’ univalence is yet to be done. Additionally, other aspects related to it can still be investigated, such as introducing new classes of functions with certain properties given by the use of this operator.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

Dedicated to memory of Mitrofan Cioban.

Conflicts of Interest

The author declares no conflict of interest.

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Alb Lupaş, A. New Applications of the Fractional Integral on Analytic Functions. Symmetry 2021, 13, 423. https://0-doi-org.brum.beds.ac.uk/10.3390/sym13030423

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New Applications of the Fractional Integral on Analytic Functions

Abstract

1. Introduction

2. Main Results

3. Discussion

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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