On Geometric Properties of Normalized Hyper-Bessel Functions

Ahmad, Khurshid; Mustafa, Saima; Din, Muhey U.; ur Rehman, Shafiq; Raza, Mohsan; Arif, Muhammad

doi:10.3390/math7040316

Open AccessArticle

On Geometric Properties of Normalized Hyper-Bessel Functions

by

Khurshid Ahmad

¹,

Saima Mustafa

²,

Muhey U. Din

³,

Shafiq ur Rehman

⁴,

Mohsan Raza

^5,* and

Muhammad Arif

¹

Department of Mathematics, Abdul Wali Khan University, Mardan 23200, Pakistan

²

Department of Mathematics, PMAS Arid Agriculture University, Rawalpindi 46000, Pakistan

³

Department of Mathematics, Islamia College Faisalabad, Faisalabad 38000, Pakistan

⁴

Department of Mathematics, COMSATS University Islamabad, Attock 43600, Pakistan

⁵

Department of Mathematics, Government College University Faisalabad, Faisalabad 38000, Pakistan

^*

Author to whom correspondence should be addressed.

Mathematics 2019, 7(4), 316; https://doi.org/10.3390/math7040316

Submission received: 18 February 2019 / Revised: 20 March 2019 / Accepted: 21 March 2019 / Published: 28 March 2019

(This article belongs to the Special Issue Mathematical Analysis and Analytic Number Theory 2019)

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Abstract

:

In this paper, the normalized hyper-Bessel functions are studied. Certain sufficient conditions are determined such that the hyper-Bessel functions are close-to-convex, starlike and convex in the open unit disc. We also study the Hardy spaces of hyper-Bessel functions.

Keywords:

univalent functions; starlikeness; convexity; close-to-convexity; hyper-Bessel functions; Hardy space

MSC:

Primary 30C45, 33C10; Secondary 30C20, 30C75

1. Introduction

Let

H

denote the class of functions that are analytic in

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

, and

A

denote the class of functions f that are analytic in

U

having the Taylor series form

f (z) = z + \sum_{n = 2}^{\infty} a_{n} z^{n}, z \in U .

(1)

The class

S

of univalent functions f is the class of those functions in

A

that are one-to-one in

U

. Let

S^{*}

denote the class of all functions f such that

f (U)

is star-shaped domain with respect to origin while

C

denotes the class of functions f such that

f

maps

U

onto a domain which is convex. A function f in

A

belongs to the class

S^{*} (α)

of starlike functions of order

α

if and only if

R e (z f^{'} (z) / f (z)) > α, α \in [0, 1) .

For

α \in [0, 1)

, a function

f \in A

is convex of order

α

if and only if

R e (1 + z f^{″} (z) / f^{'} (z)) > α

in

\dot{U}

. This class of functions is dented by

C (α) .

It is clear that

S^{*} (0) = S^{*}

and

C (0)

=

C

are the usual classes of starlike and convex functions respectively. A function f in

A

is said to be close-to-convex function in

\dot{U}

, if

f (U)

is close-to-convex. That is, the complement of

f (U)

can be expressed as the union of non-intersecting half-lines. In other words a function f in

A

is said to be close-to-convex if and only if

R e (z f^{'} (z) / g (z)) > 0

for some starlike function

g .

In particular if

g (z) = z,

then

R e (f^{'} (z)) > 0

. The class of close-to-convex functions is denoted by

K

. The functions in class

K

are univalent in

U

. For some details about these classes of functions one can refer to [1]. Consider the class

P_{δ} (α)

of functions p such that

p (0) = 1

and

R e \{e^{i δ} p (z)\} > α, z \in U, α \in [0, 1), δ \in R .

Also consider the class

R_{δ} (α)

of functions

f \in A

such that

R e \{e^{i δ} f^{'} (z)\} > α, z \in U, α \in [0, 1), δ \in R .

These classes were introduced and investigated by Baricz [2]. For

δ = 0,

we have the classes

P_{0} (α)

and

R_{0} (α)

. Also for

δ = 0

and

α = 0,

we have the classes

P

and

R

.

Special functions have great importance in pure and applied mathematics. The wide use of these functions have attracted many researchers to work on the different directions. Geometric properties of special functions such as Hypergeometric functions, Bessel functions, Struve functions, Mittag-Lefller functions, Wright functions and some other related functions is an ongoing part of research in geometric function theory. We refer for some geometric properties of these functions [2,3,4,5,6] and references therein.

We consider the hyper-Bessel function in the form of the hypergeometric functions defined as

J_{γ_{c}} (z) = \frac{{(\frac{z}{c + 1})}^{γ_{1} + γ_{2} + \dots + γ_{c}}}{\prod_{i = 1}^{c} Γ (γ_{i} + 1)}_{0} F_{c} (\bar{(γ_{c} + 1)}; - {(\frac{z}{c + 1})}^{c + 1}),

(2)

where the notation

_{m} F_{n} ((\binom{{(η)}_{m}}{{(δ)}_{n}}); x) = \sum_{k = 0}^{\infty} \frac{{(η_{1})}_{k} {(η_{2})}_{k} \dots {(η_{m})}_{k}}{{(δ_{1})}_{k} {(δ_{2})}_{k} \dots {(δ_{n})}_{k}} \frac{x^{k}}{k!},

(3)

represents the generalized Hypergeometric functions and

γ_{c}

represents the array of c parameters

γ_{1}, γ_{2}, \dots, γ_{c} .

By combining Equations (2) and (3), we get the following infinite representation of the hyper-Bessel functions

J_{γ_{c}} (z) = \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n}}{n! \prod_{i = 1}^{c} Γ (γ_{i} + n + 1)} {(\frac{z}{c + 1})}^{n (c + 1) + γ_{1} + γ_{2} + \dots + γ_{c}},

(4)

since

J_{γ_{c}}

is not in class

A .

Therefore, consider the hyper-Bessel function

J_{γ_{c}}

which is defined by

J_{γ_{c}} (z) = 1 + \sum_{n = 2}^{\infty} \frac{{(- 1)}^{n - 1}}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(α_{i} + 1)}_{n - 1}} z^{(n - 1) (c + 1)} .

(5)

It is observed that the function

J_{γ_{c}}

defined in (5) is not in the class

A .

Here, we consider the following normalized form of the hyper-Bessel function for our own convenience.

H_{γ_{c}} (z) = z J_{γ_{c}} (z) = z + \sum_{n = 2}^{\infty} \frac{{(- 1)}^{n - 1}}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n - 1}} z^{(n - 1) (c + 1) + 1} .

(6)

For some details about the hyper-Bessel functions one can refer to [7,8,9]. Recently Aktas et al. [8] studied some geometric properties of hyper-Bessel function. In particular, they studied radii of starlikeness, convexity, and uniform convexity of hyper-Bessel functions. Motivated by the above works, we study the geometric properties of hyper-Bessel function

H_{γ_{c}}

given by the power series (6). We determine the conditions on parameters that ensure the hyper-Bessel function to be starlike of order

α,

convex of order

α,

close-to-convex of order

(\frac{1 + α}{2})

. We also study the convexity and starlikeness in the domain

U_{1 / 2} = \{z : |z| < \frac{1}{2}\} .

Sufficient conditions on univalency of an integral operator defined by hyper-Bessel function is also studied. We find the conditions on normalized hyper-Bessel function to belong to the Hardy space

H^{p} .

To prove our results, we require the following.

Lemma 1.

If

f \in A

satisfy

|f^{'} (z) - 1| < 1

for each

z \in U

, then f is convex in

U_{1 / 2} = \{z : |z| < \frac{1}{2}\}

[10].

Lemma 2.

If

f \in A

satisfy

|\frac{f (z)}{z} - 1| < 1

for each

z \in U

, then f is starlike in

U_{1 / 2} = \{z : |z| < \frac{1}{2}\}

[11].

Lemma 3.

Let

β \in C

with

R e (β) > 0,

c \in C

with

|c| \leq 1,

c \neq - 1

[12]. If

h \in A

satisfies

|c {|z|}^{2 β} + (1 - {|z|}^{2 β} \frac{z h^{″} (z)}{β h^{'} (z)})| \leq 1, z \in U,

then the integral operator

C_{β} (z) = {\{β \int_{0}^{z} t^{β - 1} h^{'} (t) d t\}}^{1 / β}, z \in U,

is analytic and univalent in

U

.

Lemma 4.

If

f \in A

[13] satisfies the inequality

|z f^{″} (z)| < \frac{1 - α}{4}, (z \in U, 0 \leq α < 1),

then

R e f^{'} (z) > \frac{1 + α}{4}, (z \in U, 0 \leq α < 1) .

Lemma 5.

If

f \in A

satisfies

|\frac{z f^{″} (z)}{f^{'} (z)}| < \frac{1}{2}

[14], then

f \in UCV .

2. Geometric Properties of Normalized Hyper-Bessel Function

Theorem 1.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

with

α \in [0, 1)

and

z \in U

. Then the following results are true:

(i): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{(2 c + 7 - 5 α) + \sqrt{{(2 c + 7 - 5 α)}^{2} - 8 (1 - α) (c + 4 - 3 α)}}{4 ς (1 - α)},$ then $H_{γ_{c}} \in S^{*} (α) .$
(ii): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{\{(2 c + 7) (1 - α) - (2 c^{2} + 5 c + 3)\} + Ψ}{2 ς \{2 (1 - α) - (4 c^{2} + 10 c + 6)\}}$ , where

$Ψ = \sqrt{{\{(2 c + 7) (1 - α) - (2 c^{2} + 5 c + 3)\}}^{2} - 4 \{2 (1 - α) - (4 c^{2} + 10 c + 6)\} (c + 4) (1 - α)},$

then $H_{γ_{c}} \in C (α) .$
(iii): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{1 - α}{ς (1 - α) - 4 (c + 1) (2 c + 3)}$ , then $H_{γ_{c}} \in K (\frac{1 + α}{2}) .$
(iv): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{3 - α}{2 ς (1 - α)}$ , then $\frac{H_{γ_{c}}}{z} \in P (α) .$

Proof.

(i) By using the inequalities

n! \geq n, {(γ_{i} + 1)}_{n} \geq {(γ_{i} + 1)}^{n}, \forall n \in N,

we obtain

|H_{γ_{c}}^{^{'}} (z) - \frac{H_{γ_{c}} (z)}{z}| \leq \frac{(c + 1)}{ζ η} \sum_{n \geq 1} {(\frac{1}{ζ η})}^{n - 1},

where

ζ = {(c + 1)}^{c + 1} and η = \prod_{i = 1}^{c} (γ_{i} + 1) .

This implies that

|H_{γ_{c}}^{^{'}} (z) - \frac{H_{γ_{c}} (z)}{z}| \leq \frac{c + 1}{ζ η - 1} .

(7)

Furthermore, if we use the inequality

n! \geq 2^{n - 1}, {(γ_{i} + 1)}_{n} \geq {(γ_{i} + 1)}^{n}, \forall n \in N,

then

\begin{matrix} |\frac{H_{γ_{c}} (z)}{z}| & = & |1 + \sum_{n \geq 1} \frac{{(- 1)}^{n - 1}}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n - 1}} z^{(n - 1) (c + 1)}| \\ \geq & 1 - \frac{1}{ζ η} \sum_{n \geq 1} {(\frac{1}{2 ζ η})}^{n - 1} \\ = & \frac{2 ζ η - 3}{2 ζ η - 1} . \end{matrix}

(8)

By combining Equations (7) and (8), we obtain

|\frac{z H_{γ_{c}}^{^{'}} (z)}{H_{γ_{c}} (z)} - 1| \leq \frac{(c + 1) (2 ζ η - 1)}{(ζ η - 1) (2 ζ η - 3)} .

(9)

For

H_{γ_{c}} \in S^{*} (α),

we must have

\frac{(c + 1) (2 ζ η - 1)}{(ζ η - 1) (2 ζ η - 3)} < 1 - α .

So,

H_{γ_{c}} \in S^{*} (α),

where

0 \leq α < 1 - \frac{(c + 1) (2 ζ η - 1)}{(ζ η - 1) (2 ζ η - 3)} .

(ii) To prove that the function

H_{γ_{c}} \in C (α),

we have to show that

|\frac{z H_{γ_{c}}^{^{″}} (z)}{H_{γ_{c}}^{^{'}} (z)}| < 1 - α .

Consider

\begin{matrix} H_{γ_{c}} (z) & = & \sum_{n \geq 0} \frac{{(- 1)}^{n}}{n! {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n}} z^{n (c + 1) + 1}, \\ z H_{γ_{c}}^{″} (z) & = & \sum_{n \geq 0} \frac{\{n^{2} {(c + 1)}^{2} + n (c + 1)\} {(- 1)}^{n}}{n! {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n}} z^{n (c + 1)}, \\ = & \sum_{n \geq 1} \frac{{(n - 1)}^{2} {(c + 1)}^{2}}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n - 1}} z^{n (c + 1)} \\ + \sum_{n \geq 1} \frac{(n - 1) (c + 1)}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n - 1}} z^{n (c + 1)} . \end{matrix}

By using the inequalities

(n - 1)! \geq \frac{{(n - 1)}^{2}}{2}, (n - 1)! \geq n - 1, {(α_{i} + 1)}_{n} \geq {(α_{i} + 1)}^{n}, \forall n \in N,

we have

\begin{matrix} |z H_{α_{c}}^{″} (z)| & = & |\begin{matrix} \sum_{n \geq 1} \frac{{(n - 1)}^{2} {(c + 1)}^{2}}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(α_{i} + 1)}_{n - 1}} z^{n (c + 1)} \\ + \sum_{n \geq 1} \frac{(n - 1) (c + 1)}{(n - 1)! {(c + 1)}^{(n - 1) (c + 1)} \prod_{i = 1}^{c} {(α_{i} + 1)}_{n - 1}} z^{n (c + 1)} \end{matrix}| \\ \leq & 2 {(c + 1)}^{2} \sum_{n \geq 1} {(\frac{1}{ζ η})}^{n - 1} + (c + 1) \sum_{n \geq 1} {(\frac{1}{ζ η})}^{n - 1}, \end{matrix}

where

ζ = {(c + 1)}^{c + 1} and η = \prod_{i = 1}^{c} (γ_{i} + 1) .

This implies that

|z H_{γ_{c}}^{″} (z)| \leq \frac{ζ η (c + 1) (2 c + 3)}{(ζ η - 1)}

(10)

Furthermore, if we use the inequalities

n! \geq n, n! \geq 2^{n - 1}, {(γ_{i} + 1)}_{n} \geq {(γ_{i} + 1)}^{n}, \forall n \in N,

then we get

\begin{matrix} |H_{γ_{c}}^{'} (z)| \geq 1 - \sum_{n \geq 1} \frac{n (c + 1) + 1}{n! ζ^{n} η^{n}} \\ \geq & 1 - \frac{c + 1}{ζ η} \sum_{n \geq 1} {(\frac{1}{ζ η})}^{n - 1} + \frac{1}{ζ η} \sum_{n \geq 1} {(\frac{1}{2 ζ η})}^{n - 1} \\ = & \frac{(ζ η - 1) (2 ζ η - 3) - (2 ζ η - 1) (c + 1)}{(ζ η - 1) (2 ζ η - 1)} . \end{matrix}

(11)

By combining Equations (10) and (11), we get

|\frac{z H_{γ_{c}}^{^{″}} (z)}{H_{γ_{c}}^{^{'}} (z)}| \leq \frac{ζ η (2 ζ η - 1) (c + 1) (2 c + 3)}{(ζ η - 1) (2 ζ η - 3) - (2 ζ η - 1) (c + 1)} < 1 - α .

This implies that

H_{γ_{c}} \in C (α),

where

0 \leq α < 1 - \frac{ζ η (2 ζ η - 1) (c + 1) (2 c + 3)}{(ζ η - 1) (2 ζ η - 3) - (2 ζ η - 1) (c + 1)} .

(iii) Using the inequality (10) and Lemma 4, we have

|z H_{γ_{c}}^{″} (z)| \leq \frac{ζ η (c + 1) (2 c + 3)}{(ζ η - 1)} < \frac{1 - α}{4},

where

0 \leq α < 1 - 4 \frac{ζ η (c + 1) (2 c + 3)}{(ζ η - 1)}

. This shows that

H_{γ_{c}} \in K (\frac{1 + α}{2}) .

Therefore

R e (H_{γ_{c}}^{'} (z)) > \frac{1 + α}{2} .

(iv) To prove that

\frac{H_{γ_{c}}}{z} \in P (α)

, we have to show that

|h (z) - 1| < 1

, where

h (z) = \frac{H_{γ_{c}} (z) / z - α}{1 - α} .

By using the inequality

2^{n - 1} \leq n!, n \in N,

we have

\begin{matrix} |h (z) - 1| & = & |\frac{1}{1 - α} \sum_{n = 1}^{\infty} \frac{{(- 1)}^{n}}{n! {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n}} z^{n (c + 1) + 1}| \\ \leq & \frac{1}{(1 - α)} \frac{1}{ς η} \sum_{n = 1}^{\infty} {(\frac{1}{2 ς η})}^{n - 1} \\ = & \frac{1}{(1 - α)} \frac{2}{2 ς η - 1} . \end{matrix}

Therefore,

\frac{H_{γ_{c}}}{z} \in P (α)

for

0 < α < 1 - \frac{2}{2 {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n} - 1} .

□

Putting

α = 0

in Theorem 1, we have the following results.

Corollary 1.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

and

z \in U

. Then the followings are true:

(i): If $\prod_{i = 1}^{c} (γ_{i} + 1) >$ , $\frac{(2 c + 7) + \sqrt{{(2 c + 7)}^{2} - 8 (c + 4)}}{4 ς},$ then $H_{γ_{c}} \in S^{*} .$
(ii): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{\{(2 c + 7) - (2 c^{2} + 5 c + 3)\} + \sqrt{{\{(2 c + 7) - (2 c^{2} + 5 c + 3)\}}^{2} - 4 (c + 4) \{2 - (4 c^{2} + 10 c + 6)\}}}{2 ς \{2 - (4 c^{2} + 10 c + 6)\}}$ ,
then $H_{γ_{c}} \in C .$
(iii): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{1}{ς {1 - 4 (c + 1) (2 c + 3)}}$ , then $H_{γ_{c}} \in K (\frac{1}{2}) .$
(iv): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{3}{2 ς}$ , then $\frac{H_{γ_{c}}}{z} \in P .$

3. Starlikeness and Convexity in $U_{1 / 2}$

Theorem 2.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

and

z \in U

. Then the following assertions are true:

(i): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{3}{2 ς},$ then $H_{γ_{c}}$ is starlike in $U_{1 / 2} .$
(ii): If $\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{(c + 3) + \sqrt{c^{2} + 4 c + 2}}{2 ς},$ then $H_{γ_{c}}$ is convex in $U_{1 / 2} .$

Proof.

(i) By using the inequality

2^{n - 1} \leq n!,

n \in N,

we obtain

\begin{matrix} |\frac{H_{γ_{c}} (z)}{z} - 1| \leq & |\sum_{n = 1}^{\infty} \frac{{(- 1)}^{n}}{n! {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n}} z^{n (c + 1)}| \\ \leq \sum_{n = 1}^{\infty} (\frac{1}{n! {\{{(c + 1)}^{(c + 1)}\}}^{n} {\{\prod_{i = 1}^{c} (γ_{i} + 1)\}}^{n}}) \\ \leq \frac{1}{ς η} \sum_{n = 1}^{\infty} {(\frac{1}{2 ς η})}^{n - 1} = \frac{2}{2 ς η - 1} . \end{matrix}

In view of Lemma 2,

H_{γ_{c}}

is starlike in

U_{1 / 2},

if

\frac{2}{2 ς η - 1} < 1,

which is true under the given hypothesis.

(ii) Consider,

\begin{matrix} |H_{γ_{c}}^{'} (z) - 1| \leq & \sum_{n = 1}^{\infty} \frac{n (c + 1) + 1}{n! {(c + 1)}^{n (c + 1)} \prod_{i = 1}^{c} {(γ_{i} + 1)}_{n}} \\ \leq \sum_{n = 1}^{\infty} \frac{n (c + 1)}{n! ζ^{n} η^{n}} + \sum_{n = 1}^{\infty} \frac{1}{n! ζ^{n} η^{n}} . \end{matrix}

Since,

n! \geq n,

for all

n \in N

and

n! \geq 2^{n - 1},

for all

n \in N .

Therefore

\begin{matrix} |H_{γ_{c}}^{'} (z) - 1| & \leq & \frac{c + 1}{ζ η} \sum_{n = 1}^{\infty} {(\frac{1}{ζ η})}^{n - 1} + \frac{1}{ζ η} \sum_{n = 1}^{\infty} {(\frac{1}{2 ζ η})}^{n - 1} \\ = & \frac{(c + 1) (2 ζ η - 1) + 2 (ζ η - 1)}{(ζ η - 1) (2 ζ η - 1)} . \end{matrix}

In view of Lemma 1,

H_{γ_{c}}

is convex in

U_{1 / 2},

if

\frac{(c + 1) (2 ζ η - 1) + 2 (ζ η - 1)}{(ζ η - 1) (2 ζ η - 1)} < 1,

but this is true under the hypothesis. □

Consider the integral operator

F_{β} : U \to C

, where

β \in C,

β \neq 0,

F_{β} (z) = {\{β \int_{0}^{z} t^{β - 2} H_{γ_{c}} (t) d (t)\}}^{\frac{1}{β}}, z \in U .

Here

F_{β} \in A .

In the next theorem, we obtain the conditions so that

F_{β}

is univalent in

U .

Theorem 3.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

and

z \in U

. Let

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{(2 c + 7) + \sqrt{{(7 + 2 c)}^{2} - 8 (2 c + 3)}}{4 ς}

and suppose that

M \in R^{+}

such that

|H_{γ_{c}} (z)| \leq M

in the open unit disc. If

|β - 1| + \frac{(c + 1) (2 ζ η - 1)}{(ζ η - 1) (2 ζ η - 3)} + \frac{M}{|β|} \leq 1,

then

F_{β}

is univalent in

U .

Proof.

A calculations gives us

\frac{z F_{β}^{″} (z)}{F_{β}^{'} (z)} = \frac{z H_{γ_{c}}^{^{'}} (z)}{H_{γ_{c}} (z)} + \frac{z^{β - 1}}{β} H_{γ_{c}} (z) + β - 2, z \in U .

Since

H_{γ_{c}} \in A,

then by the Schwarz Lemma, triangle inequality and Equation (9), we obtain

\begin{matrix} (1 - {|z|}^{2}) |\frac{z F_{β}^{″} (z)}{F_{β}^{'} (z)}| & \leq & (1 - {|z|}^{2}) \{|β - 1| + |\frac{z H_{γ_{c}}^{^{'}} (z)}{H_{γ_{c}} (z)} - 1| + \frac{{|z|}^{R (β)}}{|β|} |\frac{H_{γ_{c}} (z)}{z}|\} \\ \leq & (1 - {|z|}^{2}) \{|β - 1| + \frac{(c + 1) (2 ζ η - 1)}{(ζ η - 1) (2 ζ η - 3)} + \frac{M}{|β|}\} \\ \leq & 1 . \end{matrix}

This shows that the given integral operator satisfying the Becker’s criterion for univalence [12], hence

F_{β}

is univalent in

U .

□

4. Uniformly Convexity of Hyper-Bessel Functions

Theorem 4.

If

i \in {1, 2, 3, \dots, c},

γ_{i} > - 1

and

z \in U

. If

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{(4 c^{2} + 8 c - 1) + \sqrt{{(4 c^{2} + 8 c - 1)}^{2} - 4 (c + 4) (8 c^{2} + 20 c + 10)}}{2 (8 c^{2} + 20 c + 10) ς},

then

H_{γ_{c}} \in UCV .

Proof.

Since

|\frac{z H_{γ_{c}}^{^{″}} (z)}{H_{γ_{c}}^{^{'}} (z)}| \leq \frac{ζ η (2 ζ η - 1) (c + 1) (2 c + 3)}{(ζ η - 1) (2 ζ η - 3) - (2 ζ η - 1) (c + 1)} .

By using Lemma 5, we have

|\frac{z H_{γ_{c}}^{″} (z)}{H_{γ_{c}}^{'} (z)}| < \frac{1}{2},

if

\frac{ζ η (2 ζ η - 1) (c + 1) (2 c + 3)}{(ζ η - 1) (2 ζ η - 3) - (2 ζ η - 1) (c + 1)} < \frac{1}{2} .

This implies that

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{(4 c^{2} + 8 c - 1) + \sqrt{{(4 c^{2} + 8 c - 1)}^{2} - 4 (c + 4) (8 c^{2} + 20 c + 10)}}{2 (8 c^{2} + 20 c + 10) ς} .

Hence, we obtain the required result. □

5. Hardy Spaces Of Hyper-Bessel Functions

Let

H^{\infty}

denote the space of all bounded functions on

H

. Let

f \in H

, set

M_{p} (r, f) = \{\begin{matrix} {(\frac{1}{2 π} \overset{2 π}{\int_{0}} {|f (r e^{i θ})|}^{p} d θ)}^{1 / p}, 0 < p < \infty, \\ sup \{|f (z)| : |z| \leq r\}, p = \infty . \end{matrix}

Then the function

f \in

H^{p}

if

M_{p} (r, f)

is bounded for all

r \in [0, 1) .

It is clear that

H^{\infty} \subset H^{q} \subset H^{p}, 0 < q < p < \infty .

For some details, see [15] (page 2). It is also known [16] (page 64, Section 4.5) (see also [15]) that for

R e (f^{'} (z)) > 0

in

U

, then

\{\begin{matrix} f^{'} \in H^{q}, q < 1, \\ f \in H^{q / (1 - q)}, 0 < q < 1 . \end{matrix}

We require the following results to prove our results.

Lemma 6.

P_{0} (α) * P_{0} (β) \subset P_{0} (γ)

, where

γ = 1 - 2 (1 - α) (1 - β)

with

α, β < 1

and the value of γ is best possible [17].

Lemma 7.

For

α, β < 1

and

γ = 1 - 2 (1 - α) (1 - β),

we have

R_{0} (α) * R_{0} (β) \subset R_{0} (γ)

or equivalently

P_{0} (α) * P_{0} (β) \subset P_{0} (γ)

[18].

Lemma 8.

If the function

f \in C (α)

[19], where

α \in [0, 1)

is not of the form

f (z) = \{\begin{matrix} θ + η {(1 - z e^{i γ})}^{2 α - 1}, α \neq \frac{1}{2}, \\ θ + η log (1 - z e^{i γ}), α \neq \frac{1}{2}, \end{matrix}

for ζ,

η \in C

and

γ \in R,

then the following statements hold:

(i): There exists $δ = δ (f) > 0,$ such that $f^{'} \in H^{δ + \frac{1}{2 (1 - α)}}$ .
(ii): If $α \in [1, 1 / 2)$ , then there exists $τ = τ (f) > 0,$ such that $f \in H^{τ + 1 / (1 - 2 α)}$ .
(iii): If $α \geq 1 / 2,$ then $f \in H^{\infty} .$

Theorem 5.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

with

α \in [0, 1)

and

z \in U

. Let

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{\{(2 c + 7) (1 - α) - (2 c^{2} + 5 c + 3)\} + Φ}{2 ς \{2 (1 - α) - (4 c^{2} + 10 c + 6)\}},

where

Φ = \sqrt{{\{(2 c + 7) (1 - α) - (2 c^{2} + 5 c + 3)\}}^{2} - 4 \{2 (1 - α) - (4 c^{2} + 10 c + 6)\} (c + 4) (1 - α)} .

Then

(i): $H_{γ_{c}} \in H^{1 / 1 - 2 α}$ for $α \in [0, 1 / 2) .$
(ii): $H_{γ_{c}} \in H^{\infty}$ for $α \geq 1 / 2 .$

Proof.

By using the definition of Hypergeometric function

_{2} F_{1} (a, b, c; z) = \sum_{n = 0}^{\infty} \frac{{(a)}_{n} {(b)}_{n}}{{(c)}_{n}} \frac{z^{n}}{n!},

we have

\begin{matrix} θ + \frac{ϑ z}{{(1 - z e^{i ψ})}^{1 - α}} & = & θ + ϑ z_{2} F_{1} (1, 1 - 2 α, 1; z e^{i ψ}) \\ = & θ + ϑ \sum_{n = 0}^{\infty} \frac{{(1 - 2 α)}_{n}}{n!} e^{i ψ n} z^{n + 1}, \end{matrix}

for

θ

,

ϑ \in C

,

α \neq 1 / 2

and for

ψ \in R .

On the other hand

\begin{matrix} θ + ϑ log (1 - z e^{i ψ}) & = & θ - ϑ z_{2} F_{1} (1, 1, 2; z e^{i ψ}) \\ = & θ - ϑ \sum_{n = 0}^{\infty} \frac{1}{n + 1} e^{i ψ n} z^{n + 1} . \end{matrix}

This implies that

H_{γ_{c}}

is not of the form

θ + ϑ z {(1 - z e^{i ψ})}^{2 α - 1}

for

α \neq 1 / 2

and

θ + ϑ log (1 - z e^{i ψ})

for

α = 1 / 2

respectively. Also from part (ii) of Theorem 1,

H_{γ_{c}}

is convex of order

α .

Hence by using Lemma 8, we have required result. □

Theorem 6.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

with

α \in [0, 1)

and

z \in U

. If

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{3 - α}{2 ς (1 - α)}

, then

\frac{H_{γ_{c}}}{z} \in P (α)

. If

f \in R (ϱ)

, with

ϱ < 1,

then

H_{γ_{c}} * f

\in R (τ)

, where

τ = 1 - 2 (1 - α) (1 - ϱ) .

Proof.

Let

h (z) = H_{γ_{c}} (z) * f (z)

, then

h^{'} (z) = \frac{H_{γ_{c}} (z)}{z} * f^{'} (z) .

Now from Theorem 1 of part (iv), we have

\frac{H_{γ_{c}}}{z} \in P (α)

. By using Lemma 6 and the fact that

f^{'} \in P (ϱ)

, we have

h^{'} (z) \in P (τ)

, where

τ = 1 - 2 (1 - α) (1 - ϱ) .

Consequently, we have

h \in R (τ)

. □

Corollary 2.

Let

i \in {1, 2, 3, \dots, c}, γ_{i} > - 1

with

α \in [0, 1)

and

z \in U

. If

\prod_{i = 1}^{c} (γ_{i} + 1) > \frac{3 - α}{2 ς (1 - α)}

, then

\frac{H_{γ_{c}}}{z} \in P (α)

. If

f \in R (ϱ)

,

ϱ = (1 - 2 α) (2 - 2 α)

, then

H_{γ_{c}} * f \in R (0)

.

Author Contributions

Conceptualization, K.A.; Formal analysis, S.M. and M.R.; Funding acquisition, M.U.D. and S.u.R.; Investigation, K.A.; Methodology, M.A. and M.R.; Supervision, M.A.; Validation, S.M. and M.R.; Visualization, K.A.;Writing—original draft, K.A.;Writing—review and editing, M.R.

Funding

The work here is partially supported by HEC grant: 5689/Punjab/NRPU/R&D/HEC/2016.

Acknowledgments

The authors thank the referees for their valuable suggestions to improve the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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Ahmad, K.; Mustafa, S.; Din, M.U.; ur Rehman, S.; Raza, M.; Arif, M. On Geometric Properties of Normalized Hyper-Bessel Functions. Mathematics 2019, 7, 316. https://doi.org/10.3390/math7040316

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Ahmad K, Mustafa S, Din MU, ur Rehman S, Raza M, Arif M. On Geometric Properties of Normalized Hyper-Bessel Functions. Mathematics. 2019; 7(4):316. https://doi.org/10.3390/math7040316

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Ahmad, Khurshid, Saima Mustafa, Muhey U. Din, Shafiq ur Rehman, Mohsan Raza, and Muhammad Arif. 2019. "On Geometric Properties of Normalized Hyper-Bessel Functions" Mathematics 7, no. 4: 316. https://doi.org/10.3390/math7040316

APA Style

Ahmad, K., Mustafa, S., Din, M. U., ur Rehman, S., Raza, M., & Arif, M. (2019). On Geometric Properties of Normalized Hyper-Bessel Functions. Mathematics, 7(4), 316. https://doi.org/10.3390/math7040316

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On Geometric Properties of Normalized Hyper-Bessel Functions

Abstract

1. Introduction

2. Geometric Properties of Normalized Hyper-Bessel Function

3. Starlikeness and Convexity in $U_{1 / 2}$

4. Uniformly Convexity of Hyper-Bessel Functions

5. Hardy Spaces Of Hyper-Bessel Functions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

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On Geometric Properties of Normalized Hyper-Bessel Functions

Abstract

1. Introduction

2. Geometric Properties of Normalized Hyper-Bessel Function

3. Starlikeness and Convexity in U 1 / 2

4. Uniformly Convexity of Hyper-Bessel Functions

5. Hardy Spaces Of Hyper-Bessel Functions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

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3. Starlikeness and Convexity in $U_{1 / 2}$