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Properties for Certain Subclasses of Analytic Functions Associated with Generalized Multiplier Transformation

2014-07-31LIZongtaoGUODong

LI Zong-tao,GUO Dong

(1.Foundation Department,Guangzhou Civil Aviation College,Guangzhou 510403,China;2.Foundation Department,Chuzhou Vocational and Technical College,Chuzhou 239000,China)

Properties for Certain Subclasses of Analytic Functions Associated with Generalized Multiplier Transformation

LI Zong-tao1,GUO Dong2

(1.Foundation Department,Guangzhou Civil Aviation College,Guangzhou 510403,China;2.Foundation Department,Chuzhou Vocational and Technical College,Chuzhou 239000,China)

In this paper,we introduce certain new subclasses of analytic functions def i ned by generalized multiplier transformation.By using the dif f erential subordination,we study and investigate various inclusion properties of these classes.Also inclusion properties of these classes involving the integral operator are considered.

analytic functions;subordination;convolution;multiplier transformation;inclusion properties

§1.Introduction

Let A denote the class of functions in the open unit disk U={z:|z|<1},normalized by

A analytic function f(z)is subordinate to analytic function g(z),written as f(z)≺g(z),if there exists a analytic function w(z)in U such that w(0)=0 and|w(z)|<1 and f(z)=g(w(z)).

The convolution of two analytic functionsdef i ned by

Let N be the class of all analytic functions φ(z)which are univalent in U and for which φ(U)is convex with φ(0)=1 and Re{φ(z)}>0 in U.

Making use of the principle of subordination between analytic functions,we introduce the subclasses S∗(ξ,φ),K(ξ;φ)and C(ξ,ρ;φ,ψ)of the class A,0≤ξ,ρ<1 and φ,ψ∈N,which are def i ned by

and

We note that

Set the function

For a=1,

which is discussed in[1].

Analogous to[1],the following operator is introduced

The following relations are easily derived that

Next,by using the operator Ika,c(λ,µ)f(z),we introduce the following subclasses of analytic functions for 0≤ξ,ρ<1 and φ,ϕ∈N

We also note that

§2.Inclusion Properties Involving(λ,µ)f

In order to prove our results,we shall make use of the following known results.

Lemma 2.1[4]Let φ be convex univalent in U with φ(0)=1 and R{κφ(z)+η}>0(κ,η∈ℂ).If p is analytic in U with p(0)=1,then

implies

Lemma 2.2[5]Let φ be convex univalent in U and w be analytic in U with R{w(z)}≥0. If p is analytic in U with p(0)=φ(0),then

implies

For simplicity,unless otherwise mentioned we shall writeλ,µ)f(z)=Ikf(z)throughout this paper.

Theorem 2.1If φ∈N and Re{(1−ξ)φ(z)+(ξ−1)+>0,then

where p is analytic in U with p(0)=1.

Rearranging(1.4),we have

Dif f erentiating(2.2)and multiplying by z gives that

Theorem 2.2If φ∈N and Re{(1−ξ)φ(z)+(ξ−1)+>0,then

ProofBy using(1.6)and Theorem 2.1,it follows that

which proves Theorem 2.2.

Theorem 2.3If φ,ψ∈N and Re{(1−ξ)φ(z)+(ξ−1)+}>0,then

Dif f erentiating(2.4)with z and multiplying by z,we get

Applying(1.4)again,we have

From(2.5)and(2.6),we have

Since h(z)≺ψ(z)and Re{(1−ξ)φ(z)+(ξ−1)+>0,then Re{(1−ξ)h(z)+(ξ−1)+}>0.

Theorem 2.4If k,c,λ≥0,µ≥1,then

where φ∈N.

Make use of the dif f erentiation on both sides in(2.7)and set p(z)we have

Sinceµ≥1,φ(z)∈N,Re{φ(z)+(µ−1)}>0,using Lemma 2.1,we get p(z)≺φ(z).Thus, f(z)∈(λ,µ,φ).The proof is complete.

By using similar manner,we obtain the following results.

Theorem 2.5If k,c,λ≥0,µ≥1,then

and

where φ∈N.

§3.Inclusion Properties Involving Integral Operators

In this section,we present integral-preserving properties of general Bernardi-Libera-Livington integral operator def i ned by[6-9]

From(3.1),we have

Theorem 3.1Let δ>−1 and φ(z)∈N with Re[(1−ξ)φ(z)+δ+ξ]>0.If f∈(λ,µ)(ξ,φ),then

where p is analytic in U with p(0)=1.

From(3.2)and(3.3),we have

Taking the dif f erentiation on the both sides of(3.4)and multiplying by z,we obtain

Applying Lemma 2.1 to(3.5),we conclude that Fδ(f)(z)∈(λ,µ)(ξ,φ).

Similarly applying(1.6)and Theorem 3.1,we have the following result.

Theorem 3.2Let δ>−1 and φ(z)∈N with Re[(1−ξ)φ(z)+δ+ξ]>0.If f∈MKka,c(λ,µ)(ξ,φ),then

Theorem 3.3Let δ>−1 and φ(z)∈N with Re[(1−ξ)φ(z)+δ+ξ]>0.If f∈(λ,µ)(ξ,ρ,φ,ψ),then

ProofLetf(z)∈MCka,c(λ,µ)(ξ,ρ,φ,ψ),then there exists a function g(z)∈(λ,µ) (ξ,φ)such that

We set

where p(z)is analytic in U with p(0)=1.Since g(z)∈(λ,µ)(ξ,φ),we have from Theorem 3.1,that Fδg(z)∈(λ,µ)(ξ,φ).Using(3.2)we obtain

By simple calculations,we get

Applying Lemma 2.1 to(3.7),we can show that p(z)≺ψ(z)so that f(z)∈(λ,µ) (ξ,ρ,φ,ψ),which proves Theorem 3.3.

[References]

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[4]ENIGENBERG P,MILLER S S,MOCANU P T,et al.On a Briot-Bouquet dif f erential subordination[J]. General Inqualities,1983,3:339-348.

[5]MILLER S S,MOCANU P T.Dif f erential subordination and univalent functions[J].The Michigan Mathematical Journal,1981,28:157-171.

[6]BERNARDI S D.Convex and starlike univalent functions[J].Transactions of the American Mathematical Society,1969,135:429-446.

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[9]LIVINGTON A E.On the radius of univalence of certain analytic functions[J].Proceedings of the American Mathematical Society,1966,17:352-357.

tion:30C45

CLC number:O174.51Document code:A

1002–0462(2014)02–0257–08

date:2012-10-25

Supported by the Natural Science Foundation of Department of Education of Anhui Province(KJ2012Z300)

Biographies:LI Zong-tao(1970-),male,native of Taian,Shandong,a lecturer of Guangzhou Civil Aviation College,M.S.D.,engages in theory of functions;GUO Dong(1976-),male,native of Linyi,Shandong,a lecturer of Chuzhou Vocational and Technical College,M.S.D.,engages in complex analysis.