On the convex-exponent product of logharmonic mappings

Sufficient conditions are obtained on two given logharmonic mappings $f_1$ and $f_2$ that ensure the product $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a univalent starlike logharmonic mapping. Several illustrative examples are constructed from this product.

MSC: 30C35, 30C45, 35Q30.

Let $U=\{z:|z|<1\}$ be the unit disk in the complex plane ℂ, and let B denote the set of bounded analytic functions a satisfying $|a(z)|<1$ in U. Also let $B_0$ denote its subclass consisting of $a\in B$ with $a(0)=0$. A logharmonic mapping f defined in U is a solution of the nonlinear elliptic partial differential equation

where the second dilatation function a lies in B. Thus the Jacobian

is positive, and all non-constant logharmonic mappings are therefore sense-preserving and open in U. If f is a non-constant logharmonic mapping that vanishes only at $z=0$, then f admits the representation

where m is a nonnegative integer, $Re\beta >-1/2$, while h and g are analytic functions in U satisfying $g(0)=1$ and $h(0)\ne 0$ (see [1]). The exponent β in (1) depends only on $a(0)$ and is given by

Note that $f(0)\ne 0$ if and only if $m=0$, and that a univalent logharmonic mapping in U vanishes at the origin if and only if $m=1$, that is, f has the form

where $Re\beta >-1/2$ and $0\notin (hg)(U)$. This class has been studied extensively in recent years, for instance, in [1–8], and [9].

In this case, $F(\zeta )=logf(e^{\zeta })$ is a univalent harmonic mapping of the half-plane $\{\zeta :Re(\zeta )<0\}$. Studies on univalent harmonic mappings can be found in [10–16], and [17]. Such mappings are closely related to the theory of minimal surfaces [18, 19].

In this work, emphasis is given on univalent and sense-preserving logharmonic mappings in U with respect to $a\in B_0$. These mappings are of the form

and the class consisting of such mappings is denoted by $S_{Lh}$. Also let $S_{Lh}^{\ast }$ denote its subclass of univalent starlike logharmonic mappings. The classical family $S^{\ast }$ of univalent analytic starlike functions is evidently a subclass of $S_{Lh}^{\ast }$. The representation in (2) is essential to the present work as it allows the treatment of logharmonic mappings f through their associated analytic representations h and g (see [3–5], and [6]). For example, Abdulhadi and Abu Muhanna [5] established a connection between starlike logharmonic mappings of order α and starlike analytic functions of order α.

It follows from (2) that the functions h, g and the dilatation a satisfy

Given an analytic function φ with a specified geometric property and $a\in B_0$, a common method to construct a logharmonic mapping $f(z)=zh(z)\overline{g(z)}$ is to solve for h and g via the equations

Thus the solution is $f(z)=zh(z)\overline{g(z)}$ with

In this paper, a new logharmonic mapping with a specified property is constructed by taking product combination of two functions possessing the given property. Specifically, if $f_1(z)=z{h}_1(z)\overline{g_1(z)}$ with respect to $a_1\in B_0$, and $f_2(z)=z{h}_2(z)\overline{g_2(z)}$ with respect to $a_2\in B_0$, we construct a new univalent logharmonic mapping $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, with respect to $\mu \in B_0$. Sufficient conditions are obtained on $f_1$ and $f_2$ for the product combination $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$ to be starlike. We close the work by giving several examples of univalent starlike logharmonic mappings constructed from this product.

Let Ω be a simply connected domain in ℂ containing the origin. Then Ω is said to be α-spirallike, $-\pi /2<\alpha <\pi /2$, if $wexp(-t{e}^{i\alpha })\in \Omega$ for all $t\ge 0$ whenever $w\in \Omega$. Evidently, Ω is starlike (with respect to the origin) if $\alpha =0$.

The following result from [6] will be needed in the sequel.

Lemma 1 Let $f(z)=zh(z)\overline{g(z)}$ be logharmonic in U with $0\notin hg(U)$. Then $f\in S_{Lh}^{\ast }$ if and only if $\phi (z)=zh(z)/g(z)\in S^{\ast }$.

Theorem 1 Let $f(z)=zh(z)\overline{g(z)}\in S_{Lh}^{\ast }$ with respect to $a\in B_0$, and let γ be a constant with $Re\gamma >-1/2$. Then $F(z)=f(z){|f(z)|}^{2\gamma }$ is an α-spirallike logharmonic mapping with respect to

where $\alpha ={tan}^{-1}(2Im\gamma /(1+2Re\gamma ))$.

Proof The function $F=f{|f|}^{2\gamma }=f^{1+\gamma }{\overline{f}}^{\gamma }$ is logharmonic with respect to $\hat{a}=(\overline{F_{\overline{z}}}/\overline{F})/(F_z/F)$. Indeed,

Thus

provided ${|\gamma |}^2<{|1+\gamma |}^2$, which evidently holds since $Re\gamma >-1/2$.

Also $F=f{|f|}^{2\gamma }=f^{1+\gamma }{\overline{f}}^{\gamma }=z{|z|}^{2\gamma }{h}^{1+\gamma }{g}^{\gamma }\overline{h^{\overline{\gamma }}{g}^{1+\overline{\gamma }}}$. Let $H=h^{1+\gamma }{g}^{\gamma }$, $G=h^{\overline{\gamma }}{g}^{1+\overline{\gamma }}$, and $\psi (z)=zH(z)/G{(z)}^{e^{2i\alpha }}$. Then

The condition on α ensures that

Also Lemma 1 shows that $\phi (z)=zh(z)/g(z)\in S^{\ast }$. Thus

and it follows from [[6], Theorem 2.1] that F is α-spirallike logharmonic whose dilatation is $\hat{a}(z)$. □

Remark 1 Observe that F in Theorem 1 is starlike if and only if $\gamma >-1/2$.

Theorem 2 Let $f_k(z)=z{h}_k(z)\overline{g_k(z)}\in S_{Lh}^{\ast }$ ($k=1,2$) with respect to the same $a\in B_0$. Then $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a univalent starlike logharmonic mapping with respect to the same a.

Proof Let $\mu =(\overline{F_{\overline{z}}}/\overline{F})/(F_z/F)$. It follows from (3) that

Hence $|\mu (z)|<1$ in U, which implies that F is a locally univalent logharmonic mapping.

Next F is shown to have the form (2). Since $f_1=z{h}_1\overline{g_1}$, and $f_2=z{h}_2\overline{g_2}$, then

with $h=h_1^{\lambda }{h}_2^{1-\lambda }$ and $g=g_1^{\lambda }{g}_2^{1-\lambda }$.

Since $f_k$ is starlike, that is, each ${\phi }_k=z{h}_k/g_k$ satisfies the condition $Rez{\phi }_k^{\prime }(z)/{\phi }_k(z)>0$ in U, direct computations show that

Thus F is starlike. □

The following corollary is an immediate consequence of Theorem 2.

Corollary 1 Let $f_k(z)=z{h}_k(z)\overline{g_k(z)}\in S_{Lh}^{\ast }$ ($k=1,2,\dots ,n$) with respect to the same $a\in B_0$. Then $F=f_1^{{\lambda }_1}{f}_2^{{\lambda }_2}\cdots f_n^{{\lambda }_n}$ is a univalent starlike logharmonic mapping with respect to the same a, where $0\le {\lambda }_k\le 1$ and ${\lambda }_1+{\lambda }_2+\cdots +{\lambda }_n=1$.

Theorem 3 Let $f_k(z)=z{h}_k(z)\overline{g_k(z)}\in S_{Lh}^{\ast }$ ($k=1,2$) with respect to $a_k\in B_0$. Suppose also that

Then $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a univalent starlike logharmonic mapping.

Proof The argument is similar to the proof of Theorem 2. From (5), evidently F has the form (2).

Let $(F_z/F)\mu (z)=\overline{F_{\overline{z}}}/\overline{F}$. Since $|a_k|<1$, it follows from (3) and (4) that

By assumption,

whence $|\mu (z)|<1$, which implies that F is locally univalent.

Now the associated analytic function for F is given by $\phi =(z{h}_1^{\lambda }{h}_2^{1-\lambda })/(g_1^{\lambda }{g}_2^{1-\lambda })$. Let $\phi (U)=\Omega$. From Lemma 1, ${\phi }_k=z{h}_k/g_k\in S^{\ast }$, and thus

Hence Ω is a starlike domain, and we deduce that F is a univalent starlike logharmonic mapping. □

Theorem 4 Let $f_k=z{h}_k\overline{g_k}\in S_{Lh}$ with respect to $a_k\in B$, $k=1,2$, satisfying $z{h}_k{g}_k=z$. Then $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a univalent starlike logharmonic mapping.

Proof Since

it follows from (3) that

With $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, (6) and (7) readily yield

Evidently $|\mu (z)|<1$ is equivalent to $\psi (\lambda )=|1+(1-\lambda )a_1+\lambda a_2{|}^2-|\lambda a_1+(1-\lambda )a_2+a_1{a}_2{|}^2>0$.

Now

is a continuous monotonic function of λ in the interval $[0,1]$. Since

and

we deduce that $\psi (\lambda )>0$ for all $\lambda \in [0,1]$, and thus F is locally univalent.

With ${\phi }_k=z{h}_k/g_k$, then

Hence ${\phi }_k$ is starlike univalent, and from Lemma 1, $f_k(z)=z{h}_k(z)\overline{g_k(z)}$ is starlike univalent logharmonic.

The associated analytic function for F is given by $\phi (z)=(z{h}_1^{\lambda }{h}_2^{1-\lambda })/(g_1^{\lambda }{g}_2^{1-\lambda })$. Further

and thus F is starlike. □

The proof of Theorem 4 evidently gives the following result of [[6], Lemma 3.1 and Theorem 3.2].

Corollary 2 Let $f_k=z{h}_k\overline{g_k}\in S_{Lh}$ ($k=1,2$) with respect to $a_k\in B_0$, and suppose that $z{h}_k{g}_k=z$. Then $\phi (z)=z{(h_k(z))}^2\in S^{\ast }$.

We give several illustrative examples in this section.

Example 1 Let

Then f is a univalent logharmonic mapping with respect to $a(z)=-z$, and it maps U onto U [6].

Now the function $F(z)=f(z){|f(z)|}^{2\gamma }$ is an α-spirallike logharmonic mapping with respect to

where $\alpha ={tan}^{-1}(2Im\gamma /(1+2Re\gamma ))$. In particular, if $\gamma =i$, then $\alpha ={tan}^{-1}(2)=0.352\pi$, and

The image of circles in the unit disk under f is shown in Figure 1, and Figure 2 shows the image of the radial slits in U by F.

Graph of circles in U by $\mathit{f}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\frac{\mathit{z}\mathbf{(}\mathbf{1}\mathbf{-}\overline{\mathit{z}}\mathbf{)}}{\mathbf{1}\mathbf{-}\mathit{z}}$ .

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Graph of radial slits by $\mathit{F}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\mathit{f}\mathbf{(}\mathit{z}\mathbf{)}{\mathbf{|}\mathit{f}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{|}}^{\mathbf{2}\mathit{i}}$ , $\mathit{f}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\frac{\mathit{z}\mathbf{(}\mathbf{1}\mathbf{-}\overline{\mathit{z}}\mathbf{)}}{\mathbf{1}\mathbf{-}\mathit{z}}$ .

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Example 2 Consider the functions

Since ${\phi }_1(z)=z/{(1-z)}^2$ and ${\phi }_2(z)=z/{(1+z)}^2$ are starlike analytic functions, it follows from [[5], Theorem 1] that $f_1$ and $f_2$ are starlike logharmonic mappings with respect to $a(z)=z$. Theorem 2 shows that $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a starlike univalent logharmonic mapping.

The image of F is shown in Figure 3 for $\lambda =1/3$.

Graph of circles in U by $\mathit{F}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\mathit{z}{\mathbf{(}\frac{\mathbf{1}\mathbf{-}\overline{\mathit{z}}}{\mathbf{1}\mathbf{-}\mathit{z}}\mathbf{exp}\mathbf{\{}\mathbf{Re}\frac{\mathbf{4}\mathit{z}}{\mathbf{1}\mathbf{-}\mathit{z}}\mathbf{\}}\mathbf{)}}^{\mathbf{1}\mathbf{/}\mathbf{3}}{\mathbf{(}\frac{\mathbf{1}\mathbf{+}\overline{\mathit{z}}}{\mathbf{1}\mathbf{+}\mathit{z}}\mathbf{)}}^{\mathbf{2}\mathbf{/}\mathbf{3}}$ .

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Example 3 In this example, let

and

Simple calculations show that $f_1$ and $f_2$ are respectively starlike logharmonic with dilatations $a_1(z)=-z$ and $a_2(z)=z$. Also F is logharmonic with respect to $\mu (z)=z((1-2\lambda )+z)/(1+(1-2\lambda )z)$.

Since

the conditions of Theorem 3 are satisfied, and thus F is starlike univalent.

The image of circles in U under F for $\lambda =1/3$ is shown in Figure 4.

Graph of $\mathit{F}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\mathit{z}{\mathbf{(}\frac{\mathbf{1}\mathbf{-}\overline{\mathit{z}}}{\mathbf{1}\mathbf{-}\mathit{z}}\mathbf{)}}^{\mathbf{1}\mathbf{/}\mathbf{3}}{\mathbf{(}\frac{\mathbf{1}\mathbf{-}\overline{\mathit{z}}}{\mathbf{1}\mathbf{-}\mathit{z}}\mathbf{exp}\mathbf{\{}\mathbf{Re}\frac{\mathbf{4}\mathit{z}}{\mathbf{1}\mathbf{-}\mathit{z}}\mathbf{\}}\mathbf{)}}^{\mathbf{2}\mathbf{/}\mathbf{3}}$ .

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Example 4 Let $f_1(z)=z{h}_1(z)\overline{g_1(z)}$, where $z{h}_1(z)g_1(z)=z$, $a_1(z)=z$, and

Thus

Further, let $f_2(z)=z{h}_2(z)\overline{g_2(z)}$, where $z{h}_2(z)g_2(z)=z$, $a_2(z)=z^2$, and

In this case,

Since $f_1$ and $f_2$ satisfy the conditions of Theorem 4, we deduce that $F(z)=f_1^{\lambda }(z)f_2^{1-\lambda }(z)$, $0\le \lambda \le 1$, is a univalent starlike logharmonic mapping. The image of U under F for $\lambda =1/3$ is shown in Figure 5.

Graph of $\mathit{F}\mathbf{(}\mathit{z}\mathbf{)}\mathbf{=}\mathit{z}{\mathbf{(}\frac{\mathbf{1}\mathbf{+}\overline{\mathit{z}}}{\mathbf{1}\mathbf{+}\mathit{z}}\mathbf{)}}^{\mathbf{1}\mathbf{/}\mathbf{3}}{\mathbf{(}\frac{\sqrt{\mathbf{1}\mathbf{+}{\overline{\mathit{z}}}^{\mathbf{2}}}}{\sqrt{\mathbf{1}\mathbf{+}{\mathit{z}}^{\mathbf{2}}}}\mathbf{)}}^{\mathbf{2}\mathbf{/}\mathbf{3}}$ .

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This work was completed when the first author was visiting Universiti Sains Malaysia (USM). The work presented here was supported in parts by the FRGS and USM-RU research grants. The authors are thankful to the referees for the suggestions that helped improve the clarity of this manuscript.

Authors and Affiliations

1. Department of Mathematics, American University of Sharjah, Sharjah, 26666, UAE

   Zayid AbdulHadi

2. Department of Mathematics, University of Dammam, Dammam, 31113, Kingdom of Saudi Arabia

   Najla M Alareefi

3. School of Mathematical Sciences, Universiti Sains Malaysia (USM), Penang, 11800, Malaysia

   Rosihan M Ali

Corresponding author

Correspondence to Rosihan M Ali.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

The study was conceived and planned by all authors. Every author participated in the discussions of tackling the problem and the directions of the proofs of the results. All authors read and approved the final manuscript.

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