On uniformly univalent functions with respect to symmetrical points

In this paper, we define and study some new subclasses of starlike and close-to-convex functions with respect to symmetrical points. These functions map the open unit disc onto certain conic regions in the right half plane. Some basic properties, a necessary condition, and coefficient and arc length problems are investigated. The mapping properties of the functions in these classes are studied under a certain linear operator.

MSC:30C45, 30C50.

Let A be the class of functions of the form

which are analytic in the open unit disc $E=\{z:|z|<1\}$. Let S, K, $S^{\ast }$, and C be the subclasses of A which consist of univalent, close-to-convex, starlike (with respect to origin), and convex functions, respectively. For recent developments, extensions, and applications, see [1–25] and the references therein.

A function f in A is said to be uniformly convex in E if f is a univalent convex function along with the property that, for every circular arc γ contained in E, with center ξ also in E, the image curve $f(\gamma )$ is a convex arc. The class of uniformly convex functions is denoted by $UCV$. The corresponding class $UST$ is defined by the relation that $f\in UCV$ if, and only if, $z{f}^{\prime }\in UST$. It is well known [13] that $f\in UCV$ if, and only if

Uniformly starlike and convex functions were first introduced by Goodman [3] and then studied by various other authors. If $f,g\in A$, we say f is subordinate to g in E, written as $f\prec g$ or $f(z)\prec g(z)$, if there exists a Schwarz function $w(z)$ such that $f(z)=g(w(z))$ for $z\in E$.

For $0\le \beta <1$, the class $P(\beta )$ consists of functions $p(z)$ analytic in E with $p(0)=1$ such that $\mathrm{\Re }p(z)>\beta$ for $z\in E$, and, with $\beta =0$, we obtain the well-known class P of Carathéodory functions with positive real part.

For $k\in [0,\mathrm{\infty })$, the conic regions ${\mathrm{\Omega }}_k$ are defined as follows, see [5]:

For fixed k, ${\mathrm{\Omega }}_k$ represents the conic regions bounded, successively, by the imaginary axis ($k=0$), the right branch of a hyperbolic ($0<k<1$) and a parabola $v^2=2u-1$ ($k=1$). When $k>1$, the domain becomes a bounded domain being the interior of the ellipse.

We shall consider the case when $k\in [0,1]$. Related to the domain ${\mathrm{\Omega }}_k$, the following functions $p_k(z)$, $k\in [0,1]$, play the role of extremal functions mapping in E onto ${\mathrm{\Omega }}_k$:

These functions are univalent in E and belong to the class P. Using the subordination concept, we define the class $P(p_k)$ as follows.

Let $p(z)$ be analytic in E with $p(0)=1$. Then $p\in P(p_k)$ if, and only if, $p\prec p_k$ in E and $p_k(z)$ are given by (1.2).

The conic domains ${\mathrm{\Omega }}_k$ can be generalized as given by

with the corresponding extremal function

It can easily be seen that the analytic function $p(z)$, with $p(0)=1$, belongs to the class $P(p_{k,\beta })$ if $p(z)\prec p_{k,\beta }(z)$ in E.

It is easy to verify that $P(p_{k,\beta })$ is a convex set. It is known [6] that

and, for $p\in P(p_k)$, we have

where

So we can write $p(z)=h^{\sigma }(z)$, $h\in P$.

Also

Sakaguchi [24] introduced and studied the class $S_s^{\ast }$ of starlike functions with respect to symmetrical points. The class $S_s^{\ast }$ includes the classes of convex and odd starlike functions with respect to the origin. It was shown [24] that a necessary and sufficient condition for $f\in S_s^{\ast }$ to be univalent and starlike with respect to symmetrical points in E is that

Das and Singh [2] defined the classes $C_s$ of convex functions with respect to symmetrical points and showed that a necessary and sufficient condition for $f\in C_s$ is that

It is also well known [2] that $f\in C_s$ if, and only if, $z{f}^{\prime }\in S_s^{\ast }$.

We now define the following.

Definition 1.1 Let $f\in A$. The f is said to be in the class $k-S{T}_s(\beta )$ if, and only if,

It can easily be seen that

Also, for $\beta =0=k$, the class $k-S{T}_s(\beta )$ reduces to $S_s^{\ast }$.

The class $k-UC{V}_s(\beta )$ is defined as follows.

Definition 1.2 Let $f\in A$. Then $f\in k-UC{V}_s(\beta )$ if, and only if $z{f}^{\prime }\in k-S{T}_s(\beta )$ for $z\in E$.

We note that

Definition 1.3 Let $f\in A$. Then $f\in k-U{K}_s(\beta )$ if, and only if, there exists $g\in k-S{T}_s(\beta )$ such that

Since $P(p_{k,\beta })\subset P({\beta }_1)\subset P$, ${\beta }_1=\frac{k+\beta }{k+1}$, and $k-S{T}_s(\beta )\subset S_s^{\ast }$, we note that

where $k_S$ consists of close-to-convex functions with respect to symmetrical starlike functions.

From the definition, it is clear that $k-U{K}_s(\beta )$ consists of univalent functions.

For $k=0$, $\beta =0$ and $f(z)=g(z)$, $k-U{K}_s(\beta )$ reduces to the class $S_s^{\ast }$.

We shall need the following lemmas to prove our main results.

Lemma 2.1 [15]

Let $q(z)$ be a convex function in E with $q(0)=1$ and let another function $h:E\to \mathbb{C}$ be with $\mathrm{\Re }h(z)>0$. Let $p(z)$ be analytic in E with $p(0)=1$ such that

Then $p(z)\prec q(z)$, $z\in E$.

Lemma 2.2 Let $N(z)$, $D(z)$ be analytic in E with

and let $D\in S^{\ast }$ for $z\in E$. Then $\frac{N^{\prime }(z)}{D^{\prime }(z)}\in P(p_{k,\beta })$ implies that $\frac{N(z)}{D(z)}\in P(p_{k,\beta })$ for $z\in E$.

Proof Let

Then

where

Since $\frac{N^{\prime }(z)}{D^{\prime }(z)}\in P(p_{k,\beta })$, we have

We now use Lemma 2.1 and this implies that

This proves that $\frac{N(z)}{D(z)}\in P(p_{k,\beta })$ for $z\in E$. □

The following lemma is an easy extension of a result proved in [5].

Lemma 2.3 Let $k\in [0,\mathrm{\infty })$ and ${\gamma }_1$, ${\delta }_1$ be any complex numbers with ${\gamma }_1\ne 0$ and let $\mathrm{\Re }\{\frac{{\gamma }_{1}k}{k+1}+{\delta }_1\}>\beta$. If $h(z)$ is analytic in E, $h(0)=1$ and it satisfies

and $q_{k,\beta }(z)$ is an analytic solution of

then $q_{k,\beta }$ is univalent and

and $q_{k,\beta }(z)$ is the best dominant of (2.1).

In this section, we shall study some basic properties of the class $k-S{T}_s(\beta )$.

Theorem 3.1 Let $f\in k-S{T}_s(\beta )$. Then the odd function

belongs to $k-ST(\beta )$ in E.

In particular $\mathrm{\Psi }(z)$ is an odd starlike function of order ${\beta }_1=\frac{k+\beta }{k+1}$ in E.

Proof Logarithmic differentiation of (3.1) and simple computation yield

Since $P(p_{k,\beta })$ is a convex set, it follows that $\frac{z{\mathrm{\Psi }}^{\prime }(z)}{\mathrm{\Psi }(z)}\in P(p_{k,\beta })$ and thus $\mathrm{\Psi }\in k-ST(\beta )$ in E. □

As a special case, we note that, for $k=0=\beta$, $\frac{1}{2}[f(z)-f(-z)]=\mathrm{\Psi }(z)\in S^{\ast }$ in E, and hence $\frac{z{f}^{\prime }}{\mathrm{\Psi }}\in P$. We now discuss a geometric property for $f\in k-S{T}_s(\beta )$. Here we investigate the behavior of the inclusion of the tangent at a point $w(\theta )=f(r{e}^{i\theta })$ to the image ${\mathrm{\Gamma }}_r$ of the circle $C_r=\{z:|z|=r\}$, $0\le r<1$, $\theta \in [0,2\pi ]$, under the mapping by means of a function f from the class $f\in k-S{T}_s(\beta )$.

Let

and, for ${\theta }_2>{\theta }_1$, ${\theta }_1,{\theta }_2\in [0,2\pi ]$,

Now, since

then

Hence

Also, on the other hand,

So, the integral on the left side of the last inequality characterizes the increment of the angle of the inclination of the tangent to the curve ${\mathrm{\Gamma }}_r$ between the points $w({\theta }_2)$ and $w({\theta }_1)$ for ${\theta }_2>{\theta }_1$.

We have the following necessary condition for $f\in k-S{T}_s(\beta )$.

Theorem 3.2 Let $f\in k-S{T}_s(\beta )$. Then, with $z=r{e}^{i\theta }$ and $0\le {\theta }_1<{\theta }_2\le 2\pi$, $0\le \beta <1$ and $0\le k\le 1$, we have

where σ is given by (1.3) and ${\beta }_1=\frac{k+\beta }{k+1}$.

Proof Since $\frac{f^{\prime }(z)}{{\mathrm{\Psi }}^{\prime }(z)}\in P(p_{k,\beta })$, $\mathrm{\Psi }(z)=\frac{1}{2}[f(z)-f(-z)]$ and $\mathrm{\Psi }\in k-UCV(\beta )\subset C(\beta )$.

We can write

and this gives us, with $z=r{e}^{i\theta }$, $0\le r<1$, $0\le {\theta }_1<{\theta }_2\le 2\pi$,

For $h\in P(\beta )$, we observe that

Therefore

and

We can write

and for $|z|=r<1$, it is well known that

From this, we have

Thus the values of h are contained in the circle of Apollonius whose diameter is the line segment from $\frac{1-(1-2\beta )r}{1+r}$ to $\frac{1+(1-2\beta )r}{1-r}$ and has the radius $\frac{2(1-\beta )r}{1-r^2}$. So $|argh(z)|$ attains its maximum at points where a ray from origin is tangent to the circle, that is, when

From (3.3), we observe that

Also, for ${\mathrm{\Psi }}_1\in C$,

Using (3.4) and (3.5) in (3.2), we obtain the required result. □

We note the following special cases:

1. 1.

   For $k=0$, $0\le {\theta }_1<{\theta }_2\le 2\pi$, $z=r{e}^{i\theta }$, it follows from Theorem 3.2 that

   $${\int }_{{\theta }_1}^{{\theta }_2}\mathrm{\Re }\{1+\frac{z{f}^{″}(z)}{f^{\prime }(z)}\}d\theta >-\pi (z\in E).$$

This is a necessary and sufficient condition for f to be close-to-convex (hence univalent) in E; see [7]. This also shows that $S{T}_s(\beta )\subset K$.

1. 2.

   For $k=1$ ${\int }_{{\theta }_1}^{{\theta }_2}\mathrm{\Re }\{1+\frac{z{f}^{″}(z)}{f^{\prime }(z)}\}d\theta >-\frac{\pi }{2}$.

2. 3.

   When $k\in [0,1]$, it is obvious that $\sigma \in (0,1]$. In this case, the class $k-S{T}_s(\beta )$ consists of strongly close-to-convex functions of order σ in the sense of Pommerenke [20, 21].

Theorem 3.3 (Integral representation)

Let $f\in k-S{T}_s(\beta )$. Then

where $p\in P(p_{k,\beta })$, $z\in E$.

Proof Since $f\in k-S{T}_s(\beta )$, we can write

This gives us

and the result follows when we integrate. □

When $k=0$, $\beta =0$, we obtain the result for the class $S_s^{\ast }$ given in [5].

We now study the class $k-S{T}_s(\beta )$ under a certain integral operator.

Theorem 3.4 Let $g\in k-S{T}_s(\beta )$ and let for $m=1,2,3,\dots ,G$ be defined by

Then $G(z)$ belongs to $k-S{T}_s(\beta )$ in E.

Proof Let

Since $g\in k-S{T}_s(\beta )$, $\frac{1}{2}\{g(z)-g(-z)\}\in k-ST(\beta )\subset S^{\ast }({\beta }_1)\subset S^{\ast }$, and ${\beta }_1=\frac{k+\beta }{k+1}$. Therefore it can easily be verified that $J(z)$ is $(m+1)$-valently starlike in E.

We can write (3.6) as

and, differentiating logarithmically, we have

say, where $N(0)=D(0)=0$ and D is $(m+1)$-valently starlike.

Let

Then

Since

We now apply Lemma 2.2 to obtain

This proves that $G\in k-ST(\beta )$ in E. □

Theorem 3.5 Let $f,g\in k-S{T}_s(\beta )$ and let F be defined by the following integral operator:

where $z\in E$, $\delta >0$, $\gamma \ge 0$ and $[\frac{k(1+\gamma )}{k+1}+(\frac{1}{\delta }-1)]>\beta$. Then $F(z)$ belongs to $k-ST(\beta )$ for $z\in E$.

When $g(z)=z$, $\gamma =0$, we obtain a generalized form of the Bernardi operator; see [1]. Also for $g(z)=z$, $\gamma =0$, and $\delta =\frac{1}{2}$, we have the well-known integral operator studied by Libera [11] who showed that it preserves the geometric properties of convexity, starlikeness, and close-to-convexity.

Proof Let $\frac{f(z)-f(-z)}{2}={\mathrm{\Psi }}_1(z)$, $\frac{g(z)-g(-z)}{2}={\mathrm{\Psi }}_2(z)$. Then ${\mathrm{\Psi }}_1,{\mathrm{\Psi }}_2\in k-ST(\beta )$ in E. We can write (3.8) as

Differentiating (3.9) logarithmically, and with $p(z)=\frac{z{F}^{\prime }(z)}{F(z)}$, we have

Since, for $i=1,2$, ${\mathrm{\Psi }}_i\in k-ST(\beta )$, $\frac{z{\mathrm{\Psi }}_1^{\prime }(z)}{{\mathrm{\Psi }}_1}=h_1(z)$, $\frac{z{\mathrm{\Psi }}_2^{\prime }(z)}{{\mathrm{\Psi }}_2}=h_2(z)$ both belong to $P(p_{k,\beta })$ in E, and $P(p_{k,\beta })$ is a convex set. Therefore

From (3.10) and (3.11), it follows that

We now apply Lemma 2.3 which gives us

Thus $F\in k-ST(\beta )$ and the proof is complete. □

Here we shall study some properties of the class $k-U{K}_s(\beta )$ which consists of k-uniformly close-to-convex functions.

Let $L(r,f)$ denote the length of the image of the circle $|z|=r$ under f. We prove the following.

Theorem 4.1 Let $f\in k-U{K}_s(\beta )$. Then, for $0<r<1$, $k\in [0,1]$,

where ${\beta }_1=\frac{k+\beta }{k+1}$ and σ is given by (1.3), and $O(1)$ is a constant depending only on k, β.

Proof For $f\in k-U{K}_s(\beta )$, we can write

and $\mathrm{\Psi }(z)=\{g(z)-g(-z)\}$, $g\in k-S{T}_s(\beta )$.

Since $\mathrm{\Psi }\in S^{\ast }({\beta }_1)$ and is odd, there exists an odd starlike function ${\mathrm{\Psi }}_1(z)$ such that

Thus, with $z=r{e}^{i\theta }$,

and using Hölder’s inequality, we have

For $h\in P$, it is well known [20] that

Using (4.3) and subordination for odd starlike functions in (4.2), it follows that

where C and $O(1)$ are constants depending only on ${\beta }_1$ and σ. This completes the proof. □

We now discuss the growth rate of coefficients of $f\in k-U{K}_s(\beta )$.

Theorem 4.2 Let $f\in k-U{K}_s(\beta )$ and be given by (1.1). Then

where $O(1)$ is a constant depending only on σ and ${\beta }_1$ and σ, ${\beta }_1$ are as given in Theorem  4.1.

Proof For $z=r{e}^{i\theta }$, $n\ge 1$, Cauchy’s Theorem gives us

With $r=(1-\frac{1}{n})$, we use Theorem 4.1 and obtain the required result. □

Theorem 4.3 Let $f\in k-U{K}_s(\beta )$ and let F be defined by

Then $F\in k-U{K}_s(\beta )$ in E. That is, the class $k-U{K}_s(\beta )$ is preserved under the integral operator (4.4).

Proof Since $f\in k-U{K}_s(\beta )$, we can write

Let $G(z)=\frac{1}{2}\{g_1(z)-g_1(-z)\}$ and be defined by (3.5). By Theorem 3.4, $g_1\in k-ST(\beta )$ and $G\in k-S_{s}T(\beta )\subset S_s^{\ast }({\beta }_1)$. Let $G=z{G}_1^{\prime }$. Then we can write

Thus, from (4.4) and $g=z{g}_1^{\prime }$, $g_1\in C_s({\beta }_1)$, we have

say. We note that $N(0)=D(0)=0$, and for $g_1\in C_S({\beta }_1)$,

Since $P({\beta }_1)$ is a convex set, $D\in C_s({\beta }_1)\subset S^{\ast }$ in E. We thus have

Now, using Lemma 2.2, it follows that

This proves that $F\in k-U{K}_S(\beta )$ in E. □

We study a partial converse of the above result as follows.

Theorem 4.4 Let $(\frac{2z{f}^{\prime }(z)}{g(z)-g(-z)})\prec p_k(z)$ in E and let

Then $F_1\in K_s$ for $|z|<r_1$, where

Proof We shall need the following well-known results for $p\in P(\alpha )$, $0\le \alpha <1$; see [4]:

Since $f\in k-U{K}_s(\beta )$, there exists $g\in S_s^{\ast }({\beta }_1)$ such that, for $z\in E$.

From (4.5), we have

and this gives us

where

Now, using (4.7) and (4.8), we have

where

We note that $T(0)=1+m>0$ and $T(1)=-3<0$. So there exists $r_1\in (0,1)$. The right hand side of (4.9) is positive for $|z|<r_1$, where $r_1$ is given by (4.6). This implies that $F\in K_s$ for $|z|<r_1$ and the proof is complete. □

We have the following special cases.

1. 1.

   For $k=0=\beta$, $f\in K_s$. Then $F_1$, defined by (4.5) belongs to $K_s$ for $|z|<r_0=\frac{1+m}{2+\sqrt{3+m^2}}$.

2. 2.

   When $m=1$ and ${\beta }_1=0$ (that is, $k=0=\beta$), then $F_1(z)=\frac{{(zf(z))}^{\prime }}{2}$ belongs to the same class for $|z|<\frac{1}{2}$. This result has been proved by Livingston [12] for convex and starlike functions.