Generalized \(k\)-uniformly close-to-convex functions associated with conic regions (Q417119)

Let \(\phi(z, \lambda, \mu)\) be the generalized Harwitz-Lerch Zeta function given as NEWLINE\[NEWLINE\phi(z, \lambda, \mu)=\sum^{\infty}_{n=0} \frac{z^{n}}{(\mu+n)^{\lambda}}, \quad \lambda \in \mathbb{C},\, \mu \in \mathbb{C} \backslash\{-1, -2, \dots\}. \tag{1}NEWLINE\]NEWLINE Using (1), the following family of linear operators is defined in terms of the Hadamard product as NEWLINE\[NEWLINEJ_{\lambda, \mu}f(z)=H_{\lambda, \mu}(z)*f(z), \tag{2}NEWLINE\]NEWLINE where \(f \in A,\) NEWLINE\[NEWLINEH_{\lambda, \mu}(z)=(1+\mu)^{\lambda}[\phi(z, \lambda, \mu)-\mu^{-\lambda}], \quad z \in E, \tag{3}NEWLINE\]NEWLINE and \(\phi(z, \lambda, \mu)\) is given by (1).NEWLINENEWLINEFrom (2) and (3), one can write NEWLINE\[NEWLINEJ_{\lambda, \mu}f(z)=z+\sum^{\infty}_{n=2} \left(\frac{1+\mu}{n+\mu} \right)^{\lambda} a_{n}z^{n}.NEWLINE\]NEWLINE The author consider the operator \(I_{\lambda, \mu}: A \rightarrow A\) as NEWLINE\[NEWLINEI_{\lambda, \mu}f(z)*J_{\lambda, \mu}f(z)=\frac{z}{(1-z)}, \quad \lambda \text{ real}, \mu> -1.NEWLINE\]NEWLINE This means: NEWLINE\[NEWLINEI_{\lambda, \mu}f(z)=z+ \sum^{\infty}_{n=2} \left(\frac{n+\mu}{1+\mu} \right)^{\lambda} a_{n}z^{n}, \quad \lambda \text{ real}, \mu> -1.NEWLINE\]NEWLINE By using this operator, the author defines and study some subclasses of analytic functions. These functions map the open unit disc onto the domains formed by parabolic and hyperbolic regions and extend the concept of uniform close-to-convexity. Some interesting properties of these classes, which include inclusion results, coefficient problems, and invariance under certain integral operators, are discussed. The results are shown to be the best possible.