This work presents a design study of omnidirectional dual-reflector antennas, where the main reflector is obtained from a circular generatrix. The antenna is composed of two concentric circularly symmetric reflectors and it is fed by a coaxial conical horn excited by TEM mode to produce vertical polarization. To obtain the subreflector surface, the study employs a GO synthesis technique to shape the subreflector in order to produce a uniform phase distribution in a conical aperture placed in front of the main reflector. To validate the results, it is employed a rigorous electromagnetic analysis technique based on the association of Mode Matching Technique to represent the fields inside the horn and Method of Moments to solve the integral equations of electric and magnetic fields. The solution of Method of Moments yields the induced electric current on the outer surface of the horn and the amplitude of the modes on the aperture of the horn. The exploratory study is divided in three parts. First, by using the GO approximations for the aperture fields, the geometry parameters are explored to identify compact antenna configurations that maximize the gain along the horizontal plane. However, a more uniform coverage of the ground can be obtained by tilting the main lobe. Thus, in a second step of the parametric study, it is considered a family of designs with the same main reflector and a set of subreflectors that are designed for different tilt angle of main lobe. This strategy is effective to reduce the manufacturing costs of a family of antennas designed to provide different coverage. Third, by using the hybrid method, the TEM coaxial horn is shaped to reduce the return loss and extend its operating band, and, finally, the overall antennas performance is optimized by controlling radiation pattern and return loss.