The 60 GHz unlicensed spectrum between 57 and 66 GHz has received a lot of attention over the last years for enabling short-range and over 1-Gbps high-speed wireless communications. In addition to the high-data rates that can be accomplished in this spectrum, many other benefits such as high security communications are foreseen. In general, this frequency band is destined to low power and short range fixed or mobile applications. To benefit from high-speed within a compact device, it is required to realize a subsystem combining a directional antenna and a multiplexer with the same technological process. The 3D ceramic stereo lithography process has been selected to ensure the dimensional accuracy and limit the inevitable dispersions. This thesis contributes to achieve directional antennas at 60GHz by a combined antenna design and filter, and perform this function in the same technology the 3D ceramic stereo lithography process when connecting the filter with the antenna. Therefore, the first challenge is to design and to manufacture the primary feed of the directive antenna and the channel filters using the 3D ceramic process. The second challenge is to combine the primary feed and the 4 channel filters to form a single object. The filter-antenna subsystem allows to have a directivity of approximately 14 dBi. Therefore, the radiation of the horn antenna remains unchanged over the whole frequency band [57-66]GHz by associating the manifold multiplexer. The filter-antenna subsystem provides a return loss better than 10 dB at each port.