This thesis gives a study on two techniques to suppress the side lobes and enhance the gain of a half mode substrate integrated waveguide leak wave antenna, respectively. In this thesis, we are aware of two phenomenon that may spoil the performance of a leaky wave antenna: 1. Due to the traveling wave nature of the leaky wave antennas, the remaining power at the end of the leaky wave antenna should always be carefully guided and terminated or the reflected wave will be excited with the corresponding back lobes that may spoil the radiation pattern. 2. Even if one can guide the wave in the leaky wave antenna to avoid reflections, an ideal leaky wave line source may still introduce side lobes due to the effect of the finite uniform illumination of the aperture antennas. We would here give a study on two methods accompanied with a proposed transition dedicated for a half mode substrate integrate waveguide leaky wave antenna to handle the problems mentioned above. First, a transition to efficiently convert the input power to construct the leaky mode of the leaky wave antenna is proposed to enhance the efficiency of the leaky wave antenna and avoid possible reflections at the terminal of the leaky wave antenna. This transition can be considered as a stepping stone to facilitate the later analysis and design of the leaky wave antenna. Secondly, a cosine-shaped tapering profile is proposed to taper the waveguide width of the half mode substrate integrated waveguide. Since one can thus shape the aperture field of the leaky wave antenna to satisfy the Taylor’s rules, the side lobes of the radiation pattern can having a better chance to be suppressed. Finally, a feed-back network is proposed to guide the non-radiated power back to the feed of the leaky wave antenna. The gain is expected to be enhanced with the aid of the non-radiated power. These two methods accompanied with the proposed transition can improve the performance of the leaky wave antenna at an arbitrary frequency range easily and thus has great potential in many applications.