Looking into the multiband and broadband need of 5G wireless technology, researchers are trying hard to explore antennas design having multi- and broadband characteristics. Mostly, planar and vertical designs are suggested for these types of designs because various advantages like small size, low manufacturing cost, low profile, volume production, and conformability. It seems that stacked configurations, namely, antennas in vertical direction, may be one of the solutions for getting multiband and broadband features because the physique of the overall antenna does not expand horizontally. This is one of the most important features, which provides opportunity to construct a large array with limited space. However, the design process of stacked microstrip antenna using commercially available electromagnetic software is a cumbersome task because of ‘‘Generate and Test’’ approach involved. Furthermore, because stacked patch antenna involves large number of design parameters, therefore, the designer needs to optimize so many geometrical parameters. Hence, hundreds of simulations may require to reach at the final design. In this chapter, artificial intelligence algorithms such as artificial neural network, deep learning, and particle swarm optimization metaheuristic approach have been explored to systemize the entire design process of stacked patch antennas design. The proposed hybrid algorithms are stable and flexible computationally, which is able to provide accurate results. Developed antennas are useful for satellite, wireless local area network, and radar communication applications. The performance of the designed antennas has been verified through electromagnetic simulations done by IE3D software and experimental measurements accomplished through vector network analyzer. The close resemblance of the simulation and experimental results with the design specifications confirms the validity of the developed design methodology.