In recent years, facing the challenge of severer global warming and energy crisis, electric vehicles have gotten considerable attention, and the number of electric vehicles has risen significantly. Popularizing electric cars instead of cars with internal combustion engines is believed to be more energy-efficient and be of enormous benefit to slow down the rapid growth of global warming by reducing carbon dioxide emissions. To charge large quantities of electric vehicles, widespread construction of specific electric vehicle supply equipment is indispensable. However, to maximize the utilization of energy consumption and the benefit of adopting electric vehicles, particular messages have to be exchanged between the electric vehicle and the electric vehicle supply equipment before, during, and after the charging process. These messages can contribute to the stabilization of the electric grid, the compatibility of different charging methods, the safety of the charging process, and a better charging experience for electric vehicle users. Some protocols regulate the content and the format of these messages and the underlying system architecture, including DIN 70121, CHAdeMO, ISO 15118, and more. In this work, we research the ISO 15118 series protocol, which outshines others with sophisticated features. We implement the ISO 15118 protocol stack on both sides of the electric vehicle and the electric vehicle supply equipment. Besides, with the evolution of wireless power transfer technology, wireless communication between the electric vehicle and the electric vehicle supply equipment becomes more and more critical. Wireless power transfer technology expects to achieve more seamless charging with wireless communication. We have tested and analyzed the performance of the ISO 15118 messages under wireless communication and also provided solutions to decrease the latency of the messages when there are coexistent users to meet the strict timeout requirement regulated by the specification.