Analysis of Artificial Intelligence Enabled Intelligent Sixth Generation (6G) Wireless Communication Networks

5G Generation connections, which have many novel features compared to Four-G connections, will be dispatched authoritatively very soon. Between 2027 and 2030, it is anticipated that the sixth-generation wireless communication system, utilising the entirety of artificial intelligence, will be implemented. In addition to 5G, there are a number of fundamental challenges that must be addressed, including increased scheme capability, higher data rates, and improved quality of service (QoS). This accessible manuscript discusses upcoming 6G wireless technology and its situation. Emerging technologies such as artificial intelligence and optical wireless technology are discussed. With 6G, mobile networks are anticipated to become one hundred times faster. As 6G expands beyond terrestrial networks and into space, it will enable new scenarios and services with terabytes of data traffic, enabling unprecedented human-machine interaction. 5G is intended to provide peak data rates of 20 Gigabits per second (Gbps) and average user experience rates of 120 Megabits per second (Mbps). It is anticipated that 6G speeds will be closer to 1,000 Gbps and 1 Gbps, respectively. 6G enables options such as holographic communication à la Star Trek and X reality (XR, which integrates AR, VR, and Mixed Reality). One of the goals of 6G cyberspace will be to deliver messages with a microsecond delay as opposed to a 1000-period delay. The 6G technology is enhanced by the combination of artificial intelligence and machine learning (AI), Using sub-mm waves, the 6G significantly influences the calculated communication capability for location determination. Using sub-mm Wave (e.g., wavelengths less than one millimetre) in conjunction with frequency selectivity to determine comparative electromagnetic incorporation charge will lead to significant advancements in wireless sensing technology. In terms of 5G, the calculation of mobile edge computing (MEC) is merely the tip of the iceberg. By the time 6G networks are established, it will be simpler to incorporate computation into collective communication and arithmetic. This generation continues to evolve in response to more distributed radio access networks (RAN) and the desire to utilise the terahertz (THz) range to further extend functionality, reduce latency, and improve spectrum sharing efficiency. It is expected that application 6G will find widespread use in the administration and production of emulsions. Clearly, 5G development communications are more uniform, and global spending has begun. Academic cooperation has started to incubate the next generation of wireless communication systems (namely 6G) in fields such as community security, health monitoring, and space excellent capabilities in order to further the development of wireless networks. Sixth G intended to provide the foundation for the stratification of communication needs in the 2030s.