ABSTRACT
High-speed data transit is now a reality; thanks to advancements in 5G communications technology, several wireless sensor networks have come up with ways to get important information at the network’s front end. To put it another way, the 5G system can’t be used in the industrial sector without the use of WSN. Edge cloud computing and heterogeneous network convergence are two of the technologies that make it possible for WSNs and 5G networks to work together. Also, a technology called “network slicing” makes it possible for 5G networks to offer services that are flexible and scalable. This technology allows for the seamless provisioning of adaptable front-end sensor network services, catering to a diverse array of use cases. Additionally, front-end network gateway nodes now have efficient, secure, and adaptable access to the core network thanks to radio access network (RAN) slicing technology. The 5G system’s fundamental supporting technology, wireless sensor network technology, is currently being pushed to increase the effectiveness of data transmission. In this study, we look into something that happens in multi-hop clustered wireless sensor networks (MCWSN). Each node in these networks uses a method called “simultaneous wireless information and power transfer” to decode data and get energy from a radio-frequency signal (SWIPT).
