Energy Efficient 6G performance Improvement based on Service Level Recursive Scheduling routing using Priority cycle Tags (PCT)

The Sixth Generation (6G) mobile communication system is actively promoted worldwide. One solution for ultra-high-speed communications is to use the ter-ahertz frequency band above 100 GHz. This is due to the availability of wider frequency bands than 5G. Due to the increasing performance of network issues in the transmission path, data may be leaked or injected incorrectly. Therefore, the performance of the routing network is significant for centralized routing, improving data transmission and preventing malicious activity. To overcome the issues, this work proposed the method of Enhance Service Data Transmission (ESDT) using Energy Optimized Network Route Cluster Bandwidth (EONRCB) transmission based on slicing the nearest neighbor and splitting the route in a 6G network. Initially, the traffic routing is checked based on the Transmission Node Support Weight (TNSW). Each node must constantly authenticate access control to fragment the data in packets, and access control is detected based on routing as needed. Service Level Route Count Rollback Node Aggregator (SLR-CRNA) improves the network’s performance by verifying active node exchanges. The sleeper node controller then preserves the node’s response behaviour and sends the data to the current location of the trusted node exchange. Slicing Neighbor Node Path Routing (SN2PR) also establishes connectivity between sources to 1 destination nodes in Edge Networks. Then scheduling the node priority based to enable the network to avoid the traffic in the frequency of the network based on the Priority cycle Tags (PCT) using Recursive Scheduling Time (RST) provides an optimal scheduling policy by iteratively adjusting the duration of tasks until time mismatch is minimized. RTSS can be achieved in 6G wireless networks with minimal changes in planning architecture. Performance evaluations show the effectiveness of the proposed scheme in reducing misalignment delays for random traffic periods. Service Level Route Count Rollback Node Aggregator (SLR-CRNA) is attained to avoid traffic, improve energy efficiency, and schedule the nodes with limited time transmission to assign the route and enhance network lifetime and performance. The proposed 6G-the framework has been implemented in the 6G network Time-based scheduling. It provides high network performance and has been validated by comparing the values with other methods.