A proposed ring based model for optimum data transfer and its performance assessment

Abstract

The demand for efficient solutions to transmit large volumes of data over Passive Optical Network networks has increased. This study examines two key challenges: network bottlenecks and capacity load issues. Based on these issues, a potential solution is proposed. The methodology involves a ring-based architecture consisting of N nodes, representing a complete Passive Optical Network system. These nodes serve as checkpoints for monitoring and identifying network faults. The distance between each node is uniform, and the system includes N checkpoints. The source and receiver nodes are dynamically selected. An optimized ring-based network model is introduced, offering reduced data loss and improved transmission speed. The proposed approach utilizes a ring topology with eight nodes and cores Passive Optical Network save points. To address the bottleneck issue, a tree-based network model is implemented, incorporating four hierarchical sub-networks. Performance comparisons based on packet delivery demonstrate that the proposed model achieves faster data transmission compared to existing systems.

Keywords: Ring Model, Data Transmission, Bottleneck, Capacity Load.