Delay Compensation Model in 100mbps Switched Ethernet Using Sliding Mode Controller (SMC)
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In the realm of networked systems, achieving timely and reliable communication is paramount, particularly in high-speed environments like 100Mbps Switched Ethernet networks. However, inherent delays in communication channels poses significant challenges to maintaining synchronization and real-time data transfer. This paper proposes a novel approach to address communication delay compensation in such networks through the utilization of a Sliding Mode Controller (SMC).
The proposed method leverages the robustness and adaptability of sliding mode control techniques to dynamically adjust transmission parameters and compensate for communication delays. By incorporating the SMC into the network architecture, the system can effectively mitigate the adverse effects of delays, ensuring improved performance in terms of packet delivery, latency reduction, and overall network efficiency.
Through simulation studies and practical implementation, the efficacy of the proposed approach is demonstrated, showing promising results in enhancing the reliability and responsiveness of 100Mbps Switched Ethernet networks. This research contributes to the advancement of communication protocols and control strategies in networked systems, offering a viable solution to address the challenges posed by communication delays in high-speed environments.
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