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TCP protocol Project examples using omnet++

We discuss various project examples related to the TCP protocol using the OMNeT++ tool. Our team is prepared to offer you innovative and original ideas, ensuring you receive the best thesis topics and simulation outcomes. Additionally, we provide network comparisons to enhance your research. The given below are the some project examples involving TCP protocols that you can implement using OMNeT++:

  1. Performance Comparison of TCP Variants (e.g., TCP Reno, TCP NewReno, TCP Vegas):
  • Execute numerous TCP variants like TCP Reno, TCP NewReno, TCP Vegas, etc., in OMNeT++.
  • To emulate and compare their performance in numerous network conditions like numerous levels of congestion, packet loss rates, and varying bandwidth.
  • To assess the parameters such as throughput, packet loss, and latency to regulate which variant performs better in particular scenarios.
  1. TCP Performance over Wireless Networks:
  • Explore the performance of standard TCP in a wireless network environment using OMNeT++.
  • Execute and evaluate how TCP manage the issues such as high error rates, mobility, and varying signal strengths in wireless networks.
  • Propose modifications to the TCP protocol to enhance its performance in wireless environments like using TCP Westwood or TCP Veno.
  1. Congestion Control Mechanisms in TCP:
  • Execute and measure the diverse congestion control mechanisms in TCP like slow start, congestion avoidance, fast retransmit, and fast recovery.
  • Mimic the scenarios with changing traffic loads and network conditions in OMNeT++ to study the efficiency of these mechanisms in mitigating and handling the congestion.
  • Propose and validate new congestion control methods that could possible to optimize the TCP performance.
  1. TCP Performance in High Bandwidth-Delay Product Networks:
  • Execute and emulate the TCP in networks with a high bandwidth-delay product, like satellite networks or long-distance fiber-optic links.
  • Measure the effects of the high bandwidth-delay product on TCP’s performance that concentrates on throughput, congestion window dynamics, and delay.
  • Propose and validate the modifications to TCP, like TCP BIC or TCP CUBIC, to improve the performance in such environments.
  1. TCP over Mobile Ad Hoc Networks (MANETs):
  • Examining the performance of TCP in a Mobile Ad Hoc Network (MANET) scenario using OMNeT++.
  • Measure the issues TCP faces in MANETs, like frequent topology changes and route failures.
  • Execute and measure the TCP improvements like split TCP or feedback-based mechanisms, to enhance the performance in MANETs.
  1. TCP Performance with Network Coding:
  • Executes network coding approaches in conjunction with TCP to enhance the robustness and effectiveness of data transmission in lossy networks.
  • Mimic the scenarios in which the packet loss and errors are predominant and measure how network coding can supports the TCP achieve better throughput and reliability.
  • Compare the performance of TCP with and without network coding in numerous network conditions.
  1. TCP Optimization for IoT Networks:
  • Examine the suitability and performance of TCP in Internet of Things (IoT) networks, in which the devices are common for resource-constrained and connected through the  low-power, lossy networks.
  • Execute the modifications to TCP to better manage the particular requirements of IoT networks, like reduced overhead, energy efficiency, and managing the intermittent connectivity.
  • To mimic and compare the performance of standard TCP with the enhnaced version in an IoT scenario using OMNeT++.
  1. Fairness Analysis of TCP in Multi-User Environments:
  • Execute the scenarios in OMNeT++ in which the multiple users with diverse TCP connections distributes a common bottleneck link.
  • Measure the fairness of resource allocation among the numerous TCP connections that concentrates on how well each variant preserves fairness in changing network conditions.
  • Execute and validate the mechanisms to enhance the fairness like TCP Fair Queuing or other fair scheduling techniques.
  1. TCP in Heterogeneous Networks:
  • To mimic TCP performance in a diverse network environment in which numerous segments of the network have changing the characteristics like wired, wireless, satellite.
  • Measure how TCP manages the issues posed by this heterogeneity like changing delays, bandwidths, and error rates.
  • Propose and measure modifications to TCP to better adjust to diverse network conditions.
  1. Adaptive TCP for Real-Time Applications:
  • Execute a version of TCP that adjusts to the requirements of real-time applications, like VoIP or video streaming.
  • Adjust the TCP congestion control and error recovery mechanisms to select the timely delivery over reliability.
  • Mimic and assess the performance of adaptive TCP in real-time application scenarios using OMNeT++.

We had clearly demonstrated the sample projects for TCP protocol in different sceanrios were executed using OMNeT++. We also deliver the additional information regarding the TCP protocol.

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