Global Routing Project Examples Using Omnet++

Global Routing using OMNeT++ tool projects that has been carried out by us in recent days are discussed below. Read out the ideas that we proposed in this page, get simulation results for your projects from omnet-manual.com.:

1. Implementation of Global Routing in a Multi-Domain Network:

• Objective: To implement a global routing approach across several autonomous systems (ASes) and evaluate its performance.
• Simulation Focus: Mimic a large network with several ASes, where global routing decisions are made to enhance inter-domain traffic. Measure metrics like routing table size, convergence time, and network efficiency. We can evaluates how global routing affects overall network performance and inter-domain connectivity.

2. Global Routing with Traffic Engineering:

• Objective: Execute the traffic engineering methods in a global routing framework to enhance the flow of traffic across the whole network.
• Simulation Focus: Mimic a network where global routing is merged with traffic engineering to balance traffic loads and to improve the resource utilization. We can assess the impact on network performance, containing latency, throughput, and congestion then we compare the outcomes with a network using local or regional routing strategies.

3. Global Routing with Quality of Service (QoS) Support:

• Objective: Incorporate QoS mechanisms into a global routing framework to prioritize crucial traffic across the network.
• Simulation Focus: Mimic a network where global routing decisions are made with QoS considerations, make sure that high-priority traffic such as video and voice is delivered with minimal delay and jitter. We can considers the impact on overall network performance, especially for high-priority traffic, compared to standard global routing without QoS.

4. Security-Enhanced Global Routing:

• Objective: Execute the security features in global routing protocols to defend versus attacks like route hijacking and eavesdropping.
• Simulation Focus: To emulate a network where global routing is improved with security measures such as encryption, authentication, and route validation. We can calculate the protocol’s resilience to security threats, aiming on metrics such as routing integrity, overhead, and network performance.

5. Global Routing in Software-Defined Networks (SDN):

• Objective: Execute a global routing strategy in an SDN environment, where a central controller handles routing decisions across the whole network.
• Simulation Focus: To mimic an SDN where global routing is handled by a central controller, enhancing routing paths based on real-time network conditions. Compute the benefits of centralized control, network efficiency, and adaptability to network changes then we compare the performance with traditional, dispersed routing methods.

6. Global Routing in Large-Scale IoT Networks:

• Objective: Execute the global routing in a large-scale Internet of Things (IoT) network, handling the connectivity of thousands of devices.
• Simulation Focus: Mimic a big IoT network where global routing improves the connection between the devices, gateways, and the cloud. We can evaluate the influence on network scalability, latency, and device connectivity next we investigate the challenges and benefits of using global routing in such a large, diverse network environment.

7. Global Routing in Hybrid Networks:

• Objective: In this, we can execute the global routing in a hybrid network environment where various network kinds like wired, wireless are interconnected.
• Simulation Focus: Mimic a hybrid network with numerous kinds of connections, and use global routing to handle traffic among various network types. To assess the protocol’s ability to maintain efficient routing and adaptability to various network features and compare the performance with localized routing methods in a hybrid network.

8. Global Routing for Multicast Traffic:

• Objective: Execute the global routing strategy for multicast traffic, enhancing the distribution of data to several destinations concurrently.
• Simulation Focus: We can mimic a network with multicast traffic and use global routing to handle the delivery of multicast streams across the network. We compute the influence on multicast delivery efficiency, latency, and protocol overhead likened to localized multicast routing strategies.

9. Global Routing in Delay-Tolerant Networks (DTNs):

• Objective: Here, we can adjust the global routing for use in DTNs, where network connectivity is intermittent and paths may require to be ascertained over long periods.
• Simulation Focus: Mimic a DTN environment where global routing is used to handle routing in the existence of frequent disconnections and delays. We estimate the protocol’s performance such as message delivery success, delay, and overhead compared to traditional DTN routing protocols.

10. Global Routing with Adaptive Load Balancing:

• Objective: Improve a global routing strategy that contains adaptive load balancing to improve the delivery of network traffic.
• Simulation Focus: Mimic a network where global routing dynamically modifies the routing paths based on present traffic loads, improving resource utilization and avoiding congestion. We can evaluate the impact on network throughput, latency, and load delivery compared to static or localized routing strategies.

Thus, we had expressed some project examples that are helps you to execute and analyse the global routing project effectively using OMNeT++. Also we will offer further materials about this project in another manual.