Distance routing project examples using omnet++

Distance Vector Routing using OMNeT++ tool project examples for all levels of scholars are listed below, get to know about the network performance by sharing with us all your necessary details.:

1. Basic Distance Vector Routing Protocol Simulation:

• Objective: Execute a simple distance vector routing protocol, like RIP (Routing Information Protocol), in a network.
• Simulation Focus: Mimic a small to medium-sized network using a distance vector routing protocol. Estimate metrics like convergence time, routing table size, and packet delivery ratio. Investigate how distance vector routing adjusts to various network topologies and failures.

2. Performance Comparison of Distance Vector and Link State Routing:

• Objective: Liken the performance of distance vector routing such as RIP with link state routing like OSPF.
• Simulation Focus: Emulate a network where both distance vector and link state routing protocols are executed. Compute and compare metrics like convergence speed, routing overhead, scalability, and network performance under various traffic loads and topology changes.

3. Distance Vector Routing in Mobile Ad-Hoc Networks (MANETs):

• Objective: Adjust a distance vector routing protocol for use in a MANET, where node mobility often alters the network topology.
• Simulation Focus: Mimic a MANET environment with a distance vector routing protocol such as AODV (Ad hoc On-Demand Distance Vector). Estimate metrics like route discovery time, packet delivery ratio, and overhead in a high-mobility scenario.

4. Energy-Efficient Distance Vector Routing in Wireless Sensor Networks (WSNs):

• Objective: Improve an energy-efficient distance vector routing protocol for WSNs to expand network lifetime.
• Simulation Focus: Mimic a WSN where nodes use an energy-aware distance vector routing protocol. Determine the impact on network lifetime, energy consumption, and data delivery reliability likened to standard distance vector routing protocols.

5. Securing Distance Vector Routing Protocols:

• Objective: Execute security mechanisms in distance vector routing protocols to protect versus attacks such as route poisoning and spoofing.
• Simulation Focus: Mimic a network where a distance vector routing protocol is improved with security features such as encryption and authentication. Evaluate the protocol’s resilience to attacks, directing on metrics like routing integrity, overhead, and overall network security.

6. Distance Vector Routing with QoS (Quality of Service) Support:

• Objective: Incorporate QoS support into a distance vector routing protocol to prioritize traffic based on service requirements.
• Simulation Focus: Mimic a network where a distance vector routing protocol supports QoS. Examine the impact on latency, jitter, and packet loss for high-priority traffic, like VoIP and video streams. Liken the outcomes with standard distance vector routing.

7. Adaptive Distance Vector Routing in Heterogeneous Networks:

• Objective: Execute an adaptive distance vector routing protocol for heterogeneous networks with nodes of changing capabilities.
• Simulation Focus: Mimic a heterogeneous network where nodes with various resources and capabilities use an adaptive distance vector routing protocol. Assess how successfully the protocol adapts to various node characteristics and how it affects network performance, scalability, and efficiency.

8. Distance Vector Routing in Delay-Tolerant Networks (DTNs):

• Objective: Adjust a distance vector routing protocol for use in delay-tolerant networks (DTNs) where network connectivity is intermittent.
• Simulation Focus: Mimic a DTN environment using a adapted distance vector routing protocol. Evaluate the protocol’s performance in terms of message delivery success, delay, and overhead, likening it with other DTN routing protocols.

9. Hierarchical Distance Vector Routing for Large-Scale Networks:

• Objective: Execute hierarchical distance vector routing to develop scalability in large-scale networks.
• Simulation Focus: Mimic a large-scale network where distance vector routing is applied hierarchically, with nodes organized into regions or clusters. Calculate the influence on routing efficiency, scalability, and overall network performance compared to flat distance vector routing.

10. Distance Vector Routing with Load Balancing:

• Objective: Execute a distance vector routing protocol with load balancing to enhance network resource usage and avoid congestion.
• Simulation Focus: Mimic a network where traffic is dispersed across several paths using load-aware distance vector routing. Assess the impact on network throughput, latency, and congestion compared to traditional distance vector routing without load balancing.

In this sample projects, you can know regarding the execution of Distance routing projects using OMNeT++ tool. If you want additional informations of the projects, we can deliver.