Path vector routing project examples using omnet++

Path Vector Routing using OMNeT++ tool project samples are listed below; on all areas we are ready to work with. Get fresh project ideas and topics from our researchers. Contact omnet-manual.com to get novel guidance.

1. Basic Path Vector Routing Protocol Implementation:

• Objective: Execute a simple path vector routing protocol and measure its performance in a simulated network.
• Simulation Focus: Mimic a network in which path vector routing is used to handles the routing decisions via numerous autonomous systems (ASes). Evaluate the parameters like convergence time, routing table size, and protocol overhead. Measure on how the protocol manages the route selection and loop prevention.

2. Path Vector Routing in Inter-Domain Networks:

• Objective: Execute path vector routing in a network with multiple ASes and evaluate on how it handles an inter-domain routing.
• Simulation Focus: To mimic a network with multiple ASes, in which each AS uses path vector routing to trade-off the routing information. Evaluates the effects on route propagation, stability, and efficiency. Compare the performance with other inter-domain routing protocols such as BGP.

3. Path Vector Routing with Security Enhancements:

• Objective: Execute the security mechanisms in a path vector routing protocol to secure against common routing attacks like route hijacking.
• Simulation Focus: To mimic a network in which the path vector routing is improved with security characteristics such as route validation and encryption and measures the protocol’s flexibility to security threats that concentrates on the parameters such as routing integrity, overhead, and network performance.

4. Path Vector Routing in Software-Defined Networks (SDN):

• Objective: Apply the path vector routing in an SDN environment in which a central controller handles the routing decisions.
• Simulation Focus: To emulate an SDN in which the controller uses path vector routing to handles the routing via numerous ASes. Evaluate the advantages of centralized control, network efficiency, and flexibility to network changes. Compare the performance with traditional, distributed path vector routing.

5. Path Vector Routing for Traffic Engineering:

• Objective: we need to execute the path vector routing with traffic engineering capabilities to enhance the allocation of network traffic.
• Simulation Focus: To mimic a network in which path vector routing is used to balance traffic loads via the multiple paths and evaluate the effects on network performance that has throughput, latency, and congestion and measures on how well the protocol can adjust to varying network conditions and traffic demands.

6. Path Vector Routing in Hybrid Networks:

• Objective: Execute path vector routing in a hybrid network environment in which numerous kinds of networks like wireless, wired are interconnected.
• Simulation Focus: To mimic a hybrid network in which the path vector routing handles the routing among numerous network types. Evaluate the protocol’s capability to sustain the effective routing and adaptability to diverse network characteristics. Compare the performance with other routing protocols used in hybrid networks.

7. Path Vector Routing with Quality of Service (QoS) Support:

• Objective: To incorporate QoS metrics into path vector routing to selects the traffic based on service requirements.
• Simulation Focus: To mimic a network in which the path vector routing is used with QoS support that make sure that high-priority traffic like video streaming, VoIP is provided with minimal delay and jitter and evaluate the effects on latency, packet loss, and overall network performance compared to standard path vector routing.

8. Path Vector Routing for IPv6 Networks:

• Objective: Execute the path vector routing with IPv6 support and measures its performance compared to IPv4.
• Simulation Focus: To mimic a network in which the path vector routing is used to handles the IPv6 traffic via numerous ASes. Compare the performance in terms of routing efficiency, protocol overhead, and network scalability with IPv4-based path vector routing.

9. Adaptive Path Vector Routing:

• Objective: To enhance an adaptive path vector routing protocol that adapts its routing decisions based on network conditions and traffic patterns.
• Simulation Focus: Mimic a network in which the path vector routing enthusiastically adjusts to changes in network topology, traffic load, and link failures and evaluate the effects on network stability, convergence time, and overall routing efficiency that relates to a non-adaptive path vector routing protocol.

10. Path Vector Routing in Delay-Tolerant Networks (DTNs):

• Objective: Adjust path vector routing for use in delay-tolerant networks in which the network connectivity is erratic.
• Simulation Focus: To replicate a DTN environment in which path vector routing handles the routing in the presence of frequent disconnections and latency. Measures the protocol’s performance in terms of message delivery success, latency, and overhead compared to other DTN routing protocols.

In this above demonstration shows various examples for Path Vector Routing projects that were executed using the OMNeT++ simulation tool. If you need more information regarding the Path Vector Routing we will provide it.