On Demand protocol Project examples using omnet++

On-Demand Routing Protocols using OMNeT++ that you can implement are listed here. Approach our team to get a hassel free services as per your reasech needs. If you need help with writing your thesis, you can trust us at omnet-manual.com. We’re here to support you, and we’ll look at your work to help you achieve the best results.

1. Performance Comparison of On-Demand Routing Protocols (AODV, DSR, TORA):

• Accomplish and compare the performance of various on-demand routing protocols like AODV (Ad hoc On-Demand Distance Vector), DSR (Dynamic Source Routing), and TORA (Temporally-Ordered Routing Algorithm) in OMNeT++.
• Assess the protocols in different network environment that has changing node mobility, traffic patterns, and network sizes.
• Compute metrics like route discovery time, packet delivery ratio, end-to-end delay, and routing overhead.

2. Energy-Efficient On-Demand Routing Protocol for MANETs:

• Build an energy-efficient version of an on-demand routing protocol like AODV or DSR for Mobile Ad Hoc Networks (MANETs).
• Reduce energy usage in the course of route discovery and maintenance by executing techniques.
• Ape the protocol in OMNeT++ and compare its performance with the standard versions based on energy utilization, network lifetime, and routing efficiency.

3. Secure On-Demand Routing Protocol:

• Execute security features to an on-demand routing protocol like AODV to guard from attacks like black hole, wormhole, and Sybil attacks.
• Replicate these attacks in an OMNeT++ environment and measure the effectiveness of the security-enhanced protocol in identifying and moderating these challenges while upholding routing performance.

4. QoS-Aware On-Demand Routing Protocol:

• Set up and accomplish a Quality of Service (QoS)-aware on-demand routing protocol that prioritizes traffic with certain QoS demands like video and voice, over other kinds of data.
• Mimic the protocol in OMNeT++ and compute its performance in terms of QoS metrics like delay, jitter, and packet loss, certainly under high traffic conditions.

5. Adaptive On-Demand Routing Protocol:

• Configure an adaptive on-demand routing protocol that dynamically modifies its parameters in terms of network conditions involves node mobility, traffic load, and link quality.
• Deploy the protocol in OMNeT++ and simulate several network scenarios to assess its malleability and performance compared to standard on-demand protocols.

6. On-Demand Routing in Vehicular Ad Hoc Networks (VANETs):

• Applying an on-demand routing protocol customized for Vehicular Ad Hoc Networks (VANETs) in OMNeT++.
• Recreate the protocol in realistic urban and highway scenarios with changing vehicle densities and mobility patterns.
• Assess the protocol’s performance based on route discovery time, packet delivery ratio, and scalability in VANET environments.

7. On-Demand Routing for Delay-Tolerant Networks (DTNs):

• Build an on-demand routing protocol for Delay-Tolerant Networks (DTNs), where network connectivity is intermittent, and direct paths amongst source and destination may not always be existed.
• Accomplish the protocol in OMNeT++ and estimate its performance according to the message delivery likelihood, latency, and overhead in scenarios with intermittent connectivity.

8. Hybrid On-Demand Routing Protocol:

• Develop a hybrid on-demand routing protocol that integrates the advantages of both reactive (on-demand) and proactive routing approaches.
• Execute the protocol in OMNeT++ and emulates its performance in different network scenarios to compare it from purely reactive and proactive protocols.
• Analyze metrics includes routing overhead, scalability, and adaptability to network changes.

9. Cross-Layer On-Demand Routing Protocol:

• Execute a cross-layer design for an on-demand routing protocol in which information from the physical or MAC layer is used to optimize routing decisions.
• Imitate an environment in OMNeT++ where factors like signal strength, link quality, or energy levels impact the route discovery and selection process.
• Evaluate how the cross-layer design optimize the protocol’s performance depends on consistency and proficiency.

10. On-Demand Routing with Multi-Path Support:

• Build an on-demand routing protocol with multi-path support, permitting several substituted routes to be accomplished during the route discovery phase.
• Execute the protocol in OMNeT++ and assess its performance in scenarios with high mobility or frequent link failures, concentrating on metrics like route stability, fault tolerance, and load balancing.

At the end of these examples, you have seen the brief demonstration of the above projects of On Demand Protocol’s initialization and implementation using OMNeT++ tool. Also, we provide more samples regarding these protocols through another manual.