VANET protocols Project examples using omnet++

The given project ideas that concentrate on VANET (Vehicular Ad-Hoc Network) protocols using OMNeT++ tool which are worked by us are listed below:

1. Simulation of AODV Protocol in VANET

• Objective: Execute and measure the performance of the AODV (Ad-hoc On-demand Distance Vector) routing protocol in a VANET environment.
• Details:
  • Generate a city-based VANET topology with vehicles acting as mobile nodes.
  • Execute AODV for route discovery and handles as vehicles move via the network.
  • To evaluate the metrics like route discovery time, packet delivery ratio, and latency under numerous traffic conditions.

2. Performance Analysis of DSR Protocol in Urban VANETs

• Objective: Execute and measure the performance of the DSR (Dynamic Source Routing) protocol in a VANET scenario.
• Details:
  • To build a simulation of an urban VANET environment with intersections, traffic lights, and changing the vehicle speeds.
  • Execute DSR that concentrates on how it manages the high mobility of vehicles.
  • To assess the protocol’s performance in terms of route discovery efficiency, overhead, and packet delivery ratio.

3. Evaluation of GPSR (Greedy Perimeter Stateless Routing) in Highway VANETs

• Objective: Execute GPSR in a highway VANET scenario and measure its performance.
• Details:
  • Generate a highway scenario in which the vehicles interact with each other over long distances.
  • Execute GPSR, which uses the geographic position of nodes to make forwarding decisions.
  • To analyse the performance metrics such as delivery success rate, end-to-end delay, and the effects of vehicle density on routing efficiency.

4. V2V and V2I Communication Protocol Simulation

• Objective: To mimic and compare the performance of Vehicle-to-Vehicle (V2V) and Vehicle-to-Infrastructure (V2I) communication protocols.
• Details:
  • Improve a VANET simulation with both V2V and V2I communication scenarios.
  • Execute protocols such as IEEE 802.11p for V2V and DSRC (Dedicated Short-Range Communications) for V2I.
  • Measure the reliability, latency, and scalability of each communication type in numerous network conditions.

5. Security Protocol Implementation in VANETs

• Objective: Implement a security protocol to ensure the secure communication among vehicles in a VANET.
• Details:
  • Mimic a VANET environment in which vehicles interacts sensitive information.
  • Execute a security protocol, like a digital signature or encryption mechanism, to secure data integrity and authenticity.
  • Assess the effects of the security protocol on network performance that has metrics such as delay, overhead, and resistance to attacks like spoofing or eavesdropping.

6. Cluster-Based Routing Protocol in VANET

• Objective: Execute a cluster-based routing protocol to enhance scalability in a large VANET.
• Details:
  • To emulate a large-scale VANET in which vehicles form clusters based on proximity or direction.
  • Execute a cluster-based routing protocol in which the cluster heads that handles an intra-cluster communication and inter-cluster routing.
  • Measure the performance in terms of cluster stability, communication overhead, and overall network efficiency.

7. Cross-Layer Protocol Design for VANETs

• Objective: Enterprise and execute a cross-layer protocol that incorporates MAC and routing layers for enhanced VANET performance.
• Details:
  • Improve a VANET scenario in which vehicles experience high mobility and changing network conditions.
  • Execute a cross-layer protocol that permits the MAC layer to effect routing decisions like based on link quality.
  • Measure the protocol’s efficiency in minimizing the packet loss, enhancing the throughput, and optimizing the route stability.

8. Traffic-Aware Routing Protocol in VANET

• Objective: Execute a routing protocol that adjusts to real-time traffic conditions in a VANET.
• Details:
  • To emulate a VANET with changing the traffic density, road conditions, and vehicle speeds.
  • Execute a routing protocol that adapts route selection based on traffic information like congestion levels or road closures.
  • Measure the effect on route efficiency, travel time, and packet delivery success.

Overall, we had clearly offered the detailed description to execute the numerous VANET projects samples were given above that were evaluated in OMNeT++ implementation tool. We also further provide the detailed information that related to VANET.

Approach us, as we are committed to providing you with the highest level of implementation support and guidance throughout every phase of your research into VANET protocols.