Static Routing Projects Examples Using NS2

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Here are some Static Routing project examples using NS2:

1. Basic Static Routing Simulation in NS2:

• Objective: Apply a basic static routing protocol in NS2, that routes are physically set up and do not vary throughout the simulation.
• Focus: Replicate a simple static routing network and measure the parameters like throughput, latency, and packet delivery ratio. Relate its performance with dynamic routing protocols such as AODV or DSR in a small to medium-sized network.

2. Static Routing in a Wired Network:

• Objective: Mimic static routing in a wired network using NS2.
• Focus: Execute static routes for all nodes in a wired topology such as star, ring, or mesh and evaluate the network performance based on packet delivery, delay, and bandwidth utilization. Measure the effects of traffic load on the performance of static routing in a stable, wired environment.

3. Static Routing in Wireless Sensor Networks (WSNs):

• Objective: Execute static routing in a Wireless Sensor Network (WSN) using NS2.
• Focus: Set up static routes for sensor nodes to interact with a base station. Evaluate the energy consumption, packet delivery, and network lifetime in a static routing scenario and relate it with energy-aware or dynamic routing protocols in WSNs.

4. Static Routing for a Simple Backbone Network:

• Objective: Mimic a static routing scenario in a backbone network in which static routes are used to forward traffic among multiple networks.
• Focus: Measure how static routing performs in a multi-network setup by configuring static routes among routers in a backbone network. Measure the parameters such as network overhead, packet loss, and routing efficiency related to dynamic routing protocols such as OSPF or RIP.

5. Static Routing in Mobile Ad-Hoc Networks (MANETs):

• Objective: Implement static routing in a Mobile Ad-Hoc Network (MANET) using NS2.
• Focus: Mimic static routes in a MANET environment and measure the challenges of using static routing in dynamic, mobile networks. Evaluate the effects of node mobility on packet delivery, route stability, and latency related to dynamic routing protocols like an AODV or DSR.

6. Static Routing with Link Failure Scenarios:

• Objective: Mimic a static routing network with link failures and learn on how static routing manages the network disruptions in NS2.
• Focus: Set up a static routing setup, establish link or node failures, and measure the effects on packet delivery and network performance. While static routes do not vary automatically, measure the limitations of static routing in failure scenarios associated to dynamic routing protocols that can adjust to changes.

7. Static Routing in Hybrid Networks (Wired and Wireless):

• Objective: Execute static routing in a hybrid network with both wired and wireless segments using NS2.
• Focus: Mimic a hybrid network and setup static routes for interaction among wired and wireless nodes. Evaluate network performance based on throughput, latency, and packet loss, and relate static routing performance in hybrid networks to dynamic routing solutions.

8. Static Routing with QoS Support:

• Objective: Execute static routing with Quality of Service (QoS) support in NS2.
• Focus: Replicate a network in which static routes are configured, however traffic is selected according on QoS parameters such as bandwidth, latency, and packet loss. Measure on how QoS policies enhance the performance of static routing for high-priority applications like video streaming or VoIP.

9. Performance Comparison of Static Routing and Dynamic Routing:

• Objective: Relate the performance of static routing and dynamic routing such as  OSPF, RIP, AODV in NS2.
• Focus: Replicate a network using both static and dynamic routing protocols and evaluate the parameters like packet delivery ratio, latency, routing overhead, and scalability. Measure the benefits and challenges of static routing in comparison to dynamic routing in diverse network conditions.

10. Energy-Efficient Static Routing for IoT Networks:

• Objective: Apply static routing in an Internet of Things (IoT) network using NS2.
• Focus: Setup static routes for IoT devices to interact with a central hub or server. Evaluate the energy consumption, network lifetime, and scalability of static routing in an IoT environment, and relate its performance with energy-aware dynamic routing protocols intended for IoT.

11. Static Routing in Satellite Networks:

• Objective: Simulate static routing in a satellite network using NS2.
• Focus: Setup static routes for satellite communication, in which satellite nodes forward traffic among different ground stations. measure the performance of static routing based on delay, packet loss, and throughput in high-latency satellite environments, and discover the challenges of static routing in such dynamic networks.

12. Static Routing for Small Office or Home Networks:

• Objective: Mimic a static routing configuration for a small office or home network using NS2.
• Focus: Configure static routes for devices like routers, computers, and printers in a small network and measure network performance based on packet delivery and latency. Measure the simplicity and efficiency of static routing for small-scale networks with minimal configuration changes.

13. Static Routing in a Cluster-Based Network:

• Objective: Mimic static routing in a cluster-based network in which clusters of nodes interact with each other using predefined static routes.
• Focus: Apply static routes among clusters of nodes and evaluate the effects on network performance based on routing overhead, energy consumption, and packet delivery. Relate static routing to cluster-based dynamic protocols such as LEACH or TEEN based on network efficiency.

14. Static Routing in Delay-Tolerant Networks (DTNs):

• Objective: Execute static routing in a Delay-Tolerant Network (DTN) using NS2.
• Focus: Setup static routes in a DTN, in which end-to-end connectivity is not always available, and measure the effect of intermittent connectivity on routing performance. Measure on how static routing manages the difficulties of long delays and intermittent connections in comparison to DTN-specific dynamic routing protocols.

15. Static Routing in Grid Networks:

• Objective: Simulate static routing in a grid network topology using NS2.
• Focus: Setup static routes for nodes organised in a grid pattern and measure network performance based on packet delivery, latency, and overhead. Relate static routing in grid networks to dynamic routing protocols and discover how grid topology affects static routing efficiency.

These project ideas concentrate on implementing and discovering Static Routing in diverse network environments and related its performance with dynamic routing protocols using NS2. Additional specific details regarding the static routing will be provided according to your needs.