Published On Sep 21, 2024
Title: - Resilient Autonomous Navigation Systems under Adversarial Attacks
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Implementation plan:
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Scenario-1 (Without Attack):
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Step 1: Initially, we construct a network consisting of 5 - Vehicles, 5 - gNodeB, 1 - router, 1 - Server.
Step 2: Next, we Implement the on-board unit component (Camera, Lidar, Radar, and GPS receiver) into the network without attack
Step 3: Finally, plot performance for the following metrics:
3.1: Number of Vehicles vs. Packet Delivery Ratio (%)
3.2: Number of Vehicles vs. Latency (ms)
3.3: Number of Vehicles vs. Throughput (Mbps)
3.4: Time (ms) vs. State of Sensor
Scenario-2 (With Attack):
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Step 1: Initially, we construct a network consisting of 5 - Vehicles, 5 - gNodeB, 1 - router, 1 - Server.
Step 2: Next, we Implement the on-board unit component (Camera, Lidar, Radar, and GPS receiver) into the network without attack
Step 3: Then, Implement the attack on the on-board unit component.
Step 4: Finally, plot performance for the following metrics:
4.1: Number of Vehicles vs. Packet Delivery Ratio (%)
4.2: Number of Vehicles vs. Latency (ms)
4.3: Number of Vehicles vs. Throughput (Mbps)
4.4: Time (ms) vs. State of Sensor
4.5: Successful attacks (%) vs. Attacked Sensors
Scenario-3 (After RDO):
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Step 1: Initially, we construct a network consisting of 5 - Vehicles, 5 - gNodeB, 1 - router, 1 - Server.
Step 2: Next, we Implement the on-board unit component (Camera, Lidar, Radar, and GPS receiver) into the network without attack
Step 3: Then, Implement the attack on the on-board unit component.
Step 4: Next, implement a robust Resilient Distributed Optimization (RDO) Algorithm for the V2V communication on the on-board unit component which is being attacked.
Step 5: Finally, plot performance for the following metrics:
5.1: Number of Vehicles vs. Packet Delivery Ratio (%)
5.2: Number of Vehicles vs. Latency (ms)
5.3: Number of Vehicles vs. Throughput (Mbps)
5.4: Time (ms) vs. State of Sensor
5.5: Successful attacks (%) vs. Attacked Sensors
Software requirements:
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[+] Development tool: Omnet++ 4.6 or above
[+] Development OS: Ubuntu or Windows 10
Note:-
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[1] If the above plan does not satisfy your requirement, please provide the processing details, like the above step-by-step.
[2] Please note that this implementation plan does not include any further steps after it is put into implementation.
[3] If the above plan satisfies your requirement please confirm with us.
[4] We make simulation type processes only, not a real-time process.
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1. #VehicularNetworks
2. #AttackDetection
3. #PerformanceAnalysis
4. #NetworkSecurity
5. #SimulationResearch
6. #Cybersecurity
7. #SmartVehicles
8. #DataProtection
9. #TrafficSafety
10. #IoTSecurity
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We possess a team of professional researchers who specialize in the subsequent research domains
• Wireless sensor network
• IOT
• VANET
• SDN
• Network Security
• Wireless communication
The above mentioned video serves as a guide in conducting omnet manual research work.
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