5G Beyond networks Projects examples using omnet++

“5G Beyond” means the evolution of 5G networks within what is frequently termed as 5G+ or 6G in which the focus transferred towards more advanced methods, higher frequencies (like THz communications), extreme low latency, AI-driven networking, and enhanced security, different other features. It is expected to help highly applications like immersive VR/AR, smart cities, autonomous vehicles, and more. Below are some project examples that explore 5G Beyond networks using OMNeT++:

1. THz Communication in 5G Beyond Networks

Description: Inspect the usage of Terahertz (THz) frequencies for ultra-high-speed communication in 5G Beyond networks, focusing on the threats of signal propagation and attenuation.

Key Features:

• Enactment of THz communication models, considering the distinct propagation properties at these high frequencies.
• Replicate different scenarios that has various THz link configurations containing indoor and outdoor environments.
• Performance evaluation in terms of data rate, signal attenuation, and the effect of environmental factors like humidity and obstacles.

Tools & Frameworks:

• INET Framework with Custom Modules: Extend the INET framework to encompass THz communication models and imitate their performance in 5G Beyond networks.

2. AI-Driven Network Management in 5G Beyond

Description: Explore the use of Artificial Intelligence (AI) for dynamic network management in 5G Beyond networks, where AI algorithms enhance resource allocation, traffic routing, and fault handling in real-time.

Key Features:

• Execution of AI-driven algorithms for network improvement like machine learning-based traffic expectation and resource assignments.
• Simulation of scenarios with changing network conditions as well as high traffic volumes, diverse QoS demands, and network failures.
• Performance assessments in terms of network efficiency, latency minimization, and fault retrieval time.

Tools & Frameworks:

• Custom AI Modules in OMNeT++: Build AI-based network management modules and incorporate them into the 5G Beyond network simulation environment.

3. Ultra-Reliable Low-Latency Communication (URLLC) in 5G Beyond

Description: In 5G Beyond networks, mimic advanced URLLC situations to help mission-vital applications like self-driven vehicles and industrial automation.

Key Features:

• Execution of optimized URLLC protocols that make certain ultra-low latency and high consistency, even in threating network conditions.
• Mimic the situations with strict latency and reliability desires like remote surgery, autonomous driving, and industrial control.
• Performance analysis in terms of latency, packet loss, and the reliability of communication in several network loads.

Tools & Frameworks:

• INET Framework with URLLC Extensions: Extend the INET framework to imitate URLLC in 5G Beyond networks, focusing on the particular requirements of mission-critical applications.

4. 6G Networks with Integrated Space-Terrestrial Communication

Description: Explore the integration of space (satellite) and terrestrial networks in 5G Beyond, enforcing unified global connectivity and maximize coverage in remote areas.

Key Features:

• Implementation of incorporated communication protocols that permits seamless handover amongst satellite and terrestrial networks.
• Simulation of scenarios with different levels of satellite-terrestrial incorporation, as well as scenarios with low earth orbit (LEO) satellites.
• Performance analysis in terms of metrics like handover latency, coverage, and data throughput in remote and urban environments.

Tools & Frameworks:

• Custom Satellite-Terrestrial Modules in OMNeT++: Build and imitate integrated space-terrestrial communication methods into the 5G Beyond framework.

5. Smart Cities and IoT in 5G Beyond

Description: Test the role of 5G Beyond networks in helping smart cities and enormous IoT deployments, where millions of devices are interrelated with high efficiency and low latency.

Key Features:

• Execution of communication protocols optimized for massive IoT, focusing on energy efficiency, scalability, and real-time data processing.
• Simulation of smart city scenarios with large numbers of interrelated devices like smart traffic management, environmental observing, and public safety systems.
• Performance assess in terms of network scalability, energy utilization, and data processing latency.

Tools & Frameworks:

• INET Framework with IoT Extensions: Mimicking the smart cities and IoT in 5G Beyond environment by extending the INET framework.

6. Advanced Security Mechanisms in 5G Beyond Networks

Description: Guard the 5G Beyond network from evolving challenges as well as quantum computing-resistant encryption and AI-driven threat identification by exploring advanced security protocols.

Key Features:

• Execution of security protocols like post-quantum cryptography, AI-based intrusion detection, and optimized privacy-preserving features.
• Simulation of security scenarios such as targeted attacks on vital organization and large-scale data leaks.
• Performance analysis based on metrics like security overhead, efficiency in challenge mitigation, and effect on network performance.

Tools & Frameworks:

• Custom Security Modules in OMNeT++: Set up and mimic advanced security protocols personalized for 5G Beyond networks.

7. Network Slicing with AI Optimization in 5G Beyond

Description: Making certain that every slice meets particular service demands efficiently by examining the use of AI to improve network slicing in 5G Beyond networks.

Key Features:

• Execution of AI-driven algorithms for dynamic network slice generation, resource distribution, and QoS management.
• Simulation of scenarios with numerous network slices catering to various services, includes eMBB, URLLC, and mMTC.
• Performance analysis based on slice isolation, resource usage, and service quality in several network conditions.

Tools & Frameworks:

• Custom Slicing Modules in OMNeT++: Build and imitate AI-optimized network slicing techniques into a 5G Beyond network environment.

8. Holographic Telepresence and AR/VR in 5G Beyond

Description: Support bandwidth-intensive and low-latency applications like holographic telepresence and augmented/virtual reality by overseeing the potential.

Key Features:

• Deploying of communication protocols that helps ultra-high data rates and extremely low latency, necessary for immersive AR/VR experiences.
• Replication of scenarios including real-time holographic communication and AR/VR applications like remote collaboration and virtual tourism.
• Performance estimation based on metrics like data rate, latency, jitter, and user experience quality.

Tools & Frameworks:

• Custom AR/VR Modules in OMNeT++: Configure and mimic protocols to help holographic telepresence and AR/VR in a 5G Beyond network.

9. Edge Computing in 5G Beyond Networks

Description: Decrease the latency and improve the data processing for time-sensitive applications  by examining the incorporation of edge computing in 5G Beyond networks.

Key Features:

• Implementation of edge computing architectures that unload data processing from the cloud to edge devices, closer to the end-users.
• Imitation of scenarios where edge computing is used for real-time applications like systemized driving, smart industrialized and video analytics.
• Performance assessment is based on latency reduction, bandwidth savings, and processing efficiency.

Tools & Frameworks:

• Custom Edge Computing Modules in OMNeT++: Setting up and simulate edge computing methods in a 5G Beyond network environment.

10. Sustainable 5G Beyond Networks with Green Communication

Description: Reduce energy utilization and minimize the environmental influence of network operations by exploring the use of green communication techniques.

Key Features:

• Execution of energy-efficient protocols like sleep modes, energy-aware routing, and renewable energy incorporation.
• Simulation of network scenarios with changing traffic loads, energy constraints, and renewable energy existency.
• Performance analysis in terms of energy savings, carbon footprint minimization, and the effect on network performance.

Tools & Frameworks:

• Custom Green Communication Modules in OMNeT++: Configure and simulate green communication techniques for sustainable 5G Beyond networks.

Through this sample, we have completely offered the vital information regarding the implementation of 5G Beyond Network Projects using OMNeT++ tool. if needed, we will send the related information of 5G beyond network and so on.

Our talented developers are here to make sure your projects are finished on time. If you need help with network analysis, just send us your details, and we’ll help you get the best results. Keep connected with us at omnet-manual.com! We are working on exciting 5G Beyond networks projects using omnet++. We also focus on cool areas like immersive VR/AR, smart cities, and self-driving cars, so reach out for awesome topic ideas!