Wireless Network Research Topics

Wireless networks is examined as a fast growing as well as significant field which offers enormous opportunities for conducting research. On the basis of wireless networks, we list out a few latest research plans and problems that are considered as highly ideal for exploration: 

Research Plans

1. 6G Wireless Communication

• Explanation: For 6G, the efficient mechanisms have to be investigated. It includes combined satellite-terrestrial networks, intelligent reflecting surfaces, and terahertz (THz) communication. On metrics like connectivity, latency, and bandwidth, analyze their implication.
• Research Problems: Combining heterogeneous networks, tackling propagation issues at THz frequencies, and creating novel modulation techniques.

2. Reconfigurable Intelligent Surfaces (RIS)

• Explanation: To improve wireless signal coverage and propagation, the application of RIS has to be explored. In order to enhance network performance, control these surfaces in a dynamic manner by creating methods.
• Research Problems: Actual-time control methods, combination with previous wireless frameworks, and model and enhancement of RIS components.

3. AI-Driven Network Management

• Explanation: Specifically for automatic network handling, such as traffic enhancement, fault identification, and resource allocation, create AI-related methods. In actual-time contexts, assess their efficiency.
• Research Problems: The intricateness of various network platforms has to be managed. Assure less-latency decision-making process and develop credible AI frameworks.

4. Ultra-Reliable Low-Latency Communication (URLLC)

• Explanation: For major applications such as industrial automation and self-driving vehicles, accomplish ultra-reliable low-latency communication by exploring novel mechanisms and protocols.
• Research Problems: Handling network congestion, modeling efficient error rectification approaches, and stabilizing latency and credibility.

5. Hybrid RF and Visible Light Communication (VLC) Systems

• Explanation: To develop hybrid communication frameworks, the combination of VLC and RF mechanisms must be examined. On the basis of energy effectiveness, data rates, and coverage, assess their performance.
• Research Problems: Modeling robust hybrid protocols, interference handling, and appropriate shifting among VLC and RF.

6. Wireless Energy Harvesting and Transfer

• Explanation: Gather and transmit energy to IoT sensors and devices using wireless technology. For that, explore techniques. On network sustainability and device durability, assess the implication.
• Research Problems: Assuring secure energy levels, reducing the loss of energy sharing, and effective energy harvesting approaches.

7. Blockchain for Secure Wireless Communication

• Explanation: In order to improve the morality and safety of wireless interaction networks, the application of blockchain mechanism should be investigated. For safer authentication and data exchange, create robust protocols.
• Research Problems: Combining blockchain into previous wireless protocols, assuring less-latency transactions, and scalability of blockchain systems.

8. Edge Computing in Wireless Networks

• Explanation: To enhance processing abilities and minimize latency for IoT applications, the combination of edge computing into wireless networks must be explored. For effective data handling and resource allocation, build frameworks.
• Research Problems: Guaranteeing data protection and confidentiality, handling resource limitations, and efficient deployment of edge nodes.

9. Terahertz (THz) Communication

• Explanation: In utilizing THz frequencies for ultra-high-speed wireless interaction, analyze the potential problems and practicality. Appropriate for THz bands, create novel modulation and coding techniques.
• Research Problems: Handling THz-based propagation issues, creation of ideal antenna structures, and tackling extensive path loss.

10. Massive MIMO and Beamforming

• Explanation: Improve network capability and spectral effectiveness by exploring latest approaches for beamforming and massive MIMO systems. In extensive urban platforms, examine their performance.
• Research Problems: Assuring massive MIMO systems’ scalability, modeling robust beamforming methods, and handling inter-user interference.

Research Problems

1. Spectrum Scarcity and Management

• Outline: Through the creation of dynamic spectrum allocation and sharing approaches, the issue of constrained spectrum accessibility has to be solved. Plan to investigate spectrum sensing mechanisms and cognitive radio networks.

2. Security and Privacy in Wireless Networks

• Outline: To secure from highly intricate assaults, improve safety protocols. In wireless networks, the confidentiality issues relevant to data storage and sharing should be tackled.

3. Interference Management

• Outline: In highly occupied wireless platforms, reduce intervention by creating approaches. It is important to investigate the latest interference cancellation and signal processing techniques.

4. Energy Efficiency

• Outline: As a means to expand the battery durability of IoT and mobile devices, the energy effectiveness has to be enhanced in wireless interaction. Various energy harvesting approaches and energy-saving protocols must be explored.

5. Quality of Service (QoS)

• Outline: Specifically in wireless network-based applications which need less latency and extensive credibility, assure coherent QoS. To focus on major traffic, create protocols.

6. Mobility Management

• Outline: To facilitate appropriate handovers, improve mobility handling methods. In larger mobile platforms for drones and vehicles, preserve connections.

7. Integration of Heterogeneous Networks

• Outline: In order to offer enhanced performance and stable connections, the issues and potential solutions for combining different kinds of networks have to be analyzed. Some of the major networks include IoT, 5G, LTE, and Wi-Fi.

8. Scalability

• Outline: To adapt the enhancing network traffic and increasing number of linked devices, the scalable network protocols and frameworks must be created.

9. Latency Reduction

• Outline: Particularly for applications such as augmented reality, self-driving, and gaming, minimize latency in wireless interaction through exploring techniques.

10. Standardization and Interoperability

• Outline: In assuring the interoperability among networks and devices from various industries and standardization of novel mechanisms, the potential challenges have to be solved.

What are the computer networking topic for undergraduate thesis?

In the domain of computer networking, several topics and ideas are continuously emerging. Relevant to computer networking, we recommend numerous interesting topics that could be more appropriate for an undergraduate thesis: 

1. Network Security and Intrusion Detection Systems

• Overview: Various kinds of network assaults have to be analyzed. To detect and reduce these assaults, create an intrusion detection system (IDS).
• Major Areas: Actual-time threat analysis, IDS based on machine learning, anomaly identification, and signature-based detection.

2. Software-Defined Networking (SDN)

• Overview: By considering advantages, framework, and problems, the principles and applications of SDN must be investigated. Plan to apply an SDN controller. Then, its performance will be observed.
• Major Areas: SDN security, scalability, network planning, and OpenFlow protocol.

3. Wireless Sensor Networks (WSN)

• Overview: For different applications like smart farming or ecological tracking, the model and placement of WSNs should be explored. Their energy effectiveness and performance have to be assessed.
• Major Areas: Data aggregation approaches, sensor node structure, energy harvesting, and routing protocols.

4. IoT Network Security

• Overview: In IoT networks, analyze the issues relevant to security. To improve their safety, suggest efficient solutions. For IoT devices, a secure interaction protocol has to be utilized.
• Major Areas: IoT risk evaluation, lightweight security protocol, encryption, and authentication.

5. Network Traffic Analysis

• Overview: Seize and examine network traffic through the utilization of tools such as Wireshark. To improve network performance and identify abnormalities, create robust methods.
• Major Areas: Network enhancement, anomaly identification, pattern recognition, and traffic monitoring.

6. Quality of Service (QoS) in Wireless Networks

• Overview: Consider wireless network-based applications which need less latency and extensive credibility and enhance QoS in this network by exploring approaches.
• Major Areas: Performance assessment, resource allocation, traffic arrangement, and QoS metrics.

7. Blockchain for Secure Networking

• Overview: To improve reliability and safety in network transactions, the application of blockchain mechanisms must be investigated. Apply a security technique related to blockchain.
• Major Areas: Blockchain protocols, safer data exchange, performance evaluation, and decentralized authentication.

8. Network Virtualization

• Overview: The principles of network virtualization have to be examined. For the latest networks, analyze its advantages. Aim to apply virtual networks, and their performance should be assessed.
• Major Areas: Virtual network handling, virtual network functions (VNFs), and network function virtualization (NFV).

9. Wireless Mesh Networks

• Overview: Focus on wireless mesh networks and examine their applications and framework. To enhance their performance, create and assess various routing protocols.
• Major Areas: Scalability, fault tolerance, routing techniques, and mesh network topology.

10. IPv6 Migration and Implementation

• Overview: The conversion from IPv4 to IPv6 has to be explored. Analyze the potential issues associated in this conversion. In a network platform, utilize IPv6. With IPv4, compare its performance.
• Major Areas: Compatibility problems, Ipv6 security, dual-stack application, and IPv6 addressing.

11. Network Performance Optimization

• Overview: To enhance network performance in terms of packet loss, latency, and throughput, analyze efficient techniques. Assess the efficiency of optimization approaches by applying them.
• Major Areas: Performance metrics, load balancing, traffic modeling, and network congestion control.

12. Edge Computing in IoT Networks

• Overview: In improving the performance of IoT networks, the contribution of edge computing will be investigated by our experts. Consider utilizing various edge computing approaches. Their potential implication will be examined.
• Major Areas: Resource handling, data processing at the edge, scalability, and latency minimization.

13. VoIP (Voice over IP) Systems

• Overview: Concentrate on VoIP systems and explore their performance and application. Assess the credibility and standard of the VoIP system by creating it.
• Major Areas: QoS for VoIP, VoIP safety, performance metrics, and SIP protocol.

14. Network Automation with Ansible/Puppet

• Overview: Various network automation tools such as Puppet or Ansible have to be analyzed. In handling network framework, examine their use. Automatic network handling approaches will be applied.
• Major Areas: Network tracking, scripting, automatic placements, and configuration handling.

15. Ad Hoc Networks and Routing Protocols

• Overview: Consider ad hoc networks and explore their performance and structure. To accomplish effective data sharing in ad hoc networks, create and examine routing protocols.
• Major Areas: Network strength, mobility models, routing methods (like DSR, AODV), and MANETs.

16. Network Simulation and Modeling

• Overview: To design and simulate network contexts, employ different simulation tools such as OMNeT++ or NS-3. In various network arrangements, examine the performance.
• Major Areas: Traffic analysis, network protocols, performance assessment, and simulation techniques.

17. Cybersecurity in Cloud Computing

• Overview: In cloud computing platforms, analyze the problems based on security. To secure cloud-related networks, the security approaches have to be created and applied.
• Major Areas: Cloud safety protocols, intrusion detection, access control, and data encryption.

18. Wireless Network Security

• Overview: Particularly in wireless networks like Bluetooth or Wi-Fi, explore safety problems. Reduce these problems by creating and applying efficient safety protocols.
• Major Areas: Secure pairing, wireless intrusion detection, encryption techniques, and WPA3.

19. DDoS Attack Detection and Mitigation

• Overview: Various kinds of DDoS assaults must be examined. To identify and reduce them, create effective approaches. In a network, apply a DDoS protection technique.
• Major Areas: Performance implication, anomaly identification, reduction policies, and traffic analysis.

20. Smart Grid Communication Networks

• Overview: The interaction networks that are utilized in smart grids have to be investigated. To enhance their performance, credibility, and safety, create robust solutions.
• Major Areas: Network strength, data protection, smart grid protocols, and performance enhancement are the main areas that we use.