Help Me Write My Thesis

Help Me Write My Thesis

As soon as you enroll yourself for doctoral program, considering someone to write thesis is very important. The first step to formulate in selection of thesis topic share with us your area of work we will give you original topics that adds additional credit to your work. For thesis work, various trending ideas are emerged gradually and it is important to select an appropriate topic related to your research domain. We are always ethical ,not all writers are like that we are always reliable and guide through the entire process.  Here, we suggest few theses plans for various fields where network simulation equipment can be efficiently employed are:

Computer Science and IT

  1. Performance Evaluation of Routing Protocols in Ad-Hoc Networks: To simulate and compare various routing protocols in mobile ad-hoc networks (MANETs) or vehicular ad-hoc networks (VANETs), equipment such as NS3 or OPNET are utilized.
  2. Analysis of Load Balancing in Cloud Computing Environments: By utilizing equipment such as MATLAB or CloudSim, simulate cloud data centers to examine load balancing tactics.
  3. Cybersecurity Threat Simulation and Network Vulnerability Analysis: To design different cyber-threat settings and estimate network security, network simulators are employed.

Electrical and Computer Engineering

  1. 5G Network Performance Analysis: Examine factors such as delay, throughput, and network slicing by simulating 5G wireless networks through the utilization of equipment like MATLAB or NS3.
  2. IoT Network Optimization for Smart Cities: Frame IoT networks in smart city applications by employing simulators, and concentrating on optimizing interaction protocols and energy performance.
  3. Satellite Communication Network Analysis: For global internet coverage or emergency interaction, satellite communication networks simulation is performed by utilizing equipment such as STK (Systems Tool Kit).


  1. QoS and QoE Analysis in VoIP and Video Conferencing Services: To examine, Quality of Service (QoS) and Quality of Experience (QoE) in VoIP and video streaming, network simulation tools are employed.
  2. LTE and Wi-Fi Coexistence Strategies: Examining and simulating the coexistence of LTE and Wi-Fi networks, concentrating on interference handling and resource allocation.
  3. Fiber Optic Network Simulation for High-Speed Communication: It is based on designing fiber optic networks, and examining signal integrity, non-linear effects, and dispersion.

Information Systems

  1. Network Infrastructure Optimization for Large-Scale Enterprises: To enhance consistency and effectiveness, simulate enterprise networks.
  2. Data Center Network Simulations for Efficient Resource Allocation: Modeling data center networks to improve energy consumption, network traffic handling, and server allocation.
  3. Blockchain Network Performance Analysis: To examine transaction throughput, consensus mechanisms and scalability, simulate blockchain networks.

Network Engineering

  1. Wireless Sensor Network Simulations for Environmental Monitoring: For ecological tracking or farming application, develop and enhance wireless sensor networks by employing simulation tools.
  2. Software-Defined Networking (SDN) and Network Function Virtualization (NFV) Performance Analysis: Simulating and creating SDN and NFV architectures to research their influence on network safety and efficiency.
  3. Underwater Acoustic Network Simulations for Marine Research: For applications in marine biology research, oil and gas investigation, or submarine interactions, simulate underwater communication networks.

Thesis Writing in research methodology

In thesis writing, the methodology section demonstrates the technical flow of our research. The following are the general directions that assist us to write a thesis effectively:

  1. Introduction to the Methodology Section
  • Brief Introduction: We begin by offering a short summary of the research methodology, describing in what way it meets with our research aim.
  • Rationale: State why network simulation is more suitable for our research.
  1. Choice of Network Simulation Tools
  • Selection of Tools: Why we select particular network simulation equipment (e.g., NS2/NS3, OPNET, GNS3, MATLAB) is described by us. Share their merits, significance, and challenges.
  • Comparison with Other Tools: If suitable, contrast our selected tools with other accessible choices shortly, describing why they are desirable for our research.
  1. Network Model and Simulation Design
  • Description of the Network model: We explain the network topology, the nodes comprising, the kind of network such as wired, wireless, ad-hoc, and any particular configurations.
  • Simulation Parameters: The metrics and parameters we will examine or measure are described. (e.g., throughput, delay, packet loss). Elucidate in what ways these metrics are related to our research query.
  1. Implementation Details
  • Setup: The arrangement of our simulation setting, comprising software and hardware configurations are defined.
  • Simulation Scenarios: Describe the various settings or experiments that we will simulate. Any changes or various situations under which we will test our network framework are explained.
  1. Data Collection and Analysis
  • Data Collection Methods: In what way we gather data from our simulations are described. We also mention the kind of data to be gathered.
  • Analysis Techniques: Explain the methods and processes that our work will utilize to examine the simulation data. Involve any statistical software or methods we will incorporate for analysis.
  1. Validity and Reliability
  • Ensuring Accuracy: Examine in what way we will assure the feasibility and precision of our simulations. This might involve validation of frameworks, model adjustments, or comparison with practical data.
  • Limitations: Any challenges in our methodology that could influence the understanding of our outcomes are recognized.
  1. Ethical Considerations
  • Ethical Concerns: If our research includes factors that could increase moral concerns such as simulations that replicate vulnerable or vital networks, mention in what way we will deal with these issues.
  1. Pilot Study (if applicable)
  • Preliminary Testing: If we carried out a pilot study or initial simulations, define these and how they impact the model of our major research.
  1. Timeline
  • Schedule: It is important to offer a specified time-limit for finishing our simulations and analysis, meeting with the complete time-limit of our thesis.
  1. Summary
  • Recapitulation: The methodology section is ended by outlining the main facts and redefining in what way this technique will efficiently solve our research query.

Thesis Help Using Network Simulation Tools

We specialize in conducting thesis writing on network simulation tools using up-to-date methodologies and providing concise explanations. In addition to sharing a reference paper, we will also provide you with detailed information to instill confidence in our work. Achieving success in a network simulation tools thesis is a feat accomplished by only a few individuals. However, with our team of experts by your side, you can expect to receive a high grade. We offer a range of sample topics, and by sharing your requirements with us, we will create a flawless and plagiarism-free thesis using the latest tools while guiding you throughout the process.

     1.Social Data Offloading in D2D-Enhanced Cellular Networks by Network Formation   Games

  1. Joint energy-aware and buffer-assisted relay selection method for relay-aided D2D communications
  2. Research on power control algorithm for 6G oriented D2D communication
  3. Distributed resource allocation for D2D-enabled two-tier cellular networks with channel uncertainties
  4. Modelling and Performance Analysis of Full-Duplex Communications in Cache-Enabled D2D Networks
  5. Dynamic Incentive Design in Content Dissemination Process Through D2D Communication
  6. Device-to-device (D2D) communication in MU-MIMO cellular networks
  7. Dynamic power control based on FFR for D2D communication underlaying cellular networks
  8. NOMA-D2D Technology-aided Low delay resource allocation for MEC networks
  9. Decentralized Resource Allocation for Multicast D2D Communications Using Stochastic Geometry
  10. RRC and MAC call flow procedures for D2D communication through sidelink in LTE-A
  11. Coalitional Games Based Resource Allocation for D2D Uplink Underlaying Hybrid VLC-RF Networks
  12. D2D Communication and Energy Efficiency on LTE for Public Safety Networks
  13. Enabling Relay-Assisted D2D Communication for Cellular Networks: Algorithm and Protocols
  14. Radio Link Enabler for Context-Aware D2D Communication in Reuse Mode
  15. Handover Management for D2D Communication in 5G Network
  16. Learning to Tradeoff Between Energy Efficiency and Delay in Energy Harvesting-Powered D2D Communication: A Distributed Experience-Sharing Algorithm
  17. Optimization of Resource and Energy for D2D enable Communication System using Constraint’s- based Function
  18. Resource sharing in D2D communication underlaying cellular LTE-A networks
  19. Relay Selection and Secure Connectivity Analysis in Energy Harvesting Multi-Hop D2D Networks
Live Tasks
Technology Ph.D MS M.Tech
NS2 75 117 95
NS3 98 119 206
OMNET++ 103 95 87
OPNET 36 64 89
QULANET 30 76 60
MININET 71 62 74
MATLAB 96 185 180
LTESIM 38 32 16
CONTIKI OS 42 36 29
GNS3 35 89 14
NETSIM 35 11 21
EVE-NG 4 8 9
TRANS 9 5 4
PEERSIM 8 8 12
RTOOL 13 15 8
VNX and VNUML 8 7 8
WISTAR 9 9 8
CNET 6 8 4
ESCAPE 8 7 9
VIRL 9 9 8
SWAN 9 19 5
JAVASIM 40 68 69
SSFNET 7 9 8
TOSSIM 5 7 4
PSIM 7 8 6
ONESIM 5 10 5
DIVERT 4 9 8
TINY OS 19 27 17
TRANS 7 8 6
CONSELF 7 19 6
ARENA 5 12 9
VENSIM 8 10 7
NETKIT 6 8 7
GEOIP 9 17 8
REAL 7 5 5
NEST 5 10 9

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