EVE-Ng is popular simulation software that provides access for network and research professionals by offering vast opportunities in the networking domain. According to EVE-NG applications, numerous project ideas are proposed by us that are worthwhile for performing research:

  1. Enterprise Network Design and Implementation
  • Summary: Apply routers, switches, WAN connections and firewalls to develop entire network architecture. ACL (Access Control Lists) for security, redundancy protocols such as HSRP and VRRP, creation of VLANs and inter-VLAN routing are encompassed in this project.
  • Educational Objective: To execute complicated network structure, crucially interpret the enterprise networking necessities.
  1. Multi-Site WAN Connectivity with SD-WAN
  • Summary: For connecting various sites, establish SD-WAN (Software-Defined Wide Area Network). Incorporating the simple network operations, enhanced bandwidth management and advanced security characteristics, this study represents the advantages of SD-WAN compared to conventional WAN technologies.
  • Educational Objective: In the process of connecting decentralized networks naturally, it acquires perceptions into SD-WAN technology and its benefits.
  1. Network Security with Firewalls and IPS/IDS
  • Summary: Encompassing (IPS/IDS) Intrusion Prevention/Detection Systems and firewalls, create a network with structured security appliances. For detecting harmful behaviors, develop security policies and observe traffic. To examine the configurations, simulate the attack events.
  • Educational Objective: The main focus of this research is interpreting the basics of network security and understanding the process on how to protect a network in opposition to different attacks.
  1. IPv6 Migration Strategies
  • Summary: Migrate a network from IPv4 to IPv6 and develop an efficient project. Implementing IPv6 addressing policies, translating algorithms like NAT64, DNS64 and configuring dual-stack frameworks are incorporated in this study.
  • Educational Objective: As related to migration of a future generation IP protocol, understand about IPv6 properties, advantages and problems.
  1. Cloud Networking with Hybrid Cloud Model
  • Summary: A hybrid cloud network is required to be modeled and executed which interconnects self-hosting infrastructure to a cloud service provider. This study might investigate cloud-native networking services, direct connect services and VPN connections.
  • Educational Objective: Interpret the process to synthesize cloud services with conventional data center networks and standards of cloud networking.
  1. Automating Network Configurations with Ansible
  • Summary: To generate the employment and configuration of network devices, make use of Ansible in EVE-NG. For diverse network assessments like software updates, a security policy deployment and configuration backup, this study includes writing Ansible playbooks.
  • Educational Objective: Automation standards might be interpreted through this research and understand efficient processes to implement them in network configurations.
  1. QoS Implementation for VoIP Services
  • Summary: On a network carrying VoIP traffic, develop QoS (Quality of Service) policies. As compared to latency-sensitive data, in what way the QoS might prefer voice traffic and assuring explicit and consistent voice communication are represented through this research.
  • Educational Objective: In assisting significant business techniques, it seeks to acquire knowledge of QoS algorithms and their impacts.
  1. Troubleshooting Complex Networks
  • Summary: Depending on familiar problems and errors, design a relevant network. As extending from poor configuration and routing loops to security attacks, troubleshoot and address these challenges by means of EVE-NG.
  • Educational Objective: Gain insights of interpreting various network components on how it communicates with each other and enhance problem-solving skills.
  1. Dynamic Routing Protocols Comparison
  • Summary: Configure various scenarios in EVE-NG to contrast dynamic routing protocols such as BGP, EIGRP and OSPF. For different network architectures, assess their adaptability, appropriateness and performance.
  • Educational Objective: Regarding diverse routing protocols, interpret the operational features and applicable areas.
  1. MPLS Network with Traffic Engineering
  • Summary: A MPLS (Multi-Protocol Label Switching) network has to be created and executed. In order to enhance traffic flow and strengthen network resource deployment, this research emphasizes the MPLS traffic engineering characteristics.
  • Educational Objective: This project aims to understand MPLS theories and examine traffic engineering on how it is applicable in handling bandwidth and performance.

How to simulate eve ng simulator?

Simulating an EVE-NG simulator needs to follow gradual procedures for effective implementation. To guide you on how to work with simulating a network by using EVE-NG, we provide step by step measures:

Step 1: Constructing EVE-NG

  1. Installation:
  • Within a virtual machine or on a bare-metal server, you can install EVE-NG. It contains two significant versions:
  • Community Edition (Publicly available) and
  • Professional Edition.
  • Particularly for those who are unfamiliar with EVE-NG, the Community Edition will be sufficient for multiple users.
  • You can install EVE-NG anywhere on VMware Player, VMware ESXi, virtual box or VMware Workstation. On the EVE-NG website, the procedures for the installation process are accessible.
  1. Accessing EVE-NG:
  • Through a web browser, EVE-NG is enabled after the installation process. Deploy HTTP or HTTPS like http:// to connect to the IP address of the EVE-NG host machine.
  1. Basic Configuration:
  • If you are employing a professional edition, you must conduct some primary configuration steps like incorporating licenses for professional characteristics or development of network interfaces.

Step 2: Adding Images

  1. Download Required Images:
  • You have to download the relevant images for firewalls, routers, switches etc., before you begin to simulate network devices. For Cisco devices, it might be IOPS images, other vendor-specific images and for routers, it might be VyOS.
  1. Upload Images to EVE-NG:
  • Through SCP (Secure Copy Protocol) or utilize built-in upload properties, upload the downloaded images to EVE-NG. For uploading and configuring images in EVE-NG, each device contains certain guidelines.

Step 3: Developing a Project

  1. Formulate a New Project:
  • Initially, log into the EVE-NG web interface and click on “Add new project” to design a novel project. Then for your project, provide a suitable name and explanation.
  1. Adding Devices to the Project:
  • Click on the “Add an object” button to begin to include devices within your project. Which kind of device you want to incorporate must be picked like a router or switch. Select the certain model or image which you posted earlier.
  • According to the needs, organize your network topology by dragging and dropping devices.

Step 4: Configuring Network Topology

  1. Connecting Devices:
  • Tap on a device and then select the port which you aim to apply for the connection to connect the devices. Click on another device subsequently and the port which you intend to connect it to. Among these devices, EVE-NG simulate a cable connection
  1. Starting Devices:
  • Right-click on the mouse and choose “Start” to begin each device. Through the medium of EVE-NG interface, you can enable its console after your device is started.
  1. Configuring Devices:
  • Based on your network architecture or practical needs, configure every device by using console access which is offered by EVE-NG. Security applications, routing protocols and configuring IP addresses are encompassed.

Step 5: Simulation and Testing

  1. Testing Network Configuration:
  • You can begin to examine your network after your devices are constructed. It might include examining network security configurations, pinging between devices, constructing and ensuring the routing protocols.
  1. Troubleshooting:
  • Throughout your simulation, troubleshoot any emerging issues by deploying EVE-NG tools and device console outputs.

EVE NG Simulator Thesis Topics

EVE NG Simulator Projects

Using the EVE-NG software for network simulation in research or academia can be both thrilling and demanding. It necessitates extensive expertise in EVE-NG. Here are some fascinating EVE NG Simulator Projects that we are currently working on. Don’t wait, let us know your requirements and we will provide you with excellent service.

  1. Provably secure hybrid key agreement protocols in cluster-based wireless ad hoc networks
  2. Design of a security-aware routing scheme in Mobile Ad-hoc Network using repeated game model
  3. A lightweight anonymous routing protocol without public key en/decryptions for wireless ad hoc networks
  4. Joint Power and Rate Adaptation in Ad Hoc Networks Based on Coupled Interference
  5. Topological dynamics of comparison-based fault identification in ad hoc networks
  6. Impact of Varying Node Velocity and HELLO Interval Duration on Position-based Stable Routing in Mobile Ad Hoc Networks
  7. Memetic algorithm for minimum energy broadcast problem in wireless ad hoc networks
  8. A Mobile Ad Hoc Network Public Key Encryption Algorithm Based on Hash-Chain
  9. VANET QoS-OLSR: QoS-based clustering protocol for Vehicular Ad hoc Networks
  10. A flocking-based approach to maintain connectivity in mobile wireless ad hoc networks
  11. Routing security scheme based on reputation evaluation in hierarchical ad hoc networks
  12. Reliability Evaluation of Mobile Ad Hoc Network: With and without Mobility Considerations
  13. A micro-artificial bee colony based multicast routing in vehicular ad hoc networks
  14. Spectrum-aware cross-layered routing protocol for cognitive radio ad hoc networks
  15. PSSB: Priority enforced slow-start backoff algorithm for multimedia transmission in wireless ad-hoc networks
  16. An analytical study of the communication cost of data-centric storage in mobile ad hoc networks
  17. Secure communications for cluster-based ad hoc networks using node identities
  18. Bee life-based multi constraints multicast routing optimization for vehicular ad hoc networks
  19. Synchronizability in complex ad hoc dynamical networks with accelerated growth
  20. Distributed multiple-message broadcast in wireless ad hoc networks under the SINR model