Blockchain IOT Research Projects

This technology is a combination of multiple methods which has much significance over the system. If you are eager to know about how all the technologies work together as a single system, you have to go through this research study based on “Blockchain based IoT-Edge-Cloud Environments”.

  1. Define Blockchain based IoT-Edge-Cloud Environments

This is a technology designed based on combining IoT system with Cloud computing, Edge computing and also by integrating Blockchain to it. By combining all those techniques, the significance of the system is also increased with increase in security, trust and data integrity in environments like distributed and decentralized.

  1. What is Blockchain based IoT-Edge-Cloud Environments?

This is a technology designed by combining multiple methods like IoT, edge, cloud and Blockchain. This system increases the efficiency, security and transparency of different applications like industrial automation and managing supply chain. The work of every individual method includes IoT for collecting data; edge computing is for processing those data and Blockchain ensuring recording and verifying transactions while maintaining integrity. Cloud computing provides resources for storing and further analysis.

  1. Where Blockchain based IoT-Edge-Cloud Environments is used?

In this section we are going to discuss about the uses of “Blockchain based IoT-Edge-Cloud Environments”. This technology is used in various sectors for maintaining data integrity and ensuring transparency. Working in managing supply chain for increasing traceability; used for smart cities in maintaining the urban infrastructure, also used in healthcare industries for secure handling of patient data.

  1. Why Blockchain based IoT-Edge-Cloud Environments is proposed? Previous Technology Issues

Here in this section we are going to discuss about why this technology was propose and the issues faced by it on the earlier phase.

This “Blockchain based IoT-Edge-Cloud Environments” was propose to overcome the limitations had in older methods. Some of the drawbacks of earlier technologies are mentioned here:

High Latency: The existing IoT devices choose a random server as target for offloading and allocating task rather than choosing a suitable one. Due to its heterogeneous nature, the latency of IoT devices becomes high.

Fewer Throughputs: While scheduling a task priority, resource consumption and QoS should be considered, or else it will lead to reduce in throughput. Because of no mobility in device offloading and poor scheduling takes place due to which data loss increases and throughput decreases.

Lack of Security: In the earlier devices the security breaches were high because of considering all as legitimate device and sharing task in public while offloading or scheduling, in which attackers can easily access that information. This leads to poor security and increases security breaches.

  1. Algorithms / Protocols

After knowing about the technology, uses of it and the issues faced by them in the earlier stage, now we are going to learn about the algorithms used for this technology. The algorithms provided for “Blockchain based IoT-Edge-Cloud Environments” to overcome the previous issues faced by it are: Hybrid Deep Learning (HDL), Hybrid Leader based Optimization (HLO), Improved Fuzzy Algorithm (IFA) and Stackleberg Actor Critic (StAC).

  1. Simulation results / Parameters

The approaches which were proposed to overcome the issues faced by “Blockchain based IoT-Edge-Cloud Environments” in the above section are tested using different methodologies to analyze its performance. The comparison is done by using metrics like Bandwidth utilization vs. number of tasks, Completion time vs. number of tasks, Delay vs. number of tasks, Throughput vs. number of tasks and Response time vs. number of tasks.

  1. Dataset LINKS / Important URL

Here are some of the links provided for you below to gain more knowledge about this technology which can be useful for you:

  1. Blockchain based IoT-Edge-Cloud Environments Applications

In this next section we are going to discuss about the applications of this technology. It has application in many different industries. It is applied in managing supply chain, for increasing transparency by verifying and tracking origin of the product. Used for smart cities in maintaining the urban infrastructure, resource allocation and increasing service. Employed in healthcare industry for maintaining patient data, health monitoring and to increase interoperability in medical records and devices. This technology can also be applied in the field of manufacturing, finance, education and environmental monitoring for its trust and data management.

  1. Topology

Here you are going to learn about the different choices of topologies which can be used in “Blockchain based IoT-Edge-Cloud Environments”. The topology which is chosen should support for implementing advanced algorithms in IoT devices for processing and allocating data.

  1. Environment

This “Blockchain based IoT-Edge-Cloud” can function properly under different environments; such as Blockchain node, global edge server and local edge server.

  1. Simulation Tools

Here we provide some simulation software for this system, which is established with the usage of tool like Network simulator with version 3.26 or above.

  1. Results

After going through this research paper for this study, you now have a complete understanding about this technique and the ideology behind it. You have also leant about the applications of it, the algorithms used in it and the issues faced by it previously.

Blockchain IOT Research Topics & Ideas

  1. Blockchain-Based IoT Applications, Platforms, Systems and Framework
  2. State Management against Two-message Attacks in Hash-Based Post Quantum Signatures for Large IoT Sensor Networks Using Blockchain
  3. Blockchain-Based Distributed Hybrid Cloud Identity Management for Securing IoT Devices in the Cloud
  4. A Decentralized Blockchain-Based IoT System for Privacy-Preserving Data Sharing
  5. IoT Forensics System based on Blockchain
  6. An Interpretation of the Challenges and Solutions for Agriculture-based Supply Chain Management using Blockchain and IoT
  7. A study on Security of IOT based Blockchain System using Artificial Intelligence
  8. A Secured Framework for Blockchain Technology Adoption in IoT
  9. A Cluster enabled Blockchain-based Data management for IoT systems
  10. A Blockchain-based IoT Security Solution Using Multi-chain
  11. Speeding at the Edge: An Efficient and Secure Redactable Blockchain for IoT-Based Smart Grid Systems
  12. Optimization of a Consensus Protocol in Blockchain-IoT Convergence
  13. IoT Framework in a Blockchain dependent Cloud Environment
  14. Countering Active Attacks on RAFT-Based IoT Blockchain Networks
  15. P3219/D2.0, Jul 2023 – IEEE Approved Draft Standard for Blockchain-based Zero-Trust Framework for Internet of Things (IoT)
  16. Model of Controlled Environment based on Blockchain and IoT
  17. towards Robust Consensus for Intelligent Decision-making in IoT Blockchain Networks
  18. A Leader Election Algorithm Using Blockchain for IoT
  19. A Cross-domain Data Trusted Fusion Method of Energy IoT Based on Blockchain and Metadata
  20. Audit model using controls from ISO/IEC 27002 for the information security of electronic voting based on IoT and Blockchain
  21. Demonstrating Trusted Blockchain IoT Device Based On TLS-PSK Secure Element
  22. Blockchain based Secure Communication in IoT Environment
  23. IoT Security: AI Blockchaining Solutions and Practices
  24. Design and Implementation of an Integrated IOT Blockchain Framework for Drone Communication
  25. Dynamic Secure Access Control and Data Sharing Through Trusted Delegation and Revocation in a Blockchain-Enabled Cloud-IoT Environment
  26. Edge Devices and Blockchain Integration in IoT System: A Novel Design Approach
  27. A Blockchain-Based Authentication Scheme and Secure Architecture for IoT-Enabled Maritime Transportation Systems
  28. Problems and Opportunities for Blockchain and IoT-based Intelligent Medical Records
  29. Lightweight Blockchain-Based Architecture for 5G Enabled IoT
  30. Secure IoT Communication with a Blockchain-Enabled Decentralized MQTT Network
  31. HIBE Chain: A Hierarchical Identity-Based Blockchain System for Large-Scale IoT
  32. Blockchain-Based IoT Model and Experimental Platform Design in the Defense Supply Chain
  33. Energy-Efficient Spectrum Sharing for 6G Ubiquitous IoT Networks Through Blockchain
  34. Patients Medical Record Monitoring Using IoT Based Biometrics Blockchain Security System
  35. IoT and Blockchain Integration Security
  36. Efficient Design for Smart Environment Using Raspberry Pi with Blockchain and IoT (BRIoT)
  37. Chain Discipline – Towards a Blockchain-IoT-Based Self-Sovereign Identity Management Framework
  38. GTxChain: A Secure IoT Smart Blockchain Architecture Based on Graph Neural Network
  39. A Blockchain-Enabled IoT Framework for NICU Infant Health Monitoring System
  40. IoT and Blockchain Technology Adoption Models to Increase Transaction Transparency in the Car Rental Industry
  41. A Review on Challenges, Opportunities, and Solutions for 5th Generation Based IoT Using Blockchain & AI
  42. A Lightweight Stochastic Blockchain for IoT Data Integrity in Wireless Channels
  43. Post Quantum Lattice-Based Secure Framework using Aggregate Signature for Ambient Intelligence Assisted Blockchain-Based IoT Applications
  44. Blockchain-IoT based device authentication protocol for Healthcare Multimedia
  45. Smart security system using Hybrid System with IoT and Blockchain: A security system Human sassed Detection
  46. Enhanced Blockchain Scalability for IoT-based Smart Devices -A Generic Model Development
  47. Designing a Secure Food Supply Chain System using Blockchain in Agricultural IoT
  48. Ensuring Trust and Security in IoT Systems through Blockchain Integration
  49. A Blockchain and IoT-Enabled Secure Health Data Handling Framework
  50. A Secure and Cost-Efficient Blockchain Facilitated IoT Software Update Framework