Framework for Intrusion Prevention Based on Block Chain in IoT Environment

Thamraj Narendra Ghorsad,  Amol Zade

Authors

Thamraj Narendra Ghorsad, Amol Zade

Keywords:

Internet of Things, Wireless Sensor Network, Blockchain, Intrusion Prevention, Sensor Nodes

Abstract

The Internet of Things works by helping different network devices connect via wireless and wired media. There has been a lot of research in IoT over the last few decades and millions of devices have been connected. In the development of IoT technology, security-related challenges have started to arise as well as in the expanded volume of data, a large amount of additional data is generated by IoT so the combination of different things and classes in data has changed. This has paved the way for the handling of large amounts of information and the creation of different applications to provide strong security of data. However, most research has focused on designing and building the stable topology of networks, as well as the dynamic structure of wireless sensor nodes. Given the limited difficulties of sensor nodes, it is necessary to redesign with minimal network overhead, providing strong protection against malicious actions. Therefore, in this study, we focused on proposing a framework for intrusion prevention and intrusion identification integrated into the WSN for IoT devices to provide strong security with high network distribution ratios. The proposed scheme is classified into two sections in the first section; autonomously organized clusters provide better stability to clusters based on the principle of uncertainty. And in the second section, developed an end-to-end secure and multi-hop path based using the blockchain technique. The parameters of different network metrics have shown good improvement in the results of our simulations in terms of existing solutions.

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Author Biography

Thamraj Narendra Ghorsad, Amol Zade

Thamraj Narendra Ghorsad*¹, Dr. Amol Zade ²

¹Research Scholar, G.H.Raisoni University, Amravati –Maharashtra,

INDIA

²Professor,G.H.Raisoni University, Amravati –Maharashtra, INDIA

* Corresponding Author Email: raj.ghorsad@gmail.com

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Framework for Intrusion Prevention Based on Block Chain in IoT Environment

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