# Dickson polynomial-based secure group authentication scheme for Internet of Things

**Authors:** Salman Ali Syed, Selvakumar Manickam, Mueen Uddin, Hamed Alsufyani, Mohammad Shorfuzzaman, Shitharth Selvarajan, Gouse Baig Mohammed

PMC · DOI: 10.1038/s41598-024-55044-2 · 2024-02-28

## TL;DR

This paper introduces a new secure group authentication method for IoT devices using Dickson polynomials and blockchain to reduce costs and improve security.

## Contribution

A novel Dickson polynomial-based group authentication scheme for IoT, integrated with blockchain for secure and efficient communication.

## Key findings

- The proposed scheme reduces network traffic overhead while ensuring secure group authentication.
- The framework is resistant to multiple types of cyber attacks including replay and man-in-the-middle attacks.
- Performance analysis shows the framework outperforms existing methods in computation, communication, and latency.

## Abstract

Internet of Things (IoT) paves the way for the modern smart industrial applications and cities. Trusted Authority acts as a sole control in monitoring and maintaining the communications between the IoT devices and the infrastructure. The communication between the IoT devices happens from one trusted entity of an area to the other by way of generating security certificates. Establishing trust by way of generating security certificates for the IoT devices in a smart city application can be of high cost and expensive. In order to facilitate this, a secure group authentication scheme that creates trust amongst a group of IoT devices owned by several entities has been proposed. The majority of proposed authentication techniques are made for individual device authentication and are also utilized for group authentication; nevertheless, a unique solution for group authentication is the Dickson polynomial based secure group authentication scheme. The secret keys used in our proposed authentication technique are generated using the Dickson polynomial, which enables the group to authenticate without generating an excessive amount of network traffic overhead. IoT devices' group authentication has made use of the Dickson polynomial. Blockchain technology is employed to enable secure, efficient, and fast data transfer among the unique IoT devices of each group deployed at different places. Also, the proposed secure group authentication scheme developed based on Dickson polynomials is resistant to replay, man-in-the-middle, tampering, side channel and signature forgeries, impersonation, and ephemeral key secret leakage attacks. In order to accomplish this, we have implemented a hardware-based physically unclonable function. Implementation has been carried using python language and deployed and tested on Blockchain using Ethereum Goerli’s Testnet framework. Performance analysis has been carried out by choosing various benchmarks and found that the proposed framework outperforms its counterparts through various metrics. Different parameters are also utilized to assess the performance of the proposed blockchain framework and shows that it has better performance in terms of computation, communication, storage and latency.

## Full-text entities

- **Genes:** GPR15 (G protein-coupled receptor 15) [NCBI Gene 2838] {aka BOB}
- **Diseases:** IoT (MESH:C000719207), BDC (MESH:C537093)
- **Chemicals:** Gas (MESH:D005708), ethers (MESH:D004987), CL-AtSe (-)
- **Cell lines:** S2 — Drosophila melanogaster (Fruit fly), Spontaneously immortalized cell line (CVCL_Z232)

## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/PMC10902399/full.md

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Source: https://tomesphere.com/paper/PMC10902399