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Lightweight and roubust key agreement for securing IIoT-driven flexible manufacturing systems

Lightweight and roubust key agreement for securing IIoT-driven flexible manufacturing systems
Lightweight and roubust key agreement for securing IIoT-driven flexible manufacturing systems
The ever-evolving Internet of Things (IoT) has ushered in a new era of intelligent manufacturing across multiple industries. However, the security and privacy of realtime data transmitted over the public channel of the industrial IoT (IIoT) remain formidable challenges. Existing lightweight protocols often omit one or more critical security features, such as anonymity and untraceability, and are susceptible to threats like desynchronization attacks. Additionally, they struggle to achieve an optimal balance between robust security and performance efficiency. To bridge these gaps, we introduce a new lightweight key agreement security scheme that guarantees secure access to the IIoT-enabled flexible manufacturing system (FMS). The strength of our scheme lies in its utilization of the authenticated encryption with associative data (AEAD) primitive, AEGIS, along with hash functions and physical unclonable functions, which secure the IIoT ecosystem. Additionally, our scheme offers flexibility in the form of the addition of new machines, password updates, and revocation in cases of theft or loss. A comprehensive security analysis demonstrates the efficacy of the proposed scheme in thwarting various attacks. The formal analysis, based on the Real-Or-Random (RoR) model, ensures session key indistinguishability, while the informal analysis highlights its resilience against known attacks. The comparative assessment demonstrate that the proposed scheme consistently outperforms the benchmark schemes across multiple dimensions, including security and functionality features, computational and communication overheads, and runtime efficiency. Specifically, the proposed scheme achieves peak performance enhancements of 77.55%, 44.73%, and 69.6% in computational overhead, runtime overhead, and communication overhead, respectively, underscoring its substantial performance advantages.
Industrial Internet of Things, flexible manufacturing system, physical unclonable functions, security, user authentication, Flexible manufacturing system (FMS), Industrial Internet of Things (IIoT), physical unclonable functions (PUFs)
2327-4662
17197-17209
Hammad, Muhammad
607d27f6-b565-4b3d-b3d9-897ac68cbaac
Badshah, Akhtar
f81ea725-6d13-4aa6-b9fb-3822f83778d8
Almeer, Mohammed A.
eb1e6346-311e-4a79-9fcb-e287b7768821
Waqas, Muhammad
28f978b5-2da0-4060-aa7c-d5cadc1a48e1
Song, Houbing
ff74a730-67e2-42f3-a74a-31e944b5aff7
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Han, Zhu
28e29deb-d470-4165-b198-0923aeac3689
Hammad, Muhammad
607d27f6-b565-4b3d-b3d9-897ac68cbaac
Badshah, Akhtar
f81ea725-6d13-4aa6-b9fb-3822f83778d8
Almeer, Mohammed A.
eb1e6346-311e-4a79-9fcb-e287b7768821
Waqas, Muhammad
28f978b5-2da0-4060-aa7c-d5cadc1a48e1
Song, Houbing
ff74a730-67e2-42f3-a74a-31e944b5aff7
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Han, Zhu
28e29deb-d470-4165-b198-0923aeac3689

Hammad, Muhammad, Badshah, Akhtar, Almeer, Mohammed A., Waqas, Muhammad, Song, Houbing, Chen, Sheng and Han, Zhu (2025) Lightweight and roubust key agreement for securing IIoT-driven flexible manufacturing systems. IEEE Internet of Things Journal, 12 (11), 17197-17209. (doi:10.1109/JIOT.2025.3535846).

Record type: Article

Abstract

The ever-evolving Internet of Things (IoT) has ushered in a new era of intelligent manufacturing across multiple industries. However, the security and privacy of realtime data transmitted over the public channel of the industrial IoT (IIoT) remain formidable challenges. Existing lightweight protocols often omit one or more critical security features, such as anonymity and untraceability, and are susceptible to threats like desynchronization attacks. Additionally, they struggle to achieve an optimal balance between robust security and performance efficiency. To bridge these gaps, we introduce a new lightweight key agreement security scheme that guarantees secure access to the IIoT-enabled flexible manufacturing system (FMS). The strength of our scheme lies in its utilization of the authenticated encryption with associative data (AEAD) primitive, AEGIS, along with hash functions and physical unclonable functions, which secure the IIoT ecosystem. Additionally, our scheme offers flexibility in the form of the addition of new machines, password updates, and revocation in cases of theft or loss. A comprehensive security analysis demonstrates the efficacy of the proposed scheme in thwarting various attacks. The formal analysis, based on the Real-Or-Random (RoR) model, ensures session key indistinguishability, while the informal analysis highlights its resilience against known attacks. The comparative assessment demonstrate that the proposed scheme consistently outperforms the benchmark schemes across multiple dimensions, including security and functionality features, computational and communication overheads, and runtime efficiency. Specifically, the proposed scheme achieves peak performance enhancements of 77.55%, 44.73%, and 69.6% in computational overhead, runtime overhead, and communication overhead, respectively, underscoring its substantial performance advantages.

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Accepted/In Press date: 24 January 2025
e-pub ahead of print date: 28 January 2025
Published date: 22 May 2025
Keywords: Industrial Internet of Things, flexible manufacturing system, physical unclonable functions, security, user authentication, Flexible manufacturing system (FMS), Industrial Internet of Things (IIoT), physical unclonable functions (PUFs)
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Identifiers

Local EPrints ID: 498608
URI: http://eprints.soton.ac.uk/id/eprint/498608
DOI: doi:10.1109/JIOT.2025.3535846
ISSN: 2327-4662
PURE UUID: aed9fa19-f2d0-4979-b5b0-71f5b0afe610

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Date deposited: 24 Feb 2025 17:38
Last modified: 29 Aug 2025 16:57

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Contributors

Author: Muhammad Hammad
Author: Akhtar Badshah
Author: Mohammed A. Almeer
Author: Muhammad Waqas
Author: Houbing Song
Author: Sheng Chen
Author: Zhu Han

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