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Secure operation of a stand-alone wind energy system based on an incommensurate fractional-order chaotic system

Secure operation of a stand-alone wind energy system based on an incommensurate fractional-order chaotic system
Secure operation of a stand-alone wind energy system based on an incommensurate fractional-order chaotic system
Cybersecurity for wind energy conversion systems, such as Stand-Alone Wind Energy Conversion Systems (SAWECSs) that use Self-Excited Induction Generators (SEIGs), has been a growing area of focus recently. Despite their advantages such as robust structure, low cost, minimal maintenance, and the ability to operate at varying wind speeds, SEIG-based SAWECSs rely on effective reactive power management to maintain output voltage stability. As modern technologies become more integrated into SAWECS, controlling the output voltage becomes increasingly challenging, which makes the system more vulnerable to cyber-attacks. To ensure the cybersecurity of SEIG-based SAWECS, this study proposes a novel approach, a chaotic system-based secure communication algorithm derived from the interaction between dark matter and dark energy (DM-DE). This algorithm utilizes fractional calculus to increase the complexity of chaotic flows, thereby strengthening the robustness of secure communication. The effectiveness of the proposed approach is verified through detailed analyses and simulation studies, demonstrating its capability to maintain system stability and security. The chaos-based secure operation algorithm is then tested and validated using a SAWECS comprising a 3-phase, 400V, 50 Hz SEIG with resistive-inductive loads. It is observed that the experimental results are consistent with the simulation results. This work demonstrates that chaotic system-based approaches can be used to enhance the cybersecurity of renewable energy systems.
Chaos, Cybersecurity, Fractional calculus, Renewable energy
0306-2619
Demirtas, Metin
82db9bcc-20a6-474b-a2d3-99fac09466d2
Sharkh, Suleiman
c8445516-dafe-41c2-b7e8-c21e295e56b9
Gokyildirim, Abdullah
288f6724-e83e-4491-a2cc-99e066d32929
Calgan, Haris
fdece2cb-0b11-46b9-9e7c-084af88fe978
Demirtas, Metin
82db9bcc-20a6-474b-a2d3-99fac09466d2
Sharkh, Suleiman
c8445516-dafe-41c2-b7e8-c21e295e56b9
Gokyildirim, Abdullah
288f6724-e83e-4491-a2cc-99e066d32929
Calgan, Haris
fdece2cb-0b11-46b9-9e7c-084af88fe978

Demirtas, Metin, Sharkh, Suleiman, Gokyildirim, Abdullah and Calgan, Haris (2025) Secure operation of a stand-alone wind energy system based on an incommensurate fractional-order chaotic system. Applied Energy, 384, [125477]. (doi:10.1016/j.apenergy.2025.125477).

Record type: Article

Abstract

Cybersecurity for wind energy conversion systems, such as Stand-Alone Wind Energy Conversion Systems (SAWECSs) that use Self-Excited Induction Generators (SEIGs), has been a growing area of focus recently. Despite their advantages such as robust structure, low cost, minimal maintenance, and the ability to operate at varying wind speeds, SEIG-based SAWECSs rely on effective reactive power management to maintain output voltage stability. As modern technologies become more integrated into SAWECS, controlling the output voltage becomes increasingly challenging, which makes the system more vulnerable to cyber-attacks. To ensure the cybersecurity of SEIG-based SAWECS, this study proposes a novel approach, a chaotic system-based secure communication algorithm derived from the interaction between dark matter and dark energy (DM-DE). This algorithm utilizes fractional calculus to increase the complexity of chaotic flows, thereby strengthening the robustness of secure communication. The effectiveness of the proposed approach is verified through detailed analyses and simulation studies, demonstrating its capability to maintain system stability and security. The chaos-based secure operation algorithm is then tested and validated using a SAWECS comprising a 3-phase, 400V, 50 Hz SEIG with resistive-inductive loads. It is observed that the experimental results are consistent with the simulation results. This work demonstrates that chaotic system-based approaches can be used to enhance the cybersecurity of renewable energy systems.

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More information

Accepted/In Press date: 31 January 2025
e-pub ahead of print date: 12 February 2025
Published date: 15 April 2025
Additional Information: Publisher Copyright: © 2025 Elsevier Ltd
Keywords: Chaos, Cybersecurity, Fractional calculus, Renewable energy

Identifiers

Local EPrints ID: 498715
URI: http://eprints.soton.ac.uk/id/eprint/498715
DOI: doi:10.1016/j.apenergy.2025.125477
ISSN: 0306-2619
PURE UUID: b8b067d1-e575-43d2-8025-ba66804f6ecb
ORCID for Suleiman Sharkh: ORCID iD orcid.org/0000-0001-7335-8503

Catalogue record

Date deposited: 25 Feb 2025 18:09
Last modified: 26 Feb 2025 02:35

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Contributors

Author: Metin Demirtas
Author: Suleiman Sharkh ORCID iD
Author: Abdullah Gokyildirim
Author: Haris Calgan

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