Spatial-temporal security stability analysis and regulation against different types of attacks on industrial control systems

Zhaowen Feng; Guoyan Cao; Karolos M. Grigoriadis; Quan Pan

doi:10.1002/rnc.6955

Spatial-temporal security stability analysis and regulation against different types of attacks on industrial control systems

Zhaowen Feng, Guoyan Cao, Karolos M. Grigoriadis, Quan Pan

School of Automation

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

In this article, reaction-diffusion phenomena are considered in the security risk modeling of industrial control networks represented in the spatial-temporal domain. Different types of cyber-physical attacks, including TDS (time delay switch), FDI (false data injection), and DoS (denial of service), are modeled within a comprehensive parameteric-varying parabolic partial differential state-space structure. A theorem is proposed to ensure that the system is asymptotically stable with prescribed (Formula presented.) performance, which guarantees stability regardless of the various types of attacks. Finally, corresponding examples of risk control design against the different threats on industrial control networks are simulated to demonstrate the effectiveness of the results proposed in this article.

Original language	English
Pages (from-to)	11392-11410
Number of pages	19
Journal	International Journal of Robust and Nonlinear Control
Volume	33
Issue number	18
DOIs	https://doi.org/10.1002/rnc.6955
State	Published - Dec 2023

Keywords

industrial control systems
linear parametric varying control
reaction-diffusion
risk regulation
stability analysis

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10.1002/rnc.6955

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title = "Spatial-temporal security stability analysis and regulation against different types of attacks on industrial control systems",

abstract = "In this article, reaction-diffusion phenomena are considered in the security risk modeling of industrial control networks represented in the spatial-temporal domain. Different types of cyber-physical attacks, including TDS (time delay switch), FDI (false data injection), and DoS (denial of service), are modeled within a comprehensive parameteric-varying parabolic partial differential state-space structure. A theorem is proposed to ensure that the system is asymptotically stable with prescribed (Formula presented.) performance, which guarantees stability regardless of the various types of attacks. Finally, corresponding examples of risk control design against the different threats on industrial control networks are simulated to demonstrate the effectiveness of the results proposed in this article.",

keywords = "industrial control systems, linear parametric varying control, reaction-diffusion, risk regulation, stability analysis",

author = "Zhaowen Feng and Guoyan Cao and Grigoriadis, {Karolos M.} and Quan Pan",

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T1 - Spatial-temporal security stability analysis and regulation against different types of attacks on industrial control systems

AU - Feng, Zhaowen

AU - Cao, Guoyan

AU - Grigoriadis, Karolos M.

AU - Pan, Quan

PY - 2023/12

Y1 - 2023/12

N2 - In this article, reaction-diffusion phenomena are considered in the security risk modeling of industrial control networks represented in the spatial-temporal domain. Different types of cyber-physical attacks, including TDS (time delay switch), FDI (false data injection), and DoS (denial of service), are modeled within a comprehensive parameteric-varying parabolic partial differential state-space structure. A theorem is proposed to ensure that the system is asymptotically stable with prescribed (Formula presented.) performance, which guarantees stability regardless of the various types of attacks. Finally, corresponding examples of risk control design against the different threats on industrial control networks are simulated to demonstrate the effectiveness of the results proposed in this article.

AB - In this article, reaction-diffusion phenomena are considered in the security risk modeling of industrial control networks represented in the spatial-temporal domain. Different types of cyber-physical attacks, including TDS (time delay switch), FDI (false data injection), and DoS (denial of service), are modeled within a comprehensive parameteric-varying parabolic partial differential state-space structure. A theorem is proposed to ensure that the system is asymptotically stable with prescribed (Formula presented.) performance, which guarantees stability regardless of the various types of attacks. Finally, corresponding examples of risk control design against the different threats on industrial control networks are simulated to demonstrate the effectiveness of the results proposed in this article.

KW - industrial control systems

KW - linear parametric varying control

KW - reaction-diffusion

KW - risk regulation

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EP - 11410

JO - International Journal of Robust and Nonlinear Control

JF - International Journal of Robust and Nonlinear Control

IS - 18

ER -

Spatial-temporal security stability analysis and regulation against different types of attacks on industrial control systems

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