Zero-Sum Game-Based Optimal Secure Control under Actuator Attacks

Journal article (2021)

Authors

C. Wu Harbin Institute of Technology
Xiaolei Li Harbin Institute of Technology
W. Pan Robot Dynamics - Mechanical, Maritime and Materials Engineering
Jianxing Liu Harbin Institute of Technology
Ligang Wu Harbin Institute of Technology
Research Group
Robot Dynamics (Mechanical, Maritime and Materials Engineering) (TU Delft)
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Published Date

2021

Language

English

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Faculty

Mechanical, Maritime and Materials Engineering

Department

Cognitive Robotics

Research Group

Robot Dynamics

Abstract

This article investigates the zero-sum game-based secure control problem for cyber-physical systems (CPS) under the actuator false data injection attacks. The physical process is described as a linear time-invariant discrete-time model. Both the process noise and the measurement noise are addressed in the design process. An optimal Kalman filter is given to estimate the system states. The adversary and the defender are modeled as two players. Under the zero-sum game framework, an optimal infinite-horizon quadratic cost function is defined. Employing the dynamic programming approach, the optimal defending policy and the attack policy are derived. The convergence of the cost function is proved. Moreover, the critical attack probability is derived, beyond which the cost cannot be bounded. Finally, simulation results are provided to validate the proposed secure scheme.

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