CASCADED SECURE STATE ESTIMATIONS AS CYBER RESILIENCE AGAINST SENSOR AND ACTUATOR ATTACKS ON AUTONOMOUS SYSTEMS
The emergence of autonomous systems in various industrial sectors has resulted in increased efficiency and safety in operations. The Industrial Revolution 4.0 provides a foundation for applying the digitization of various autonomous systems, optimizing processes, and creating opportunities for im...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/84189 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The emergence of autonomous systems in various industrial sectors has resulted in
increased efficiency and safety in operations. The Industrial Revolution 4.0
provides a foundation for applying the digitization of various autonomous systems,
optimizing processes, and creating opportunities for implementing smart
industries. However, the increasing reliance on digital technology in industrial
activities makes autonomous systems vulnerable to cyber threats. In particular,
threats or attacks on sensors and actuators pose a significant risk of direct harmful
consequences. This research focuses on addressing this challenge by developing
cascaded secure state estimation methods designed to improve cyber defense
against sensor and actuator attacks on autonomous systems. The proposed
cascaded secure state estimations, in the form of two nonlinear observers, is
developed to estimate the true state of the system and the magnitude of the attack
on the sensors and actuators by each observer. In this development process, the
necessary conditions to ensure the convergence and stability of the state estimation
and attack estimation are formulated as a linear matrix inequality. Validation of
this secure state estimation method for its efficacy is conducted through
implementation on autonomous vehicles, such as numerical simulations on an
autonomous container truck and experimental testing on an autonomous container
truck under sensor and actuator attacks. The implementation results show high true
state estimation accuracy and similarly for estimating the magnitude of sensor and
actuator attacks. This method yields an RMSE of 2.77 m and 0.0983 rad for position
and orientation sensor attack estimation, and errors of 0.1079 m and 0.0143 rad
for actuator attack impacts estimation in a simulated autonomous container truck.
In experiments, it achieved a trajectory lateral error of 0.0245 m and an orientation
error of 0.0054 rad. These results demonstrate the potential for significantly
improving the security and reliability of autonomous system implementations
against sensor and actuator attacks. |
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