Constraining attacker capabilities through actuator saturation

Sahand Hadizadeh Kafash; Jairo Giraldo; Carlos Murguia; Alvaro A. Cardenas; Justin Ruths

Constraining attacker capabilities through actuator saturation

Sahand Hadizadeh Kafash
, Jairo Giraldo
, Carlos Murguia
, Alvaro A. Cardenas
, Justin Ruths

Research output: Contribution to journal › Article › Academic

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Abstract

For LTI control systems, we provide mathematical tools - in terms of Linear Matrix Inequalities - for computing outer ellipsoidal bounds on the reachable sets that attacks can induce in the system when they are subject to the physical limits of the actuators. Next, for a given set of dangerous states, states that (if reached) compromise the integrity or safe operation of the system, we provide tools for designing new artificial limits on the actuators (smaller than their physical bounds) such that the new ellipsoidal bounds (and thus the new reachable sets) are as large as possible (in terms of volume) while guaranteeing that the dangerous states are not reachable. This guarantees that the new bounds cut as little as possible from the original reachable set to minimize the loss of system performance. Computer simulations using a platoon of vehicles are presented to illustrate the performance of our tools.

Original language	English
Article number	1710.02565vl
Number of pages	8
Journal	arXiv
Publication status	Published - 1 Oct 2017
Externally published	Yes

Keywords

Computer Science - Systems and Control
Mathematics - Dynamical Systems
Mathematics - Optimization and Control

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abstract = "For LTI control systems, we provide mathematical tools - in terms of Linear Matrix Inequalities - for computing outer ellipsoidal bounds on the reachable sets that attacks can induce in the system when they are subject to the physical limits of the actuators. Next, for a given set of dangerous states, states that (if reached) compromise the integrity or safe operation of the system, we provide tools for designing new artificial limits on the actuators (smaller than their physical bounds) such that the new ellipsoidal bounds (and thus the new reachable sets) are as large as possible (in terms of volume) while guaranteeing that the dangerous states are not reachable. This guarantees that the new bounds cut as little as possible from the original reachable set to minimize the loss of system performance. Computer simulations using a platoon of vehicles are presented to illustrate the performance of our tools.",

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T1 - Constraining attacker capabilities through actuator saturation

AU - Hadizadeh Kafash, Sahand

AU - Giraldo, Jairo

AU - Murguia, Carlos

AU - Cardenas, Alvaro A.

AU - Ruths, Justin

PY - 2017/10/1

Y1 - 2017/10/1

N2 - For LTI control systems, we provide mathematical tools - in terms of Linear Matrix Inequalities - for computing outer ellipsoidal bounds on the reachable sets that attacks can induce in the system when they are subject to the physical limits of the actuators. Next, for a given set of dangerous states, states that (if reached) compromise the integrity or safe operation of the system, we provide tools for designing new artificial limits on the actuators (smaller than their physical bounds) such that the new ellipsoidal bounds (and thus the new reachable sets) are as large as possible (in terms of volume) while guaranteeing that the dangerous states are not reachable. This guarantees that the new bounds cut as little as possible from the original reachable set to minimize the loss of system performance. Computer simulations using a platoon of vehicles are presented to illustrate the performance of our tools.

AB - For LTI control systems, we provide mathematical tools - in terms of Linear Matrix Inequalities - for computing outer ellipsoidal bounds on the reachable sets that attacks can induce in the system when they are subject to the physical limits of the actuators. Next, for a given set of dangerous states, states that (if reached) compromise the integrity or safe operation of the system, we provide tools for designing new artificial limits on the actuators (smaller than their physical bounds) such that the new ellipsoidal bounds (and thus the new reachable sets) are as large as possible (in terms of volume) while guaranteeing that the dangerous states are not reachable. This guarantees that the new bounds cut as little as possible from the original reachable set to minimize the loss of system performance. Computer simulations using a platoon of vehicles are presented to illustrate the performance of our tools.

KW - Computer Science - Systems and Control

KW - Mathematics - Dynamical Systems

KW - Mathematics - Optimization and Control

UR - https://ui.adsabs.harvard.edu/abs/2017arXiv171002576H/abstract

M3 - Article

JO - arXiv

JF - arXiv

M1 - 1710.02565vl

ER -

Constraining attacker capabilities through actuator saturation

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Keywords

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