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Main Authors: Riya, Farhin Farhad, Hoque, Shahinul, Yang, Yingyuan, Li, Jiangnan, Sun, Jinyuan Stella, Qi, Hairong
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2301.12487
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author Riya, Farhin Farhad
Hoque, Shahinul
Yang, Yingyuan
Li, Jiangnan
Sun, Jinyuan Stella
Qi, Hairong
author_facet Riya, Farhin Farhad
Hoque, Shahinul
Yang, Yingyuan
Li, Jiangnan
Sun, Jinyuan Stella
Qi, Hairong
contents Deep Neural Networks have proven to be highly accurate at a variety of tasks in recent years. The benefits of Deep Neural Networks have also been embraced in power grids to detect False Data Injection Attacks (FDIA) while conducting critical tasks like state estimation. However, the vulnerabilities of DNNs along with the distinct infrastructure of the cyber-physical-system (CPS) can favor the attackers to bypass the detection mechanism. Moreover, the divergent nature of CPS engenders limitations to the conventional defense mechanisms for False Data Injection Attacks. In this paper, we propose a DNN framework with an additional layer that utilizes randomization to mitigate the adversarial effect by padding the inputs. The primary advantage of our method is when deployed to a DNN model it has a trivial impact on the model's performance even with larger padding sizes. We demonstrate the favorable outcome of the framework through simulation using the IEEE 14-bus, 30-bus, 118-bus, and 300-bus systems. Furthermore to justify the framework we select attack techniques that generate subtle adversarial examples that can bypass the detection mechanism effortlessly.
format Preprint
id arxiv_https___arxiv_org_abs_2301_12487
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Mitigating Adversarial Effects of False Data Injection Attacks in Power Grid
Riya, Farhin Farhad
Hoque, Shahinul
Yang, Yingyuan
Li, Jiangnan
Sun, Jinyuan Stella
Qi, Hairong
Cryptography and Security
Deep Neural Networks have proven to be highly accurate at a variety of tasks in recent years. The benefits of Deep Neural Networks have also been embraced in power grids to detect False Data Injection Attacks (FDIA) while conducting critical tasks like state estimation. However, the vulnerabilities of DNNs along with the distinct infrastructure of the cyber-physical-system (CPS) can favor the attackers to bypass the detection mechanism. Moreover, the divergent nature of CPS engenders limitations to the conventional defense mechanisms for False Data Injection Attacks. In this paper, we propose a DNN framework with an additional layer that utilizes randomization to mitigate the adversarial effect by padding the inputs. The primary advantage of our method is when deployed to a DNN model it has a trivial impact on the model's performance even with larger padding sizes. We demonstrate the favorable outcome of the framework through simulation using the IEEE 14-bus, 30-bus, 118-bus, and 300-bus systems. Furthermore to justify the framework we select attack techniques that generate subtle adversarial examples that can bypass the detection mechanism effortlessly.
title Mitigating Adversarial Effects of False Data Injection Attacks in Power Grid
topic Cryptography and Security
url https://arxiv.org/abs/2301.12487