Cyber-Resilience Enhancement and Protection for Uneconomic Power Dispatch Under Cyber-Attacks

Zhao, Pengfei; Gu, Chenghong; Ding, Yucheng; Liu, Hong; Bian, Yuankai; Li, Shuangqi

doi:10.1109/tpwrd.2020.3038065

Cited by 15 publications

(9 citation statements)

References 40 publications

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“…It is known from Reference 27 that the following assumptions are required to accurately estimate the system states via UIO (7):…”

Section: Traditional Uio-based Attack Detectionmentioning

confidence: 99%

“…It is easy to verify that Assumption 1 is true with C i and Ξ i given in (2) and ( 5), respectively. Under Assumption 2, we can decompose T i as T i = T 1 i + T 2 i , and design these matrices in (7) by the following expressions…”

Section: Traditional Uio-based Attack Detectionmentioning

confidence: 99%

“…Suppose that the malicious attacks on three areas are: y a 1 (t) = [0.2(t − 2) 0.4(t − 2)] ⊤ for t ≥ 2 s; y a 2 (t) = [0.1 cos(t) 0.3 sin(t)] ⊤ for t ≥ 4 s; y a 3 (t) = [0.1 0.3] ⊤ for t ≥ 7 s, respectively. The comparison detection results between the proposed UI-SMO ( 13) and the traditional UIO (7) are shown in Figures 4-6, in which the detection residual thresholds for the traditional UIO (7) based on (12) are given as (for i = 1, 2, 3):…”

Section: Simulationmentioning

confidence: 99%

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Decentralized attack detection for multi‐area power systems via interconnection‐decoupled sliding mode observer

Niu

2023

Intl J Robust & Nonlinear

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This article deals with the false data injection attack (FDIA) detection problem for multi-area power systems. Considering the large-scale characteristic of the multi-area power systems, a novel decentralized detection scheme is proposed to detect FDIAs. First, an unknown input sliding mode observer (UI-SMO) is designed to decouple the interconnected terms, meanwhile, a robust term in the UI-SMO can attenuate the effect of the load variation, by which the obtained residual is only sensitive to local FDIAs. The strict reachability of the sliding surface in the estimate error space is ensured by the robust term with an auxiliary variable, and the stability of the sliding mode dynamics is achieved. Then, a detection logic is delicately designed based on a two-phase residual threshold. Due to the strong attenuating ability to load variation, the proposed detection scheme shows better detectability than some existing works with only decoupling interconnections. Finally, the theoretical results are backed up by a three-area power system simulation with comparison between proposed UI-SMO-based and traditional UIO-based detection scheme.

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“…It is known from Reference 27 that the following assumptions are required to accurately estimate the system states via UIO (7):…”

Section: Traditional Uio-based Attack Detectionmentioning

confidence: 99%

Section: Traditional Uio-based Attack Detectionmentioning

confidence: 99%

Section: Simulationmentioning

confidence: 99%

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Decentralized attack detection for multi‐area power systems via interconnection‐decoupled sliding mode observer

Niu

2023

Intl J Robust & Nonlinear

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“…When a smart grid is under false data injection attack, its optimal operation differs from the normal condition. A twostage distributionally robust optimization model for economic dispatch of power systems under the load redistribution attack is proposed in [85], which also considers uncertainties of renewable energy sources. The model schedules on day-ahead and real-time basis in the first and second stages, respectively, and finds a less conservative dispatch solution in comparison with robust optimization.…”

Section: B Optimal Dispatch Of An Attacked Power Systemmentioning

confidence: 99%

“…Ref. [22] deploys Bender's decomposition technique to solve the MINLP problem, while the column and constraint generation method is used in [2], [23], [85] to solve multi-level models. Both decomposition techniques find the optimal solution in an iterative way.…”

Section: Solving Optimization Problems In Cppsmentioning

confidence: 99%

Optimization Models in Cyber-Physical Power Systems: A Review

et al. 2022

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The growing interconnection between information networks and power grids enables a more efficient and economical operation, but also introduces significant challenges in modern cyber-physical power systems, such as malicious cyber-attacks. Several cyber-attacks have been reported in the recent decade, affecting hundreds of thousands of people. These attacks can lead to large power system blackouts, and optimization models are essential tools for optimal decision-making in reliable and secure operation of cyber-physical power systems. In this paper, optimization models in cyber-physical power systems are extensively reviewed and classified based on their applications, including cyber-security and optimal operation. One major application of optimization is in cyber-security evaluation of smart grids. This paper investigates the models to implement cyber-attacks against state estimation, coordinated cyber-physical attacks aiming to cover each other, and financially-motivated attacks in electricity markets; optimal defense strategies and interactions between the attacker and the defender are also introduced. Furthermore, optimization models used in the operation and dispatching of cyber-physical power and energy systems, optimal routing of information networks, and privacy-preserving models are presented. Finally, as solving optimization models is a crucial step in optimal decision-making, solvers in the literature are also introduced.

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