A Systematic Review on Cascading Failures Models in Renewable Power Systems with Dynamics Perspective and Protections Modeling

Zakariya, Mohamad Zhafran; Teh, Jiashen

doi:10.1016/j.epsr.2022.108928

Cited by 19 publications

(4 citation statements)

References 188 publications

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“…Ref. [7][8][9][10][11][12][13][14][15] Studied the cascading failure and robustness of multilayer networks.…”

Section: Data Availability Statementmentioning

confidence: 99%

“…Adnan et al [10] reported a hybrid probabilistic modeling method to balance load flow and an assessment algorithm to describe the transient stability in multiple interdependent power grid cascading failures. Zakariya [11] discussed the interdependent power networks' cascading failure models in terms of features, limitations, and computational speed. Peng et al [12] proposed a model of double-layer network structure with simplicial complexes and discussed the higher-order interactions between the networks.…”

Section: Introductionmentioning

confidence: 99%

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Robustness of Double-Layer Group-Dependent Combat Network with Cascading Failure

Yu¹,

Xiao²,

Cui

2023

Electronics

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The networked combat system-of-system (CSOS) is the trend of combat development with the innovation of technology. To achieve the combat effectiveness, studying the ability of CSOS to cope with external interference is of great importance. Here we report a modeling method of CSOS from the perspective of complex networks and explore the robustness of the combat network based on this. Firstly, a more realistic double-layer heterogeneous dependent combat network model is established. Then, the conditional group dependency situation is considered to design failure rules for dependent failure, and the coupling relation between the double-layer subnets is analyzed for overload failure. Based on this, the initial load and capacity of the node are defined, respectively, as well as the load redistribution strategy and the status judgment rules for the cascading failure model. Simulation experiments are carried out by changing the attack modes and different parameters, and the results show that the robustness of the combat network can be effectively improved by improving the tolerance limit of one-way dependency of the functional net, the node capacity of the functional subnet, and the tolerance of the overload state. The conclusions of this paper can provide a useful reference for network structure optimization and network security protection in the military field.

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“…Ref. [7][8][9][10][11][12][13][14][15] Studied the cascading failure and robustness of multilayer networks.…”

Section: Data Availability Statementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Robustness of Double-Layer Group-Dependent Combat Network with Cascading Failure

Yu¹,

Xiao²,

Cui

2023

Electronics

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“…Large-scale power outages are usually caused by cascading failures (CF), which typically manifest as local disturbances such as generator failures and transmission line issues. These small disturbances gradually trigger CF of power grid components through grid connections, leading to malignant cascading reactions [1,2]. Therefore, it is crucial to quickly and accurately track the development path of CF, as well as develop targeted prevention and control strategies for CF and interruption control in accidents, to ensure the safe operation of the power system and reduce losses from power outages [3,4].…”

Section: Introductionmentioning

confidence: 99%

A Blocking Method for Overload-Dominant Cascading Failures in Power Grid Based on Source and Load Collaborative Regulation

Sun,

Liu,

Liu

et al. 2024

International Journal of Energy Research

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Adjusting generator output and cutting off load can effectively solve the problem of continuous overload and disconnection of power lines caused by power flow transfer. To suppress large-scale power outages caused by overload-dominant cascading failures, a blocking method for overload-dominant cascading failures in the power grid based on source and load collaborative regulation is proposed. The shortest path algorithm was used to identify loads and generators with shorter electrical distances from overloaded lines. Under the premise of meeting the static safety constraints of the power grid, considering the regulation of generator output and the removal of interruptible loads, a multiobjective cascading failure blocking model is established with the minimum overall control cost of the system and the minimum probability coefficient of line failure. Use the NSGA-II algorithm to solve the model and obtain the optimal plan for adjusting generator output and cutting off load. Through example verification, the proposed method can effectively alleviate the phenomenon of line overload, thereby blocking the continuation of overload-dominant cascading failures.

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“…The trend in measuring the resilience of intelligent infrastructure is toward more integrated and holistic approaches. This transition is primarily motivated by the realization that smart infrastructures are interdependent systems in which a disruption in one component can have cascading effects [12] throughout the entire network. Consequently, the traditional, isolated method of measuring resilience is being supplanted with methods that can capture these interdependencies.…”

Section: Introductionmentioning

confidence: 99%

Measuring Resilience in Smart Infrastructures: A Comprehensive Review of Metrics and Methods

Almaleh

2023

Applied Sciences

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In today’s world, the safety, economic prosperity, and social well-being of nations depend heavily on highly interconnected critical infrastructures. These infrastructures encompass power networks, natural gas systems, communication networks, water treatment facilities, and transportation systems. Gaining insight into the behavior of these infrastructures, particularly during stress or attacks, has become crucial for both the private and public sectors. Ensuring an adequate level of functionality during emergencies, such as disasters, is also a priority, which can be attained by enhancing infrastructure resilience. Resilience metrics and models play a significant role in understanding the complex interplay between the behaviors and operational characteristics of interdependent critical infrastructures. Additionally, these models and metrics must demonstrate the interdependencies among infrastructures to provide a more comprehensive representation of infrastructure resilience. This paper reviews, categorizes, and presents resilience metrics and models for Smart Interdependent Critical Infrastructures (Smart ICIs). This paper provides a comprehensive evaluation of various resilience models and measurements tailored specifically for interdependent critical smart infrastructures. It includes the essential terminology and definitions related to the resilience of Smart ICIs, investigates the universally recognized phases and capabilities of resilience, and examines the various types of failures that could potentially affect Smart ICIs.

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A Systematic Review on Cascading Failures Models in Renewable Power Systems with Dynamics Perspective and Protections Modeling

Cited by 19 publications

References 188 publications

Robustness of Double-Layer Group-Dependent Combat Network with Cascading Failure

Robustness of Double-Layer Group-Dependent Combat Network with Cascading Failure

A Blocking Method for Overload-Dominant Cascading Failures in Power Grid Based on Source and Load Collaborative Regulation

Measuring Resilience in Smart Infrastructures: A Comprehensive Review of Metrics and Methods

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