Improving the resilience of power grids against typhoons with data‐driven spatial distributionally robust optimization

Yin, Zhaoyuan; Fang, Chao; Yang, Hong; Fang, Yi-Ping; Xie, Min

doi:10.1111/risa.13995

Cited by 5 publications

(1 citation statement)

References 51 publications

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“…In contrast, in a decentralized approach, more than one decision‐maker with various objective functions is present in the system, presenting different attitudes regarding the others. Many studies have been conducted using bi‐level or tri‐level optimization, analyzing the problem of critical infrastructure network restoration after disruption in a centralized and decentralized environment, considering various assumptions while focusing on maximizing the resilience or minimizing the vulnerability of the network grid (Bell et al., 2008; Brown et al., 2006; Ghorbani‐Renani et al., 2020; 2021; Lo Prete & Radhakrishnan, 2023; Ouyang, 2017; Qiao et al., 2007; Yin et al., 2023; Zhao & Zeng, 2013). Note that high computation time is prevalent in this solution approach, especially when more than two decision‐makers are involved in the decision‐making environment (Gupta et al., 2015; Liu et al., 2021).…”

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confidence: 99%

Game‐theoretic algorithm for interdependent infrastructure network restoration in a decentralized environment

Rangrazjeddi,

González,

Barker

2024

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Having reliable interdependent infrastructure networks is vital for well‐being of a safe and productive society. Systems are vulnerable to failure or performance loss due to their interdependence among various networks, as each failure can propagate through the whole system. Although the conventional view has concentrated on optimizing the restoration of critical interdependent infrastructure networks using a centralized approach, having a lone actor as a decision‐maker in the system is substantially different from the actual restoration decision environment, wherein infrastructure utilities make their own decisions about how to restore their network service. In a decentralized environment, the definition of whole system optimality does not apply as each decision‐maker's interest may not converge with the others. Subsequently, this results in each decision‐maker developing its own reward functions. Therefore, in this study, we address the concern of having multiple decision‐makers with various payoff functions in interdependent networks by proposing a decentralized game theory algorithm for finding Nash equilibria solutions for network restoration in postdisaster situations.

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