Coordinated Optimization of Generation and Compensation to Enhance Short-Term Voltage Security of Power Systems Using Accelerated Multi-Objective Reinforcement Learning

Deng, Zhuoming; Lu, Zhilin; Guo, Zhifei; Yao, Wei; Zhao, Wei; Zhou, Baorong; Cao, Hong

doi:10.1109/access.2020.2974503

Cited by 9 publications

(4 citation statements)

References 21 publications

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“…In addition to the motivating examples discussed above, recent years have seen multiobjective learning and planning methods applied across a wide range of problem domains including: distributed computing [27,124], drug and molecule design [62,214], cybersecurity [162], simulation [132], job shop scheduling [98], cognitive radio networks [100,129], satellite communications [45,63], recommender systems [78], power systems [34,35,97,193], building management [213], traffic management [70], manufacturing [36,54,80], bidding and pricing [76,207], education [151], and robotics [64]. The scope and variety of these applications supports our assertion that many important problems involve multiple objectives, and are best addressed using explicitly multi-objective methods.…”

Section: Other Topicsmentioning

confidence: 99%

A practical guide to multi-objective reinforcement learning and planning

Hayes

Rădulescu

Bargiacchi

et al. 2022

Auton Agent Multi-Agent Syst

151

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Real-world sequential decision-making tasks are generally complex, requiring trade-offs between multiple, often conflicting, objectives. Despite this, the majority of research in reinforcement learning and decision-theoretic planning either assumes only a single objective, or that multiple objectives can be adequately handled via a simple linear combination. Such approaches may oversimplify the underlying problem and hence produce suboptimal results. This paper serves as a guide to the application of multi-objective methods to difficult problems, and is aimed at researchers who are already familiar with single-objective reinforcement learning and planning methods who wish to adopt a multi-objective perspective on their research, as well as practitioners who encounter multi-objective decision problems in practice. It identifies the factors that may influence the nature of the desired solution, and illustrates by example how these influence the design of multi-objective decision-making systems for complex problems.

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Section: Other Topicsmentioning

confidence: 99%

A practical guide to multi-objective reinforcement learning and planning

Hayes

Rădulescu

Bargiacchi

et al. 2022

Auton Agent Multi-Agent Syst

151

View full text Add to dashboard Cite

show abstract

“…In addition to the motivating examples discussed above, recent years have seen multi-objective learning and planning methods applied across a wide range of problem domains including: distributed computing [Qin et al, 2020, da Silva Veith et al, 2019, drug and molecule design [Zhou et al, 2019, Horwood andNoutahi, 2020], cybersecurity [Sun et al, 2018], simulation [Ravichandran et al, 2018], job shop scheduling [Méndez-Hernández et al, 2019], cognitive radio networks [Messikh andZarour, 2018, Raj et al, 2020], satellite communications [Hu et al, 2020, Ferreira et al, 2019, recommender systems [Lacerda, 2017], power systems [Deng and Liu, 2018, Deng et al, 2020, Wang et al, 2019, Mello et al, 2020, building management , traffic management [Jin and Ma, 2019], manufacturing [Govindaiah and Petty, 2019, Lepenioti et al, 2020, Dornheim and Link, 2018, bidding and pricing [Yang et al, 2020, Krasheninnikova et al, 2019, education [Rowe et al, 2018], and robotics [Huang et al, 2019]. The scope and variety of these applications supports our assertion that many important problems involve multiple objectives, and are best addressed using explicitly multi-objective methods.…”

Section: Other Topicsmentioning

confidence: 99%

A Practical Guide to Multi-Objective Reinforcement Learning and Planning

Hayes,

Rădulescu,

Bargiacchi

et al. 2021

Preprint

View full text Add to dashboard Cite

Real-world decision-making tasks are generally complex, requiring trade-offs between multiple, often conflicting, objectives. Despite this, the majority of research in reinforcement learning and decision-theoretic planning either assumes only a single objective, or that multiple objectives can be adequately handled via a simple linear combination. Such approaches may oversimplify the underlying problem and hence produce suboptimal results. This paper serves as a guide to the application of multi-objective methods to difficult problems, and is aimed at researchers who are already familiar with single-objective reinforcement learning and planning methods who wish to adopt a multi-objective perspective on their research, as well as practitioners who encounter multiobjective decision problems in practice. It identifies the factors that may influence the nature of the desired solution, and illustrates by example how these influence the design of multi-objective decision-making systems for complex problems.

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“…The dynamic-based method includes a set of differential algebraic equations (DAEs) defining system dynamics [51][52][53][54]. It does not consider the required VSM but dynamic voltage stability.…”

Section: Related Workmentioning

confidence: 99%

“…Geng et al [52] proposed a hybrid method of dynamic simulation and direct method that solves discretised DAE as non‐linear programming. The authors in [53, 54] proposed a method converting DAE to non‐linear programming to be solved by artificial intelligence.…”

Section: Introductionmentioning

confidence: 99%

Modified tangent vector‐based voltage stability constrained optimal power flow considering limit‐induced bifurcation

Omi

Shirai

2020

IET Generation, Transmission & Distribution

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A modified tangent vector (TV)-based voltage stability constrained optimal power flow method is proposed. The proposed method determines an optimal stable equilibrium point (SEP) satisfying the required voltage stability margin (VSM) considering limit-induced bifurcation (LIB). LIB, which occurs when a generator reaches a reactive power limit during load increasing, may cause an optimistic overestimation of voltage stability and inadequate operation. The key of the proposed method is to use approximated TV for considering LIB as a voltage stability constraint to ensure that the solution becomes an SEP and to avoid inappropriate operation caused by LIB. The validity of the approximation is evaluated analytically and numerically in this study. The threshold for the approximated TV is updated based on the continuation power flow calculation result to satisfy the required VSM. The proposed method was implemented on MATPOWER, and evaluated with a 2-machine 4bus system and an IEEJ standard WEST10-O/V system. The results show that the proposed method can determine the optimal SEP satisfying the required VSM even if LIB occurs.

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Coordinated Optimization of Generation and Compensation to Enhance Short-Term Voltage Security of Power Systems Using Accelerated Multi-Objective Reinforcement Learning

Cited by 9 publications

References 21 publications

A practical guide to multi-objective reinforcement learning and planning

A practical guide to multi-objective reinforcement learning and planning

A Practical Guide to Multi-Objective Reinforcement Learning and Planning

Modified tangent vector‐based voltage stability constrained optimal power flow considering limit‐induced bifurcation

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