Solving security constrained optimal power flow problems: a hybrid evolutionary approach

Carolina G. Marcelino; Paulo E.M. Almeida; Elizabeth F. Wanner; Manuel Baumann; Marcel Weil; Leonel M. Carvalho; Vladimiro Miranda

doi:10.1007/s10489-018-1167-5

Solving security constrained optimal power flow problems: a hybrid evolutionary approach

Carolina G. Marcelino, Paulo E.M. Almeida, Elizabeth F. Wanner, Manuel Baumann, Marcel Weil, Leonel M. Carvalho, Vladimiro Miranda

Resultado de pesquisa › revisão de pares

40 Citações (Scopus)

Resumo

A hybrid population-based metaheuristic, Hybrid Canonical Differential Evolutionary Particle Swarm Optimization (hC-DEEPSO), is applied to solve Security Constrained Optimal Power Flow (SCOPF) problems. Despite the inherent difficulties of tackling these real-world problems, they must be solved several times a day taking into account operation and security conditions. A combination of the C-DEEPSO metaheuristic coupled with a multipoint search operator is proposed to better exploit the search space in the vicinity of the best solution found so far by the current population in the first stages of the search process. A simple diversity mechanism is also applied to avoid premature convergence and to escape from local optima. A experimental design is devised to fine-tune the parameters of the proposed algorithm for each instance of the SCOPF problem. The effectiveness of the proposed hC-DEEPSO is tested on the IEEE 57-bus, IEEE 118-bus and IEEE 300-bus standard systems. The numerical results obtained by hC-DEEPSO are compared with other evolutionary methods reported in the literature to prove the potential and capability of the proposed hC-DEEPSO for solving the SCOPF at acceptable economical and technical levels.

Idioma original	Inglês
Páginas (de-até)	3672-3690
Número de páginas	19
Revista	Applied Intelligence
Volume	48
Número de emissão	10
DOIs	https://doi.org/10.1007/s10489-018-1167-5
Estado da publicação	Publicadas - 1 out. 2018
Publicado externamente	Sim

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Publisher Copyright:
© 2018, Springer Science+Business Media, LLC, part of Springer Nature.

Financiamento

Financiadoras/-es	Número do financiador
CEFET-MG
Helmholtz-Project Energy System
INESC TEC
ITAS
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior
Conselho Nacional de Desenvolvimento Científico e Tecnológico
Fundação de Amparo à Pesquisa do Estado de Minas Gerais

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10.1007/s10489-018-1167-5

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title = "Solving security constrained optimal power flow problems: a hybrid evolutionary approach",

abstract = "A hybrid population-based metaheuristic, Hybrid Canonical Differential Evolutionary Particle Swarm Optimization (hC-DEEPSO), is applied to solve Security Constrained Optimal Power Flow (SCOPF) problems. Despite the inherent difficulties of tackling these real-world problems, they must be solved several times a day taking into account operation and security conditions. A combination of the C-DEEPSO metaheuristic coupled with a multipoint search operator is proposed to better exploit the search space in the vicinity of the best solution found so far by the current population in the first stages of the search process. A simple diversity mechanism is also applied to avoid premature convergence and to escape from local optima. A experimental design is devised to fine-tune the parameters of the proposed algorithm for each instance of the SCOPF problem. The effectiveness of the proposed hC-DEEPSO is tested on the IEEE 57-bus, IEEE 118-bus and IEEE 300-bus standard systems. The numerical results obtained by hC-DEEPSO are compared with other evolutionary methods reported in the literature to prove the potential and capability of the proposed hC-DEEPSO for solving the SCOPF at acceptable economical and technical levels.",

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author = "Marcelino, {Carolina G.} and Almeida, {Paulo E.M.} and Wanner, {Elizabeth F.} and Manuel Baumann and Marcel Weil and Carvalho, {Leonel M.} and Vladimiro Miranda",

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AU - Weil, Marcel

AU - Carvalho, Leonel M.

AU - Miranda, Vladimiro

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Solving security constrained optimal power flow problems: a hybrid evolutionary approach

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