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dc.contributor.advisorMorales-González, Juan Miguel 
dc.contributor.advisorPineda-Morente, Salvador 
dc.contributor.authorPorras Cabrera, Alvaro
dc.contributor.otherIngeniería Eléctricaes_ES
dc.date.accessioned2024-02-22T11:56:40Z
dc.date.available2024-02-22T11:56:40Z
dc.date.created2023-07-25
dc.date.issued2024
dc.date.submitted2023-09-22
dc.identifier.urihttps://hdl.handle.net/10630/30606
dc.descriptionMost of the existing joint chance-constrained OPF models provide a limited vision of power systems operation, since, under extreme circumstances, these approaches may leave the system vulnerable. Otherwise, ensuring the system's security for the whole spectrum of uncertainty realizations would result in excessive operating costs. To circumvent such a caveat, we introduce a novel stochastic OPF model that integrates both automatic and manual reserves.es_ES
dc.description.abstractPower systems are among the most complex and colossal engineering structures in modern society, whose operation implies a challenge due to the coordination of multiple generating units to ensure a safe and dependable energy supply. In the last decades, significant changes have occurred in power systems globally with the purpose of transitioning to sustainable systems, which has brought about new challenges in their operation. In this context, this thesis tackles two of the most significant problems in power system operations, namely, the unit commitment (UC) and the optimal power flow (OPF). Both UC and OPF constitute optimization problems that pose considerable computational challenges. Firstly, UC requires the use of binary variables to model the on/off state of generating units, resulting in a combinatorial decision-making process that incurs a significant computational burden. Furthermore, addressing network constraints escalates the complexity of attaining an optimal solution. Leveraging the fact that most transmission lines are oversized in today's power systems, this thesis introduces a cost-driven optimization approach aimed at eliminating superfluous network-constraints, leading to a notable reduction in the computational burden associated with UC. Secondly, OPF problems often involve the incorporation of stochastic factors, demanding a sophisticated modeling approach to capture their impact. In line with a current trend, we resort to the joint chance-constrained OPF model that improves the power systems operation disregarding system's security in low probable, high impact uncertainty realizations. Without a finite, tractable reformulation, we use the sample average approximation which produces a mixed-integer problem cursed by big-Ms. To solve it efficiently, in this thesis, we propose a novel methodology based on a tightening-and-screening procedure and valid inequalities.es_ES
dc.language.isoenges_ES
dc.publisherUMA Editoriales_ES
dc.rightsinfo:eu-repo/semantics/openAccesses_ES
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/*
dc.subjectEnergía eléctrica - Producción - Tesis doctoraleses_ES
dc.subjectProgramación de enteros - Tesis doctoraleses_ES
dc.subjectSistemas electroenergéticos - Tesis doctoraleses_ES
dc.subject.otherPower systems operationes_ES
dc.subject.otherUnit commitmentes_ES
dc.subject.otherOptimal power flowes_ES
dc.subject.otherChance-constraintses_ES
dc.subject.otherMixed-integer programses_ES
dc.titleTight and Compact Models for Power Systems Operation.es_ES
dc.typeinfo:eu-repo/semantics/doctoralThesises_ES
dc.centroEscuela de Ingenierías Industrialeses_ES
dc.rights.ccAttribution-NonCommercial-NoDerivatives 4.0 Internacional*


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